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ip € X}.
(ii) ^Fm + (£), ) «s an algebra of Boolean type that is absolutely freely generated by St. PROOF. Prove (i) by induction. Let S be the set appearing in the right-hand side of (4.14). Now Fm + (£) contains St and is closed under => and -i, but £ is the intersection of all such sets, so £ is included in all such sets, including Fm + (£). This shows S C Fm + (£). For the opposite inclusion, note first that AtFm + (£) C St C £, next, that S is closed under => and -i, and, finally, if ip € £ and x €V, then \/xip e St C £. Since Fm + (£) is the intersection of all sets that contain AtFm + (£) and are closed under => , -i, and Va, for all x 6 V, and S is such a set, it follows that Fm + (£) C S. Since Fm + (£) is closed under =^, we will use "=>" to denote not only the connective => but also the binary operation /3 on Fm + (£) defined by /3(ip,i/>) = (
ip) = , ( iP) = v( Sb (V), uniquely determined by the following rules. The only difference between the functions var(-) and free(-) is that the universal quantifier adds a variable, but subtracts a free variable. free(p) = var(^) ) is the set of variables of ) C V n }, Fm+ (m) (£) := { v = and ->, — is closed under Vj, whenever y £ var(t). The statement "t is free for x in t/j" is short for "i is free to be substituted for x in ip", that is, the computation of Subfi'ip) requires the rule (4.33) only when x £ var(t) or x £ free(tp). Substitution of a term for a variable when that term is not free to be substituted for that variable can have undesirable consequences. For example, a formula making an assertion about x may not make the same assertion about y if y is substituted for x when y is not free for x. For example, the variable y is not free to be substituted for x in MyRxy. The result of making such a substitution anyway is the formula Suby(VyRxy) = VyRyy. The formula VyRxy asserts that x is R to everything, but Sub*(VyRxy) does not say y is R to everything, but instead that something is R to itself. For a more commonplace mathematical example, suppose we define a function / : w —> ui by setting 4 T m n ( £ ) , and which satisfies the following conditions whenever x,y E Vn, c E C, R € TZ, f E T, rank(/) = rank(i?) = r, h,... ,tr E T m n ( £ ) , A,B E U, and ip) = Sub^itp) 0, terms t i , . . . , tr £ Tm(£), formulas C Fm + (£) and any loose interpretation M, we say that M is a model of $, and write M \= $, iff .M |= y; for every ip E $. We say that a formula 7J 6 Fm + (£) is logically valid iff 0 |= ip, that is, iff M \= ip, then M\= ip. (iii) M\= {T, F} by fT if M\= t/>[s']. Vvhip)[s] for every loose interpretation M and every sequence s GUM, i.e., either M \/= y vji {tp => tj)) [a] or M \fc fry,,/,) : v,rj> £ Fm+(£)}, (" [VaVj,^ tf) => (V, V.tf)], j,)] where tf) => ((V => & => 0 ) => (V => C)), 0 ) , (v> => 0) => (V> => (f => 0), V) =>" (- => Subt ¥>], where x £ hee(ip). v) => WX v^v), V), where (p is atomic, x € var(<^), and rp is obtained from (p by replacing a single occurrence of the variable x by the variable y, ip}. We prove by induction that if <&,tp \-d ip then ^ e ! l . We have & \-d ip => v5 by (4.76), so ip G fi. If V1 G $ U Ed then (^> => (^ => ip),ip, ip from $ using H<j and MP, so $ h d tp => ip and f e d . So far we have shown $ U H d U {^} C Q. To show O, is closed under MP, suppose ip,tp => f £ O, i.e., $ h d y> => ^/) and $ h d 95 =>(?/;=> f). Hence there is a proof (<TI, . . . , o>) of 7J => ^ from $ using H^ and MP, and there is a proof (TI, . . . , TS) of ip => (ip => f) from <1> using H^ and MP. Let Xi := (tp => ip) => (( £)) => ( (^ => 0) =^ (V =^ 0 . X3 := V => £ an (V1 => 0) => (( VO => ( 0 ) , X2 : = (tp => ip) => (tp => | ) , ip) C2 :=Va;(y> =^ V") =^ (V3 =^ Vj;V) £0 => (£2 => £a)» - ((*> => £1) => £2) => £s, - tp => (£1 => (£2 => £3)), - ( (£1 => £2)) => £3, - V => ((£1 => £2) => £3), there are 20 tautologies, and all but one of them can be proved using only the Deduction Theorem and properties of provability. The one that cannot be proved in this way is ((ip => ip) => tp) => tp, which is known as Peirce's tautology. Theorem 144. It is not the case that \-d ((ip => ip) => tp) => tp for every tpeSt. PROOF. Use an alternative definition of —> as an operation on a set with more than two elements. Let M be third object distinct from T and F. Define —* as in Table 3. Let C be the => -closure of St. Then, as in Th. 125, every valuation v : St —> {T, M, F} has a unique extension to a map v : C —> {T, M, F}. A formula ip 6 C is an arrow tautology with respect to this new definition of —> if v(tp) = T for every valuation v. It may be checked that every instance of (HI) and (HII) in C is a tautology with respect to this new —>, and the property of being a tautology with respect to this new definition is preserved by MP. But Peirce's tautology is ip) => 4. -.p => i 5. tp) => tp \- -1(99 =3- tp) ° and stv (i>) h" tpv, but r _ i => V, p) and fi(tp,ip,p), i.e., there is some r 6 Fm^"(£) such that PROOF. ip,(ip => p) => ( p),a), fi( p,a)), p^ip, {tp^ p) =>a,(ip=>p) =>a,T),f6( ,(ip =^ p) => a,(i/> => p) => cr), fe( ff) => ((^ = p) = or)), /r(^, (00 => p) => a)), / 2 6 (¥>, ip, p) = (Op = V>) = p) => ( ( p ((V => P) =* P ) , V) ^ P) => ((o- => P) ^ p)), ~^ip,^ip => ip^ ip. ip] = v V i 0 V)]( Subl V)] iji,ip,ij>) € MP then {Sij(ifi => %p),Sijtp,Sijip) E MP since S y ( p => ip) = Sy Sijip. Third, Gen is similarly preserved by Sy. The next two results require only instances of (HI), (HII), (HIII'), (HIV), and (CV) (special cases of (HV')). T h e o r e m 157. hhn PROOF. %tp ^ MyMxip hh ip and <3> hh -up. The theory $ is inconsistent if there is some sentence cp G Sent + (£) such that <3> hh cp and $ hh -up. Note that consistency is preserved "going down", while inconsistency is preserved "going up", in the following sense. Assume $ C $' C Sent + (£). If $' is consistent, so is <3>. If $ is inconsistent, so is $'. Theorem 162. Let * C Sent+(£). (i) $ is consistent iff there is some ip E Sent+(£) such that $ l/h ip. (ii) $ is inconsistent iff $ hh ip for every tp 6 Sent + (£). PROOF. The two parts are clearly equivalent. We prove only part (ii). First, if $ proves every sentence, it surely proves some sentence and its negation and hence is inconsistent. On the other hand, if $ is inconsistent, then by definition there is some ip G Sent + (£) such that $ hh ip and $ hh -199. Let tp G Sent + (£). We have hh ip => (-.99 => ip) by Th. 147, so ip, -«p hh ip. Therefore * hh ip by (4.68). ((-iy; => ip) => ip) by Th. 147, so $ h h ^/). But V was arbitrary, so $ is inconsistent, contrary to assumption. Part (ii): If $ h h -K^, then $ U {ip} is inconsistent because $, ip h h y> and $,^3 h h -up by (4.67) and (4.70). Conversely, if $ U {ip} is inconsistent, then $, 95 h h - A} is consistent, then -up = ip\ G TA+I C T a , so assume TxU^n,} is inconsistent. Then } is also inconsistent. Thus T a U {tp} and T a U {~>y>} are inconsistent. By Ta U Th. 162, Ta is therefore inconsistent, contrary to (4.150). Thus Ta is complete. There is a variation on the proof. Alter the definition of T«+i to FK U {^>»} if TK U {^»} is consistent FK U {-iipK} otherwise for every ordinal K < a. In this variation, the completeness of Ta is obvious, while Th. 162 is used in the inductive proof that Ta is consistent. In the proof of Th. 165 above, the consistency of Ta is obvious, and Th. 162 is used instead for completeness. 15. 11 and a is a nontrivial isomorphism of{U,S,{e}), i.e., cr is a permutation ofU, ae = e, and S\a = a\S. Then there are at least \{n — 2)(n — 3) diversity cycles [x,y,z] that are moved by a, i.e., [x,y,z] ^ [ax,ay,az\. PROOF. Suppose [x,y, z] is a diversity cycle that is fixed by a, that is, [ax,try, az] = [x,y,z\. Then a maps {a;, y, z, Sx, Sy, Sz} onto itself. So to know that a cycle [x, y, z] is moved by cr, it suffices to know that {a;, y, z, Sx, Sy, Sz} is not closed under a. Since a is nontrivial, there is some x E U ~{e} such that ax ft x. Assume Sx ^ x. Note that if u, v, y, z g U ~{e, a;, Sx}, then [a;, u, v] = [x, y, z] iff u = y and v = z. Suppose ax ^ Sx. If u, v € U ~{e, x, Sx, txx, txSx}, then we also have ax ^ {x,u, v, Sx, Su, Sv}, so the diversity cycle [«,«.,«] is moved by cr. Hence there are at least (n — 5)(n — 5) diversity cycles that are moved by a, since \U~{e,x,Sx,(Tx,oSx}\ = n —5. However, (n — 5)(n — 5) > | ( n — 2)(n — 3) since n > 11. cp. )) C Va(ii) If A,B e n then var(G(A = B)) C V3(III) If T = 0 then var(G( V of disjoint sets C/i for i E I, and an embedding g of 21 into ILe/ ^ e (^)- For each j G /, let pj be the projection function from r i j 6 / ^ e ( ^ i ) o n to £He(f/j) and create an interpretation Mj by setting, for every Frri3(£) which is closely related to the translation mapping H constructed by Tarski-Givant [240, §3.9] and used by them to prove the equipollence of £ x and £3". Let Z be the universe of the subalgebra of ^1113(2) generated by {voilvi : R 6 72.}, . Consider an arbitrary interpretation M. By (4.52), (-)M is a homomorphism from the predicate algebra ty into 9\e(M). By Th. 549, the restriction of Den^ to Fm3(2)(£) is a homomorphism from 3m3(2) m to 9*e (M), so DerrM(ft(-)) is also tp') := ~ ^ S y ^ . i>), Y-l VK(^ ^ Vm9 ) | £ = 3v 2 (S12 (f V $ ) A S02C) ip [a] iff either A ^ and write *4 |= $ if A \= ip for every ip £ $. A formula <£ £ FmJ(£) is algebraically n-valid iff ^4. |= v? for every n-dimensional algebraic interpretation A. A formula ip £ Fm^(jC) is algebraically valid if ip is algebraically n-valid whenever 3 < n < u and V e Fm+(£). 8. Algebraic satisfaction and substitution Given a function 7 : n —> n, let 7 : Vn —> Vn be the corresponding function on variables defined by 7(VJ) = v7(j) for all i < n, that is, 7 := v^ x |7|v. The next theorem corresponds to Th. 136. Theorem 562 (Maddux [146, Lem. 19]). Suppose £ is a binary relational language, 3 < n < to, Sub'"'(-) is a good substitution for n-variable logic, and A is an n-dimensional algebraic interpretation with atomic algebra 21 £ SA, semantical basis N C Bn%. If a £ N, 7 : n —> n, and (p £ Fm^(yC), then ra VvjVviV3 for some [a]. By propositional logic, this is equivalent to showing that if A \= V v; VVj. [c] by our assumption. This proves that every instance of (AIV) is algebraically n-valid. Validity for (AV), (AVII), (HIV), (CIV), and (CVI). First we consider schemata (HIV) and (CIV). Let ip,ip € FmJ(£) and i < n. We wish to show, for a given a € N, that (7.137) Subvj^), where Vj is free for Vi in if. For any good substitution Sub'-'-'(-) which does not needlessly respell bound variables, we have Subv}
) + h{tp) h{ip), so h{tp) = A(^>). D 10. Eree SAs and RAs of formulas Assume £ is a binary relational language. The algebra 3^3(2)/—« w a s shown in Th. 553 to be a free RRA on \R\ generators. We show in this section that $m3(2)/—3 is a free SA on \TZ\ generators, and ^m3(2)/—4 is a free RA on \R\ generators. The next theorem strengthens Th. 552 by replacing = with ~5i. Theorem 568 (Maddux [139, Th. 11(23)(ii)], [156, Th.5.2]). Suppose C = £(0,0, %, rank) is a binary relational language. If tp £ Fms^OC), then there is some %j) € ©g^ ra a( a )' ({voiZvi : R € 7Z}) such that tp ~^ ip. PROOF. Let T be the map defined in the proof of Th. 552 and let Z be defined by (7.49). We prove by induction on the complexity of formulas that Sb (E) of ^3/—^ into the relation algebra of all subrelations of some equivalence relation E e V: (7.173) € Sent* (£) such that ) := 1', while if free(p) = {vj 0 , v ^ , . . . , Vjn} and *o < *i , then (7-180) ) > ip. For this it is enough to unwind the relevant definitions. For part (vi), assume QAB,^ l~+ KABW), SO QAB,KAB{^) l" KAB(
v : Fm+(£) -» {T, F}, +
such that, for all ip, ip £ Fm (£), (4.16)
v(tp) = v(
(4.17)
v(
(4.18)
v(~"P) = ~v(
PROOF. Since a valuation v is a function from the set St of generators of (Fm+(£), =>,-.) to the algebra ({T, F}, ->, - ) , and (Fm+(£), => , ) is absolutely freely generated by St, the valuation v has a unique extension to a homomorphism v from (Fm+(£), =j-, -.) to ({T, F}, ->, - ) , which is what conditions (4.16)-(4.18) assert. D On the basis of the previous Th. 125, we say that a formula (p 6 Fm + (£) is a tautology iff v(tp) = T for every valuation v : St —> {T, F}. The next two theorems provide the basis for the truth-table method of determining whether a formula is a tautology. There is a function st such that st(
172
4. LOGIC WITH EQUALITY
elements of St occurring in ip. The values of a valuation on this set completely determine the value of the valuation on ip. Theorem 126. Let £ be a nice language. There exists a unique map st : Fm+(£) —> Sb (St) such that (i) st(v?) = M i/peSt, (ii) st(ip => iP)=st(tp)l>st(tP), (iii) st(-ip) =st(ip). PROOF. We imitate the proof of Th. 125. Consider the algebra (Sb(St),(3,v) of Boolean type where j3(X,Y) = X U Y and v(X) = X for all X,Y C St. Let / = ({
Theorem 127. Let C be a nice language and
1.8. Free variables. Next we define the set of variables that occur in a term t € Tm(£) or in a formula ip € Fm + (£). The definition is recursive, and there is theorem, left unstated and unproved, that there is a unique function satisfying each of the rules stated below, which could be proved by an argument illustrated by the proof of Th. 125. For each nice language there is a function var(-) : Tm(£) U Fm+(£) -> 56 (V),
uniquely determined by the following rules, in which x £ V, c £ C, f G J-, rank(/) = r, tu...,tr G Tm(£), R G U U II, rank(fl) = r, A,B G II, and V?,V e Fm+(£). var(x) = {x}, var(c) = 0, var(/ii var(Rti
T) T)
= var(ii) U
U var(tT),
= var(ii) U
U var(ir),
var(A = B) = 0, v a r ( y => ip) = var(y) U v a r ( ^ ) ,
var(-up) = var(ip), var(\txip) = var(ip) U {x}.
1. SYNTAX
173
The set of variables that occur freely in a formula
if
ip £ AtFm+(£),
free(^? => ip) = free(ip) Ufree(^), )) = iree(ip), ) = free(y) ~{x}.
For every formula
Sent(£) C Sent+(£),
(4.20)
Sent x (£)CSent+(£),
(4.21)
Sent x (£)nSent(£) = 0.
For every n < w, let (4.22)
Vn := {v; : i < n}.
In particular, Vo = 0 and Vu = V. We say that a term t £ Tm(£) is an n-term if var(i) C Vn- We define the set of n-terms by (4.23)
Tm n (£) := {t : t € Tm(£), var(i) C Vn}.
Similarly, a formula ip E Fm + (£) is an n-formula if var(^j) C Vn, and that ip is an n-sentence if ip is an n-formula and free(^j) = 0. Whenever m < n < to, let Fm n (£) := {ip : ip E Fm(£), var(v?) C Vn}, Fm n ( m ) (£) := {ip : ip E Fm n (£), free(v?) C V m } , Fm+(£) := {ip :
Then Fm^(£) is the set of n-formulas and Sent^(£) is the set of n-sentences. Here are a few more simple consequences of these definitions for a nice language £. Fm n ( n )(£) = Fm n (£),
174
4, LOGIC WITH EQUALITY
Fm+n)(£) = Fm+(£), Fm+(£) = Fm+(£), Fm w(0) (£) = Sentw(£) = Sent(£), Fm+ (0) (£) = Sent+(£) = Sent + (£). 1.9. Closures of formulas. Let £ be a nice language. For every tp £ Fm + (£), [(p] is a sentence, called the closure of (p, obtained by universally quantifying
r
if free(^?) = 0, if free(i^) = { v ^ , . . . , vth } and »i <
< i&.
1.10. Substitution. We will define two kinds of substitution, the replacement of a variable or constant by a term, and the interchange of two variables. If £ is a nice language, u € V U C, and t g Tm(£), then the function Sub?*(-) replaces u with t and is uniquely determined by the following rules, in which rank(.R) = r > 0, x £ V, c G C, t £ Tm(£), / £ T, rank(/) = r > 0 , R£TIUU, A,B g II, ti,... ,tr € Tm(£), and (p,ifi € Fm + (£): (4.24)
Sub^(ti) = *,
(4.25)
Sub?(s) = x if « / x,
(4.26) (4.27) (4.28) (4.29) (4.30) (4.31)
Sub^c) = e if « / e, Sub?(/ti...t,) = /(Sub?(ti)...Sub?(<
subr(^ = B) = t SubfiRh.-.tr) = fl(Sub?(ti)...Sub?O = Subr(^) =* Sub?^) = -.Sub?(v),
(4.32)
Sub^(Vti^)
(4.33)
Sub?{V.v) = yxSubt(tp) whenever
The following simple consequences of the relevant definitions can be easily proved by induction. Substitution of a term for a variable has no effect on terms and formulas in which that variable does not occur free. If a variable x does not occur
1. SYNTAX
175
in a term t, then substitution of t for x will eliminate all free occurrences of x in a formula. T h e o r e m 129. Let C be a nice language, x £ V, t,t'
£ Tm(£), and tp £
Fm+(£). (i) //a: g var(t') iften Subf (*') = t'. (ii) //a; 0 free(y>) iften Subf (
(4.34)
/(«)== X)(i + n)
for every n £ UJ. We may use this formula to calculate values for /. For example, 4
(4.35)
/ (5) = J^ii + 5) = (1 + 5) + (2 + 5) + (3 + 5) + (4 + 5) = 30.
We cannot correctly evaluate f(i) by straightforward substitution in (4.34), because replacing "n" with "i" produces 4
(4.36)
f(i) := ^(i
+ i) = (1 + 1) + (2 + 2) + (3 + 3) + (4 + 4) = 20,
i=i
which, in particular, implies /(5) = 20, contradicting the calculation in (4.35). For every nice language C, every ip 6 Fm + (£), and all i,j € w let Sijtp be the result of interchanging VJ and VJ, that is, simultaneously replacing every occurrence of Vj with Vj and every occurrence of Vj with Vj. For example, if R € H and R is ternary, then Soi(Vvl3vo-RvoviV2) = Vvo3vl-RvivoV2. Suppose i, j , k £ ui, c £ C, 0 < r £ w, R e H U II, the rank of R is r, / G J-', the rank of / is r, and ti,... ,tr G Tm(£). The rules governing the operation Sij are:
4. LOGIC WITH EQUALITY
Sy(Vfc)=Vfc
lfkytij,
Sy (c) = c, ti---* r ) = /(Sy(*i)...Sy(* r )),
fo> => tf) = Syfo>) => Sy (), Sy
) = --Sy (ip),
Sy (Vvj, v) = Vvj, Sy v?
iik^ij.
Notice that one form of substitution uses variables (as well as terms) as inputs, while the other uses indices of variables rather than the variables themselves; for the ways these notions are most frequently used later, this tends to produce notationally simpler expressions. The notion of interchanging (or transposing) two variables was introduced in Maddux [139, p. 188]. Another type of substitution was introduced by Monk [182] and a variation on it was used by Tarski-Givant [240]. All of these variant substitutions are designed to avoid various difficulties that arise when the usual notion of substitution is applied to languages with finitely many variables. For a discussion of these difficulties, see Tarski-Givant [240, pp. 66-71]. These variant notions of substitution are examples of good substitutions, which we now define. Classical substitution may produce undesirable results, and is therefore restricted in various axiom schemata to instances which produce only desirable results. Good substitutions may always be applied, since they simply "respell bound variables as they go along", and therefore always avoid undesirable results. Let £ be a nice language and n < to. A good substitution for n-variable logic is an operation Sub^(-) that associates a formula Sub'9'(<^) 6 Fm^(jC) with every formula
Sub [9l (x) = g(x),
(4.38)
Sub[9l(c)=c,
(4.39)
Sub [ 9 l (/ii
(4.40)
[9l
Sub (i?(ii
(4.41)
Sub[9]{A = B) = A = B,
(4.42)
Sub [9l (-.v?) = -.Sub [9l (<^),
(4.43)
Sub[9](
(4.44)
Sub [ 9 l (V^) = Vh(x)Sub[h](
r)
= )
=> SubM(V>),
2. SEMANTICS
177
(which depends on x,
h(x) E Vn, h{y) = g(y) for every y eVn ~{s}, h(x) i \J{var(h(y)) : y G Vn,h(y)
+ x}.
By a good substitution we mean a good substitution for w-variable logic. For a good substitution, h in (4.44) may depend on all of x, 2 and i? M C M if r = l, (ii) ( = ) ^ = M 1 , (iii) each function symbol f E J- ot rank r = rank(/) is assigned by M to a function fM such that fM : Mr -) M if r > 2 and fM : M -) M if r = l, (iv) each constant c £ C is assigned by M to an element cM £ M. Ii M satisfies all of these conditions except possibly (ii), we say that M is a loose interpretation. Some basic results about interpretations do not depend on the condition (ii) and are therefore stated for loose interpretations. It should be emphasized that every interpretation is a loose interpretation, but not conversely. (This terminological situation arises elsewhere, e.g., every relation algebra a semiassociative relation algebra, but not conversely.) 2.2. Sequences. Recall from (2.393) that "M is the set of functions from u) into M. "M
: = {3 :
s : ui ->
M}.
W
Functions in M are called ^ - s e q u e n c e s of elements of M. For every a>sequence 8 £ "M and every k £ u, we say that Sk is the (k + l ) s t element of s, and express this by writing s = {so, si, 82, S3,...). If s G ^M, k G w, and d G M, then we let s(k/d) be the sequence that coincides with s except that the (k + l ) s t element of s(k/d)
i s d.
T h u s s(k/d)
= (so,si,S2,
S3,...
s(k d)i = < yd
,Sk-i,d,Sk+i,
if k = 1 e
Here is an alternate definition. s(k/d) := (s n {it} x M) U {{k, d)}.
and
178
4, LOGIC WITH EQUALITY
2.3. Denotations. Every loose interpretation M, for a nice language C supplies a denotation for the nonlogical symbols of C (see (4.1)) and for the equality symbol = . A sequence a € w M acts as a further assignment of variables V to elements of M. According to a sequence s, the variable Vj denotes Sj. The set of terms, together with the operations on them determined by the function symbols, forms an absolutely free algebra X which is absolutely freely generated by V U C; see Th. 122. Together, the loose interpretation M, and the sequence a € " M provide a map from V U C into the elements of M. Note that M is the universe of an algebra 31 that is similar to 1, in the sense that 21 has operations that are also indexed by the function symbols. In this case the operation of SI corresponding to / € J- is fM, while the operation corresponding to / in the free algebra X is the one defined in a specific set-theoretical manner which insures that the algebra X is absolutely freely generated by the constants and variables of C Thus the loose interpretation M. and the sequence a together determine a map from the generators of X into the universe of the algebra 21. Since X is absolutely freely generated by V U C, there is a unique extension of this map to a homomorphism from X into 21. This map will be denoted by aM, so the image of the term t under this map is aM(t). (If we include the constants of £ as distinguished elements of X and their interpretations by M. as distinguished elements of SI, then X would be absolutely freely generated by V rather than VUC.) Similarly, if M is an interpretation (and not just a loose interpretation) then there is a unique homomorphism from the predicate algebra *$ = {II, +,~,;, ",1'), which is absolutely freely generated by the relation symbols of rank 2, into the square relation algebra 9te (M). Note that = (also written V) is sent to the correct relation for this to be true, namely, to the identity relation on M. If, on the other hand, M. is a loose interpretation but not an interpretation, then = may not be mapped to the identity relation on M, The images of the binary relation symbols are binary relations on M, as they should be. The non-binary relation symbols are mapped by M. to non-binary relations, but none of those relation symbols is used in the creation of the predicate algebra 5p. For every A € II, let AM be the image of the predicate A under the unique extension of the map {RM :ReH,rank(R)
= 2)
to a homomorphism on the predicate algebra ?p. A more formal expression of these definitions is that for every loose interpretation M for C, every k £ w, every sequence « £ U M , every constant e £C, every function symbol / E T where rank(/) = r, all terms t i , . . . ,tT £ Tm(£), and all predicates A, B g II, (4.45) (4.46)
aM{wk)
:= ak,
M
s (c):=cM,
(4.47)
aM(ft1 -..*,) := / M ( * M ( i i )
(4.48)
(A + B)M :=
(4.49)
(A)M
(4.50)
AMUBM,
:=M2~AM,
(A;B)M:=AM\BM,
sM(U)),
2. SEMANTICS
(4.51)
(A)M :=
179
{AMy\
The last four conditions above assert that the function (-)M is a homomorphism on the predicate algebra *p. In case M. is an interpretation, then we also have (=)M = VM = M 1 , so the function (-)M is a homomorphism from the predicate algebra qj into 9*e (M):
{-)M eHom{¥,mt{M)).
(4.52)
2.4. Satisfaction. Satisfaction is a ternary relation that may or may not hold between a loose interpretation M for a nice language £ = C(C, J-, 72., rank), a formula ip 6 Fm + (£), and a sequence s 6 " M . When it holds, we write M \=
M \= A = B [s] iff AM = BM,
(4.54)
M\=Rh---tr[s]
(4.55)
M|=(p^i(i[s]iff either M fi tp[s] OT M \= ip[s],
(4.56)
7W^-^[s]
(4.57)
.M |= Vv,^ [s] iffM\=
iff
iff
(^sM(t1),...,sM(tr))
€RM,
Mfi
We say that a loose interpretation .M with domain M is a model of ip 6 Fm + (£), and write .M |= y, iff M \=
180
4. LOGIC WITH EQUALITY
(iv) If M\= A = B then M\=A + C = B + C,M\=C + A = C + B, M \= A = B, M \= A;C = B;C, M \= C;A = C;B, and M \= A = B. (v) IfM\=A = BandM\=A = C then M\= B = C. PROOF. For part (i), suppose
Then v has a unique extension to v. One may now use the tables in (4.13), the honiomorphism conditions (4.17) and (4.18), and the clauses (4.56) and (4.55) in the definition of satisfaction to show by induction that i)(ip) = T iff M \= ip [s] for every ip E Fm + (£). Since ip is a tautology, we have i)(
(t)=S
(t).
Let
P := {t : t E Tm(£), if s, s E "M agree on var(i) then sM(t) = s'M(t)}. We will show that P contains all variables and constants of £, and is closed under the formation of new terms from terms in P. Consequently, P = Tm(£). Let c 6 C be a constant of £. Assume s,s' E^M. Then sM(c) = cM = M s' {c). Thus c £ P.
2. SEMANTICS
181
Consider an arbitrary variable Vj E V. Assume a, a' G UM and Sh = ajj. whenever vj. g var(vj). But var(vj) = {VJ}, so this assumption simply says that 8j = aj. Then SM(VJ) = % = aj = a'-^v,-). Thus v,- G P . Assume / E T is a function symbol of £ with rank r and t i , . . . , tT £ P. We claim that ft\ tr 6 P . To prove this, assume s,s' 6 WM and sj, = s'j. whenever t r ) = var(ti) U U var(t r ), so it follows that Vjb G var(/ti tr). Now var(/ti * and s' agree on var(ii), a and a' agree on var(ia), . . . , and a and s' agree on var(t r ). From these consequences and the assumption that ti,...,tr 6 P , we may conclude that aM(h) = s'M(h),...,
(4.58)
sM(tr) = s'M(tr).
But then aM(fh
) = fM(sM(h),...,
sM(tr))
= fM{slM{t1),...,slM{tT))
(4.58)
M
= a' (ft!
Thus fti
tr e P .
Now we can show that satisfaction of a formula by a sequence depends only on the free variables of the formula. T h e o r e m 132. Let £ be a nice language and let M be a loose interpretation for C with domain M. For every formula tp E Fm + (£), if sequences s,s' E W M agree onfree(cp), then M\=
iff
M\=tp[a'].
PROOF. Use induction on formulas. Let P := {tp :
{sM(t1),...,sM(tr))£RM, M|=i2ii
For the other atomic case, in which A, B g I I and we wish to show A = B € P , it suffices to observe that, for all sequences a, a' E " M , a and a' agree on freef A = Bj = 0, and the following statements are equivalent by (4.53). M\=A = B[s],
182
4. LOGIC WITH EQUALITY
AM=BM, M \=A = B[s']. If s, s' G "M agree on free((p => ip) = free(ip) U free(^), then the following statements are equivalent by (4.55). M \=tp => ip[s], either A4 \j= ip [s] or M \= ip[s], either M ^ y[s'] or A4 |= V[s'], M
ip,ip € P
\=
Assume that y>,^> G P . If s,s' G ^ M agree on free(-xp) = free(y), then the following statements are equivalent by (4.56).
M \= -n/3 Is']-
Assume that s,s' €. ^M agree on free(VVkip). The following statements are equivalent by (4.57). M\=(f
[s(k/d)] for every d G M,
M \=
ip G P, note (a) below
Note (a): For every d € M, s(k/d) and s'(k/d) agree on freeC^vj.^) by hypothesis, but they also agree on {v^} since s(k/d)k = d = s'(k/d)k, so they agree on free(VVs,¥?) U {v^}. But free(y>) C free(VVs,¥:>) U { v *}; s o s(k/d) and s'(k/d) agree D on free (
M \=
[s1].
2.6. Satisfaction and substitution. It is not always true that
This fails, for example, if R € 1Z, rank(i?) = 1, ip = ip = Rvo, M = {a, b}, a ^ b, RM = {b}} se"M, and so = b, since
M ^V
2. SEMANTICS
The trouble is that the universally quantified variable vo occurs free in the formula ip. If this is not the case, then, as we see next, no such counterexample is possible. Theorem 134. If £ is a nice language,
PROOF. "We wish to show that M \= Vvk(
M\=VVk{
(4.60)
M | = tfi[s].
Let de M. Erom (4.59) and (4.57) we get (4.61)
M\=
i/> [a(k/d)].
Prom (4.61) and (4.55) we conclude that (4.62)
either M £
By hypothesis, vj. ^ free(^)), so * and a(k/d) agree on free(y>). It follows by Th. 132 and (4.60) that (4.63)
M\=V[a(k/d)].
By (4.62) and (4.63), we get M \= i/f [a(k/d)]. We proved this for every d 6 M, so it follows by (4.57) that M 1= Vv&^ [«]. The next two theorems are lemmas for the proof of Th. 137. The first one states the connection between the substitution of a term for a variable and the alteration of a sequence. Theorem 135. Suppose £ is a nice language, M is a loose interpretation for £ with domain M, a GWM, t,t' G Tm(£), and keu. Then (4.64)
s(k/8M(t))M(t').
sM (Subr*(O) =
PROOF. Use induction on terms. First consider the case when t' is a variable, say t' = v r o . Then, by the relevant definitions, 3 M (v ro ) = sm
if m / k
j
11 m — K
(t;
and \9m [aM(t)
iim^k ifm = ,
so (4.64) holds when t' is a variable. In case t' is a constant, say t' = c € C, we have
184
4. LOGIC WITH EQUALITY
A s s u m e t h e t h e o r e m holds for t e r m s i i , . . . ,tr s y m b o l of r a n k r. T h e n M
(/ti
tT)) = SM(f
G T m ( £ ) and / 6 f ,
SubVth ( t l )
a function
Sllb^ (ir))
= fM(s(k/sM(t))M(t1),..
.,s(k/sM(t))M(U))
s(k/sM(t))M(ft1---tr).
=
D T h e o r e m 136. Suppose £ is a nice language, M is a loose interpretation for £ with domain M, s G UM, t G Tm(£), ip G Fm+ (£), k G u, and t is free for Vk in ifi. Then
M\=
(4.65)
PROOF. The proof is by induction. Let k G co, t G Tm(£), and P := {tp : i> G Fm+(£) and for all s G UM, M
iff Af|=Subrfc(V)M}-
We will show that P has the closure properties listed in the definition on p. 175 of "is free to be substituted for", which implies that ip G P, as desired. First we show that if vfe g free(V>), then
(4.66)
ipeP.
Let s € " M . Then the following statements are equivalent: M \= tp [s]
note (a) below
fe
M \= Sub^ (ip) [s]
note (b) below
M
Note (a): s(k/s (t)) and s agree everywhere except possibly at k, but vj, is not agree on the free variables of ip. free in ip by assumption, so s and s(k/sM(t)) Apply Th. 132. Note (b): By Th. 129, Sub*" (ip) = ip. This completes the proof of (4.66). Next we show that every atomic formula is in P. Consider an atomic formula A = B with A,B e Tl. Then A = B € P by (4.66). Next consider an atomic £ Tm(£). Let formula Rti T where R € U U II, r = rank(iZ), and ti,...,tr s G uM. Then the following statements are equivalent: M
\=Rti---tr[s(k/sM(t))], ,
8(k/8M(t))M(tr))
G -RM, i?^,
Th. 135
2. SEMANTICS
Thus every atomic formula is in P. Next we will show P is closed under = and universal quantification with respect to variables that are not free in t. Suppose «/>,£ G P. Let s GWM. Then we have M\=1>[s(k/sM(t))]
iff
M\=SUbvt-(1>)[s],
M\=S[8(k/sM(t))] iff A<|=Sub^ (£)[*], so the following statements are equivalent:
M^sub^a, => e)M, M ^ Sub"fe ('4>) [s] or M \= Sub"<" (0 [s], M ^^[s{klsM{t))\
or M\=^[s(k/sM(t))],
V,X G P
Thus «/> = J - ^ 6 P , which completes the proof that P is closed under . For closure under -i, assume ip £ P and let s £ "M. Then the following statements are equivalent:
MY=ip[s(k/sM(t))], Thus -it/; E P, so P is closed under -i. Finally, we assume ip 6 P and y ^ var(i), and show that Vyip G P- Suppose y = VJ. If fc = j then y = v^ and V& ^ free(VJ/-i/1)! s o Vj,^ G P by (4.66). Therefore, assume k ^ j . We wish to show that VVj V1 G P- Let s GWM. Then the following statements are equivalent. X |= ip [s(k/sM(t))(j/d)] M
X |= ip [s(j/d)(k/s (t))] M
for all d G M,
(4.57)
for all d G M,
note (c) below
M\=tp [s(j/d)(k/s(j/d) (t))] for all d G M, M \= Sub^fe (V>) [sO'/d)] for all d G M,
note (d) below note (e) below,
>f ^ V v . Sub^(V>)H, M^Sub^(Vv^)[s],
(4.57) (4.33)
Note (c): s{k/sM(t))(j/d) = s(j/d){k/sM{t)) since k ^ j . Note (d): Since M vj f var(t), we have s {t) = s(J/d)M(t) by Th. 131. Note (e): We can apply the assumption that tp G P, with s(j/d) in place of s. This completes the proof that P is closed under universal quantification with respect to variables that are not free in t. Since has the required closure properties, we conclude that ip G P, so (4.65) holds. Theorem 137. Let C be a nice language, t G Tm(£), k G u>, andip G Fm + (£). If t is free for Vk in tp, then \= Vvj,^ => SubJh (ip).
186
4. LOGIC WITH EQUALITY
PROOF. Let M be a loose interpretation for £ with domain M, and let s £ M. We wish to show that M \= VVfev? =^ Sub^fc(i^) [s]. For this purpose, assume .M |= V v ^ M - : t follows from this by (4.57) that M \= ip[s(k/sM(t))]. We may apply Th. 136 since t is free for vjt in cp by assumption, so M. \= SubJ'*' (<^) [s], as desired. U
The hypothesis that t is free for x in ip is necessary, since there are formulas of the form Vxip => Sub?(ip) that are not logically valid. For example, \i R £ 1Z, and rank(iZ) = 2 then => Siiby(3yRxy) => 3ySuby{Rxy) = Vx3yRxy => 3w.RSub* = Vx3yRxy => 3yRyy. However, \/x3yRxy => 3yRyy is not logically valid, since if M = {a, b}, a ^ b, and RM = {(a,b) ,(b,a)}, so that RM is simply the diversity relation on the two-element set M, then M \= Mx3yRxy (in M, everything is different from something), but M ^= 3yRyy (in M it is not the case that there is something different from itself). 3. Axiomatization and formalisms A ("syntactical" or "uninterpreted") formalism (see Tarski-Givant [240, §1.6]) is a pair (S, h), where S G V is a set (whose elements are called "sentences" or "formulas") and h is a binary relation (called "provability" and read "proves") which relates subsets of E to elements of S, that is, h C Sb (S) x S, and which satisfies the following conditions for all $ , $ C S and all ip,ip £ S. (4.67) (4.68) (4.69) (4.70)
if f £ * then $ h
Consider two formalisms T\ = (Si, hi) and Ti = (S2,h2). We say that T\ is a subformalism of Ti (and Ti extends T\) if Si C S2 and $ hi ip implies <& \~2 tp whenever $ C S i and ip £ Si, that is, hi C I-2. For every one of the formalisms that we will consider, such as the formalisms C, C+, and Cx of Tarski-Givant [240], the set of sentences is a subset of Fm+(£) for some nice language £. Consequently the semantical notions defined for any nice language C are available. Accordingly, and following Tarski-Givant [240], if Si, S2 C Fm + (£) and T\ is a subformalism of T2, we say that the formalisms T\ and J~2 are equipollent in means of expression if for every ip2 £ S2 there is a ipi 6 Si such that ip2 = ipi, and that T\ and Ti are equipollent in means of proof if $ l~2 v? implies $ hi (p whenever f C E i and j j g E i , i.e., h 2 n(5fo(Si) X S I ) = K .
3, AXIOMATIZATION AND FORMALISMS
187
If T\ and .Fa are equipollent in means of proof then, for every $ C Si and every p € Ei, we have # ha
MP := {{
and generalization is defined by (4.72)
Gen : = {{V,Vm
:m£V,
Fm+(£)}.
Here are graphic illustrations of MP and Gen:
(4.73)
MP
V
^ f *
Gen - £ _ .
Two other binary rules of inference, which are used in the formalism Cx and its variants, are the binary rule Rp, which is the union of several sets: (4.74)
Rp :={(A = B,A + C = B + C) : A,B,C
U{{A = B,A = B~) : A,B
£U}
ell}
U {{,4 = B, A;C = B;C) : A,B, C £ II}
1SS
4, LOGIC WITH EQUALITY
and the ternary rule (4.75)
Tr ;= {{,4 = B, A = C, B = C) : A, B, C g n } .
If all the predicate equations of the form C = C were included as axioms of £x, then the rule Rp could be viewed as a special case of the rule of replacement, which allows us to infer A' = B' from A = B and C = D, whenever C occurs as a part of A or B and A' = B' is the equation obtained from A = B by replacing some occurrence of (7 by D. For example, from the axiom A + C = A + C and the hypothesis A = B we get A + C = B + C by the rule of replacement, a conclusion we could have reached directly from the hypothesis A = B by Rp. 3.2. Proofs. In terms of a given set of axioms and rules of inference, we define what it means to be a proof. Suppose we have a set of sentences £ G V, a set of axioms S C E, a binary rule of inference, say B C E 2 , and a ternary rule of inference, say T C S33. Let # C S and tp E £. A proof in £ of tp from hypotheses # using axioms S and rules B and T is a finite sequence (ipo,..,, %j)n) of elements of E such that ijin =
{ij)j ,ipi) g B for some j < i, {i/ij,il>k,*l>i) 6 T for some j,k
We define $ \-%' tp to mean that there is a proof of tp from $ using axioms S and rules B,T. To express that h is defined in this way from the axioms H and the rules B and T, we may also say that h is provability using axioms S and rules B and T. If S, B, and T are determined by context, we may omit mention of them, referring simply to a proof of tp from # and writing #1-93 instead of $ \~a'T We may also omit # if it is empty and make other standard notational simplifications, writing, for example, h tp instead of 0 h tp, and $, tp h ifi instead of $ U {(p} \~ ip, etc. We will add superscripts or subscripts to the symbol h to denote provability for various particular choices of sentences, axioms, and rules. The next theorem states that if we define provability in this way, using axioms and rules, then we will obtain a formalism. Theorem 138. If S C E g V, B C E 2 , T C E 3 , and h is provability in E using axioms H and rules B and T, then {23,1-} is a formalism, i.e., (4.67)-(4.70) hold. Furthermore, if we first construct a formalism by this method, and then construct a second formalism using a larger set of sentences, larger set of axioms, and larger rules of inference, then the second formalism extends the first.
4. FORMALISMS OF Tarski-Givant
189
Theorem 139. Suppose Hi C Si £ V, fli C £?, Ti C £?, hi is provability in Si using axioms Hi and rates Si and Ti, H2 C £2 € V, B2 Q S | , T2 C £f, and I-2 is provability in £2 using axioms H2 and rates B2 and T2. // £1 C £2, Hi C H2; Bi C B2, T\ C T2; ifeen (£i,hi) is a subformalism if (£2,^2). PROOF. We have £1 C £2 by hypothesis. Let $ C £1 and j j g S i . Suppose $ hi <£. Then there is a proof of ip from $ using axioms Hi and rules B\ and T\. From the hypotheses Si C S2, Bi C B 2 , and Ti C T2 we see that every sentence in the proof is either in $, or in Hi (hence also in H2), or follows from earlier sentences by Bi (hence also by B2) or by Ti (hence also by T2). Consequently, this proof is also a proof of ip from $ using axioms H2 and rules B\ and T2.
Many more quite general theorems could be proved. We give here a single example involving the rule MP. Theorem 140 (MP). Suppose £ C Fm+(£) and £ is 'closed under conclusions': if if => ip £ £ then ip 6 £. Let H C £ C Fm + (£), and let h be provability in £ using axioms H and rule MP (and possibly some other rules). Then, for all $ C £ and ip, ip £ £, if $ h ip and $ h ip => ip then $ h ip. PROOF. Concatenate a proof of ip => ip from $ with a proof of ip from $ (in either order) and extend it by one more sentence, namely ip. Since ip £ £ by hypothesis, the resulting finite sequence is a proof in £ of ip from $. The last formula in this newly constructed proof follows from two previous formulas by
MP. We will often refer to Th. 140 by writing "MP". Similarly, "Gen" may refer to the fact that if ip is provable then so is V ^ . 4. Formalisms of Tarski-Givant Among the dozens of formalisms discussed by Tarski-Givant [240], we are particularly interested in the formalism C and its extension £ + , their variants with only finitely many variables and/or more than one binary relation symbol, the equational formalism Cx, and some variants of £ x with weakened axiom systems. Table 1 lists the names and brief descriptions of fourteen formalisms from Tarski-Givant [240]. The first eleven of these (designated by symbols containing "£") have an underlying language with no constants, no functions symbols, and just one binary relation symbol, that is, a nice language C = £(0,0, {E}, rank) where rank(E) = 2. For these eleven, the sets of sentences, axiom schemata, rules of inference, and symbols for the provability relation are given in Table 2. In case the language has n + 1 binary relation symbols, i.e., C = £(0, 0,72., rank), \U\ = n + l, and rank*(^) = {2}, the formalisms £, £+, and £ x are called M(n\ M(n)+, and M{n)x, respectively. All the axiom schemata appearing in Table 2 and several others are listed in the next few pages. A notable feature of the first group of axiom schemata, namely (AI)-(AIX), is that all their instances are sentences. They were adopted from the system Si of Tarski [235]. Tarski's system Si provides axioms for the logically valid sentences and requires only the rule MP. Tarski's system 1S2 provides axioms
4. LOGIC WITH EQUALITY
Reference [240, §1-2, §1.3] [240, §2.1, §2 .2] [240, §3.1] [240, §3.7, p. 72] [240, §3.7, p. 72] [240, p. 89] [240, p. 89] [240, p. 91] [240, p. 91] [240, p. 89] [240, p. 89] [240, p. 191] [240, p. 191] [240, p. 191]
Description in [240] predicate logic of one binary relation extended predicate logic of one binary relation c+ equational logic of one binary relation cx 3-variable subformalism of £ c3 3-variable subformalism of £+ r+ standardized 3-variable subformalism of £3 Cs3 standardized 3-variable subformalism of £g Cs+ n-variable subformalism of £+, n > 4 Cn n-variable subformalism of £+, n > 4 r+ Cox subformalism of £ x without associative law x Cw subformalism of £ x with weak associative law predicate logic of n + 1 binary relations, n > 0 M^ M^+ extended predicate logic of n + 1 binary relations, n > 0 .A/lO)x equational logic of n + 1 binary relations, n > 0 Name £
1. Some formalisms of Tarski-Givant [240]
TABLE
c c+ £3
r+ -i
L
Cs3 £.+ Cn
r+
^nx
c
Cwx Cox
h h h+ h3 ^
Sentences Sent(£) Sent+(£) Sent3(£) Sent+(£) Sent3(£) Sent^(£) Sentn(£) Sent+(£) Sent x (£) Sent x (£) Sent x (£)
h+ \~n
hx hx
Axiom schemata (AI)-(AVIII) (AIX) (AI)-(AVIII) (AIX) (AI)-(AVIII) (AIX') (AI)-(AVIII) (AIX') (AI)-(AVIII) (AIX') (AI)-(AVIII) (AIX') (AI)-(AVIII) (AIX') (AI)-(AVIII) (AIX') (BI)-(BIII) (BV)-(BX) (BI)-(BIII) (BV)-(BX) (BI)-(BIII) (BV)-(BX)
(DI)-(DV) (AX) (AX)
(DI)-(DV) (DI)-(DV) (DI)-(DV)
(BIV) (BIV)
Rules MP MP MP MP MP MP MP MP Rp Tr Rp Tr RpTr
TABLE 2. Axioms and rules for formalisms
for the logically valid formulas (not just the sentences), and uses the rule of Gen as well as MP. The systems 5i and S2 in Tarski [235] were obtained by modifying a system of Quine [203, 202, 204, 205, 207] which also uses only MP. Tarski's systems avoid the notion of substitution. Throughout this survey of schemata the following assumptions and notational conventions apply: £ = £(C, T, 1Z, rank) is a nice language, n < ui, ip,ip,£ € Fm+(£), i € T m ( £ ) , x,y€Vn, i,j
P) => (0
[(<£>=> i
J'
[
/J ' r J'
=> 0)1.
4. FORMALISMS OP "Barskl-QIvant
(AV)
[V,(
(AVI)
[V.
(AVII)
[9? => Vx
(AVIII)
[ 3^ (a!=y) ], where
(AIX)
191
x*y,
[a!=y => (
Although (AI)-(AIX) are complete when there are countably many variables, several additional schemata must be considered when formulating axiom sets for logic with finitely many variables. Schemata (AVI'), (AIX'), and (AX) below are formulated in terms of a variant type of substitution denned by Tarski-Givant [240, pp.66-67], which we will not define, but which happens to be a good substitution. The general schema of simple substitution: [ V , p =
(AVI') The general Leibniz law: (AIX')
[x=y => (v =>
The transposition schema, a variant of (AIX'): (AIX")
[ v ^ v , - =>(*.=> Su
The general tranposition schema, obtained from (AIX") by allowing all formulas, not just their closures: (AIX*)
Vi=Vj =J- (tp => Sijip).
The general associativity schema: (AX)
[3 V2 (3 V1 (p[v 0 , vi] A tf [vi, v2]) A «- 3 V2 (ip[v0, v2] A 3 V0 W[v 2 , v 0 ] A
A variant of (AX): (AX')
[3v 2 (3
Givant proved (see Tarski-Givant [240, p.71-2, fn. 13*]) that C3 and £ j may be equipollently formalized by replacing axiom schemata (AIX') and (AX) with the axiom schemata (AIX") and (AX'). Additional axiom schemata for £+ which serve as definitions for the predicate operators and the predicate equality symbol: (DI)
VVOVV1 (vo^i + Bvi
(DII)
V V0 V vl (v 0 Zvi «
(Dili)
Vv 0 V vl (v 0 ^;Bvi « 3v 2 (v 0 Av 2 A v 2 Svi)),
(DIV)
V V0 V vl (v 0 Ivi »
(DV)
A = B
» (voAvi V v 0 Svi)), -.voAvi),
viAvo),
» Vv 0 V vl (v 0 ^vi «
v 0 Bvi).
192
4. LOGIC WITH EQUALITY
Predicate equations used as axiom schemata for £x: (BI)
A + B = B + A,
(BII)
A+(B + C) = (A + B)+C,
(Bill)
A + B + A + B = A,
(BIV)
A;(B;C) = (A;B);C,
(BV)
(A + B);C = A;C + B;C,
(BVI)
A;V=A,
(BVII)
1 = A,
(BVIII)
(A + B)" = A + B,
(BIX)
(A;BY = B;A,
(BX)
A;A~B + B~ = B~.
The semiassociative law (a weakening of the associative law): (BIV)
A;(B;1) = (A;B);1.
Lukasiewicz [243] proved that the following three schemata form a complete set of axioms for prepositional calculus. Lukasiewicz's proof is given below in Th. 148. For an outline of a somewhat different proof, see Church [50, p. 160, Ex. 29.2]. (LI)
{V => 4) => (( Q => {V => 0 ) ,
(LII)
(-up =>
(LIII)
9? =* (-.p =* ip).
Schemata (AI)-(AIII) are just the closures of these formulas. Henkin [89, 92] proved Godel's Completeness Theorem for the case in which there are relation symbols of arbitrary finite rank but no constants and no function symbols, i.e., for a language C = £(0, $,H, rank). For his notion of provability he used M P and a restricted form of Gen as rules of inference, together with the following axiom schemata: (HI)
(
(HII)
y) =* (^ =* V ) ,
(HIII)
(^^ => ^ ) => (^ => ^ ) ,
(HIV)
V^C^ =^
(HV) (HVI) (HVII)
VJB^ => Suti^ip, where y is free for x in ip, x=x, %=V => (
) =s- (v? ^ V x ^ ) , where a; ^ free(ip),
Henkin's first three axiom schemata also suffice to derive all tautologies using just MP. This was proved by Lukasiewicz (see Lukasiewicz [244, p. 136], Tarski
4. FORMALISMS OP Tarski-Givant
193
[234, p. 43]), thus simplifying the axiomatization of Prege [73]. Prege's system was based on axiom schema (HII) and five others:
(FI)
& => (V => 0 ) => «¥> => 1>) => {
(FIII)
(
(FIV)
(
(FV)
-.-.p => p,
(FVI)
p => -.-.p.
,
It will be shown below that the axiom schemata (HI) and (HII) are enough to prove the Deduction Theorem for propositional calculus. They can, in turn, be derived from it, so they are, in this sense, equivalent to the Deduction Theorem. In the proof, (FI) can be used in place of (HI), hence (FI) and (HII) are also enough to prove the Deduction Theorem. Since (FI) can be derived via the Deduction Theorem, provability using (HI), (HII), and MP is the same as provability using (FI), (HII) and MP. Lukasiewicz proved that (FIII) is redundant (see (4.85) below) and (FIV)(FVI), can be replaced by (HIII). Axiom schema (HIII) is a law of contraposition, and is one of many axiom schemata that can be used here, such as this variation on (HIII): (HIII')
(-.p => -.V) => ((-"P => ip) =>
For languages that include constants or function symbols (C ^ 0 or T ^ 0), the appropriate extensions of (HV)-(HVII) are (HV')
\/x
(HVI')
t=t,
(HVII')
Subf (
x=t => (
Tarski [235, Th. 1, Th. 5] proved that his systems Si and £2 are complete by deriving Henkin's axioms and noting that both systems are semantically sound. By Tarski [235, Th.2], (AVI) may be replaced in Si by [Vx
(AVI*)
However, Monk [178] proved that (AVI) cannot be eliminated entirely. On the other hand, by Tarski [235, Th.3] and the ensuing remark, (AVI) may be deleted entirely if the provision "where x ^ y" is omitted from (AVIII), but this change is not desirable for languages with only a finite number of variables; see TarskiGivant [240, p. 8]. The rules of inference in Tarski's second system S2 are MP and Gen, and its axiom schemata are Lukasiewicz's (LI)-(LIII) together with five others:
(civ)
vx(
(CV)
V ^ => V,
(CVI)
(fi => V^v?, where x £ var(ip),
(CVII)
3x(x=y),
where x ^ y,
194
(CVIII)
4. LOGIC WITH EQUALITY
x=y => {
Kalish-Montague [121] proved that schema (CV) can be omitted, and that the remaining schemata are independent. 5. Soundness Every instance of every schema in the previous section is logically valid. The theorem expressing this is called the "Soundness Theorem", for it says that if we define a notion of provability using any set of axioms that consists entirely of instances of any of the schemata in the previous section, and any of the rules MP, Gen, Rp, and Tr, then our deductions are "sound" in the sense that we cannot derive something false. Theorem 141 (Soundness). Assume that C is a nice language, n < ui, H C Fm+(£), and that every formula in E is an instance of one of the axiom schemata (AI)-(AIX), (AVI'), (AVI*), (AIX'), (AIX"), (AIX*), (AX), (AX'), (BI)-(BX), (BIV), (CIV)-(CVIII), (DI)-(DV), (FI), (FIII)-(FVI), (HI)-(HVII), (HIII'), (HV'), (HVI'), (HVII'), (LI)-(LIII). Then every formula in S is logically valid. Let h be provability in Fm^(yC) using axioms H and any combination of the rules MP, Gen, Rp, and Tr. / / * C Fm+(£) and ip € Fm+(£), then $ h tp implies $ \= ip. PROOF. Every instance of schemata (HI)-(HIII), (HIII'), (LI)-(LIII), (FI), and (FIII)-(FVI) is logically valid by Th. 130(i). Every instance of (AI)-(AIII) is logically valid by Th. 130(i)(iii). Every instance of (CV), (HV), and (HV') is logically valid by Th. 137. Every instance of (HIV) is logically valid by Th. 134. Direct proofs suffice for the remaining schemata. These involve little more than careful inspection of the relevant definitions and various elementary results. For example, the logical validity of every instance of (BI) follows from (4.48), (4.53), and (2.35), while the logical validity of instances of (DI) will also involve (4.54)(4.57). The logical validity of instances of (BIV), (AX), and (AX') rests ultimately on (2.116), the associativity of relative multiplication. Assume $ C Fm^(jC),
6. Deduction theorem Theorem 142 (Deduction Theorem). Assume C = C(C,J-,1Z, rank) is a nice language, n < u>, H<j C Fm^~(£) is any set of formulas that contains all the instances in Fm+(£) of schemata (HI) (or (FT)) and (HII), and Sg C FmJ(£) is any set of formulas that contains all the instances in FmJ(£) of schemata (HI)
6. DEDUCTION THEOREM
195
(or (FI),), (HII), and (HIV). Let \-d be provability in Fm^(yC) using axioms 3<j and rule MP. Let h 9 be provability in Fm+(£) using axioms Sg and rules MP and Gen. Suppose tp,tp £ Fm+(,C) and $ C Fm+(£). (4.76)
\-d tp => tp,
(4.77)
$, tp \-d ip iff
(4.78)
$,tp\-9
$ \-d tp => ip,
ip «if * I"9 V => V1, M ewen/ v? 6 Sent+(£).
PROOF. Proof of (4.76): Let tp £ Fm+(£). The following five formulas are also in Fm+(£). ip! := (tp => (tp => tp)) => ((ip => ((ip = > ? ) ) = >
The sequence (ipi,ip2, V)3,V'4;'i/'5) ' s a proof of 95 => 95 from 0 using axioms H^ and rule MP, since {rpi,i/>2, ips., ipi, V's} ^ FmJ(£), ^1 is an instance of (HI), tp2 is an instance of (HII), {ipi,tp2,ip3) G MP, ^4 is an instance of (HII), and (ip3,ip4,ips) G MP. Proof of (4.77): Assume ip, ip 6 FmJ(£) and $ C FmJ(£). For one direction, we simply note that if $ \-d tp => ip then $ , tp \-d tp => V by (4.70), and $, (^ \-d ip by (4.67), so *,
Then xi is instance of (HI), (xi:°"r,X2) G MP, and {X2,TS,XZ) G MP, so the following sequence of formulas is a proof of tp => £ from $ using H^ and MP: (4.79)
(<7i,...,0y,Ti,...,Ts,xi,X2,X3>-
Th. 142 still holds if we replace (HI) with (FI) and alter the proof at this point by setting Xi := (
X3 := V => C.
196
4. LOGIC WITH
EQUALITY
and noting that %i is an instance of (FI), (xi, T S , X2) £ MP, and (x2, 0>, X3) £ MP, so (4.79) is again a proof of ip => £ from $ using H<j and MP. Since $ U 5 j U {<^} C 0 and Q is closed under MP, we have shown that if <&, tp \-d ip then Q \-d tp => T/J, as desired. Proof of (4.78): Now suppose ip E Sent+(£). In one direction the proof of (4.78) is the same as in (4.77). For the other direction, we again let Q = {ip : ip E Fm+(£), $ h9 tp => ip}. Then $ U Sg U {ip} C 0 and fi is closed under MP, as shown by the proof of (4.77). We need only show 0 is also closed under Gen. Assume ip E il, i.e., $ h 9 ip => ip, so there is a proof (CTI, . . . , ar) of tp => ip from <& using Sg and MP and Gen. Let ti:=Vx(
T h e n (o>,Ci) £ Gen, £ 2 is a n instance of (HIV) since x £ free(y) = 0, a n d (C2,Ci:Cs) ^ M P , so (CTI, . . . , OV,CI>C2J &} ls a proof of ip => ^txtp from $ using H s , MP, a n d Gen. D
7. Implicational fragment Through this section we assume £ = C(C,J-,1Z, rank) is a nice language, n < UJ, and \-d is provability in FmJ(£) using axioms (HI), (HII), and rule MP. T h e o r e m 143. Let tp, $,£ e Fm+(£). Then (4.80)
\-d ip => y>,
(4.81)
h d v? ^> (V> => tp),
(4.82)
h d 95 ^> ((y> =} ip) =} V;),
(4.83)
h ((95 => tp) => ip) => ip,
(4.84)
h
(4.85)
h
(7J => ( ^ => £)) =^ ((^j => ^ ) => ( ^ => ^ ) ) , (ip => (ip => £))
(ip
(ip => ^ ) ) ,
d
(4.86)
h (v? ^> V) => ((V => (^ => £)) => (V =^ 0 ) ,
(4.87)
h
ip => ( ( y =^ ^1) => ((95 => (ip => 0)
=^ f ) ) ;
d
(4.88)
h (v? => V) => ( W => £) => (V => C))>
(4.89)
\-d (ip =>£)=>
(4.90)
\~ ip => ((tp => (ip => £)) => (ip => (,)).
(('P => tp) => (>p => V1)))
Every part of this theorem is very easy to prove with the help of the Deduction Th. 142 and the properties of the provability relation \-d, without any reference to the axioms (HI) and (HII). For example, although (4.80) is a repetition of Th. 142, we now can put forward the following alternative proof. We have tp \-d tp by (4.67). By the Deduction Theorem, treated as an additional postulated property of the provability relation \-d, we conclude that \-d tp => tp. Similarly, (4.82) may be
7. IMPLIOATIONAL FRAGMENT
197
proved by noting first that (ip => ip, tp, ip) is a proof of ip from {ip, tp => ip} using no axioms and rule MP, hence tp,tp => ip \-d ip. We therefore conclude by two applications of the Deduction Theorem that \-d tp => ((tp => ip) => ip). For a similar proof of (4.83), first note that (tp => tp) => ip, tp => p Hd ^ since ((y> => y>) => $, y> => tp, ip) is a proof of ip from {(y> =J> tp) => $, y> =s> tp} using no axioms and rule MP. By the Deduction Theorem we obtain tp => tp \-d ((ip =>
4. LOGIC WITH EQUALITY
—>
T M F
T T T T
M M T T
F F F T
TABLE 3. Unique 3-element table for independence of Peirce's tautology
not a tautology in this new sense, for if v(tp) = M and v(ip) = F then v(((
= M.
On the 3-element set {T, M, F}, with T as designated element, there is, up to isomorphism, only one definition of —> that can be used in this way to show that Peirce's tautology is not hd-provable. If we wish to define —> instead on the 4-element set {1,2,3,4} and use 1 as designated element (so that ip £ C is a tautology iff v{
0
Tarski proved that ip is an arrow tautology iff it has a proof using axioms (HII), (LI), (Ta) and the rule MP. To express this more briefly we will say that (HII), (LI), (Ta) are complete for arrow tautologies. . Bernays pointed out that (Ta) may be replaced by Peirce's tautologies (Pe) in Tarski's theorem, so (HII), (LI), (Pe) are also complete for arrow tautologies. Independence of both systems was proved by Lukasiewicz. See Tarski [237, Th. 29 and subsequent remarks]. Furthermore, Lukasiewicz [242, 244] (see also Tarski [237, Th. 30, fn. f]) proved that the shortest single axiom schema that axiomatizies the implicational propositional calculus is (LIV)
f) => (X
7. IMPLICATIONAL FRAGMENT
1 1 1 1 1
—>
1 2 3 4
2 2 1 1 1
4 3 3 1 1
3 3 3 1 1
1 1 1 1
2 3 3' 1 3 3 1 1 1 1 1 1
2 1 1 1
4 3 1 1
3 3 1 1
1 1 1 1
2 1 1 1
3 3 1 1
4 3 1 1
1 1 1 1
2 1 1 1
4 3 1 1
4 3 1 1
1 1 1 1
2 1 1 1
4 4 1 1
3" 3 1 1_
1
2 1 1 1
3 4 1 1
4" 3 1 1_
1
2 1 1 1
3 3 1 1
3" 4 1 1_
1 1 1 1
2 1 1 1
3 3 1 1
4" 4 1
1 1 1
2 1 1 1
2 1 1 1
4" 4 4
1 1 1
3 1 1 1
2 1 1 1
4" 4 4
1 1 1 1
2 1 1 1
3 3 1 1
4" 4 4 1
2 1 2 1
3 3 1 1
4" 4 4 1
2 1 2 2
3 1 1 1
4" 4 4 1
1 1 1
1 1
1—i
M
1 1
1 1 1
1—i
1 1 1 1
TABLE 4. All 4-element tables for independence of
1 1 1 1 1 1
2 3 3' 1 4 3 1 1 1 1 1 1 2 4 3' 1 3 4 1 1 1 1 1 1 2 3 4' 1 1 1 4 1 1 1 4 1 1 1 1 2 3 4' 1 1 3 4 1 4 1 1 Peirce's tautology
For an outline of the proof of Lukasiewicz's theorem, see Church [50, 18.4]. Church [50, 18.3] also has suggestions for proving the theorems of Tarski and TarskiBernays. By (4.88), every instance of (LI) is provable using (HI), (HII), and MP, so the theorems of Tarski and Bernays still hold if we replace (LI) by (HI). Consequently (HII), (HI), (Ta) are complete for arrow tautologies, and so are (HII), (HI), (Pe). So far, we have found four sets of schemata that are complete for arrow tautologies. Each of them consists of three schemata among (HII), (HI), (Pe), (LI), (Ta), and each of them includes (HII). The inclusion of (HII) is essential in the sense that the remaining four schemata are not complete for arrow tautologies. Table 5 shows an alternative definition of —> on {1, 2, 3, 4} with respect to which, with 1 as the distinguished element, the property of being a tautology is preserved by MP and all instances of (HI), (Pe), (LI), (Ta) are tautologies, but some instances of (HII) are not tautologies, since 2—> (3 —> 2) = 2 —» 4 = 4 ^ 1. There are two other choices of three schemata among (HII), (HI), (Pe), (LI), (Ta) that may produce sets of axioms that are complete for arrow tautologies, namely (HII), (HI), (LI), and (HII), (LI), (Ta). In view of (4.88) and Th. 144, we see that the first of these possibilities is not complete for arrow tautologies. To show that (HII), (LI), (Ta) are also not complete, use the definition of —> in Table 6, with
4. LOGIC WITH EQUALITY
—>•
1 2 3 4
1 1 1 4 1
2 2 1 4 2
3 2 1 1 2
4 4 4 4 1
TABLE 5. A table for the independence of (HII)
-
>
•
2 3 4 2 2 4 1 1 1 4 3 3 1 i—l i—l
1 2 3 4
1 1 1 1 1
TABLE 6. A table for the incompleteness of (HII), (LI), (Ta)
(HII) (HI) (Pe) (LI) (Ta) || + - - + - 1 + - + - - 1 + - + - 1 + + - - 1 + - - + 1 - + - + 1
1234 1222 1222 1222 1234 1224 1224
2 2 2 2 2 2
1234 1112 1111 1111 1114 1114 1114
3 3 3 3 3 3
1234 1112 1114 1111 4114 2224 1144
4 4 4 4 4 4
1234 1111 1131 1221 1221 1221 1221
TABLE 7. Incompleteness of some axiom schemata for implication
which instances of (HI) fail since (3 -> (2 -> 4)) -> ((3 -> 2) -> (3 -> 4)) = 4. Table 7 proves that no set of axioms formed by choosing two schemata from (HII), (HI), (Pe), (LI), (Ta) is complete for arrow tautologies. This includes independence for the axiom sets in the theorems of Tarski and Bernays. In the table, "+" indicates that all instances are tautologies with respect to the table given to the right and "—" indicates otherwise. 8. Completeness of (HI), (HII), (HIII') In this section, assume C = C(C, T, 1Z, rank) is a nice language, n < u>, and \-p is provability in Fm+(£) using axioms (HI), (HII), (HIII') and rule MP. By the Soundness Th. 141, whatever can be proved is a tautology. For completeness we must show the converse, that every tautology in Fm^(C) can be proved from 0 using axiom schemata (HI), (HII), (HIII') and rule MP. Theorem 145. For all ip,ip 6 Fm^(£), (4.91)
-«p,
8. COMPLETENESS OP (HI), (HII), (HIII')
(4.92) (4.93) (4.94)
—1—\(I) \—
(4.95)
1—
(4.96)
—'— (fi
(Z5 1—
(4.97)
(I).
l
1—
—^- (/?
—'—'^«
(p —^
*
(4.98) (4.99) (p => ij), —Of => Ip \~P Ip.
(4.100)
(4.91): a proof of J/1 from y>, -195 is
PROOF
1. -,
Hyp.
2.
Hyp. (HII)
3.
-up
4.
ip => ( -T0 =>
5.
-iip
=> (
(HII)
y)
1, 3, MP 2, 4, MP
= > -MP
6.
P
7.
-nip)
8.
ip) :
=>. ( ( ^ v => v ) => V)
(HIII') 5, 7, MP 6, 8, MP
9. (4.92): By (4.91) and Th. 142. (4.93): a proof of ip from -1^3 => -iip, -up => ip is 1.
-i
Hyp.
=> -
2.
=> ((-1^3 => I/)) => y>)
(HIII') 1, 2, MP
3. h
Hyp. 3, 4, MP
(4.94): 1. 2.
p -i
^ip\-
p
3. -.-.(£ h 4.
—'^ => p
—'^
=>
(4. .67) 1, Th. 142
-l^ip
Tl 1.142, (4.70)
-1^3
P
-1^3
=>
5. - . - . v ? h
"
, -«p => -«p h ip
p
(4.95): By (4.94) and Th. 142.
(4. .93) 2, 3, 4, (4.68)
4. LOGIC WITH EQUALITY
(4. 96): 1. 93 h
(4.95), (4.70)
2. 93 h p 3.
—,—,—,
—1—1"-199 = >
4. 93h
(4.70), Th. 142 —K£>, —1—1—iy? =>- y?
h
199.
p
(4.93)
p
1, 2, 3, (4.68)
(4. 97): By (4.96) and Th. 142. (4. 98): 1. 99,-1^,-1-1(99 =^ tp) \-p ip ^
tp
(4.94), (4.70)
P
2. 99, -.t/), -.-.(99 =^ V) !" V P
(4-67)
1
3. 99,99 =^ V !~ V
("y5 => V>,
4. 99, -up, -1-1(99 => V) !~P V1
1, 2, 3 , (4.68)
p
5.
4, T h . 142
6. 99,-1^,-1-1(99 =^ -J/I) h p -it/i
(4.67)
p
7. 99,1V) h -.-.(99 => ip) => -up
6, T h . 142 p
8. -1-1(99 => tp) => -np,-i-i(
(4.93)
p
9.
5, 7, 8, (4.68)
(4.99): \~p p
1. 99 => tp,^p
( 4 . 9 4 ) , (4.70)
p
2. 99 => V , - ' - ' ¥ ' l" 99 ^> V>
(4.67)
P
3 . 99, 99 = ^ V !~ V> 4. p ^
(p ^
p
tp, -.-.99 h V
1, 2, 3, (4.68)
5. 99 => tp hp -.-.99 => tp 6. -*p,ip
4, T h . 142
=> ip hp -.-.99 => tp
7. -.V>, 99 => tp h
p
tp,
-.-.99 => -.V> p
8. -1-199 => -,^,-.-.99 =^> tp \- -mp p
9. -nip, p => tp \- -mp
5, (4.70) (4.67), T h . 142 (4.93) 6, 7, 8, (4.68)
10. 99 => tp hp -nip => -199
9, T h . 142
(4.100): 1. 99 ^
tp,^ip
=> tp \-p -up => -.-.99 p
(4.99), (4.70)
2. 99 => tp, -nip => tp \- -«p => -nip
(4.99), (4.70)
3. -up =^ -.-.99,-iV> => -199 h p V>
(4.93)
4. 199 ^> V, ¥> => V1 I" P «/>
1, 2, 3 , (4.68)
D
8. COMPLETENESS OF (HI), (HII), (Hill')
For every valuation v : St —> {T, F} and every formula
(4.101)
„ { [
?
[
it v(
Note that v(ipv) = T for every valuation v and every formula tp £ Fm+(£). Theorem 146. For every valuation v : St —> {T, F} and all formulas ip,ip € Fm+(£), (4.102)
(4.103) (4.104)
p",V" l"p (v => VO", st"(v3) h p v?".
PROOF. (4.102): There are two cases. 1. v(tp) = F
Hyp.
2. v?" = -mp
1, (4.101)
3. v{-mp) = T
1, (4.18), (4.13)
4. (-up)" = -i^)
3, (4.101)
p
5. -mp \- -mp v
(4.67)
p
v
6. ip \- {-mp) 1. t)(ip) = T 2.ip
v
2, 4, 5 Hyp.
= ip
1, (4.101)
3. v{-mp) = F
1, (4.18), (4.13)
4. (-.p)" = -n^ip
3, (4.101)
5. 9? hp -n^ip
(4.96)
p
6. 95" \- {~nip)
v
2, 4, 5
(4.103): There are three cases (not mutually exclusive). 1. v(1>) = T
Hyp.
v
2. ip =ip
1, (4.101)
3. t)(p => ip) = T v
4. (v? ^ ip) = ip => ip p
1, (4.17), (4.13) 3, (4.101)
5. i> \- ip ^ i>
(4.67), Th. 142
6. tp" ,ipv \-p (ip =^ ip)v
2, 4, 5, (4.70)
1. v(ip) = F
Hyp.
2. v?" = -.<£
1, (4.101)
3. v{ip^^) = l
1, (4.17), (4.13)
204
4, LOGIC WITH EQUALITY
> tpy = 4. (
v
=j. ^
p
(4.92)
5. -uph- p =$ ip "
H
"
(p
=" ^
r
1. «(*,) 2. tp
3, (4.101) 2, 4, 5, (4.70) Hyp-
= ¥?, ^ B = - . ^
1, (4.101)
3. «(93 :=>i/«) = F
1, (4.17), (4.13)
4. (93 =;
3, (4.101) p
-.(p =4- ^ )
(4.98)
6. 9 3 " , ^ " |- (tp => ipf
2,4,5
5. 93, - 1 ^; h
p
(4.104): Let X = {tp : tp g Fm+(£) and stv(tp) \-p tp0}. It suffices to show by induction that X = Fm+(£). To see that St C X, note that if
so, by (4.70), st"(p => ^ ) >-P ¥>" and stv(f => ^ ) I"P ^"- We have 97",^" K (99 => V)™ ^ (4-103), so st B (^ => V) h P (^ =5- VO™ by (4.68). Thus tp => ^ 6 X. To see that X is closed under -i, assume p G X, i.e., st"(ip) h p
9, COMPLETENESS OP (LI)-(LIII)
20S
Consider an arbitrary valuation v : St —> {T, F} and let w : St —¥ {T, F} be the same as v except that v(ipi-i) =/= w(ipi-i). By the inductive hypothesis we have
By the Deduction Th. 142, plus, in case i < n, the observations that ipf = ipf, ..., tpZ = ipn , we conclude that
(4.105) (4.106)
th — M^tf-i =>
or simply h p ^*_i => ^? and h p ^ L i =* ¥> in case t = n + 1. It follows from the choice of w that {ipl-\,ipt-i\ — {ipi-i,~^j>i-i}, and (4.107)
ipi-i =s- p,-.^i-i =4- p P V
by (4.100), so, by (4.105), (4.106), (4.107), and (4.68), we obtain %j}J,...,ijjl\-p(p if i < n and ^ * , . . . , ^ h p ^? if « = n + 1. This completes the proof by induction. Applying the result with i = n +1 yields Hp ip for every valuation v : St —> {T, F}, so h p (p. D 9. Completeness of (LI)-(LIII) In this section we show that Lukasiewicz's axiom schemata (LI)-(LIII) axe complete by deriving (HI), (HII), (Mil') from them. The axiom schemata (HI), (MI), (Mil') are complete, hence (LI)-(LIII) are derivable from (HI), (HII), (Mil'). Theorem 148. Assume C = £(C, IF, TZ, rank) is a nice language, n < u, and \-L is provability in Fm^(C) using axioms (LI), (LII), and (LIU) o-nd rule MP. Let f 6 FmJ(£). ip is a tautology iff\~L (p. (Lukasiewicz [243]) We will show that hL ip whenever p is an instance of (HI), (HII), or (Mil'). Recall that MP is a set of triples. It is a functional relation, in that if {ip, ip, p) and {tp, ip, a) are in M P then p = a. We will treat MP in this proof as a partial function. This means that MP(ip,i/>) is defined to be p if ip = ip p and undefined otherwise. Below we define 36 functions on formulas and draw 33 conclusions listed after the definitions. Our claim, which needs to be confirmed as part of the computations carried out in this proof, is that each of these functions is defined on all inputs and produces the indicated output. For example, our claim concerning fi is that for aH(p,ip,p,a G Fm£(£) the partial (tp p),a) operation MP is defined on the pair of inputs fi(
and, furthermore, the output r of M P on those two inputs is f4(p,ip,p,a)
=T= (((ip => p) => {tp => p)) => or) ^ {{ip => ip) => a).
206
4. LOGIC WITH EQUALITY
The range of /i is the set of instances of (LI). Therefore, hL fite,ip,p) for all tp,ip,p 6 Fm+(£). From our claim concerning / 4 we know that / 4 (^J, ,p,
MP(/ 4 (v?,V,/0,((v=>p)=^)=> (W => P) =^ <*)), fi(ip => p,
fw{f,ip) := MP(fg(
/6(-.^,v,v,v)), fu(>p,ip)
MP(MP(/io(Hp => f) =>
fi4(
ip) : = MP(/ 9 (v?, V, W> =3- v>) => V), / i 5 ( v , ^ ) ) ,
fa{
f2Ote,^)
:
=
2lte,1P,P) 22te,1p,p)
MP(f5(ip,1p ^ P,P,
te, VS P, a)
MP(/i(v? ^(ip^p),ip^(v^-
fiite,
fate,
p), a), f21 (ip, tp, p)),
V>) := MP(MP(/ 23 (v?, "«^, tp, (te => */>) =>
fste,i>)),
9, COMPLETENESS OP (LI)-(LIII)
2
2i(
fso(
=> p),f
:
= M P ( / ( /
(
)
ip,ip =$>i/),p,ij} => p),
fM((p,i/>,p)),
v?=J- {if)^tp),tp^ip,!p^ Then, for all ip,ip,p,a,r
p),f$*,{
£ Fm+(£),
fi{
, p, or,r ) = (r => ((¥? =* p) => ff)) => ((¥? =* V>) ^ (r ^ ( ( ^ => p)
ft,{
((tp =>iP)=> ((p => ff) ^ (p ^ «r))),
M
hi{
f),
fi2{tp,r) = T => ((-iy> =>*?)=> y), fi3{p,ip,T)
= (-.p ^ ^>) => (T =4- ( ( ^ =S- v) =* ¥>))
fii{
{{i> ^P)^
fie(
= {(p =* (^ => p)) => (^ =>(¥>=> p)),
/22(V» V>,/») = (^ =* P) => ((¥> ^1p)^(V^ hi{v^,P,a)
p)),
= ( ( ^ =* (9? ^ p)) ^ er) ^ ((9? =^ (^ => p)) ^ er),
8
4. LOGIC WITH EQUALITY
f25(
,
1
1
/27(v, V ) = (OP => V ) => VO => (00 =>
/ 3 o(«p, V>) = ( ^ =^ ( ^ =^ V1)) => (¥> => V1), f3i(ip,ip,p,(7) = (v^a)^
(((
h2{tp,1p,p,(T) = (('fi^ip) =>p)=> (0?=>ff)=> ((o-=^p)=>p)), fa{
((
f34(
((if => {if) => p)) => (y>=^p)).
What remains is to deduce the instances of (HIII'). Let (p,i/j £ FmJ(>C). First, notice that
From (LIII) we know that ip, -rtp h L ip. Therefore (4.108)
-up, -up => -itp,-up
=4> ip h L ip.
We have shown that hL x whenever \ IS a n instance of (HI) or (HII). Therefore the Deduction Theorem holds for h L . By the Deduction Theorem and (4.108), we get -up => -iip, -up => ip h L -up => ip.
From (LII) we know that -up => ip hL ip, so (4.109)
-.
By applying the Deduction Theorem to (4.109) we get (4.110)
hL (-.p = -.t/;) => ((-.yi = t/;) => y>).
From Th. 147 we know that every tautology is provable using (HI), (HII), (HIII'), and MP. We have also just shown that hL \ whenever \ S Fm+(£) is an instance of (HI), (HII), or (HIII'). Therefore, every tautology is provable using (LI)-(LIII) and MP.
10. Quantifier axioms In this section we present consequences of axiom schemata (AI)-(AIII) (the closures of Lukasiewicz's axioms schemata (LI)-(LIII)) together with the quantifier axioms (AIV)-(AVII). The next theorem, due to Quine, may be described as a kind of modus ponens for closures of formulas.
10. QUANTIFIER AXIOMS
209
Theorem 149 (Quine [202, '111], [204, "111]). Assume C = C{C,F,1l, rank) is a nice language and n < u. Let h j be provability in SentJ(£) using axioms (AV)-(AVII) and ruleMP, Suppose ^ , ^ 6 Fm+(£). (4.111)
J/H+ [v => 4] and h+ [
PROOF. The proof proceeds by induction on the number of free variables in ip => ip. Base case: If |free(^? => ip)\ = 0 then [tp => ip] = tp => tp and [tp] = ip, so (4.111) asserts that if h+ ip ^ ^ and h+ tp then h+ ^ . This holds by Th. 140. Inductive case: Now we assume that (4.111) holds for k (our inductive hypothesis) and show that it holds for k + 1. Assume \free(tp => iji)\ = k + 1 and (4.112)
H+[p=>^].
(4.H3)
h+M-
Let x € free(^? =^ ^) such that [^? => i/i] = [Vx((p => i>)]- Then (4.112) implies
(4.114)
KMV.te^)]-
Note that IfreefV^f^ => i>) => (VK^ =^ V a ^))| = k and we have (4.115)
h+ [V.(yi => V) => (V.v =* V,V)]
by (AV), so it follows from this and (4.114) by the inductive hypothesis that (4.116)
h+ [V.10 => V , ^ ] .
If a; € free(^) then [^?] = [ V ^ ] , so (4.113) implies (4.117)
H+ [%
On the other hand, if x $ free(tp) then \free(tp => Va,^?)| < k, and we have (4.118)
H+Iy.^V.p]
by (AVII), so once again (4.117) holds, this time by (4.113), (4.118), and the inductive hypothesis. Note that |free(Va.^ => Vs^OI = k, so by (4.116), (4.117), and the inductive hypothesis we have (4.119)
H+ [V,tf ].
If x 6 free(^) then [tji] = [Va,^] and so we get (4.120)
H+ [tf]
by (4.119) alone. On the other hand, if x £ free(^) then IfreefVaj^ =^ tf>)\ < fc, and (4.121)
h+ [ V ^ => V]
by (AVI), so we again obtain (4.120), this time via (4.121), (4.119), and the inductive hypothesis. As a corollary we get the propositional completeness theorem for closures of tautologies.
210
4. LOGIC WITH EQUALITY
Theorem 150. Assume C = C(C,J-,1Z, rank) is a nice language and n
If\-+ [if = V ] and h + [t/> =* £ ] *>>en ^ n [ v = £ ]
(4.123)
If
Fm + ( £ ) «s a tautology,
then h + [ p ] .
PROOF. (4.122) can also be deduced directly from just (AI) and (4.111). Thus the proof of (4.122) actually requires only (AI) and (AV)-(AVII). From Lukasiewicz's Completeness Th. 148 and Quine's theorem (4.111) it follows that (AI)-(AIII), (AV)-(AVII) suffice to deduce the closure of every tautology, so (4.123) holds.
Quantifier prefixes arising from closures distribute over implication. Theorem 151 (Tarski [235, Lem. 20]). Assume C = C(C, T, 11, rank) is a nice language and n < UJ. Let h+ be provability in Sent+(£) using axioms (AI)(AIII), (AV)-(AVII) and rule MP. If
Vifc_1(v
=> ip),
then (4.124)
h + [ ^ => V] => ( V v v - V v ^ ^ = V v ^ - ' - V v ^ ^ ) .
PROOF. The proof is by induction on k. If k = 0 then the desired result is a special case of (4.123). We will assume as inductive hypothesis that the theorem holds for k and prove it for k + 1. Accordingly, let us suppose that
(4.125)
[
This hypothesis tells us that free( ip) = {v; 0 ,..., VjJt_1, v,fc} and io < 4_i < ifc. It follows that (4.126)
[ V V i > => V) => (Vvifcv => Vvife^)]
(4.127)
[V Vife ^ => V v i ^ ] = V v i 0 - - - V v i f c _ 1 ( V V i ^ => V Vifc ^).
From (4.125), (4.126), (4.127), and our inductive hypothesis we conclude that h+ [V Vifc (^ =* V) => (VVifc¥3 = VVifcV)]
(4.128)
= ([¥> => V] => [VVifcV= = V vlfc V])By (AV) we have (4.129)
h+ [VVifc(v5 = il>) = (VVifc¥3 => V Vifc V)],
so by (4.128) and (4.129) we get (4.130)
h+ [ p = V] = [Vvifc¥> => VVifcV]
by (140). From (4.127) and the inductive hypothesis we obtain (4.131)
h + [ V v . v? = Vv. V] =
<
10. QUANTIFIER AXIOMS
By (4.130), (4.131), and (4.122) we finally obtain (4.132)
h + [ ^ => V] => ( V v ^ - ' - V v ^ ^ V v , ^ => V VJ0 ---Vv iik _ 1 Vv jfc V),
as desired. By adding (AIV) we can show that quantifier prefixes may be permuted. T h e o r e m 152 (Tarski [235, Lem. 21]). Assume C = C(C,F, 11, rank) is a nice language and n < LV. Let h j be provability in Sent^(C) using axioms (AI)(AVII) and rule MP. If ip E Fm^(£), a is a bijection between k < n and free(ip), and TT is a permutation of k, then (4.133)
h+ y a o
ak_1
ya^0---yawk_lV.
PROOF. We only prove the theorem whenever -K is a transposition. The general result follows by induction using (4.122) and the fact that every permutation of a finite set is a product of transpositions. We proceed by induction on k. If k = 0,1 the result holds by (4.123) (closures of tautologies are provable). Assume k > 2 and, as inductive hypothesis, that the theorem holds for every permutation of every m < k. Suppose TT interchanges m and m + 1, where 0 < m < k — 1. Let Va = yao
afe_1,
vv = Vc0
Qm1
,
V™ = v Q m + 1 v a m v a r o + 2
yak_t
We wish to prove that for all tp and a, (4.134)
H+Va¥> = V,ra¥>.
From the injectivity of a and {ao, {a 0 ,
,«fc-i} = free(
,am_i} =
There is some permutation A : m —> m such that VxtXvV = [Vv*p], Since Va = VMVV and V^ai^ = VMV,r,,
(AIV)
2.
h+ V A M V ^
1, (4.124), MP (Th. 140)
3.
h+ V M V ^
=> V\v>l™v ^
VAMV^
Ind.
Hyp.
212
4. LOGIC WITH EQUALITY
4. h+ Vx^vf
=> V^v
5. h + V M V ^ => V M V ^
Ind. Hyp. 3, 2, 4, (4.122)
The next result may be described as a kind of generalization rule for closures. T h e o r e m 153 (Quine [202, * 112], [204, *115]). Assume C = C{£,F, U, rank) is a nice language and n < u>. Let h^ be provability in Sent^(£) using axioms (AI)-(AVII) and rule MP. Suppose ip £ Fm+(£) and x £ Vn. (4.135)
If\-+[V],ihen\-+[Vx
PROOF. If x £ free(^) then the result follows by (AVII) and (4.111). If x E free(^) then the result is a special case of (4.133). The proof of Quine [204, "115] is not suitable for n-variable logic because it requires variables beyond those free in (p. Such variables may not exist in a language containing only a fixed finite number of variables. On the other hand, the switch from Quine closure in Quine [202] to Berry closure in Quine [204] made it possible to avoid the axiom schema (AIV). 11. Equality axioms Now we add the equality axiom schemata (AVIII) and (AIX). In the following theorem and its proof we use aR(
Ifx i free( V) => (P => V ^ ) ] . Ifn>2then\-+[x=x].
(4.138) Ifn>2
then h+ [x=y => y=x].
(4.139) If\-+ [x=y => (ip => V)] thenV-l [y=x => (-.^ => -,
=> (ip => rj))\
(4.141) If\-+[x=y
=> (if => tl>)\ thenVt\x=y
(4.142) Ifz^x,y,
\-t[x=y
(4.143) IfR(
\-+[x=y
tiienY-+[y=x
=> ((f =>
=> ( V)] then^+[x=y => (Vzip => \f^)].
then h+ [x=y => (
(4.145) Ifx + y then h+ [ V ^ => Subxyip]. (4.146)
=> ((«/> => 0 => (ip => ?))]
h + [Vxtp => Subxycp].
11, EQUALITY AXIOMS
213
PROOF. (4.136): Assume zc ^ free(
(AV)
2. h + [ ^ = V.p]
(AVII) v
3. l-« [V a (^ => V) => (¥> => ®^)]
!. 2> (4-111), (4.123)
Proof of (4.137): Let y be a variable distinct from x. This is possible since we assume n > 2. h+ [j/=a =}- (y=a; =s- T = T ) ]
(AIX)
h+ [-.x=a! => - v = x ]
(4.111), (4.123)
h+ [^x=x
=> V,(-.y=3!)]
(4.111), (4.136)
h V , ( - . y = i ) => i=3!]
(4.111), (4.123)
^
\-+[x=x\
(AVIII), (4.111)
Proof of (4.138): ^t [x=y => (x=x => y=x)\
(AIX)
h+ [s!=3! => (x=y => y = i ) ]
(4.111), (4.123)
h+ [x=y => y=x]
(4.111), (4.137)
Proof of (4.139) and (4.140): By (4.111), (4.123) and (4.138). Proof of (4.141): By (4.111), (4.123). Proof of (4.142): If z j= x, y then h+ [V,(x=» =
Hyp., (4.135)
h+ [a;=y =^- V»(v? => V)]
(4-111), (4.136)
H+ [a;=y ^ ( V ^ =4- V,^)]
(AV), (4.122)
Proof of (4.143): Let P be the set of all tp g Fm+(£) such that for all i> 6 Fm+(£) . Let 8j. be set of and all x,y G VB, if R(ip,tp,x,y) then 1- a:=j/ => (tp => (p 6 FmJ(£) with exactly fe occurrences of =>, -i, or V. Using (AIX) and (4.139)(4.142), one can prove by induction on k G w that 8*. C P. Then Fm+(£) = Proof of (4.144); If ^5 = Sub|^? the result follows by (4.123). If tp ^ Subfyi there is a sequence (£o, ,^i) of formulas where tp — £0, Sub|^J = £j, and ii(^j,^j+i,a;,j/) for i = 0, , I. We obtain (4.147)
h+ x=y => (tp => fj)
for all t < I by induction on i, using (4.111), (4.123), and (4.143). The desired result is the case « = I.
214
4. LOGIC WITH EQUALITY
Proof of (4.145): Assume x / y and let tp = Sub^ tp. Note that x £ free(ip). I—^~ [x=j/ =>( ip)]
(4.144)
^t [v => h4> => ^x=y)]
(4.111), (4.123),
h+ [Wxtp => Vx(-itp =4> -*x=y)]
(4.135), (AV), (4.111)
h+ [ixtp => (-.^ => Vx^x=y)]
(4.122), (4.136)
l"n [-Nx^x=y
(4.111), (4.123)
=> ( V ^ => t/>)]
h+ [ V ^ => ip]
(4.111), (AVIII)
Proof of (4.146): From (4.145) and (AVI). 12. Axioms for a binary relational language We say that £ is a binary relational language if £ is a nice language such that £ = £(0, 0,1Z, rank) and rank*(7?.) C {2}. It will become apparent that for such languages it is convenient to restrict n so that 3 < n < w. Assume that £ is a binary relational language and adopt the definitions in Tables 1 and 2. In particular, h+ (if n > 4, h+ in case n = 3) is provability in Sent+(£) using axioms (AI)-(AVIII), (AIX'), (DI)-(DV), and rule MP. Thus h+ is the notion of provability for the formalism £+ if \U\ = 1 and M(nk)+ if k = \TZ\ > 1. The presence of (AI)-(AVII) in the axiom set for £ j implies that the following results apply to h+: (4.111), (4.122), (4.123), (4.124), (4.133), (4.135). To know that (4.136)-(4.146) also apply to h+, we need to show that h+ tp whenever tp is an instance of schema (AVIII) or (AIX). Now all instances of (AVIII) are included in the axiom set for h j , and we show next that every instance of (AIX) is provable in £+, as noted by Tarski-Givant [240, p. 68, p. 70, fn. 13*]. Consequently (4.136)(4.146) hold for h+. T h e o r e m 155. Assume £ is a binary relational language and 3 < n < u>. Let h+ be provability in Sent+(£) using axioms (AI)-(AVIII), (AIX'), and rule MP. Then h j tp whenever tp is an instance of (AIX). PROOF. (Givant) Consider an instance of (AIX), say where tp is atomic, x £ var(tp), and tp is obtained from tp by replacing a single occurrence of the variable x by the variable y. Since every relation symbol is binary, we have tp = Ruv for some u, v € Vn with x = u or x = v. If u / v then £ is actually an instance of (AIX'), hence h^~ £. Suppose u = v = x and tp = Rxx. Then either ip = Rxy or ip = Ryx, say ip = Rxy. Then 1. h [t/=a; => (-iRxy => ->Rxy[y/x])]
(AIX')
2. I- [y=x =^ (-
1, def. of [-/-]
3. \-[y=x = (Rxx => Rxy)]
2, (4.111), (4.123)
4. \-[x=y => y=x]
(4.138)
5. I- [x=y =^ (Rxx => i?a;y)]
3, 4, (4.122)
12, AXIOMS FOR A BINARY RELATIONAL LANGUAGE
218
For an arbitrary nice language we let h* be probability in FmJ(£) using axioms (HI), (HII), (HIII'), (HIV), (HV'), (HVI'), (GVII), (GVIII), (AIX*), (DI)(DV), and the rules MP and Gen. For a binary relational language, with no constants or function symbols, every instance of axiom schemata (HV') or (HVI') is an instance of (HV) or (HVI), respectively. For ordinary logic with infinitely many variables this axiomatization is redundant but has the advantage of being a satisfactory axiomatization even if n < u). The axioms we have chosen for H^ are based on the axioms used by Henkin, together with simplifications taken from Quine [202, 204] and Tarski [235]. As Tarski-Givant [240, p. 8] point out, avoiding the notion of substitution and the rule of generalization helps to simplify their proof of the Main Mapping Theorem for £x and £+. But they found that simply restricting Tarski's axioms (AI)(AIX) to a fixed finite number of variables does not produce an adequate axiom set, so they explicitly included axiom schema (AIX'). The axioms chosen here for h£. incorporate the suggestion of Tarski-Givant [240, p. 70] regarding the axiomatization of finite-variable logic, that schema (AIX") should replace schema (AIX'). Since we prove the Main Mapping Theorem by means of Tarski's QRA theorem, there is no advantage in avoiding Gen, and for some proofs it is actually more convenient to use formulas instead of restricting provability to their closures, as illustrated by the following theorem which, along with Th. 157 and Th. 158 below, applies to an arbitrary nice language £ and any n
i. y-n V , V B V = vv
(cv)
2. hi Vylfi => if
(CV)
3. V4. h
h n
h n
Vmyv(p => tp
V a (V x V s 9? =>
5. Y\ VxVv
> Vxv)
1, 2, prop. cal. Gen
(HIV), Th. 140 Gen
4. LOGIC WITH EQUALITY
7. hhn VxVv
6, (HIV), Th. 140.
T h e o r e m 158. \~n Vz(<^> =£* ip) =£* (Vx^? =^ ^x^P) PROOF.
1. hj^ Va,(v? => ^> ) = > ( < £ = >
^>)
(CV)
2. h ^ Va;^ => y>
(CV)
3. \~n Va,(v? => ip) => (Vxip => ip) 7
1, 2, prop. cal. 7
4. \~n Va;(Vx(<^ =^ V ) ^* (yx^p =** V )) h
Gen
5. h n Mx{ip => V) => V ^ V ^ ^> V)
(HIV), T h . 140
6. hj; V^^v? =^> ip) => (Wxip => \/xip)
(HIV)
7. h n Va;(i^ => ip) => (Va;^ =^ Vj;?/')
5, 6, prop. cal.
D Theorem 159. Assume that C is a binary relational language, 3 < n < to, and ip E Fm+(£). Then r-!j ip iff\-f [ip] and, for n>A,\-hnip iff\-+ [
(4.148) J2:={p:peFm+(A K First we observe that fl closed under MP and Gen according to (4.111) and (4.135), respectively. What remains is to show that O contains every formula ip £ Fm^(jC) that is an instance of one of the axiom schemata. If
13. QUOTIENTS OF INTERPRETATIONS
217
whenever ip is an instance of one of the axiom schemata (AI)-(AVIII) or (AIX'). Every instance of (AI)-(AIII) is the closure of some tautology ip, but we have h^ (p by Th. 147, so its closure is also provable by Gen. Every instance of (AIV) is provable by Th. 157 and Gen. Every instance of (AV) is provable by Th. 158 and Gen. Every instance of (AVI) is an instance of (HV') because every variable is free for itself in every formula, so every instance of (AVI) is provable. To see that every instance of (AVII) is provable, suppose ip G Fm + (£), x G Vn, and x £ free(^). We have \-hn tp => ip by (4.76), so \-hn Vx(
Y-lip
iff h + ^ iff \=
PROOF. Indeed, if h^ ip then h+
13. Quotients of interpretations In the next few sections we prove Godel's Completeness Theorem under the assumptions that - £ = C(C, T, H, rank) is a nice language, - V-1 is provability in Fm + (£) using axioms (HI), (HII), (HIII'), (HIV), (HV), (HVI'), (CVII), (CVIII), (AIX*), (DI)-(DV), and the rules MP and Gen. Since we are restricted to the assumption that there are infinitely many variables, we will simplify our notation and write hh in place of h^. Most of the proof involves only the axiom schemata (HI), (HII), (HIII'), (HIV), (HV), (CVII), and (DI)-(DV). It results in the construction of a loose interpretation with various properties. The remaining axiom schemata are (HVI'), (CVIII), and (AIX*). When they are satisfied by a loose interpretation, it is possible to create an interpretation as a quotient. Suppose M is a loose interpretation for £ with domain M, and M is a model of (HVI'), (CVIII), and (AIX*). Let E = (=)M = VM. Then E is reflexive over M because M is a model of (HVI'), transitive because M is a model of this instance of (CVIII): Vl=V 2
=> (vo=Vl
=> V 0 =V 2 ),
218
4. LOGIC WITH EQUALITY
and symmetric because M is a model of this instance of (AIX*): Vo=Vl => (vo=Vl => Vl=Vo).
Thus E is an equivalence relation on M. Furthermore, since M is a model of various other instances of (CVIII), we can show that E is a congruence relation with respect to the interpretations of all other function and relation symbols. In more detail, this means that if / £ J , fi £ K, rank(/) = rank(ii) = r, a i , . . . ,ar 6 M, 6i,... ,br E M, and (ai,foi),..., {ar,br) 6 E, then (fM(a1,...,ar),fM(b1,...,br))eE, (ai,...,ar)eRM
(b1,...,br)ERM.
iff
This can be proved by induction on r using particular instances of (CVIII). Suppose xi,... ,xr,yi, ,yr are distinct variables. Then, since M is a model of instances of (CVIII), we have M
\= Xl=yi
=> (Rx 1X2X3
-Xr-lXr
M \= xi=yi
=> (Ryix2x3---Xr-iXr
M \= xr=yr
=> (Ryiy2y3-
=> RyiX2X3
-Xr-lXr),
=
-yr-iXr
=> Ryiy2y3
-yr-iyr),
hence r
M \= f\ Xi=yi => (Rxix2x3
xr => Ryiy2y3
Let s £ " M be a sequence that assigns xi, ..., xr, yi, . . . ,for,respectively, i.e., if x% = VJ then SJ = aj, eic. Then
yr)yr to 01, . . . , ar, 61,
r M
\= f \ Xi=yt i=i
=> ( i ? a ; i x 2 x 3
xr => Ryiy2y3
[s],
but, by the hypothesis that (ai, foi),..., (ar,br) 6 i?, we have r
-M |= ^ i = » i W , i=i
so M
\= Rx\x2X3
xr
Ryiy2y3
-yr[s],
M
which tells us that if (a\,..., ar) 6 R then (foi,..., br) 6 RM. Using an instance of (HVI') as well as more instances of (CVIII), we have M
\= fxiX2X3
M
\= Xl=yi
Xr=fxiX2X3 => (fxiX2X3 => JX\X2X3
M\=X2=y2
=>
Xr, r-lXr=fx\X2X3
Xr-lXr=fyiX2X3
Xr-lXr Xr-\Xr)i
(fx1X2X3---Xr-1Xr=fy1X2X3---Xr-1Xr xr-1xr=fy1y2X3
xr-ixT),
14. CONSISTENT AND COMPLETE THEORIES M \= xr=yr
=> (fxix2x3
r-ixr=fyiy2y3
=> fxix2x3
219 -yr-ixr
xr-1xr=fyiy-2y3
yT-iyr),
hence T
M\=
f \ Xi=yi i =l
=> fxix2x3
xr=fyiy-2y3
yr-
It follows that if (au fei),.. ., (ar, br) 6 E then (fM(au ..., ar), fM(bu ..., br)) 6 E. This congruence property of E makes it possible to define another loose interpretation M/E, whose domain is the set M/E of ^-equivalence classes of elements of M, as follows: CM/E
RM/E
._
CM/E
for
— {(ai/E,...,
fM/E(ai/E,...,
e y e r y
c e
C ;
RM},
aT/E) :(a1,...,aT)e
aT/E) := fM(au
..
.,ar)/E.
The congruence property of E is required to show that the last formula is unambiguous. It can then be proved by induction that for any formula ip and any sequence s E"M, M \=ip[s]iff M/E \= tp[s/E], where s/E 6 "(M/E) is defined by (s/E)i = Si/E for every i G w. Hence the same sentences are true in M and M/E. Furthermore, the interpretation of = in M/E is the identity relation on M/E, since =M/E = {(a/E,b/E) : (a,b) G E} and a/E = b/E iff (a,b) G E. Thus M/E is an interpretation. We gather these observations into a theorem that will be applied in the proof of Th. 169. Theorem 161. Suppose M is a loose interpretation for C, M is a model of (HVI'), (CVIII), (AIX*), and E = (=)M. Then E is a congruence relation on M, the quotient M/E is an interpretation, and M \=
220
4. LOGIC WITH EQUALITY
Theorem 163. 0 is consistent. PROOF. For a given nice language C = C(C, J-, 1Z, rank), define M as follows. Let M = {0}, let cM = 0 for every constant c G C, let RM = M r a n k ( f l ) for every relation symbol R € 11 with rank(iZ) > 2 and RM = M if rank(i?) = 1, and let fM(0,...,0) = 0 for every function symbol / € T. Also, let (=)M = VM = M1, so that M is an interpretation. Let s = (0, 0, 0, 0,...). Assume 0 is not consistent. Then h h tp and h h -up for some sentence ip. By the Soundness Th. 141, |= ip and |= -iv?) so M \= tp [s] and M \= -up [s], a contradiction. T h e o r e m 164. Assume $ is consistent and ip € Sent + (£). Then (i) either $ U {y} is consistent, or else $ U {~"^} is consistent, (ii) $ U {ip} is inconsistent iff $ h h -iy>, (iii) $ U {-«p} is inconsistent iff & h h ip. PROOF. Part (i): Assume $ U {ip} and $ U {"'y'} are both inconsistent. Let V> € Sent+(£). Then *, tp h h V and $, - i ^ h h ^ . The Deduction Th. 142(ii) may be applied since ip is a sentence, so $ h h ip =h ip and $ h h -195 => t/;. We have h h (
f TK U {VvJ ^T«
S
if TK U {ipK} is consistent otherwise
For every limit ordinal A < a, let T\ := UK
TK is consistent for every K < a.
The proof is by (possibly transfmite) induction on K. TO is consistent by hypothesis. If TK is consistent, so is T K +i, by definition. Let A < a be a limit ordinal, and assume TM is consistent for every pi < X. If 7 \ is inconsistent, then by (4.69) there are sentences ipi,..., ipm G T\ and tp G Sent + (£) such that ipi,..., ipm h h tp and ipi,..., tpm l~h ""£ For each i = 1 , . . . , m, we have xpi £ T\ = U«
IB. WITNESSES
221
there is some KJ < A such that ipi € TKi. Let fi = max(Ki,..., Km). Then /* < A and ipi,..., ipm £ Tp since TKi C TM for « = 1 , . . . , m. Hence TM is inconsistent, a contradiction. Thus (4.150) holds, so Ta is consistent. Next we show Ta is complete. Let
Witnesses
If C C C is a set of constants of a nice language £, and # C Sent+(jC) is any theory, we say C is a set of witnesses for # if for every formula tp with one free variable x £V, there is some constant ce C such that # Hh Sub;?((p) => ¥3:93. Theorem 166 (Witness Interpretation Theorem). Assume that C is a nice language, C = C(C, T\ 7Z, rank), # C Sent + (£), # is consistent, # is complete, C C C is a set of constants of C, and C is a set of witnesses for # . Lei (4.151)
M :={t:t
e Tm(£), var(<) = 0}.
For every constant cfzC, every function symbol f € J-, and every relation symbol , let Re (4.152)
cM := c,
(4.153)
fM(h,...,tT):=fti---tr
(4.154)
RM :={{tu...,tT)
ifh,...,tT :tu...,tr
eM
and r = r a n k ( / ) ,
£ M, r = rank(ii), # hh Eti
-tT}.
Then M is a loose interpretation for C and M \= # . PROOF. First we show, for every * € W M and every t € M, that (4.155)
sM(t)=t.
For a fixed sequence s G " M we will prove sM(t) = t by induction on the complexity of terms. If t is a constant, then sM(t) = tM = t by (4.152), so we may assume t = fti---tT and sM(ti) =ti, ..., $M(U) = U, Then sM{ft1---tr)=fM{sM{t1),...,sM{tr))
222
4. LOGIC WITH EQUALITY
fM(U,...,tr)
= = ft1---tr
(4.153)
Next we show that if we have a relation symbol R E 72.UII with rank r = rank(i?), terms t\,...,tT E M, and a sequence s E wM, then M\=Rh---tr[s]
(4.156)
iff
$h
h
Rh
T.
u
We do this by induction on predicates for a fixed s E ' M. The base case is that R € 72.U {=}. In this case the following statements are equivalent: 1. M
\=Rti---tr[s] sM{tr))
M
2. (s (h),...,
E RM
definition of |=
3. ( t i , . . . , i , . ) e B M h
4. * h RU
(4.155)
tr
(4.154)
Next we assume that (4.156) holds for A, B E II and show that it also holds for A + B, A;B, A, and ~A. We deal only with A + B and A;B. The following statements are equivalent. 1. M \= tiA + Bt2 [s] 2. ( s M ( ( i ) , sM(t2)) M
+ B)M
e(A
M
M
definition of |=
M
definition of {-)M
3. {s {t1), s (t2)) EA UB 4. (sM(ti),8M(Jt2))
€ AM or (sM(ti),sM(t2))
€ BM
5. ^W |= tiAt2 [s] or M \= tiBti [s] h
definition of |=
h
6. * h txAU or * h txBU
(4.156) for A, B
h
note (a) below
h
note (b) below
7. $ h tiAt2 V hBt2 8. * h tiA + Bt2
Note (a): Clearly statement 6 implies statement 7 by propositional calculus. For the converse, suppose statement 7 holds. If $ hh t\At2 then statement 6 holds. If not, i.e., $ l/1 t\At2 then, since t\At2 is a sentence and $ is complete, we have $ hh -itiAt2. But then we conclude by propositional calculus from this and statement 7 that $ hh t\Bt2, and again statement 6 holds. What this shows is that for any sentences £ and \ , $ hh £ V \ iff $ hh £ or $ hh \Note (b): We have an instance of (DI): o l
(
Bvi « (v0Avi
Since the terms t\ and t2 have no variables by (4.151) and therefore are free for every variable in every formula, we also have these instances of (HV'): l"h VVOVV1 (v 0 A + flvi «
(v o -4vi V
hh (tiAt2VtiBt2)).
15. WITNESSES
We conclude by propositional calculus that hh to A + Bti <^> (toAti V Consequently statements 7 and 8 are equivalent. Next we consider A;B. First we prove (4.156) in one direction. 1. M \=tiA;Bt2[s]
Hyp.
2. {ti,t2) £ (A;B)M
definition of \=, (4.155)
3. (tut2)
M
eA \B M
4.
M
definition of (-)
and (t3,t2) £ B
M
for some t3 £ M
5. M\= tiAt3 [s] and M \= t3Bt2 [s] h
(4.155), definition of |=
h
6. * h tiAt3 and $ h t 3 Bt 2
(4.156) for A,B
h
7. * h tiAt3 A <3-Bt2
prop. cal.
8. $ h 3V2(ii^4v2 A v2Bt2)
(HV'), prop. cal.
h
9. h V V 0 V v l (v 0 A;Bvi <^ 3v 2 (vo4v 2 A v 2 Bvi)) h
10. h tiA;Bt2
-» 3V2(i]
A v 2 Bt 2 )
(Dili)
(HV'), prop. cal. 8, 10, prop. cal.
Now we proceed in the opposite direction. 1.
$\-htiA;Bt2
Hyp.
h
(Dili), (HV'), prop. cal.
h
3. $ h -.(
for some c £ C
4. * h h
prop. cal.
5. * h h
2, 4, Th. 140
6. * hh tiAc and $ hh cBt2
prop. cal.
7. M\= hAc[s] and M \= cBt2 [s]
(4.156) for A,B
8. {sM(t1),sM(c))eAM
definition of |=
2. * h 3V2(ti^4v2 A v2B<2)
and{sM(c),sM(t2))£BM
definition of
AM\B
9.
definition of (-)
10. 11.
definition of |=
\=tiA;Bt2[s]
This completes the proof of (4.156). Next we show that for every tp £ Sent + (£) and every s £ " M, (4.157)
iff
We prove (4.157) by induction on the number of connectives and quantifiers in sentences
4. LOGIC WITH EQUALITY
prove (4.157) for A = B, where A, B G II. There is a witness Co G C such that
(4.158)
and a witness ci £ C such that hh
(4.159)
c0Bci) => V vl (c 0 Avi <^> c 0 Bvi).
By (DV), hh A = B <£> VvoVvl(voylvi <£> v 0 Bvi),
(4.160)
so by propositional calculus we obtain $ hh (coAci « coBci) = A = B. We also get * hh A = B = (coAci & c0Bci)
(4.161)
without the use of witnesses, appealing instead to (4.160), instances of (HV'), and propositional calculus. Consequently $ hh (coAci « c0Bci) « A = B.
(4.162)
Now we show that M \= A = B [s] implies $ hh A = B. M \= A = B [s] M
A
= B
Hyp. definition of \=
M
((co,ci) £ A
and (co,ci) £ B
)
M
or ((co,ci) 0 i and (co,ci) 0 B M ) (.M |= coAci [s] and 7\4 |= coBci [s]) or (A4 ^= CQACI [S] and A4 ^= coBci [s]) h
(4.155), definition of |=
h
(* h coAci and * h c0Bci) or ($ t/h coAci and $ t/h CoBci)
(4.156)
($ hh coAci and $ hh coBci) or ($ h -ico^4ci and $ h h
$ r
CQACI <^> CQBCI h
*r
$ is complete prop. cal. prop, cal., (4.162)
A= B
For the opposite implication, proceed as follows. M^A AM
= B[s] j M
({tut2)<EAM
Hyp. definition of |=
and ( t i , t 2 ) £ B M )
or «ti,*2> ^ AM and <*i,*2> € BM) (M \= hAt2 [s] and M ^ t\Bt2 [s])
for some ti,t2 € M
16. WITNESSES
225
or (M ft hAt2 [s] and M \= hBt2 [s]) h
h
($ h tiAt2 and $ \f
(4.155), definition of |=
tiBt2)
or ($ l/h tiAi 2 and $ hh tiBt2) h
(4.156)
h
($ h t\At2 and $ h -ifiBt 2 ) or (<3> hh —iti>lt2 and $ hh t\Bt2) h
t\Bt2)
h
<=> tiBt-2
$ h -i(ti7lt 2 $ l/ t\At2
$ is complete prop. cal. $ is consistent
h
$ l/ A = B
(4.162), prop. cal.
This completes the proof that (4.157) holds for all atomic formulas. Assume (4.157) holds for tp e Sent+(£). We prove it for -up E Sent+(£), first in one direction, M\=^tp
[s]
M. \/= tp [s]
Hyp. definition of |=
h
$ l/ ip
(4.157) for tp
$ h -itp
$ is complete
and then the other: $ h —up
Hyp.
$!/(/?
$ is consistent
M^tp[s]
(4.157) for 99 definition of |=
M\=^
Assume (4.157) holds for tp,ip G Sent+(£). Sent + (£), first in one direction,
We prove it for if
M ^ tp => tp [s]
Hyp.
M \=
definition of |=
$ hh tp and $ \/" tp
(4.157) holds for tp and «/
h
h
$ h tp and $ h -.V $ h Q
h
\f
$ is complete
-.{tp => >4,)
prop. cal.
ip
$ is consistent
tp
and then the other: $ l/ h
Hyp.
$ h ^ ( ^= ^)
$ is complete
$ h 99 a n d $ h -i«/>
prop. cal.
$ h 99 a n d <& \/ ib
$ is consistent
ip £
226
4. LOGIC WITH EQUALITY
M \= ip [s] and M \/= ip[s]
(4.157) holds for ip and ip
M y= ip => ip [s]
definition of |=
+
k
Suppose VVkip G Sent (£). Notice that SubJ (ip) has fewer occurrences of the universal quantifier than WVhip. Also, since free(VVktp) = 0, we have free(y>) C {vj;}. Every term t in M contains no variables, and the only free variable in ip is v/t, so SubJk (ip) is a sentence by Th. 129(iii). This means that the inductive hypothesis applies to SubJ'*' (ip), hence (4.157) holds for SubJ'*' (ip) whenever t € M. We will prove (4.157) for Vvhif- There are two cases. In the first case we suppose that free(y>) = 0. Then Sub*k (ip) = ip whenever t € M, so (4.157) holds for ip. M \=s^vklp[s]
Hyp.
M \= ip [s(k/t)] for alH € M
definition of |=
M. \= ip [s]
when t = Sk
h
$ h ip
(4.157) for ip
$ h Vvh
Hyp.
h
$ h ip
(HV'), Th. 140
.M |= y[s]
(4.157) for y>
M\=
M \= VVfc v [s]
s and s(fc/t) agree on free(
The other case is that free(ip) = {vj,}. Since C is a set of witnesses for $, there is some c G C such that $ h h SubZk(ip) = VVfcv5-
(4.163)
We proceed to show (4.157) in this case, first in one direction: M\=VVh
Hyp.
M. \= ip [s(k/t)\ for every t G M
definition of |=
M\=
(4.155)
for every t G M
fc
Al |= SubJ ((^) [s] for every t £ M !
$ h SubJ'* (y) for every t G M
Th. 136, note (c) below inductive hypothesis
fe
$ h Subc (ip)
when i = c € C C C C M
$h h V Vfe ¥3
(4.163), Th. 140
Note (c): For every t € M, t contains no free variables, hence t is free for vj, in if. For the other direction, we have: 1. J\/[ ^ VVfc if \s\
Hyp.
2. M.y= ip [s(k/t)]
for some t G M, by the definition of |=
15. WITNESSES
fi
3. M
(4.155)
4. M Y= S u b ^ (ip) [s]
Th. 136, note (c) above
5. <& \f SubJ'*'(y).
inductive hypothesis
6. $ hh —iSub^fc (y3)
* is complete, Sub^(y) £ Sent + (£)
7. \- yxip => SubJrfe(i^)
(HV'), note (c) above
h
h
8. h -iSubl (
h
227
=> -HVk
(4.99)
-WVk
6, 8, Th. 140
h
* is complete, VVk
10. * ^ Vvfc^
Thus (4.157) holds for VVfev?- The proof of (4.157) is now complete, and with it, the proof of the entire theorem, since a consequence of (4.157) is that M \= $. T h e o r e m 167 (Witness Consistency Theorem). Let £ = £(C,J~, 7?., rank) be a nice language. Suppose $ C Sent + (£) is a consistent theory, c £ C is a constant, tp £ Fm + (£), {x} = free(ip), and c does not occur in ip or in any sentence in $. Then <& U {Sub;? (y>) => Wxf} is consistent. PROOF. Assume $ U {Subc(i^) => Va;i^} is inconsistent. Then, by Th. 164,
so by propositional calculus we get (4.164)
$ h h Subc(y)
(4.165)
$ h h -WxV>.
By (4.164), there is a proof (ipi,..., ipm) of Sub^(
228
4. LOGIC WITH EQUALITY
This last formula will be an instance of (HV') if Suby(t) is free for z in By the selection of y we know y does not occur in ipi, so y ^ z. Therefore, no new free occurrences of z axe introduced in SubJ(£). Thus Sub|ubc(-t) will put Sub^(i) into the same locations in Sub^(^) that Subf puts t in f. Note that Sub^(i) may contain y, so we need to know that no free occurrence of z in Sub^(£) is in the scope of a quantified y. But this is true because y does not occur in ipi. Thus Sub° (ipi) is an instance of (HV'). If ipi is an instance of (DI)-(DV), (HVI'), or (CVII), then c does not occur in ipi, hence Sub^(^) = ipi. Suppose ipi is an instance of (AIX*), say v;t=Vj => (£ => SkjS,)- Since y does not occur in ipi, we have Vjt ^ y ^ v,- and SubS(SwO = SwSubS(O, hence SubJ(^) is v , = v , => (Sub^K) => S y S u b ^ ) ) . Thus Sub^(^i) is also an instance of (AIX*). Similarly, if ipi is an instance of (CVIII), say v=w =>(£=> x), where x a n d f are atomic and x is obtained from £ by replacing an occurrence of v by w, then v ^ y ^ w since y does not occur in ipi, and again it is easy to see that Sub^(^) is an instance of (CVIII). So far we have shown that if ipi is an axiom, so is Suby(ipi). If ipi £ $, then SubJ(^i) = ipi since c does not occur in any formula in $, so Sub^(^) 6 $. 1£ipi is o b t a i n e d by MP, say j,k < i a n d ip^ = (ipj => ipi), t h e n Suby(tpk)
= (Suby(ipj)
=>
Suby(ipi)), so Suby(ipi) is also obtained by MP. If ipi is obtained by Gen, say j < i and ipi = Vzipj, then Suby(ipi) = VzSuby(ipj), so Sub^(^i) is also obtained by Gen. Thus (Suby(ipi),..., Suby(ipm)} is a proof from $. Now c does not occur in
Then, by MP, $ hh ip, whence, by Gen, $ hh V^^, contradicting (4.165). Theorem 168 (Witness Extension Theorem). Suppose C is a nice language, C = C{C,T, TZ, rank), $ C Sent + (£), and $ is consistent. Then there are a set C £ V, a nice language C' = C(C, T, 1Z, rank), and a theory $' C Sent + (£') such that (4.166)
$ C $',
(4.167)
$' is consistent,
(4.168)
C is a set of witnesses for $',
(4.169)
\C\ = |Sent+(£)| = |Sent+(£')|,
(4.170)
C' = C U C, 0 = C n C.
PROOF. Choose a set C such that \C\ = |Sent + (£)|. The elements of C are called "new constants". Let C! = C'(C', T, 1Z, rank) be the language whose relation and function symbols are the same as those of C with the same ranks they have in
15. WITNESSES
229
£, and whose constants C' are all the constants of £, together with all the elements of C, i.e., C = CUC. C can be chosen so that £' is nice. This requires C to be disjoint from the variables, connectives, quantifier, symbols, terms, and formulas of £. £ and £' have the same number of sentences: |Sent + (£')| = |Sent + (£)|. £' has more axioms than £, namely, all instances of the axiom schemata that contain new constants. With respect to this larger language with more axioms, $ is still consistent—any proof of a contradictory sentence using formulas from $ and axioms from £' can be converted to a proof in £ by replacing the finitely many new constants that appear in the proof with variables that do not appear in the proof—see the proof of Th. 167 for details. Thus (4.169) and (4.170) hold. Let a = |Sent + (£')| = |Sent + (£)|. Note that a is also the number of formulas of £' that have exactly one free variable. Let {ipK : K < a) be a well-ordering of all the formulas of £' that have exactly one free variable. For every K < a, let CK = {c : c G C, c occurs in tp\ for some A < K}. There are at most finitely many constants from C occurring in each ip\, so \CK\ < ui whenever K < w, and \CK\ = K whenever to < K < a (although no such case arises when a = UJ). Since \C\ = a, it follows that | C ~ C K | = a whenever K < a. Choose a well-ordering of C. For each K < a, let cK be the least element of C~(CK U {c\ : A < K}), which is not empty since |C~(C K U {c\ : A < K})\ = a whenever K < a. It follows that if K < a, then (4.171)
for every A < K, CK does not occur in tp\, and cK ^ c\ if A < K.
For every K < a let $ K = $ U { S u b ^ ( ^ ) => V.VA : A < K, {x}= and let $' = $„. Clearly (4.166) and (4.168) hold. Next we show that * K is consistent for every K < a. This includes, as a special case, that (4.167) holds. We use induction on n < a. First we prove consistency for n = 0. Note that $0 = <£ We know $ is consistent in C, but we must show $ is also consistent in C'. To do this, note first that any proof in £' of a formula in Fm + (£) from $ can be converted to a proof in £ by replacing the finitely many constants in C that occur in the proof by variables that do not occur anywhere in the proof, as shown in the proof of Th. 167. Now suppose $ is inconsistent in £'. Then <1> proves all sentences, so choose a contradictory sentence tp £ Sent + (£). By replacing constants in C by new variables in a proof in £' of %p from $, we get a proof in £ of %p from $, contradicting the consistency of <1> in £. It follows that <1> is consistent in £'. Assuming $K is consistent, the consistency of <&K+i follows by Th. 167. To see this, note that $ K + i = $ K U {Sub^(V«) => V,V4 where {x} = free(ipK), and, by (4.171), cK does not occur in any formula in $ K , and does not occur in tpK. The consistency of $A for limit ordinals X < a follows immediately from the consistency of $ K for all K < A, as in the proof of (4.150) in the proof of Lindenbaum's Lemma, Th. 165.
230
4. LOGIC WITH EQUALITY
Now we can show that every consistent theory has a model no larger than the language. Theorem 169. / / $ C Sent + (£) and $ is consistent, then there is an interpretation M for £ such that M \= $ and \M\ < |Sent + (£)|. PROOF. By Th. 168, there are £', $', and C such that (4.166)-(4.170) hold. By Lindenbaum's Lemma, Th. 165, there is a complete consistent theory $" D $'. Note that C is a set of witnesses for $" as well as $'. By Th. 166, there is a loose interpretation Mo for £ such that Mo \= $" and \MQ\ = |Sent + (£)| = |Sent+(£')|- We also have Mo \= $ since $ C $". Let E = (=)M°. By Th. 161, E is congruence relation on Mo, Mo/E is an interpretation, and Mo/E \= $, so we let M = Mo/E. Then we have M \= * and \M\ = \M0/E\ < \M0\ = |Sent+(£)|. D
16. Completeness and compactness The Completeness Theorem was first proved by Godel [81]; see van Heijenoort[247] or Godel [82]. Many other proofs of this theorem have appeared in the literature. The one in given in the preceding sections has followed Henkin [89], as presented in Mendelson [169], with appropriate modifications for the presence of predicate operators and predicate equality. Recall (from p. 217), that £ = C(C,T, 1Z, rank) is a nice language, and hh is provability in Fm + (£) using axioms (HI), (HII), (HIII'), (HIV), (HV), (HVI'), (CVII), (CVIII), (AIX*), (DI)-(DV), and rules MP and Gen. Theorem 170 (Completeness Theorem). For every ip £ Sent + (£),
If $ hh ip, then $ \= tp by the Soundness Th. 141. For the converse, assume $ l/ ip. Since >p £ Sent + (£), it follows that <3> U {~"y?} is consistent by Th. 164. By Th. 169, there is an interpretation M such that M \= $ U {^ip}. Thus M \= $ and M \= -«/?. Since ip is a sentence, it follows that M \/= f> by Th. 133. Thus M is a model of $ that is not a model of ip, hence $ ^= (p. PROOF.
h
A consequence of the Completeness Theorem (Th. 160, p. 217), is that for every ip 6 Fm + (£), hh ip iff h+ ip iff |= ip. Theorem 171 (Compactness). If every finite subset of $ C Sent + (£) has a model, then $ has a model. PROOF. Since every finite subset of $ has a model, every finite subset of $ is consistent, since having a model implies consistency. If $ itself were inconsistent then there would be a proof of a contradiction from $, but by (4.69) there would then be a finite inconsistent subset of <3>, a contradiction. Consequently <3> is consistent and has a model by Th. 169.
16. COMPLETENESS AND COMPACTNESS
231
A theorem first proved by Lowenheim [131], with different and improved proofs by Skolem [218, 219, 220] and further improvements by Tarski (see [221, Bemerkung der Radaktion, p. 161], Tarski [238, p. 568], Tarski-Vaught [241, Th. 2.1], Vaught [249, p. 870]) and Mal'cev [159], became the Lowenheim-SkolemTarski theorem. We present here only a weak version, followed by J6nsson's statement of Lowenheim's original theorem. Theorem 172 (Lowenheim-Skolem Theorem). If a theory # C Sent + (£) has a model then it has a model M with \M\ < |Sent + (£)|. PROOF.
A theory with a model is consistent, so the conclusion follows from
Th. 169. The original theorem of Lowenheim [131] states that if an equation of the calculus of relations fails in some infinite domain, then it already fails in a countable domain. What follows is a contemporary algebraic statement of this fact. Theorem 173 (Jonsson [113, 8.1]). If K and A are infinite cardinals, then HSP{«e(«)} = HSP{«e(A)}. PROOF. By BirkhofFs Th. 95, it suffices to show the same equations hold in both ZRZ(K) and Ote(A). We will show that if an equation fails in £fte(A) then it also fails in 9le(K). Let C = £(0,0,7?., rank) be a binary relational language such that \7Z\ = K. Since n > w we also have |Sent + (£)| = K. Let A, B 6 II and suppose A = B fails in Dte(A). This means that there is some assignment / : 11 —> Sb (A2) of the relation symbols in 72. to relations on A such that if h is the extension of / to a homomorphism from the predicate algebra *$ of £ into 9te (A), then h(A) / h(B). We must show A = B also fails in JJte (K). By Th. 82 there are only finitely many relation symbols in 72. that actually appear in A or B. Let Hi be all the others. Since \TZ\ = K > w, we conclude that \R'\=K as well. Let
$ = {-,(A = B)} U {1 = 1;R;1 :RETl'} U{R;0';R
u{^(R-S)
:ReH'}
:R,sen',R?s}.
Next we show # is consistent, for which it is enough to show every finite subset of $ is consistent. Consider any finite subset A C $. Construct an interpretation M' for C with domain M' = X as follows. For every R 6 ft ~ 71' let RM' = f(R) = h{R), From this alone we know that AM' ^ BM', hence M' \= ->{A = B), regardless of how the remaining binary relation symbols are assigned by M! to relations on A. If R 6 7Z' and R does not occur in a sentence in A, then we may let RM be any relation on A, say RM = A2. To complete the construction of M!, let {Ri, ,Rn} C It' be the finite set of relation symbols in H' that occur in some sentence in A, choose distinct fix,... ,/x» 6 A, and let (Ri)M = {(A«i,/ii)}, . . . , (Rn)M = {{ftn, fin}}- Then M' [= tp for every tp £ A, so A is consistent.
232
4. LOGIC WITH EQUALITY
Since $ is consistent, by Th. 169 there is an interpretation M. for C such that M \= $ and \M\ < |Sent+(£)| = K. If R € 11' then M \= 1 = l;fl;l and M \= R;0';R
< V, so there is some fin G A such that RM
= {(^R,fin)}-
For
distinct R,S £ K' we have .M |= -^(R=S), hence p fl ^ ps. Since |7?.'| = K, it follows that K < \M\. Thus we have |M| = K and 7\4 ^ -i(A = B), so the equation A = B fails in 9\e (K).
CHAPTER 5
Boolean algebras 1. Axioms R1-R3 23 is a Boolean algebra iff 03 is an algebra of Boolean type satisfying the three identities R1-R3 below. In more detail, this means that there exist sets B, +, and ~ such that 23 = {B, +,~), + : B2 -> B, and ~ : B -> B, and, for all x,y,z
£ B,
Ri R2 R3
x + y = y + x, x + (y + z) = (x + y) + z, x + y + x + y = x.
(axiom of commutativity) (axiom of associativity) (Huntington's axiom)
Let BA be the class of Boolean algebras. It follows from the Class Existence Theorem that BA exists. Axioms R1-R3 are due to Edward V. Huntington [105, 104]. The axiom set in Huntington's first paper [105] included the law of idempotence, namely x + x = x. The idempotence law was even "proved" in Huntington [105] to be independent of the other three axioms. However, the law of idempotence was subsequently (and correctly) shown in Huntington [104] to be redundant. There is an interesting problem connected with this axiomatization, which originated with Herbert Robbins. The Boolean dual of Huntington's axiom R3 is i o. J. i
Ju ~\ y ~\ Ju ~\ y — Ju.
The problem Henkin-Monk-Tarski [93, Problem 1.1] was to determine whether R3 can be deduced from the commutativity, associativity, and the dual Huntington axioms. It is easy to see that if a finite algebra satisfies the dual Huntington axiom, then it also satisfies the Huntington axiom. Suppose a finite algebra satisfies the dual axiom. From the form of this axiom it is clear that the operation ~~ is onto. Since the algebra is finite, the operation ~~ must also be injective. Substitute x for x in (5.1) to get x = x + y + x + y. Since ~~ is injective, this entails x = x + y+x + y. Using specialized theorem-proving software, W. McCune [164] proved that there is an equational derivation of Huntington's R3 from Ri, R2, and (5.1). Axioms Ri and R2 say that (B, +) is a commutative groupoid. The first two interesting consequences of R1-R3 are Theorem 174. (R1-R3) (5.2)
x + x = y +y
5. BOOLEAN ALGEBRAS
(5.3)
X =
X.
PROOF. X+ X
-y- \-x + y) + (x + y-\- x + y)
R3
-x- \-y + x) + {y + x-hy + x)
Ri,R2 R3
IIIH
HII
= y +y -x + x + x
R3
= x 4 -x + x + x
R2
= x 4 -x + x + x
(5.2) Rs
X
If an algebra 58 = {B,+,~} satisfies R1-R3, then by (5.2) the sets {x + x : x £ B} and {x + x : x £ B} both have exactly one element in them. In relation algebras we have a distinguished element 1' from which we define 1 := 1' + 1 ' . For Boolean algebras in general, we may instead agree to let 1 be the unique element in {x + x : x £ B}, and let 0 be the unique element in {x + x : x £ B}. Of course, 0 and 1 could be added to the signatures of both relation and Boolean algebras, as is often done. If we consider Boolean algebras as algebraic structures of the form {B, +,~, 0,1), we get a sufficient axiom set by adding the following two identities to R1-R3: (5.4) l = x + x, (5.5)
0 = x + x.
Note the redundancy thus introduced: the identity x + x = y + y follows from (5.5) as well as from Huntington's three axioms. Define eight additional binary operations on B. Three of them get their own names and notation: the centered dot denotes the binary operation called meet or intersection, while the minus sign — denotes the binary operation called difference. fooo{x,y) := x + y,
fm(x,y)
fon(x,y)
fioo(x,y) := x + y,
:= x + y,
foio (x, y) := x + y,
:=x +
y=:x-
/101 (x,y) := x+ y =: y - x,
fooi(x,y) := x + y, fuo(x,y) := x + y =: x - y. The symmetric difference is more complicated: (5.6) x G y := (x - y) + (y - x) = /no + /101 =x + y + x + y. The asymmetry of choosing + as primitive and as denned is reflected in the convention that binds more strongly than +, so that, for example, x
y + x
y = {x y) + (x
y)
1. AXIOMS R1-R3
= x + y + x + y. There are many other ways to define Boolean algebras, and there is an extensive literature concerning alternative choices of fundamental operations and axioms; see Sikorski [216, p. 3]. Here is a highly redundant axiom set that exhibits duality. Theorem 175. 03 is a Boolean algebra iff 23 is an algebra of Boolean type satisfying the identities below. (5.7)
(x + y) + z = x + (y + z) x+y=y+x
(5.8) (5.9)
(x -y)
X+ X = X
(5.10) (5.11)
x + (x y) = x
z =
x
(y
x
y =
y
x
X
X =
X
z)
x (x + y) = x
x + y z = (x + y) (x + z)
x (y + z) = (x y) + (x
(5.12)
x + y = x-y
x -y = x + y
(5.13)
0+ x = x
1 x = x
(5.14)
1+^ = 1
0 -x = 0
(5.15)
X + X = 1
x
(5.16)
0= 1
(5.17)
W= x
z)
x = 0
T= 0
The identities in Th. 175 may be proved from axioms R1-R3, but in doing so, one cannot assume the identities 1 = x + x and 0 = x + x. Instead, each identity involving 0 or 1 should be proved in the form obtained by replacing occurrences of 0 and 1 with terms of the form x + x and x + x, respectively, without using the same variable for different occurrences. For example, the identities 1 + x = 1 and 0 x = 0 should be proved in the form y + y + x = z + ~z and y + y x = z + ~z; for such proofs see Maddux [155, Th. 3,5]. The next theorem has some more identities that hold in every Boolean algebra.
Theorem 176. (R1-R3) (5.18) (5.19)
x - \-y =
x-y,
(5.20)
x -= (x-y)
(5.21)
x -= (x + y)- (x + y),
(5.22)
x -\-y = x +
(5.23)
X
y = x- (x + y),
(5.24)
X
y + x z = (x + y) (x + z),
(5.25)
(v
7
af ~y = x + y, +
w + v x)
(x-y),
x-y,
v
y + v
z = v
y+ v
x
z.
Theorem 177. / / an algebra of the form 25 = (B, +, -,~, 0,1) satisfies both commutative laws (5.8), both distributive laws (5.11), as well as (5.13) and (5.15), then (B,+,~) is a Boolean algebra.
236
6, BOOLEAN ALGEBRAS
2. Partial orderings, completeness, atoms, density For every algebra 2$ = (B, +,~) of Boolean tjpe, define a binary relation < » on B by x <m V iff x + V = V, for all x, y E B. Define another binaxy relation >m y iS x + y = x. We often delete subscripts, and, in accordance with standard mathematical notational practices, write, for example, x < y instead of {x,y) E <58, and x < y instead of (x,y) E Di fl
a; + 2 = a;+(gj + 2) = (2; + gj)+2 = gj + 2 = 2) hence a; < 2. (ii); If x
0 < x < x < 1. a; = y iff x
x ^ y
y^ x
x+y =y
^>f
f<«
x-y = y
"x + y = "x xy
=x
aT + j / = l x-y = 0
(v) If x
€ BA. Then
(i) < is a Boolean lattice ordering in which the join of {x, y} Q B is x + y and the meet of {x,y\ is x y, (ii) > is the converse of <, (iii) > is a Boolean lattice ordering for which the join of {x,y} C B is x y and the meet of {x,y} is x + y. Theorem 181. If < is Boolean lattice ordering, then there is a Boolean algebra {B,+,~) in which B is the field of <, the binary operation + is defined by x + y := 5^{a;, y}, and x is the complement of x. A Boolean algebra 93 = {B, +,~) E BA is said to be complete if the partial ordering < of 93 is complete. The set of nonzero elements of a Boolean algebra
3. MEETS AND JOINS OF SUBSETS
55 is the set {x : 0 ^ x £ B}. Other orderings of importance are the restrictions of < and > to the nonzero elements, namely,
>' = (>) H (B ~{0}) 2 = f]({x : 0 ^ x E B} x {x : 0 ^ x E B}). An element x of 03 is an atom of 03 just in case x is not zero and no nonzero element of 03 is below x. Let At*& be the set of atoms of 03. Again, (5.26)
x is an atom of 03 <=> 0 ^ x £ B AVv(y £ B => x y = 0V x
(5.27)
At
: = { x : 0 =/= x e B / \ V y { y e B => x - y = 0 V x <
y)}.
The atoms of 03 are the minimal nonzero elements with respect to <, while the atoms of 03 are the minimal elements with respect to < ' . A subset I C B o f a Boolean algebra 23 = (B, +, ~) € BA is said to be dense in 03, or simply dense, if every nonzero element of B has a nonzero element of X below it, that is, X is <'-dense below 1. Note that X is dense iff X U {0} is dense. We say that a Boolean algebra 03 is atomic if the set of atoms of 03 is dense. Theorem 182. X is dense in 23 £ BA iff every element is the join of the set of elements of X lying below it, i.e., for all y E B, y>xex PROOF. Let y E B. Certainly y is above every element of {x : y > x E X}. If y is not also the least upper bound, then there is some z that is an upper bound of {x : y > x £ X} such that y — z^0. By the density of X, there is some x such that 0 / i 6 l and x < y — z. Then x < y but z is an upper bound, so x < z. We also have x < y — z <~z, so x < z -~z = 0, hence x = 0, a contradiction.
3. Meets and joins of subsets Collected here are some facts about (possibly infinite) joins and meets in Boolean algebras. Throughout this section we assume that 03 = (B,+,~) £ BA, x,y E B, and X, Y E Sb (B). In applying '-notation to the Boolean algebra 03, we use infix notation for * and +*: (5.28) (5.29) (5.30)
X* ={x:xE
X},
X+*Y = {x + y : x E X,y EY}, X-*Y =
(5.31)
^ * W
(5.32)
Y[\X)
{xy:xEX,yEY},
(5.33)
<*(X) = {y:3x(xEXAx
(5.34)
>*(X) =
{y:3x(x£XAy<x)}.
Theorem 183. Let 23 = (B,+,~)
E BA. Then ^ $ = 0 and T7 0 = 1-
5. BOOLEAN ALGEBRAS
PROOF. Every element is an upper bound of the empty set (every element is above every element in the empty set), and every element is also a lower bound for the empty set. So the least upper bound of the empty set is the least element, namely 0, and the greatest lower bound of the empty set is the greatest element, namely 1.
Joins and meets of certain (possibly infinite) sets exist: Theorem 184. Let 03 = (B,+,~) € BA, andy e B. Then both ~[{{x : x > y} and E { x : x < y} exist, and y =
Next, a rather obvious but useful fact. Theorem 185. Let 03 = (B,+,~) € BA, and y€B. exists then ^2f*{x : f(x) < y}
IfJ2f*{x
:
fix) < v}
The next theorem includes infinitary versions of "De Morgan's Laws", and infinitary versions of commutativity and associativity. Theorem 186. Let 55 = (B,+,~) € BA, and X,Y € Sb (B). (i) If$2X exists then U(X*) als° exlsts and E x = Hi*') (ii) IfUx exists then E ( ^ * ) also exists and]JX = (iii) Assume ^2 X and ^2 Y exist. Then ^2(X +* Y) also exists, and if orX = % = Y, then J2(X +* Y) = J2 X + J2Y. (iv) Assume [ ] X and [ ] y exist. Then Yl(X Y) also exists, and if X ^ 0 ^ y 0TX = $ = Y, then ^\{X Y) = \[X \[Y. The hypotheses in the third and fourth parts of the previous theorem cannot be omitted because
^(X+*0) = ^ 0 = O, but YX
+ Y® = YX
+ O=
YX'
For the next theorem, note that => y x ( x £ X => 3y(x
Y)).
1
In other words, E^ f(<|E) is the binary relation consisting of ordered pairs of sets (X, Y) such that everything in X is smaller than something in Y. This is true, for example, whenever X QY, because < is reflexive. Theorem 187. Let 55 = (B,+,~) £ BA, X,Y £ Sb (B), and X C Sb (B). (i) Suppose that (X,Y) € 'E zrT t(
thenJ2X <J2Y-
(ii) Suppose that {X,Y) € E r T f(>|E), e.g., X D 7 . IfU^
and RY exist,
(iii) // £ X and J2 Y exist then £(XUY) exists and £ ( X U Y) = £ X + Y.Y. (iv) If[\X and l\Y exist then U(XUY)
exists and U(XUY) =
3. MEETS AND JOINS OF SUBSETS
We prove the first equation of the last part. Note that E * % = e X}. We claim that every element of this set is below E ( U ^ 0 - Let X E X. Then X
xG\€X} = {x 3x(x£X
AX £ X)}
C {x
Al£
X)}
= {x
-X
ex}}
= {x
C {x : x < y j ( T j X)} and conclude that £ ( ( J # ) < J2{x : x < £(£*(*))} = £(£*(*)) The next theorem says that every element of a set is above the meet of that set, that being below the meet of a set is equivalent to being below every element of that set, and that being above the meet of a set is equivalent to being above everything that is below every element of the set. Similar statements can be made for meets. Theorem 188. Let 03 = (B,+,~) E BA, and X 6 5*6 (B). (i) IfY\X exists, then
yx(xex => Y{x<x), < z)). If E -^ exists, then
~^2,X
Vy(V*(x EX^x
y)).
Finally, we have some distributive laws. Theorem 189. Let 03 = (B, +,~) G BA, x G B, and X,Y G Sb (B). \O.OO I
(5.36)
Jb ' /
1
— /
I 1 Jb r '
1 1.
x + \[Y
(5.37)
nx+ny:
(5.38)
VX
V y = V(X
* Y).
240
5. BOOLEAN ALGEBRAS
PROOF. TO prove the third statement, assume z £ X +* Y. This means that z = x + y for some x E X and y E Y. We have \\X < x and \\Y < y, so l\X + Y[Y < x + y = z. Thus ]JX + ]JY is a lower bound of X +* Y, so Y[X + ]JY < ]J(X +* Y). For the opposite inclusion, we assume z is a lower bound of X +* Y and prove z < fJX + fj Y. Each of the following statements implies the next one.
Va!Vy(a; £ X Ay eY
=> z <x + y)),
Vy(y € Y => Vx(x € X => z < x + y)), Vy(yEY
=> Wx(xEX
=>
Vy(y£Y
=> z
Vy(yEY
=> z-y-T\X
z-y<x)),
y<]JX), = O)),
Vy(yEY => z-\[X
z
Vx(x£X
=> Vy(y€Y
=>
x-y
Alternatively, we may prove the last part by duality:
4. IDEALS, FILTERS, AND ULTRAFILTERS
4. Ideals, niters, and ultrafilters Let 03 = (B, +,~) G BA. We say that I is an ideal of 23 if I is a subset of B that is "closed going down" and closed under +, i.e., I CB x € I Ax>y € B ^ y € I, x,yel => x + yel, An ideal / of 93 is proper if / ^ B. We say that F is a filter of 93 if if F is a subset of B that is "closed going up" and closed under , i.e., 0^FCB x e F A x < y e B x,y
E I => x
=> y E F,
y E F.
A filter F of 23 is proper if F ^ B and is called an ultrafilter of 23 if it is a maximal proper filter, that is, a proper filter that is not a proper subset of any other proper filter. We will use the set of ultrafilters of a Boolean algebra on many occasions, and introduce a notation for it. For every 23 6 BA, let [7/23 := {U : U C B A U is an ultrafilter of 23}. For any x,y £ B, let [x, y]<s,
{z
z € B, x < z <
y).
[x, l],g is called the principal filter of a;, and [0, x]^ is called the principal ideal of x. For every S C B, the set {x : 3X(X C S, X is finite, ]JX < x € B} is called the filter generated by 5", and the set {x :3X(XCS, X is finite, Y. x < x 6 B} is called the ideal generated by S. Various elementary facts are collected in the next theorem, including justification for some of the terminology just introduced. Theorem 190. Let 23 E BA. (i) B is an ideal of 23 and a filter of 23. (ii) 0 is an ideal of 23 and a filter of 23. (iii) I is an ideal of 23 iff >*(/) Q I and I+* I
242
5. BOOLEAN ALGEBRAS
(ix) / / / is an ideal of 93 and x £ B, then the ideal generated by I U {x} is {y : y <x + z, z £ I}. (x) If F is a filter of 23 and x £ B, then the filter generated by F U {x} is {y:y>x-z,z£F}. (xi) A filter F of 21 is an ultrafilter of 23 iff for every x £ B, either x £ U orx£U. A Boolean algebra may not be complete, in that some of its subsets may not have greatest lower bounds. However, no such set is an ultrafilter, according to the following theorem. or
Theorem 191. Let U be a proper ultrafilter o/93 £ BA. Then either FJ U = 0 II U is an atom of 23.
PROOF. Clearly 0 is a lower bound of U. If 0 is the only lower bound, then it certainly is the greatest lower bound, hence 0 = FJ U. Suppose, on the other hand, that £ is a nonzero lower bound U. For every nonzero y £ B, either y £ U (hence x < y) or else y £ U (hence x < y). Since x is below or disjoint from every nonzero element, it is an atom of 23. Furthermore, we cannot have ~x £ U, since that would imply x < x, hence x = 0, contrary to the hypothesis that U is proper. Thus x £ U. From this and the assumption that a; is a lower bound of U, it follows that U is the principal filter generated by x. Finally, x is the greatest lower bound of U, for if y is some other lower bound of U, then y < x since x £ U. We have, therefore, demonstrated that the only lower bounds of U are 0 and x. The filter generated by S will contain 0 iff some finite meet of elements in S is 0. Sets for which this never happens are said to have the the finite intersection property (FIP), i.e., the meet of any finite subset of a set with the finite intersection property is nonzero. Next is the of the Ultrafilter Theorem, on the existence of ultrafilters. It may be proved using the Axiom of Choice. It is an abstract Boolean algebraic version of Th. 86. Theorem 192 (Ultrafilter Theorem). Let 23 £ BA. / / a subset of 23 has the finite intersection property, then it is a subset of a proper ultrafilter.
5. Functions between Boolean algebras Suppose we have two Boolean algebras, 23 = (B,+,~) £ BA and 23' = {B', +', ~ ) £ BA. To distinguish between the defined notions for 23 and 23', we add a prime. (In this section the notation <' means the partial ordering of the Boolean algebra 23', rather than the restriction of the partial ordering of 23 to nonzero elements.) Assume a : B —I B', that is, a is a unary function mapping B into B'. Recall that this means a C B x B', a\V = B x V, and a H a\D\ = 0. We say that a is - constant if cr^Vlcr = a^1 \a, - normal if a (0) = 0 ' , - dual-normal if a (1) = 1', - m o n o t o n i c if x < y =^ a (x) <' a (y) f o r a l l x , y £ B ,
5. FUNCTIONS BETWEEN BOOLEAN ALGEBRAS
-
243
order-reversing if x < y => a (x) >' a (y) for all x,y £ B, self-dual if a (x) = a (x) for all x £ B, a d d i t i v e i f a (x + y ) = a (x) +' a (y) f o r a l l x , y 6 B , s u b t r a c t i v e if a (x — y) = a (x) —' a (y) f o r a l l x , y 6 B , m u l t i p l i c a t i v e if a (x y ) = a (x) a (y) f o r a l l x , y £ B , a homomorphism if a is additive and self-dual, an embedding if a is both a homomorphism and also injective, an isomorphism if a is both an embedding and is onto.
These definitions illustrate the need to use separate notation for separate algebras, but we will often conform the custom of using the same symbols for corresponding operations in different algebras. Notice that this definition of homomorphism, specific to algebras of Boolean type, agrees with the general definition of homomorphism given earlier. The properties defined above can be expressed equationally. For example, a is monotonic iff (<) C crK^Ker" 1 ). Other characterizations of monotonicity are given in the next theorem. Theorem 193 (Tarski-Givant [225]). Assume 55 = (B,+,~) {B , +', "') € BA, anda-.B^B'.
€ BA, 55' =
1
(i) The following statements are equivalent: (a) a is monotonic, (b)
y) = a {x - (1 -
=
= a(x) = a(x)-a
y))
a(x)-a(l)-a(y)
- o - ( l ) +a(x) (y).
-a(y)
5. BOOLEAN ALGEBRAS
Finally, a is additive since
= a(l)
a(l) + a(l)
a(x) +a(l)
a(y)
= a(x) + a(y).
D 6. Congruence relations, ideals, filters, and homomorphisms The next theorem states the links between congruence relations, ideals, and filters in Boolean algebras. Recall from (5.6), in the context of Boolean algebras, x © y = x y + x -y a n d x © y = x y + x -y.
Theorem 194. Let 03 E BA. (i) If R is a congruence relation on 03, then (a) (i?oE)(0) is an ideal, (b) (i?oE)(l) is a filter, (c) R={{x,y):xey£(RoE)(0)}, (d) R={{x,y):xeye(RoE)(l)}. (ii) / / / is an ideal o/93 and R = {{x, y) : xOy £ I}, then R is a congruence relation and I = (Ro E)(0). (iii) If F is a filter of 03, and R = {{x, y) : x Q y E F}, then R is a congruence relation and F = (Ro E)(l). The next theorem gives a convenient way of checking whether a function between Boolean algebras is a homomorphism. Theorem 195. Assume 03 = (B,+,~) € BA, 03' = (B', +',"'} € BA, a : B —> B'. Then a is a homomorphism iff^x^yix < y <=> a (x) <' a (y)) iff (<) = ff|(<')k"1A subset X of w is cofinite if \w ~ X | < w. The set of cofinite subsets of w is a subset of 0S((o;) that has the finite intersection property. By the Ultrafilter Theorem, it is contained in an ultrafilter U € {7/031 (to). Any lower bound of U in 0S((o;) must be a subset of every cofinite subset of w, but the only such set is 0. Therefore U is a nonprincipal ultrafilter. Conversely, every nonprincipal ultrafilter of 031 (LJ) must contain every cofinite subset of to. 7. Complete additivity and multiplicativity The following definitions introduce strengthenings of additivity and multiplicativity. Assume 03 = (B, +,~) £ BA, 03' = (B', +', ~'> e BA, and a : B -4- B'. We say that a is completely additive if, for every X C B such that X is not empty and ~^X exists, J2
7. COMPLETE ADDITIVITY AND MULTIPLICATIVITY
245
a is universally additive if a is completely additive and normal. By excluding the case x = 0 from the definition of complete additivity we prevent complete additivity from implying normality. Note that the function a is universally additive if the condition a (%2X) = ^2 a*{X) holds without any restriction on the cardinality of X. The next few definitions use a positive integer m as parameter. Assume 0 ^ m £ LJ. For every I C B , let us write M C m X when we mean \M\ < m and M C X. Following Henkin [91, 2.1] and Jonsson [116, 2.1], we say that a is madditive if, for every nonempty finite subset X C B, o"(J^X) = J^ {a (£) M) : M C m X}. Define a to be completely m-additive if, for every nonempty (and possibly infinite) X C B such that ^ X exists, E { ° " ( E * 0 M Cm X} also exists and a (£) X) = J^ {a (£) M) : M C m X}. Now we relativize the previous two concepts to an element of 23. Let z £ B. We say that a is m-additive under z if the following condition holds for every X C B: if X is nonempty, finite, and xi-z
= x2-zfoi
all xi, £ 2 <E X, thenaC£X)
= T,'W (Y. M)
M
<^m X}.
Say
that a is completely m-additive under z if the following condition holds for every X C B: if X is nonempty, J^ X exists, and xo ~z = x\ ~z for all xo, x\ £ X, then a (£) X) = J^ {a ( ^ M) : M C m X}. Note that cr is completely m-additive under 1 iff a is completely m-additive, and a is m-additive under 1 iff a is madditive. Say that a is oi-additive if a is m-additive for some m, and completely cj-additive if a is completely m-additive for some in. Next are some dual notions. We say that a is completely multiplicative if, for every X C B such that FJ X exists and X is not empty, FJ cr* (X) exists and
// // // // If //
a a a a a a
is completely additive then a is additive. is additive then a is monotonic. is completely multiplicative then a is multiplicative. is multiplicative then a is monotonic. is completely m-additive then a is m-additive. is m-additive then a is monotonic.
5. BOOLEAN ALGEBRAS
(vii) (viii) (ix) (x)
Every m-additive function is (m + l)-additive. a is 1-additive iff a is additive. a is completely 1-additive iff a is completely additive. a is 2-additive iff for all x,y,z £ B, a (x + y + z) = a (x + y) +' a (x + z) +' a (y + z).
(xi) a is completely 2-additive iff for every X C B such that ^2X exists, ^2 W (xi + X2) : x\,X2 G X} also exists and = ^
{a (xi
(xii) a is 3-additive iff for all w,x,y,z
+ £2)
: £i,£2 £
X}.
6 B,
a (w + x + y + z) = a (w + x + y) +' a (w + x + z) +' a (w + y + z). (xiii) a is completely 3-additive iff for every X C B such that ^X ^2 {a (xi + X2 + Xi) : xi, X2,xz 6 X} also exists and
exists,
^2 W (xi + ^2 + X3) : xi,X2,X3 G X}. (xiv) a is m-additive a (a 1 +
iff for all a i , O 2 ,
+ a m + i ) = a (ai +
,am+i G B + am-2
+ am-i
+
»m)
+' a (01 +
+ om_2 + o m _i + a m +i)
+ a (01 +
+ om_2 + o m + a m +i)
+' a (02 +
+ o m +i).
PROOF. We only show that 2-additivity implies monotonicity. Suppose x < y. Then s + a; + j/ = j/, socr(a; + a; + j/) = cr (3/), but, by the 2-additivity of a and x + y = y, we have a (x + x + y) = a (x + x) + a (x + y)+a (x + y) = a (x)+a (y), so a (x) < a (y).
Theorem 197 (Jonsson-Tarski [118, 1.2]). For every Boolean algebra 23 and every x 6 B, the functions ) and £ are universally additive and completely multiplicative, and the functions x + (-) and (-) + x are universally multiplicative and completely additive. Every constant function is completely additive and completely multiplicative. If 93 has more than one element then the function x (-) is not universally multiplicative and x + (-) is not universally additive since 0
8. COMPLETENESS AND ATOMS
247
8. Completeness and atoms Compare the following theorem to Sikorski [216, p. 64]. Theorem 198 (Hirsch-Hodkinson [99, 2.16]). Assume 03 = (B,+,~) £ BA, 55' = (fl', +', ~ ) £ BA, and a : B —> B'. Assume 03' is atomic, a is an embedding, and a is completely multiplicative. Then 03 is atomic. PROOF. Pick any nonzero element 6 ^ 0 of 03. Then a (6) ^ 0' since a is injective and normal. Choose any atom a of 03' such that a <' a(b). Such an atom exists because 03' is atomic and a (6) ^ 0'. Consider the subset of B consisting of those elements whose images under a contain a, namely Ua = {x : x £ B A a (x) >' a}. This set forms a filter in 03 because a is (monotonic and) multiplicative. The hypothesis that a is an atom of 03' implies that for every element x of B, either x £ Ua or x £ Ua, since, by the dual-normality and additivity of a, a <' 1' = a (1) = a (x + x) = a (x) +' a (x). Therefore, Ua is an ultrafilter, and by Th. 191 there are two cases: either Y\Ua = 0 or else Y\Ua is an atom of 03. This first alternative cannot occur because we would then have, by normality and complete multiplicativity,
0 = a (0) = a (j[Ua) =n
For the converse, assume a (x) = Y^ x>a^Atm a ( a ) f° r e v e r v x € A. Let X C A. Assume 5^X exists. Then, since 03 is atomic,
248
6, BOOLEAN ALGEBRAS
SO
= J 3 {CT (a) : J ^ X > a e J]
, x e X}
= ^2 {a (x) : x G X}
zxl358
Step (*) uses the law £ ' (|J X) = E ' (E""<*0-
D
The composition of two monotonic functions is always monotonic. The next theorem includes two important special cases: the composition of two (unary) additive functions is always additive, and the composition of two (unary) w-additive functions is always w-additive. Theorem 200 (Henkin [91], Jonsson [116, 2.5]). Assume ©o,93i,932 G BA, a : Bo -¥ Bi, r : Bi -¥ B2, and 0 < k,m € w. (i) If (r is m-additive and T is k-additive, then er|r is km-additive. (ii) If (r is completely m-additive and T is completely k-additive, then a\r is completely km-additive. PROOF. The essential part of the proof is the following calculation, which shows that VChmX
The notations E°> £*> ^ d 5 J 2 re fe r to Q3o,93i, and ©2, respectively.
a is m-additive >
\ uchmx
r
T[a [ / ]
T (a (VJ X) j
)
Z
U}}
T is «-additive
BA, a-mon, r-mon ff-mon,
T-mon.
D The direct product of two Boolean algebras, or a system of Boolean algebras, is a Boolean algebra:
a, !8 e BA => a x » e BA,
8. COMPLETENESS AND ATOMS
249
l £ V , i : I ^ B A => Y[% € BAIt follows that if 93 = {B, ) £ BA and a is a binary operation on B, then <x is a unary function between Boolean algebras because it is a function from (the Boolean algebra) 9} x 9} to 93. As such, it may or may not be monotonic. Similarly, every n-ary operation on B is a function between Boolean algebras. T h e o r e m 201. Suppose 2$ = (B, ) € BA, Fi is a set of unary operations on B, F% is a set of binary operations on B, and C is the clone generated by F\ U F 2 . (i) If every operation in Fi U F% is monotonic, then every operation in C is monotonic. (ii) If every operation in F\ U Fi is additive, then every operation in C is additive. PROOF. Assume a,r,(3 : Bn -+ B, x,y € -B", and let p = (CTIP
Assume a, T, j3 are monotonic. If x < y, then er (as) < a (y) and T (X) < r (y) since a and r are monotonic, so (a (%), r (a;)} < (a (y), r (y)}, hence p (as) = /J(ff (as), r (x)) < /J(ff (»), r (y)) = p (y) since /3 is monotonic. If er, T, /3 are additive then so is p, since = f}{a (x) +a(y),T(x)+T
(y))
= P(a (x), T (x)) + P(
cr, r are additive $ is additive
= P 0«0 + P (v) D
Next we will see that this theorem holds for w-additivity as well as monotonicity and additivity. Suppose OS = (B, BA and ; is a binary operation on B. We use infix notation x\y instead of \({x,y)). Suppose that ; is additive in each variable, that is, it satisfies the identities of left and right distributivity, namely, x;(y + z) = x;y + x;z and (a; + y);z = x;z + y;z. Notice that ; is left and right distributive iff ; is additive under (0,1) and (1,0), respectively. The additivity of ; as a unary map from B x B to B is expressed by the identity {v + x);(w + y) = v;w + x;y. Prom left and right distributivity we only know that (v + x);(w + y) = v\w + v\y + x;w + x\y, and it is easy to arrange examples in which ; fails to be additive. On the other hand ; is 2-additive as a unary map because
+ w + y); (v + x + z) = M;W + U;X + U;Z + W;V + W;X + w;z + y;v + y;x + y;z = (u;v + u;x + w;v + w;x) + (u;v + u;z + y;v + y;z) + (w;x + w;z + y;x + y\z)
— (u + w); (v + x) + (u + y); (v + z) + (w + y); (x + z). These observations are generalized in the next theorem.
5. BOOLEAN ALGEBRAS
Theorem 202. Assume *B0, 55i, 5*2 £ BA, / ? : B o x B i - > B 2 , ^ is kunder (1, 0), and /? is m-additive under (0,1). TTien /3 is (k + m)-additive. PROOF. For every R (Z Bo x B i , we have
0(£) fl) = /3((^ Do (fl), £ Ra (R)))
=E since /3 is fc-additive under (1,0)
= E (E KCkDo(R)
MCmRa(R)
since /? is wi-additive under (0,1)
= E( E K'CkR
< E
M'CmR
PC£M)
MCk+mR
since if K'
T h e o r e m 203. Assume Q30,Q3i,Q32 £ BA, a : B o -> B i , r : B o -> B2, B 3 = -Bi x B2, p = a]?'1 n rlCT 1 , and p : Bo -> B 3 .
(i) / / p is k-additive and T is m-additive, then p is max(fc,ra)-additive. (ii) / / p is completely k-additive and T is completely m-additive, then p is completely max(fc, m)-additive. PROOF.
Note that p (x) = {a (x), T (X)) for all x 6 B o . Let X C B o .
KCkX, MC m X
8. COMPLETENESS AND ATOMS
251
From Th. 200 and Th. 202 we get the following key result, which is needed to show that w-additive operations generate an w-additive clone. It encompasses both Th. 202 and Th. 203, and it is the essential part of an inductive proof of Th. 205. Theorem 204. Assume 23o, 23i, 23 2 , 233 G BA, a : Bo -> Bi, T : Bo -> B2, j3 : Bi x Bi -¥ B3, a is k-additive, T is m-additive, j3 is j-additive under (1,0), and ft is l-additive under (0,1). Let 7 = (cr|P—1 fl -rlQ" 1 )|/3. Then 7 : Bo —> B3 and 7 is (jl + km)-additive. PROOF. Note that 7(0;) = (3(a (x), T (a;)) for all x € Bo. Let X C Bo.
( 4 K KCkX
MCmX
3
( E
3
K):KChX} iC,{r(S° M):MCroX}
WQjk + Im-
- E" D Theorem 205. Suppose 23 = (B, ) £ BA, Fi is a set of unary operations on B, i*2 is a set of binary operations on B, and C is the clone generated by F\ U i*2- -(f ewen/ operation in F\ U F2 *s ui-additive, then every operation in C is co-additive. Even if ; is a left and right distributive binary operation on a Boolean algebra, the function a defined by a (x) := x;x is not necessarily additive, since a (x + y ) = (x + y ) ; ( x + y ) = x ; x + x ; y + y ; x + y ; y , a(x) + a ( y ) =x ; x +y ; y . It is possible t h a t x ; y +y ; x isn o n z e r o a n d n o t i n c l u d e d i n x ; x +y ; y . For e x a m p l e , w e m a y t a k e ; t o b e relative m u l t i p l i c a t i o n i n 231(3 x 3), t h a t is,x ; y = x \ y , a n d
252
5. BOOLEAN ALGEBRAS
let x = {(0,1}} and y = {(1, 2}}. On the other hand, a is 2-additive since a (x + y + z) = (x + y + z);(x + y + z) = x;x + x;y + x;z + y;x + y;y + y;z + z;x + z;y + z;z = (x + y); (x + y) + (x + z); (x + z) + (y + z); (y + z) = a (x + y) + a (x + z) + a (y + z) . The 2-additivity of a also follows from the fact that a = (PIP" 1 n P|Q~ 1 )|(;)In general, an n-ary function that is m-additive in each variable (that is, it is wi-additive under each (0, , 0,1, 0, , 0}) gives rise to an win-additive unary function if all its variables are set to the same value.
9. Duals and conjugates Now we consider a relationship that may hold between two functions that both map one Boolean algebra into another. Assume © = (B,+,~) £ BA, 03' = (B1,+',-') <E BA, a: B -> B'', and T : B -> B''.
We say that T is the Boolean dual of a if, for every x £ B, T (X) = a (x) . Note that T is the Boolean dual of a iff r = ~~ | a | ~'. Theorem 206. Duality is a symmetric relationship: i/93,© £ BA, a : B —> B', and T : B —> B', then r is the dual of a iff a is the dual of T. Furthermore, if T is the dual of a, then (i) a is monotonic iff T is monotonic, (ii) a is additive iff r multiplicative, (iii) a is completely additive iff T is completely multiplicative, (iv) a is universally additive iff T is universally multiplicative. PROOF.
If r is the Boolean dual of a, then
T
= ~\ a \~', so
1
r
| -' = -1 ~ | a | - | -' = a,
hence a is the Boolean dual of r. a is monotonic $$VxVy(x < y => a (x) < a («/)) => a{x)
y) = a (x
y)
= a{(x + y)) = a (x) + a (y) = a(x) -a (y)
9. DUALS AND CONJUGATES = T{X)-T
253
(y) ,
and conversely, by a similar proof. Again consider a pair of functions between Boolean algebras, but this time one of the functions maps one algebra to another, while the other function maps the other algebra to the one, say a : B —> B' and r : B' —» B are unary functions between Boolean algebras 03 and 93': 23 —?—> 23' — T - ^ 23 We say that a is a conjugate of r iff a (x)
y = 0' O x
T
(y) = 0
for all x 6 B and all y E B'. In case 03 = 58', we say a is self-conjugate if a is a conjugate of itself. We begin with the simple observation that the relation "is a conjugate of" is both symmetric and functional. T h e o r e m 207. Assume OS, OS' G BA, a : B -> B', and r,p: B' -> B. (i) T is a conjugate of a iff a is a conjugate ofr. (ii) If T and p are conjugates of a, then T = p. Theorem 208 (Jonsson-Tarski [118, 1.13, 1.14]). Let 23, 23' £ BA, a : B -> B', and T : B' -> B. (i) If T is a conjugate of a on 23, then T (y) = ]J{x :y
= J2&
V}
for every y 6 B. (ii) The function a has a conjugate iff the following conditions are satisfied: (a) a is universally additive, (b) ^2{x : a (x) < y} exists for every y 6 B. Perhaps it is worth noting, before we proceed to the proof, that
] > > :a (x) < y} = ^ ( a " 1 ) * ^ : x < y} = X ) ^ " 1 ) ' ( > ' ({»})). PROOF. For the first part, assume r is a conjugate of a. Then T(V)
= Y{{x x > T (y)} = T~\{x : y a (af) = 0}
= ]\{x
:a(x)<
:a{x) <
y}
a and r are conjugates
5. BOOLEAN ALGEBRAS
For the second part, first assume a has a conjugate, say T. From 0 = 0 T (1) it follows that 0 = a (0) 1 = a (0), so a is normal. Assume X C B and J^ X exists. Then a (^2X) is included in all the upper bounds of a*(X) because < X
T
a and r are conjugates
(y) = 0
<=> £ < r (y) for all x 6 X <=> x
T
(y) = 0 for all x £ X cr and r are conjugates
<=> cr (x) y = 0 for all x £ X <=> c 0») < 2/ for all x € X > j / is an upper bound of a* (X)
The first statement is true when y = a (J^ X ) , so
This shows that a is completely additive. Since a is also normal, a is universally additive. Finally, J\{x V < a (x)} exists for every y £ B by the first part. For the converse, assume that a is universally additive (hence also monotonic) and that \[{x : y < cr (x)} exists for every y £ B. Define a function r by setting r (y) := Yl{x : y < a (x)} for every y E B. Then (5.39)
r(y)
so T (y) contains every x such that y < a (x). Consequently, if a (x) y = 0, then y < a (x), hence x < T (y), which implies x T (y) = 0. Conversely, if x T (y) = 0, then x < T (y), hence a (x) < a (T (y) J
a is monotonic ^
c (x) : y <
)
(5-39) a is universally additive
9. DUALS AND CONJUGATES
Theorem 209 (Jonsson-Tarski [118, 1.15]). Let a and T be functions on a Boolean algebra 03. The following statements are equivalent: (i) a and r are conjugates of each other, (ii) for all x,y £ B, (a) a[x-T (y)j < a (x) y, (b)
T
[y a O)J <
T (y)
x.
(iii) a (0) = 0 , r ( 0 ) = 0 , and, for all y , z e B , (a) (j(y)-z
(x) ' V ^ V, s o °~ (x) ' y = 0. Conversely, if a (x) y = 0, then y = y a (x), so
T (y) = T (y a (x)J < x, hence x T (y) = 0. Thus a and T are conjugates of each other. Suppose a and r are conjugates of each other. Then a and r are normal by Th. 208(ii), i.e., a (0) = 0 = r ( 0 ) . To show that Th. 209(iii)a holds we first observe that a is additive by Th. 208(ii) and that Th. 209(ii)a holds by the first part of the proof. Then
= (a (y T (z)) + a [ y T (Z) I ) z
a is additive
< (a (y T (z)) +a(y)-z)-z
Th. 209(ii)a
The proof of Th. 209(iii)b is similar. Thus Th. 209(i) implies Th. 209(iii). For the converse, assume Th. 209(iii). If a (y) z = 0, then, since r is normal and Th. 209(iii)b holds, r (z) y < r (z a (y)) = r (0) = 0. Conversely, if r (z) y = 0 then a (y) z = 0 by the normality of r and Th. 209(iii)a. Thus a and r are conjugates of each other. The function ) is self-conjugate because, for all x, y, z, we have (x-(y))-z = 0 iff y- (x (z)) = 0. Self-conjugate functions are completely additive, the function x (-) is therefore completely additive, and it is also obviously normal, so it is universally additive, as was observed earlier.
256
5. BOOLEAN ALGEBRAS
10. Regular-open BA of a closure operator Suppose we have only one Boolean algebra: 23 = (B,+,~) £ BA, and a : B —) B, that is, a is a unary function mapping B into B. All the previous definitions apply, but we gain some others, due to the possibility of considering interactions between elements that belong to the domain and the range of the operator. We say that a is -
expanding if x < a (x) for every x £ B, contracting if x > a (x) for every x £ B, idempotent if a (a (x)) = a (x) for every x £ B, involutive if a (a (x)) = x for every x £ B, a closure operator on 03 if a is normal, monotonic, expanding, and idempotent, - a topological closure operator if a is normal, additive (not just monotonic), expanding, and idempotent. In this section we show that from a topological closure operator on a Boolean algebra we obtain a new and rather special Boolean algebra, called the regularopen algebra. We use alternative notation and topological terminology that is applicable in the general case, although it is most appropriate in applications that come later. Throughout this section we suppose that * is a unary function on the Boolean algebra 93 = (B,+,~), that is, * : B —> B, and that ° be the Boolean dual of ', i.e., ° is defined by (5.40)
x° :=W
for every x £ B. We say that an element x £ B is *- closed if x' = x, 'open if x° = x, *- regular if x = x'°, *- regular-open if x = x° = x'°, *nowhere dense if x'° = 0, *- dense iff x* = 1, and simplify the terminology to "closed", "open", "regular", "regular-open", "dense", and "nowhere-dense" within the context of the fixed function *. Define C, O, R C B by (5.41)
C := {x : x' = x £ B},
(5.42)
O:={x:x° = x £ B},
(5.43)
R:={x:x'°=x£B}.
C is the set of closed elements, O is the set of open elements, and R is the set of regular elements. The boundary of an element x £ B is x' x' = x' x°. Using the alternative notation, recall that * is a closure operator on 23 if, for all x,y £ B, 0* = 0 , x < y =^ x' < y', x < x ,
or, simply, x < y => Q < x < x < y = y
,
11. REGULAR-OPEN BA OP A TOPOLOQICAL CLOSURE OPERATOR
257
and that * is a topologieal closure operator on !8 if, for all x,y £ B, 0* = 0 , {x + y)' = x* +y", x < x*, x"=x"J or, simply, 0* <x + y<(x
+ y)m = (x + y)".
Every topologieal closure operator is also a closure operator, since additive functions are monotonic. In both concepts, idempotence [x" = as*) can be weakened from an equality to the inclusion x" < x', since the opposite inclusion is deducible from the assumption that * is expanding. To illustrate these notions, consider, for example, a finite set U and a number n e w with 1 < n < |Z7|. Say that a subset X C U is "small" if \X\ < n and "big" if |X| > n. The condition imposed on n and U insures that there are both small and big elements. Let a be the function on the Boolean algebra of subsets of U that sends every "small" subset of U to 0, and every "big" subset to itself. Then
{#,©,') e BA, where, for all x,y 6 B, x®y:=
(x + y)*°,
For a topologieal closure operator, all regular sets are open, so R is also the set of regular-open elements. For this reason we refer to this Boolean algebra as the regular-open Boolean algebra associated with *. The proof is broken down into parts to show what can be deduced from various combinations of the properties defining a topologieal closure operator.
2B8
B. BOOLEAN
ALGEBRAS
Theorem 210. Assume 23 = (B,+,~) £ BA, * : B -> fl, ° : B -> B, and that (5.40), (5.41), (5.42), and (5.43) hold. (i) © is commutative. (ii) If x E R then x' e R and x" = x. (iii) (a) i G O e i e C . (b) leCftfeO. (c) * is expanding iff ° is contracting. (d) * is contracting iff ° is expanding. (e) * is idempotent iff ° is idempotent. (iv) Assume ' is monotonic and expanding. (a) For every X CC, if\[X exists then \[X £ C. (b) If x,y € C then x y € C. (c) For every I C O , if^X exists then J ] I e O . (d) Ifx,y£Othenx + y£O. (v) Assume ' is idempotent. (a) x' £ C and x° £ O for every x 6 B. (b) i?C O. (vi) Suppose ' is additive. (a) If x,y € C then x + y € C. (b) If x,y £O then x -y £O. (vii) / / * is expanding, then x x' = 0 /or ewery s. (viii) / / * is monotonic, expanding, and normal then x ® x' = 1 /or every x £ R. (ix) Suppose ' is monotonic, expanding, and idempotent. Then, for every x€B, x°'°' = x°' and x'°'° = x'°, hence x'° €R and x ® y € R. (x) Suppose ' is additive, expanding, and idempotent. Then ffi is associative on open elements. (xi) Suppose ' is additive and idempotent. (a) IfyGO then (x y)'° = x'° y'°. (b) (x-y°)'°=x'°-y°'°(c) If y £ C then {x + y)om = xom + y°m. (d) (x + y')°' = x" + y'°'. (e) If x,y e R then x y 6 R. (xii) Suppose ' is additive, expanding, idempotent, and normal (a topological closure operator). Then Huntington's axiom R3 is satisfied by regular elements: (x' (By1)' ffi (x' © y)' = x if x,y 6 R. PROOF. Proof of (i): x © y = (x + y)'° = (y + x)'° =y®x. Proof of (ii): If x £ R then x'° = x, so x" = x°° = x'° = x, and x' £ R since x' = x° = ^ ° =x°'° =x"°. Proof of (iii): For the first part,
and the second part is a corollary of the first. is expanding -&yx(x < x')
11. REGULAR-OPEN BA OF A TOPOLOGICAL CLOSURE OPERATOR
> ° is contracting If * is idempotent, then x°° =x" =x' = x°, and, similarly, if ° is idempotent, then so is *. Proof of (iv): Suppose X C C and n ^ exists. If x E X, then x = x' and x > Y\X, so x = x' > (X\.x)' by monotonicity. This shows (II-'0* is a lower bound of X, so JTX > (fl-^)*- Since * is expanding, we also have so < (Ux)', Ux = (Hx)'Suppose X C O and £ X e x i s t s - T h e n Ux {x : x £ X)
x = x - a F ° = x - a ; * = 0 since * is
x ffi x = {x + x°)'°
defs.
= (x'+x)° ^
/
xER
. —\ O
O
> (x + x)
-mon,
-exp
= i° = 0*" = 0
'-normal
= 1. Proof of (ix): Since * is expanding, we have (5.44)
x < x'
for all x. In particular, (5.45)
x°<x°'.
The Boolean dual function ° is monotonic since * is monotonic, so, applying the monotonicity of ° to (5.44), we get also X
o ^ o < X .
Into this last law substitute x° for x, and, noting that ° is idempotent since * is idempotent, deduce (5.46)
5. BOOLEAN ALGEBRAS
This law can also be deduced from (5.45) by applying the monotonicity and idempotence of °. Now apply (5.46) with x' in place of x, and also apply the monotonicity of *, to get
Each of the laws obtained so far has a dual form, obtained from the given law by applying it to x in place of x, and taking the complement of both sides. Starting from x < x*, this produces first x < x*, and then x > x°. The dual forms of the laws above (which can also be deduced from x° < x by dual reasoning) are (5.47) (5.48) (5.49) (5.50) (5.51) (5.52)
x° < x, X
_i
< X
X
o*
X
x°'°' X
x
< X < X
o*o
< X
As a consequence, we obtain x°'°' = x°' and x'°'° = x'°. Proof of (x): We need only observe that * is monotonic and expanding to conclude that if x, y £ O then x + y £ O and (x + y)° = x + y. Hence (x + y)'°' = (x + y)°'°' = (x + y)°' = (x + y)' = x* + y'. U s i n g t h i s w e r e d u c e o n e s i d e of t h e a s s o c i a t i v e l a w for ffi w i t h x,y,z
6 O to a
special form:
One can show similarly that x®{y®z) = (x* +y' + z')°. Proof of (xi): Because * is additive, both ° and * are monotonic. Consequently, (5.53)
{x y)'° < x*° y'°.
This is half of the first part. Using only the additivity of *, we get o
x
y
/
= (x
.
—\
y + x
y)
= {x-y)
-y
o
-y
+{x-y)
< {x y)' +y'
y°
= {x y)' +y°
y°
= {x
y)'
so, for all x, y, we have (5.54)
x'-y°
<{x- y ) ' .
-y
11. REGULAR-OPEN BA OF A TOPOLOGICAL CLOSURE OPERATOR
If y £ O then oo
x'° = (x
o \
<(x = (x
o
is idempotent
\o )
is multiplicative
O
(5.54), ° is monotonic y is open
) \
< (x
\
— \x (r —
O
(5.54), *° is monotonic
0
is idempotent,
hence, combining this with (5.53), we have /
\ o
o
o
(x y) = x -y . This completes the proof of the first item. The next four are easily obtained consequences. For example, for the fifth item, assume x,y £ R. Then x'° y'° = x y a n d y £ O, so (x-y) = x -y = x y,
which shows x y £ R. The hypothesis that y (or x) is open cannot be removed. For an example, consider the topological space consisting of the unit line segment [0,1]. Let x be the rational numbers in [0,1], and let y the irrationals. Then (x y)'° = 0*° = 0 but x' = [0,1] = y' so x'° y'° = [0,1]. Proof of (xii): Suppose x,y E R. Then x ffi y = (x /
+ y ) O
defs
O
\ O
1
= (x + y ) = (x*° +y'°)°
1
j_
is additive
= (x + y)°
x,y £ R
= (x y)'
def.
We have (x y)" = x y since x y £ R by Th. 210(xi), so (5.55)
(x © y')' = (x y)" = x y
and y £ R since y"° = y°'° = y^° =y° = y', so (x © y) = (x ®y ) = x y . Since y£R,we
have (y + y')'° = 1 by Th. 210(viii). Hence
{x © y')' © {x © y)' = {x-y)®{x= (x
y + x
y) y')'°
zxl482 def. of ffi
= (x [y + y )) = x'°
(y + y')'°
Th. 210(xi), x £O
= x (y + y')'°
x e R
= x 1
zx!482
5. BOOLEAN ALGEBRAS
so Huntington's axiom holds for regular x, y. Theorem 211 (regular-open algebra). If * is a topological closure operator on 23 = <£,+,-) eBA, and x° = x' for every x E B, then the set R : = {x : x'° = x,x E B} of regular elements of 03 is the universe of a Boolean algebra
«R = (fl,e,')eBA, under the operations © and ', defined by
For every XCR,if^2
X exists then ^
X also exists and
£** = (£"*>". and ifYl
X exists then J\
X also exists and
lfx = c[fxr. /f *B is complete, then $R is also complete. PROOF. R is closed under ' by Th. 210(ii), and R is closed under © by Th. 210(ix). © is commutative everywhere by Th. 210(i), associative on open elements by Th. (x), and Huntington's Third Axiom holds on regular elements by Th. (xii)(xii). For idempotent operators, regular elements are open. Therefore the regular elements satisfy Huntington's three axioms and *H = (R, ©,') € BA. For the rest, we only do part. Suppose X C R and ^X exists in 23. Then we claim that (%2X)mo is the least upper bound of X in SR. Note first that the partial ordering < of *H is the same as the partial ordering < of 03 restricted to the regular elements in R, since 53 and $R have the same meet operator by Th. (xii)5.55. Any regular u € R that is above every x G X will also be above Y, X, hence u>^2X, so u = u'° > {^2X)'° since *° is monotonic. Thus {^2X)'° E R is a lower bound of all upper bounds of X in R. To show (52X)'° is above every element in X, we use the assumption that X C R. So if x G X, then x <^X and x'° = x, hence x = x'° < {^2X)'°. Thus {^2X)'° is a regular element that is above every element of X, and also below every regular element that is above every x £ X, i.e., (Y,X)'° is the least upper bound of X i n K .
We have seen that a topological closure operator * gives a Boolean algebra of regular elements. The map *° sends elements of 03 to regular-open elements of 53. This map is a homomorphism iff the following two identities hold: (x + y)
=x X
®y
= (X
= (x +y ) , ) = X'°
.
12, TOPOLOQICAL SPACES AND CLOSURE OPERATORS
263
The second identity may fail. For example, it fails if x is the set of rational numbers in the space of real numbers. Both x and its complement have the same regularization (interior of the closure), namely R, the set of real numbers. On the other hand, the first identity holds since *° is completely additive on R by the proof of Th. 211. For a more direct proof, taking x* for x in Th. 210(xi)(iv), we get /
.
\um
(x +y ) By additivity of ", this gives
mam
=x
,
+y
.
Take ° of both sides, and get (x"+y")ma.
(x + y)"" = But the left-hand-side simplifies, leaving {x + yj
= {x
+y
} .
12. Topological spaces and closure operators Any subset of a complete Boolean algebra can be used to create a closure operator. Theorem 212. Assume 93 is a complete Boolean algebra, and let S C B, Define " : B -> B by
(5.56)
x ' := ]J{b
:x
for every x £ B. Then ' is a closure operator (monotonic, expanding, idernpotent, and normal), and ' is a topological (additive) closure operator whenever S is closed under +. Finally, all elements of S are closed: S C C := {6 : b* = b £ B}. PROOF.
First, * is monotonic because if x < y, then {& : x < b e S} 2 {& : y < b £ S},
hence x* = ]J{b :x
]J{b :y
=y*.
Also, a; is a lower bound of {& : x < b G S}, so x < II{^ x < b £ S} = x*. Thus " is expanding. If x < b g S, then b g {b : x < b € S}, hence b* = f[{b ; x < b g S} < b. Thus {b : x < b g S} C {b : x' < b g S} which gives us x* = ]J{b :x
]J{b : x* < 6 g S} = x".
It follows that * is idempotent because it is also expanding and monotonic. Thus " is a closure operator. Assume S is closed under +. To show " is additive, and hence is a topological closure operator, first use closure under + to first show {c : x +y < c £ S} = {a + b : x < a £ SAy
264
5. BOOLEAN ALGEBRAS
and then compute as follows. (x + y)' = Y\{c
:x +
y
-b:x
{a : x < a E 5} +* {6 : y < b E 5}) : x < a £ S} + JJ{& : y < b £ S} = x~ +y'. If x £ 5 then x < x £ 5, so x* = ]J{b hence x = x' and x EC.
x < b £ S} < x, but x < x' in general,
T is a topological space (or topology) iff T is closed under arbitrary unions and finite intersections:
X CT => [jx £T, X,Y ET ^ XHY ET. The previous theorem is an abstract version of the progression from topological space to topological closure operator. A corollary is obtained by applying it to the complete Boolean algebras of subsets of a set. Every topology on a set U gives rise to a topological closure operator on Q3I({7). Theorem 213. Let U £ V and let T be a topology on U. If',°:Sb 56 (U) where X' = p | { [ / ~ y :XCU~YAY X° = \J{Y
(U) ->
ET},
:XCYAYeT},
for every X E Sb (U), then ' is a topological closure operator, ° and ' are dual, and T is the set of '-open elements: T = {x : x = x°}. Let T be the usual topology on R, the set of real numbers. In more detail, define open intervals as usual, namely (a, 6) := {c : c £ R, a < c < b} whenever a, 6 E R and a < b. Then for every X C R, the interior of X is the union of the open intervals that X contains: X° = \J{(a,b)
: a,b £ R, (o,6) C X}.
If x = (0,1/2) £ T and y = (1/2,1) £ T, then x and y are regular-open and their union is not, since (x U y)'° = (0,1)
(0,1/2) U (1/2, l) = i U y ,
so x® y ^ xUy. The need for (-)*° in the last equation of Th. 211 is illustrated by choosing Xn = (—1/n, 1/n) for n E co and X = {Xn : n E co}, for then X is a set of regular-open elements whose intersection is not regular open, since f] X = {0} and
13, COMPLEX ALGEBRA OP A BINARY RELATION
268
13. Complex algebra of a binary relation This section introduces a general method that starts with a relation on a set and produces a completely additive operator on the Boolean algebra of subsets of that set. We begin with the case of a single binary relation on a set. In this case the relation induces a unary operator. Later we will use this method to produce operations of higher rank from relations of higher rank. Let U be a set, let 95 = 95[(C/), and let R be a relation on U: R C U x U. We may often read (x, y) € R as "a: is below y" or ay is above a;". Let * be the restriction of R* to subsets of U: ' := R* n {Sb (U)f = ((E-^R) o E) n {Sb (U)f. Thus R determines an operator on 33, that is, a map from subsets of U to subsets oft/: * : Sb (U) -* Sb (U). If R is empty then * = 5*6 ([/) x {0} since $*(X) = 0. Note that if X £ Sb (E7) then X' = R*(X) = {y : 3x(x £ X A (x,y) £ R)}. As before, we use ° to denote the Boolean dual of *. Let Then X° =U~R"'(U~X) = {y:yeUAVx((x,y)eR
4-i
for every I 6 Si (U). A set X G Sb (U) is '-closed iff X* = X iff everything above something in X is in X, and X is "-open iff X° = X iff everything below something in X is in X: X = X' « XeSb(U)A\/x%((x,y)eRAa:eX X = X° » X £ Sb (U) AVxVv({x,y) £Rhy£X
=* y 6 X), 4i£l).
It follows that X is "-open iff it contains the iZ-cones of all its elements. We say that X is R- dense below y iff¥x({z,y) £ R =^ 3s(z G X A{z,x) £ R)). Hence X is i?-dense below y iff everything below y has something in X below it. Next we record the meaning of the regularization operator " °. X*° = U~R*(U~R*(X)) = {y-^4{x,y)£R => 3s({z,x)£RAzeX))} = {y : X is iZ-dense below y}
We say two sets x,y £ U are incompatible iff their ii-cones are not disjoint, hence x,y are ij-compatible
> Bz((z,x) 6 RA (s,y) € R) «
{z^jeR'^R.
5. BOOLEAN ALGEBRAS
The regularization of the cone of q £ U is
=
{P
^V{{VTP) £ R => Va n d Q a
r e
incompatible)}
= {p : p is hereditarily compatible with q}
Here are some further computations along the same lines, but without reference to q.
T C ((E- 1 ^) o EJIUE"1 fS) o E) = ((E-'IR) fiZ) o E, ( i T 1 o E)|* C ( B - 1 o E)|((E-1|JR) o E) = (RT^R) o E, (B" 1 o E)|-| C (R-1 o E)|((E"1|JR) o E)|((E"1 f f l ) o E) = (( J R- 1 | J R)oE)|((E- 1 tii)oE) The following theorem illustrates how properties of R can be expressed as properties of the associated operator *. This theorem is the starting point of correspondence theory; see van Benthem [245]. T h e o r e m 214 (Jonsson-Tarski [119, 3.5]). Assume U £ V, 23 = 93l([/), R C U x U, and ' = R* H (56 (t/)) 2 . Then * :Sb(U)^Sb(U). * is normal and completely additive. f/1 C i£ iff * is expanding. .R is transitive iff X" C X* /or e^er?/ X € 56 ([/). iZ is symmetric iff * is self-conjugate. iZ" 1 is functional iff * is multiplicative. iZ is symmetric and functional iff X" = X C\U' for all X E Sb (U). R is functional and its domain is U iff X" = X for all X E Sb ([/). ( * is an involution). (ix) U1 U (-R|.R) C R iff * is a topological closure operator on 5H({7).
(i) (ii) (iii) (iv) (v) (vi) (vii) (viii)
PROOF. Normality of * follows from i?*(0) = 0. Complete additivity of * follows from complete additivity of R*. Indeed, for any X e V we have
since (J \R* = (R*)*\ [J, which can be proved as follows:
U \R* = ((E^IE- 1 ) o E)|((E-1|i2) o E)
defs.
14. COMPLETE BA OF A PARTIAL ORDERING
E
267
(2.429)
o E)) o EJIUE-^E"1) o E) E
defs. (2.429) (2.432).
14. Complete BA of a partial ordering If R is a preorder then R\R C R^IR since
R\R = (Id n R)\R\R
CR
R is reflexive
\R
R is transitive
(and R C (J? 1|JR) f ^ 1 ) by (2.164). Relations sathence R C W^^R-^R) isfying the opposite inclusion are given a special name. In general, we say that a binary relation R is separative (Koppelberg [123], Jech [107, p.48]), or fine (Takeuti-Zaring [224]), or satisfies condition (a), (Sikorski [216, p. 38, Ex. B)], Biichi [47]) if BrTt(-R"1|-R) C R. R is separative iff VxVy(Vz((z,x) £ R => 3w({w,z) £RA{w,y)
€ R)) => (x,y) € R).
If R is a preorder, then the algebra 91 that appears in the next theorem is called the complete Boolean algebra of R.
Theorem 215. Let R £ V, U = Fd(R), 55 = *B(([/), ' = R* C\ (Sb (U))2, and ° = ((E"1 ffl) o E) n (56 (U))2. (i) Suppose that R is a preorder, that is, R is a reflexive and transitive relation. Then ' is a topological closure operator on Q3l([/), and the set of '-regular sets, namely
n-.= {x -.x'° = x esb(u)}, is the universe of a complete Boolean algebra $R := (72., ©,'), where X®Y
=
(XUY)'°
and X' = (U~X)° for all X, Y £ 1Z, and for every X C 72., the least upper bound of X in $R exists, the greatest lower bound of X in 9i exists, and
268
5. BOOLEAN ALGEBRAS
(ii) If R is a separative preorder then -R"1 o E maps U into the family 1Z of '-regular subsets ofU and sends the relation R to the inclusion relation (iii) If R is a separative partial order, then R-1 o E is injective. (iv) // R is separative and Do (R) = Fd (R) then
for every X E Sb (U). (v) Assume R is transitive and R has the property that for every z E U there exists some u G U such that z is not below u and u is an upper bound of the set of elements of U that are not compatible with z. Then (R^lR^iX) C X'° for every open X E Sb (U). (vi) Suppose 03 = (B, +,~) G BA, 0 ^ U = B ~{0}, and R is the restriction of the partial ordering < z E X. Since X is dense below y, we have y G X'°. But X'° = X since X G X C U, so y G X. Since this is true for every X E X, it follows that y E [~\ X, so we have proved P) X'° C f] X. Note that *° is expanding on open sets, for if X = X° then X C X' since * is expanding, so X = X° C X'° since ° is monotonic. Assume it is not the case that D % C (P) X)'°. Then X cannot be open, so there are z and y with z < y E P| X and z ^ p| X. Hence there exists some X E X such that z £ X. But y E X since y G P| X, so X is not open, contradicting the assumption that X
so R^1 o E, the map that takes each p E U to its iZ-cone (R^1 o E)(p) = (R^1) ({p}), maps U into the family of '-regular subsets of U. The cone map i?" 1 o E sends the relation R to the inclusion relation E"1 f E by (2.220). Proof of (iii): The cone map R^1 o E is injective whenever R is extensional. For reflexive transitive relations, antisymmetry is equivalent to extensionality by Th. 80, so if R is a separative partial order, then the cone map is injective. Proof of (iv): Assume y E X'°, i.e., X is .R-dense below y. We will show, using the hypothesis that -R is separative, that y is below every upper .R-bound of X. Let u be an upper .R-bound of X. Assume z is below y. Since X is dense in y, there is some x E X that is below z. Since x E X and u is an upper .R-bound of X, x is below u. Thus everything below y is iZ-compatible with u. Since R is separative, this implies that y is below u, as desired. Since y is below every upper -R-bound of X, we have y G R^(K1'(X)), but y was an arbitrary element of X'°,
14. COMPLETE BA OF A PARTIAL ORDERING
so Ril'(R'!t(X)) D X'°. For a more computational proof, first note that C (Sb (U)f\(Sb (U))2 = (Sb (U))2 U R'1) f I C V|(i? U i?"1) f E, so, taking converses, we have 0-1
c EF
What we wish to show is equivalent to To show this, begin as follows. These computations parallel the proof given above.
ii|E|T~ W l ^ " 1 C R\E\(E~X o (RrfftR'
By one of the equation-solving laws and the separability of R, this gives us
EIT'WlE"1 C W^^R-^R) C R so, shifting the rightmost E"1 to the other side, we get
Then multiply on the right by R^, and get E'
C(iJfE)|^
C EUfljV. We also have E
.,o-l|
= R\V
270
6, BOOLEAN ALGEBRAS
since Do(R) = Fd(R). Combine the previous two equations, move E from one side to the other, and get
Proof of (v): Suppose y is below every upper bound of the open set X. Suppose z is below y. We want to find something in X below z. Let I be the set of elements of U that are not compatible with z. By hypothesis, there exists some u € U such that z is not below 11 and ti is an upper bound of I. Assume, for the sake of getting a contradiction, that X C I. Then u is an upper bound of X, hence y is below u. Since R is transitive and z is below y, we conclude that z is below «, a contradiction. Therefore, X is not a subset of /. Choose any v £ X such that v $ I. Since v is not incompatible with z, there is some x that is below both z and v. Since X is open and x is below v € X, it follows that x £ X, This complete the proof that every z below y has something below it in X. In short, X is ii-dense below y1 hence y € X'°. Proof of (vi): It suffices to show that R is separative and has the property that for every z £ U there exists some u G U such that z is not below u and w is an upper bound of the set of elements of U that are not compatible with z. To show R is separative, assume x,y G U and everything below x is compatible with y. Note that x y is below x. It follows that if x y ^ 0, then x y £ U and x y is compatible with y, hence there is some w € U such that w < x y and w < y. But this implies w / 0 and w <x-yy = 0, a contradiction. Therefore x-y = 0, hence x < y. For the other property, suppose z £ll. Then z / 0. If a = 1 then every element of [/ is compatible with z, so the set of elements incompatible with z is 0, and every element of U is an upper bound of 0, hence we may simply take w = z. Suppose z :/ 1. Then 0 /: a, so z G E7. Let u = a. Then z is not below it, since otherwise we would have z < « = z, hence 2 = 0. If a; is not compatible with z, then a; z = 0, hence x < 2 = w. Thus -B is an upper bound of the set of elements incompatible with z. 15. Completion of a BA Let © and € be Boolean algebras. We say that € is a completion of 05 iff 58 is a dense subalgebra of £ and £ is complete. (See Sikorski [216, p. 154], Koppelberg [123, 4.19].) Suppose £ is a completion of 03, X C B, and the join Y^ X exists in 2$. Since £ is complete, the join J ] 4 " ^a^so exists in €. Density implies that these joins are the same. First, J^m X is an upper bound of X in <£, so S nonzero b 6 B that S X >^2 ^2 X. li these joins are distinct, then there isCsome x B lies below the difference: 0 / b < J2™ X and 0 = 6 E - u* then b > ^ c X, so & J^ X is a strictly smaller upper bound of X that lies in 58, a contradiction. Hence £ * X = £ e X whenever I C B a n d ^ X exists. Furthermore, OS is a complete subalgebra of €, in the sense that 23 completely generates €, i.e., every element of £ is the join of a subset of B, The next two theorems show that completions are unique and exist.
16. PERFECT EXTENSION OF A BA
271
Theorem 216. Completions are unique. Suppose that 03, €, €-' £ BA and that
:0<x
Note that R e V and B ~{0} = Fd (R). Let
2
,
1
° = ((E- ffl)oE)n(56(B~{0})) 2 , TZ = {X :X'° =X eSb(B ~{0})}. Then * is a topological closure operator on 031 {B ~{0}) by Th. 214. By Th. 215, TZ is the universe of a complete Boolean algebra D\ := (72.,©,'), where X ffi Y = (XUY)'° and X' = (5~{0}~X)° for all X,Y e TZ. By Th.81, we have a : B —> H, a is injective, and a sends R into the inclusion relation, that is, if x,y e B, then a(x) C a(y). Every element of TZ is '-open, so by Th. 215, (R^\R^)(X) = X'° for every X £ TZ. Using this together with either Th.81 or Th. 215, we conclude that a preserves all least upper iZ-bounds and greatest lower iZ-bounds, in the sense that for all X C B ~{0}, if Y,RX e x i s t s t h en
and if n ^ X exists then
Note that F*(B ~{0}) is a dense subset of SH, because every X £ TZ is open, so if X / 0, then X contains the cone F(x) of each of its elements x €. X. Therefore a*(B) is the universe of a dense subalgebra of D\, and a is an embedding of 03 into SH. From this it is possible to construct a completion of 23 by putting a copy around 03 of the part of 9t that is disjoint from the image of 03 under the cone map a. 16. Perfect extension of a BA A representation of a Boolean algebra 03 is a Boolean homomorphism a : B -» 56 (X) from 03 = (B,+,~) € BA to the Boolean algebra 031 (X) of all subsets of a nonempty set X € V. In the construction of a completion, we encountered such a function, mapping B to subsets of B~{0}, but it was not a homomorphism into 03t(B~{0}). Note that a relates each element of B to a subset of X. We'll consider a relation that goes the other way around, and
272
5. BOOLEAN ALGEBRAS
relates each element of X to a subset of B. Consider a as an arbitrary relation aCBxSb (X), and let r = ((EICT"1) O E) n (X x 56 (B)). Then r is a function that maps each element i £ l t o the set of elements of B that are cr-related to a subset of X that contains x. The next theorem shows that when IT is a Boolean homomorphism, r maps each element of X to an ultrafilter of 03, hence r = ((Elcr^1) o E) fl (X x {7/03). Therefore a homomorphism from a Boolean algebra to a Boolean algebra of sets can be obtained by using the ultrafilters of 03 as elements of those sets. This is done in the second part of the theorem. For every 03 £ BA, define 03+ to be the Boolean algebra of subsets of the set of ultrafilters of 03. Thus 03+ := ®I(E7f 93) = (56 (17/35) ,Uuf
23 is a complete and atomic Boolean algebra. Theorem 218. Assume 03 = (B,+,~) £ BA. (i) Suppose a : B —> 56 (X) is a homomorphism from 03 into 031 (X), X ^ 0 , andr = ((E^" 1 ) o E) n (X x 56 (B)). Then T : X -> £7/03. For each x £ X, T (X) = {6 : 6 6 B, x £ o (6)} is an ultrafilter of 03. (ii) Let a = (E o E) l~l (B x 56 (E//55)). Then a : B -> 56 (E//55), a is an embedding of 03 into 23+ and, for every b € B, a (b) := {U : b € U € PROOF, (i): Let x e X. If a, 6 £ T(X), then x < a (a) and x < f(6), so x < a (a) a (b) = a (a b) since a is multiplicative, hence a b £ r (x), and if a > b E T (x), then a; £
a {x + y) = {U : x + y € U € £7/03} = {U:(x€UVy€U)AU€
Uf
= {U -.(xeu e tz/03) v (y e u e t//03)} = {U : x G U € 17/55} U {[7 : j / £ U € f7/O3} = (T (x) U
A Boolean algebra £ 6 BA is a perfect extension of a Boolean algebra 03 £ BA iff (5.57) (5.58)
03 is a subalgebra of £, £ is complete and atomic,
(5.59)
i f l C B and Y^
(5.60)
if a, a £ At€, a ^ a', then a
x
= 1, t h e n Y^
Condition (5.59) says that 1 is compact in <£.
Y = 1 for s o m e finite Y
- X>
17, SUMMARY OP CONSTRUCTIONS
273
Theorem 219. Perfect extensions are unique, for if 58, £, C' £ BA, and £ and <£ are perfect extensions of 95, then there is an isomorphism a : C —¥ C between Boolean algebras C and €' leaving 95 fixed, i.e., such that a (%) = % for all x £ B. Theorem 220. Every Boolean algebra has a perfect extension. Use Theorem 218 to show that 95+ is a perfect extension of a subalgebra isomorphic to 95. PROOF.
17. Summary of constructions For ease of reference and comparison, several major constructions are summarized here. 17.1. Dedekind-MacNeille completion. The Dedekind-MacNeille completion of the partial ordering R is a function F that sends elements of the range of R to subsets of £, where F:=(R~1oE)r\R~1\V, C :={X :$^X
= (R^lR^iX)
C Fd(R)}.
F embeds R into the inclusion relation ( E r T t E) n £ 2 . See Th. 81. 17.2. Regular-open Boolean algebra. See §5.10. The Boolean algebra of regular-open elements of the topological closure operator " on the Boolean algebra 58 = (B, +,~) is 9t = (R, ® , ' } , where i ° := xm, R:={x:x = xmo x®y:= (x + y)*°,
£B},
17.3. Complete Boolean algebra of a partial ordering. See §5.14. The complete Boolean algebra of a partial ordering R is Dt := {"R,,ffi,'},where U := {X : X*° = X 6 Sb (Fd(R))},
' :=R*n(Sb(Fd(R))f,
X' := and RT1 o E is a map that sends the relation R to the inclusion relation E"1 f E.
5. BOOLEAN ALGEBRAS
17.4. Completion of a Boolean algebra. See §5.15. The completion of a Boolean algebra 23 = (B,+,~) is (any Boolean algebra containing 03 that is isomorphic to) the complete Boolean algebra 91 := {1Z, ©,'), where
K:={X:X'°=Xe X®Y :=(XUY)'°,
Sb (B ~{0})},
.— yJD ^{vJ j ^ -A ) , 1
1
and a := ((R^ o E) n i?" ^) U {(0, 0)} is an embedding of 03 into *R. 17.5. Perfect extension. See §5.16. The perfect extension of a Boolean algebra 03 = (B,+,~) is (any Boolean algebra containing 03 that is isomorphic to) the complete atomic Boolean algebra 23 + , where (5.61) 03+ := 031 (£7/23) = (Sb (C7f«8) ,Uuf*ruf*), and a := (E o E) n (B x S6 (C//53)) is an embedding of 03 into 03+ such that, for every 6 G B, a (6) := {U : 6 G £/ G C//Q3}. 18. Extending Boolean operators Assume Q3o = (B 0 ,---),93i = (Bi,---) G BA, So C Bo, a : So -> Bi. We will also assume 03i is complete, for if it were not, then, for the purposes of this section, it would suffice to replace 031 with a completion of 531. Note that a and T are only partial functions on 23o whenever So ^ Bo- Extend the notions of monotonicity and complete additivity from functions to partial functions as follows. We say a is monotonic on So if x < y implies a (x) < a (y) for all x, y £ So. Similarly, a is completely additive on So if X^1 a*(X) = f (X^° ^ 0 whenever 0 ^ X C So, ^2° X exists, and ^2° X £ So- Define functions a and a on all of Bo as follows. For every x £ Bo let i
a (x) := JT a (a) , x
2^
CT a
( )-
x>a£S0
If 23o = 231 and a is the identity map on So, then a is the identity on meets of subsets of So and a is the identity on joins of subsets of So, but neither a nor a is necessarily the identity on all elements of Bo. For example, in the fourelement Boolean algebra 03o whose universe is {0, a, 6,1}, if a is the identity map on So = {0,1}, then a (a) = a (6) = 1 and a (a) = a (b) = 0. We say that a extends a (upward) if a D a, and a extends a (downward) if a D a. It may happen that a and a do not extend a. For example, if 23o and 03i are nontrivial Boolean algebras (in which 0 / 1), So = {0,1}, a (1) = 0, and a (0) = 1, then 0
18. EXTENDING BOOLEAN OPERATORS
276
l>aeS0
In this example, we chose a specific non-monotonie function, but the first few parts of following theorem show that any non-monotonic function would do. If 0 < m € w, we say that an element a of a Boolean algebra 58o is of height ra if it satisfies the following condition for every subset I C B j : if J^°' X exists and a < Yf X € Bo then there is a subset M C I o f cardinality m = \M\ such that a < J^° M. An element has height m iff it cannot be partitioned into more than m nonempty parts. Atoms are the elements of height 1, joins of pairs of atoms have height 2, and an element has height m iff it is the join of a set of m atoms. Height measured relative to some subset So C Bo is called So-height. An element x has So-height m if x is below the join of a, m-subset of every set of elements whose join contains x. We say that So is meet-compact if, whenever X is a subset of So whose meet JJ X is below an element b € So, X has a finite subset F whose meet is below 6, more formally, V&¥jf ((6 G So A X C So A J J ° X < &) = 3i?(F C X A F is finite A J}° F < 6)). We say that So is join-compact if, whenever X is a subset of So whose join ^2° X is above an element b g So, then X has a finite subset F whose join is above b, that is, G So A X C So A ^2°
x
>b C X A F is finite A ^ ° F > 6)).
Theorem 221. Assume !8o,58i g BA, 0 j4 So C B o , S i M complete, a : So —> S i , anrf CT a
o" W = I I
( ). * (*) = X ) °" (°) >
/or all a; G Bo- 2%en (i) CT and & are monotonic. (ii) For every x £ So,
(iii) (iv) (v) (vi)
If (T is monotonic and a; € So ffeenCT(a;) = a (x) = a {x). a is monotonic iff
276
5. BOOLEAN ALGEBRAS
(x) 7/0 < m G u; and every element of So is of height m then a is completely m-additive. PROOF. Proof of (i): Let x,y E Bo and assume x < y. By the transitivity of <, we have {a : y < a 6 So} C {a : s < a 6 So}. Applying a*, which preserves inclusions, yields <J*{a y < a G So} C a* {a : x < a G So}Applying Y[ changes C into >, so
d{x)= n 1 ff(o)< n x
1
y
Similarly, from x < y we get {a (a) : x > a G So} C {a (a) : y > a G So} so
( ) = Yl a (a) - Yl a(a) = ° (y)
& x
x>a£So
i/>aGSo
Proof of (ii): From i 6 So we get a (x) 6 {a (a) : x < a 6 So} and a (x) £ {a (a) : x > a E So}. It follows that a(x) = Y\
cr{a)
a (a) = a (x) .
x>aES0
x
Proof of (iii): Suppose a is monotonic and a: £ So. Then a (x) is a lower bound of {a (a) : x < a G So}, for if x < a G So then a (x) < a (a). Similarly, a (x) is an upper bound of {a (a) : x > a G So}. This gives us
a(x)= Y^ v(a)
£
Proof of (iv): This part follows immediately from parts (i) and (ii). Proof of (v): Additivity is the case m = 1, but we give proofs for both that differ only slightly. Note that, since So is closed under +, (5.62)
{a + b : x < a e S o , y < b e S o }
= { c : x+y < c e
So}.
To prove this for C, given a,b E So, let c = a + b; for D, given c e So, let a = b = c. Consequently, a (x + y) =
II
a (c)
definition of a
x+y
Yl TT
x
(
b)
a (a) + a (6)
V
(5.62) a is additive
18. EXTENDING BOOLEAN OPERATORS
= a (x) + a (y)
definition of a
Proof of (vi): a is m-additive because S(X! -\
\~ Xm+1)
n xi
1 a
^
..., xm + i
because So is closed under +
Y]
+am)-\
(
\-a(a2-\
\-am+i)
n
cr(a'm+i)
because a is m-additive
because So is closed under +
=
Yl x\-\
" («i) H
1"
\-xm
x2-t
h^ m + l
by Th. 189 =<7 ( x i +
Proof Y?d*{X) a(^°X), directions,
+ Xm) +
+a (X2 +
+ Xm + l)
of (vii): Suppose I C B 0 and Yl° X exists. We wish to show that = d{Y? X). For every x £ X we have x < £ ° X , hence a (x) < so ~Y^1 XIEX ® E) — ' ' ' ( l ^ 0 ^ ) - For a calculation that handles both let y = J^ X. Then y>a£So
y>a£So
- E1
a I V^ ( V^
u) I
5*o is dense in Q3o
j/>oes 0
(y ((
/ ,
i/>aGSo xEX a-x>u£So
^ ( u )))
" i s completely additive
5. BOOLEAN ALGEBRAS
°"(w))
( \J
see
note (a) below
Note (a): If x £ X then y > x, so the condition i > u 6 5o is equivalent to the existence of some a such that y > a £ So and a x > M £ SoProof of (viii): The key calculation, suitably altered:
since So is dense in 23 o 2J
a(ui +
\-um)))
since a is completely m-additive
=
E
(
E
ff{ui-\
h«m))
= E 1 ( E 1 "(«)) Ei,...,i m £X a;iH
h^m>wG5o
since So is closed under + =
^2
O-(Xl ~\
him)-
Proof of (ix): This part follows from Th. 199, but we also repeat the proof of that theorem in current notation. Since So = At^&o, we have
°(x)=
E
a a
()
for every x £ Bo. Assume X C Bo and Yl° X exists. Then
E 1 -(«)
19. COMPOSING EXTENDED BOOLEAN OPERATORS
y xeX
y
a (a)
see note (b) below
x>a£At
xdX
Note (b): Use the law E ^ U * ) = E 1 ( E 1 **) Proof of (x): This part generalizes the previous one, and its proof is essentially the same. Assume 0 < m £ w, every element of So is of height m, X C _B0, and E ° X exists. Then
a
(°)
a (a) v 7
the height of elements of So is m see note (b) above v7
D The hypothesis that So is dense cannot be omitted from part (viii). Suppose ©o is the 4-element Boolean algebra with universe Bo = {0,a,6,1}, 23i = 23o, So = {1}, and a is the identity on So- Then a is additive but a is not additive (and not completely additive) since
° (°) = y,
a (x) = V 0 = o = a- (6),
a (a) + a (6) = 0 ^ 1 = a (1) = a (a + b) . Part (iv) is no longer provable if complete additivity is replaced by additivity. It is possible that So is dense and a is additive, but a is not additive. Suppose ©i = ©o = 931 (w) = the Boolean algebra of all subsets of u, and So is the set of finite and cofinite subsets of a;. Suppose a maps the finite sets to 0 and the cofinite sets to OJ. Then a is additive but not completely additive. Partition w into two infinite sets x and y. Then the only elements of So included in x are finite sets, which are all mapped to 0 by a and join only to 0, hence a (x) = 0 = a (y), but the join of x and y is w, which contains all elements of So, so a (x + y) = a (UJ) = u. 19. Composing extended Boolean operators We now consider a sequence of maps among different algebras. The dependence of a and a on the underlying algebras and sets will have to be deduced from context. For example, the symbol ^ is used in the next theorem in three different ways.
5. BOOLEAN ALGEBRAS
Theorem 222. Assume Q30,Q3i,*B2 £ BA, So C Bo, Si C Bi, <8i and Q32 are complete, a : So —> Si, and r : Si —> B2:
_ B2
^ B2
Then (i) f(a (x)) < (alr^x) and f (a (x)) > (O-\T)~(X), for every x £ Bo(ii) Assume (a) So is closed under , (b) Si is meet-compact, (c) cr and T are monotonic. Then, for every x 6 Bo, (O"|T)~(:E) = f (a(x)). (iii) Assume (a) So is closed under + , (b) Si is join-compact, (c) a and T are monotonic. Then, for every x 6 Bo, (
:x
since this inclusion implies
r (?(«))=
If
r
S(x)
W ^ IT T(ff(a)) = H r » ) . x
Assume x < a 6 So. Then a (x) < a (a) < a (a) by Th. 221(i)(ii), and a (a) e Si, so a (a) £ {6 : o (x) < b € Si}, hence T (cr (o)) £ {T (6) : a (x) < b £ Si}. Similarly, for the other inclusion it suffices to show that (5.63)
{r (cr (o)) : x > a £ So} C {r (6) : a (x) > b £ Si}.
To see this, consider T(a(a)), where x > a 6 So- Then
f(a(x))=
Y?
r
(6)^E
2
r{a{a)) = {a\r)-{x).
19. COMPOSING EXTENDED BOOLEAN OPERATORS
281
Proof of (ii): It suffices to show that, for every x € A, every member of {r(b) :a{x) < b £ Si} is greater than or equal to a member of {T (
: x < a € So},
since this implies
r(a(x))=
^
T b
( ^ I T r(a(a)) = (a\rr(x).
S(x)
z
Accordingly, consider an arbitrary element of the first set, say T (fo), where a{x)= Y^
cr{a)
x
Note that {a (a) : x < a E So} is a subset of Si. By compactness of Si, there is a finite subset of {a (a) : x < a £ So} whose meet is included in b. So there is a finite subset F of {a : x < a € So} such that n 1 <**(F)
a(c) = a (H° F) KH1 a*(F)
(a (a;)) = r
since f is completely m-additive ^2
r(
h«r(am))
;>ai,...,a m G5o
since f and r agree on Si, Si is closed under +
since a and r are monotonic, Si is closed under + D
The next theorem is simply a binary version of the previous one, and has essentially the same proof.
282
5. BOOLEAN ALGEBRAS
Theorem 223. Assume 23o, 93i, 232, 233 £ BA, So C Bo, Si C Bi, S2 C B2, a : So -> Si, T : So -> S2, /3 : Si x S2 -> B3, Let 7 = H P " 1 n T I Q " 1 ) ^ .
(i) Then P(a (x),?(x)) <j(x) and f3(a (x) ,f (x)) >j(x) for all x € Bo. (ii) Assume (a) So is closed under , (b) Si and S2 are meet-compact, (c) P, a, and T are monotonic. Then, for every x € Bo, /3(
{P(a(a),r(a))
: x < a € So} C {/3(6) : {5(x),?(x))
< b £ Si x S2}
since this inclusion implies
p(B(x),?(x))=
^
/W)^ II 3 P(*(a),T(a))=j(x).
(9(x),?(x))
x
Assume x < a € So- Then a (x) < a (a) < a (a) and f(x) < f(o) < r (o) by Th. 221, so ( O - ( O ) , T ( O ) } € {b: {a(x),?{x))
< b € Si x S 2 } ,
hence P(a (a), r (a)) € {P(b) : < 6 £ Si x S 2 }. Proof of (ii): It suffices to show that, for every x £ Bo, every member of {P(b) : {a (x) ,T (x)} < b £ Si x S2} is greater than or equal to a member of {P(cr (a) , T (a)) : x < a € So} since this implies
P(a(x),f(x)) =
f]3 (9(x),T(x))
M)^ IT3 /3(«r(a),r(a))=7(x). x
Consider an arbitrary element of the first set, say /3(6i, 62), where
{a(x),?{x)) = / n ' ff(°)> I I 1 r(a)\ < (61,62) £ Si xS 2 . Note that {cr (a) : x < a G So} and {T (a) : x < a € So} are subsets of Si. By compactness of Si, there is a finite subset of {a (a) : x < a £ So} whose meet is included in 61, so there is a finite subset Fi of {a : x < a £ So} such that
20. EXTENDING OPERATORS WITHIN A BA
n 1 cr*(Fi) < 61. Let a = H° Fi. Then x < a since Fi C {o : x < a G So}, and, since So is closed under , we also have ci 6 So- Since a is monotonic, it follows that a (ci) = a (Y[ Fi) < Y[ °"*(-Fi) < &i- Similarly, there is some C2 G So such that T (c2) < b2, so (a (a), T (C2)> < {bi,b2), hence /3(
x>aES0
^(( C T ( a i) i r ( a i ) ) H
E
\- {cr{am) ,T(am)))
x>ai ,...,am £5o
since J3 is completely m-additive
since fi and /5 agree on S\ x 52, 5i x 52 is closed under + x>a£S0
since fi, a, and r are monotonic, Si x S2 is closed under + = 7(x). D 20. Extending operators writhin a BA Let 23O G BA. Assume that Q3o is complete. Assume 0 ^ So C Bo. Let (5.64)
C := {[[X : X C So} = H* Sb (So)
be the set of closed elements. All elements of So are closed (for if x € So then x = \[{x} and {x} C So). Let (5.65)
O:
be the set of open elements. All elements of So are open. Since they are also closed, they are clopen. Note that meets (in ©0 x Q3o) of subsets of So x So are elements of C x C, for if X C So x So, then Do (X), Ra (X) C So, hence n ° x ° X = ( n Do (X), n Ra (X)) e C x C, where n° X ° denotes meet in 23O x 23O. Therefore C xC = {[[0X0 X : X C So x So},
284
5. BOOLEAN ALGEBRAS
and, for similar reasons, OxO
= { ^ 0 X 0 X : X C So x So}.
Suppose that we have a binary operator on So, namely ft : So x So —> So, and a unary one, namely a : So —> So, and thus an algebra of Boolean type, namely {So, ft,0"). Extend a and /3 to open and closed elements (only, and not to all of Bo) as follows. For all closed x, y € C, let
(5.66)
a[x):=
\[ a (a),
ft{x,y)
:=
x
\[
0(o),
{z,y)
and, for all o p e n x,y 6 O, let (5.67)
a (x) := y^ a (a),
ft(x,y)
:=
^^
/?(a)-
Another way to say this is that
Y[
a(a) :x € C ) ,
x
ft:=(
f]
ft(a,b):{x,y)€CxC),
\{x,y)<{a,b)eSoxSo
x>aeS0
E
ft(a,b):{x,y)eOxo\.
So is closed under a, so the cr-image of a subset of So is a subset of So, hence the meet of the cr-image of a subset of So is closed. This shows that C is closed under a. Similarly, C is closed under ft, and O is closed under both a and ft. Therefore d-.C^C,
/3:CxC^C,
a-.O^-O,
ft.OxO^fO.
In this situation there are three algebras of Boolean type, namely (So,ft,(r), (C,ft,a} and (O,ft,a'). Thus ft and a generate a clone on So, ft and a generate a clone on C, and ft and a generate a clone on O. The next theorem is stated for Boolean algebras with a single binary and a single unary operation (with a distinguished element of So thrown in), but it holds for any number of operations of any (finite) rank. The first two parts follow from the earlier theorem that the operators and their extensions agree on SoTheorem 224. Assume Q30 G BA, «B0 is complete, 0 ^ So C Bo, ft : So x So —> So, ft is monotonic, a : So —> So, a is monotonic, and i E So- Define O, C, a, ft, a, and ft as m (5.64), (5.65), (5.66), and (5.67). (i) {So,ft,
21. PRESERVATION THEOREMS FOR COMPLETE EXTENSIONS
285
(ii) (So,/?,
vf = Pi n An+1
vf = P2 n An+1
(«(«i)) a = (Pi n An+1)\a
= Pi n cn+1
vi = P 2 n cn+1
(u(v!)f = (Pi n cn+1)\d
vf
so, by Th. 222 and Th. 223,
= = = =
((((Pi n A n+1 )|a)|p- 1 n (p2 n ^ n+1 )|Q (((Pi n A n + I )i5)|p- 1 n (P2 n An+1)iQ-1)|/3 (((Pi n cn+1)\a)\p-1 n (P2 n c n+1 )|Q- 1 )|/3 (b(u(v1),v2)f
Suppose an equation (to,*i) is valid in 21, where to,ti £ Fn, i.e., a t a = tf- Then (io,ii) is valid in C, since D
21. Preservation theorems for complete extensions Regarding the next two theorems see Monk [181, 1.9, 1.10], Givant-Venema [79, Cor. 31], Henkin-Monk-Tarski [93, Rem. 2.7.22]. Theorem 225. Assume 21, 25 € BA, 25 is a completion of 21, 0 : A2 -> A, a : A —> A, and I £ J 4 . Define O, a, and $ as in (5.65) and (5.67) with So = A. Then O = B and
286
5. BOOLEAN ALGEBRAS
(i) if (3 and a are monotonic, then (A,/3,a,t.) is a subalgebra of (B,(3,(T,L), (ii) if /3 and a are completely LJ- additive, then any equation which is valid in (A, (3, a, L) is also valid in (B, j3, a, t). Suppose that (^4, + ,~) is a Boolean algebra and 21 = {A, +,~,/3, a, ) is an We call such an algebra algebra of some type, where (3 : A2 —> A, a : A —> A, a Boolean algebra with operators (3, a, Note that we put no requirements on the operators. In particular, they need not be additive. Much of the literature differs in this respect from the convention adopted here. The algebra 231(21) := (A, +,~) is called the Boolean part or Boolean reduct of 21. Some terminology that applies to Boolean algebras will be extended to Boolean algebras with operators with the understanding that the terms apply to the Boolean part. Examples include atom, atomic, complete, and dense subset. Examples of notions for which we do not follow this custom are completion and perfect extension. The latter concepts apply to Boolean algebra with operators, but in those cases their meanings are supplemented with conditions that must be satisfied by the operators. Suppose that 23 = {B,+,~,j,T, ) is a Boolean algebra with operators and that 93 is similar to 21. We say that 23 is a completion of 21 if the Boolean algebra 231(23) is a (Boolean) completion of 931(21) and the operators of 23 are the upward extensions (taking So = A C B) of the corresponding operators of 21: 7 = /?,
T
= a,
Theorem 226 (Monk [181, 1.9], Givant-Venema [79, 31(i)]). 7/21 <= BA is a Boolean algebra with completely u-additive operators then 21 has a completion 21. Every equation that is valid in 21 and involves completely u-additive operators is valid in 21. For examples of non-preservation, see Givant-Venema [79, §4]. Theorem 227. Assume 21, 23 £ BA, 23 is a perfect extension of 21, /3 : A2 — A, a : A —> A, and i, £ A. Define C, a, and (3 as in (5.64) and (5.66) with So = A. Then At*B C C, and (i) if j3 and a are monotonic, then (A,/3,cr,i) is a subalgebra of (C,J3,a,LJ, (ii) if ft and a are monotonic, then any equation which is valid in {A,/3, a, i) is also valid in (C,t3,a,bj. Define O, j3 and a as in (5.65) and (5.67) with So = C, replacing j3 and a with (3 and a. Then B = O and (iii) (C,J3,(r,i) is a subalgebra of (B,j3,ct,i), (iv) (Jonsson-Tarski [118, Lem. 2.4], Henkin [91, Lem. 2.14], Jonsson [116, Lem. 2.2]) if 0 < m £ u, a is m-additive, Hm is the set of elements of height m, and x £ C, then
(v) if P and a are co-additive, then fi and a are completely co-additive,
21, PRESERVATION THEOREMS FOR COMPLETE EXTENSIONS
287
(vi) if (3 and a are completely u -additive, then any equation which is valid in (A, /3, a, i) is also valid in (B, J3,CT,I) . P R O O F . TWO key properties of 58 as a perfect extension of St are that (vii) if X C A and £ B X = 1, then Yf Y = 1 for some finite subset Y CX, (viii) if 0 ^ b, b' G At%$ then there is some a £ i such that b < a and b' a = 0.
It follows from (viii) implies that the atoms of 58 are closed, that is, At*8 C C = {JJX : X C A}, and (vii), the compactness of 1, implies both the joincompactness and meet-compactness of A. Indeed, if Yf6 X > a € A far some X C A and a G A, then ^ B (JfU{S}) > a + a = 1, so by (vii) we have jf* Y = 1 for some finite subset Y C XU{5}, hence 53 (^ ""{<*}) ^ & a n ( i ^ ~{5} is a finite subset of X. If the operators j3,a are monotonic, then by Th. 224(i), {A,fl, a, t) is a subalgebra of (C,f3,a,i), and, by Th. 224(iii), every equation that valid in (A, /3, a, i) is also valid in {C, /3, a, i). Every element of OS is the join of atoms of 58, all of which are in C, so B = O. By Th. 221(i), /3 and ff are monotonic, so (C,0,ff,i) is a subalgebra of (B,P,&,i) by Th.224(ii). Assume 0 < m 6 w, a is ro-additive, Hm is the set of elements of height m, and x G C. We show next that
Prom just the monotonicity of a we get one inclusion, namely
Since ?8 is atomic it suffices to show that every atom of © below cr (x) is also below the join on right hand side. So assume p € At%$ and p < <x (a;). Let 0" = {a ; a: < a 6 A} and F = {a : o e A, p < f f (a)}. Note that U CV C.A and E7 is a filter, although V need not be closed under . Choose a filter W C A that is maximal with respect to the property that U CW CV, and let w = ]J W. We will show that x > w g i? ra and p < a (w). Since a; is closed, x = ]J U, so from U C W, we get z = Y[U ">JJW = w. For every a e A such that tw = f[W < a there is, by the meet-compactness of A, a finite subset E C W such that [ J E < o , so that if e = Y\E then e < a, and e € W since W is closed under , hence also a (e) < a (a) by the monotonicity of a. Therefore,
What remains is to show that w has height m. Suppose w contains m + 1 distinct atoms of 35. Then it can be shown, using (iv), that there is a set Z of m + 1 pairwise disjoint elements of A with J^ Z = 1 and w z ^ 0 for every z € Z, For every z € Z, we have I £ A, and ~z $ W, for if z € W, then 7 > n W = w, so0 = 2 - 2 > 2 : - w . By the maximality of W, there is some yt G W such that 0 = p a {ys 1). Let y = Ylsez
yB £ W, so that 0 = p a (y). For every z G Z
5. BOOLEAN ALGEBRAS
we have 0 = p a (y ^2{Z ~{z})) since y "^{Z ~{«}) < yz ~z- But then, by the m-additivity of a, we have zez so there is some z €. Z such that p < a (y ^2{Z ~{z})), a contradiction. Thus w G Hm- It follows from (iv) that, for every b G B, b x w
v( )= Yl °( )= Y b>x£C
b>x>w£Hm
${w)= Y °( )' b>weHm
and so a is completely m-additive by Th. 221(x). If j3 and a are w-additive, then J3 and a completely w-additive and agree with /3 and a on C, so, by Th. 224(v), any equation valid in (A, /3, a, i) is also valid in {B, J3, IT, t). D Suppose that (^4,+,~) is a Boolean algebra and 21 = {A, +,~, (3, a, is an algebra of some type, where j3 : A2 —¥ A, a : A —> A, , and 25 = {B, +,~,7,r, ) is another Boolean algebra with operators that is similar to 21. We say that 03 is a perfect extension of 21 if the Boolean algebra 031(03) is a (Boolean) perfect extension of 231(21) (see p. 273 and p. 274) and the operators of 23 are obtained from those of 21 in the manner described in Th. 227, that is, 7 = /3, T = a, etc. Citations for the following theorem are Jonsson-Tarski [118, 2.15, 2.18], Henkin [91, 3.8], Jonsson [116, 3.11] Theorem 228. // 21 is a Boolean algebra with ui-additive operators then 21 has a perfect extension. Every equation that is valid in 21 and involves Lv-additive operators is valid in every perfect extension o/2t. Jonsson [116, Ex.3] mentions that a (x) =x => K = 0 is not preserved in the passage from an algebra to a complete extension of that algebra. A similar example x=0 Vx=l Vx=V. This is true in the from Kramer-Maddux [124] is x;x < x finite-cofinite subuniverse of the complex algebra of a countable Abelian group, but fails in every complete extension. See also Jonsson [116, Ex. 2].
CHAPTER 6
Relation algebras 0.1. Equational axioms Ri Rio. We say that 21 is a relation algebra if 21 is an algebra of relational type, i.e., there are sets + , " , ; , " , ! ' € V such that 21 = {A,+,-,;,",V),
+:A*-->
1' e A ,
; : A
2
A,
: A -> A,
--> A,
" : A —> A,
and for all x, y,z £ A, Ri
R2
R3 R4 Rs Re RT Rg
R9 Rio
x + y = y + x, x + (y + z) = (x + y) + z, x + y + x + y = x, x;(y;z) = {x;y);z, (x + y);z = x;z + y ; z , x;V
=x, X =
X,
(x + yY = x + y, \^',y)
— y\^i
X-gyy + y = y
+- commutativity +-associativity Huntington's axiom ;-associativity ;-distributivity identity law "-involution "-distributivity "-involutive distributivity Tarski/De Morgan axiom
Let RA be the the class of relation algebras. Identities R1-R3, due to Edward V. Huntington [104, 105], assert that the Boolean reduct of 21 is a Boolean algebra, so that 21 is a Boolean algebra with operators. If R1-R3 are valid in 21, then the law of double negation, x = x, is valid in 21. The definition of relative addition and the law of double negation have these three consequences:
Axiom R5 asserts that the operation ; distributes over + from the right, while distributes over + according to Rg. Axioms R4, R6, R7, R9 assert that the relative part of 21 is a monoid with a special unary operation (with no particular name, so far as I know). Axioms R4 and R6 say that {A, ;, 1') is a semigroup in which 1' is a right identity element. With the help of R7 and R9, it can be shown that 1' is also a left identity, so (^4, ;, 1') is actually a monoid. Axiom R6 could be extended to assert that 1' is an identity element. The resulting axiom set would be more symmetrical but also more redundant.
290
6. RELATION ALGEBRAS
Axiom Rio is equivalent to x;x;y < y, since < is defined so that x < y <S> x + y = y. Rio is also equivalent to x;xjy y = 0, but proving this requires the help of R1-R3. Rio is the link between the Boolean and relative parts of 21. As we shall see, it follows from R1-R3, R7, Rg, that J is an additive operator on the Boolean part (A,+,~), that " is self-dual (x = x), that " is self-conjugate (x y = 0 iff x y = 0), and that """ is, in fact, an isomorphism of the Boolean part onto itself that preserves all joins and meets. 0.2. Duality. Because relation algebras have Boolean algebras as reducts, the principle of duality for Boolean algebras also applies to relation algebras. If (A, +,~) is a Boolean algebra then (A, -,~) is also a Boolean algebra, called the Boolean dual of (^4, + , ~ ) . Every Boolean algebra is isomorphic to its Boolean dual via the map that takes an element to its complement, ~~ : A —> A. All this is due to R1-R3. Adding R7, Rs, Rg, produces another form of duality, called converse duality, from which it follows that an equation involving ; is satisfied iff the corresponding converse dual equation is satisfied. The converse dual equation is obtained from the given equation by replacing terms of the form x\y by y;x. For example, if R5 holds in 21, we conclude that 21 also satisfies x;(y + z) = x;y + x;z (the converse dual of R5), and if R6 holds in 21, then 21 also satisfies V ;x = x (the converse dual of Re). There are in total four duality principles. The last one is Boolean converse duality, which combines Boolean duality with converse duality; see Th. 319. 0.3. Proper relation algebras satisfy axioms R-i— R,io- For the next theorem, recall some definitions from §3.11. The Boolean algebra of subsets of U is m(U):={Sb(U),Uu,-u), the square relation algebra on U is 9te (U) := (Sb (U2) , U C 7 2 , - c / 2 , \V2, - ^ , U1), and the equivalence relation algebra on E is 6b (E) := (Sb (E), UE,-E,
\E,
~1E, Id n E) .
An algebra 21 of relational type is a proper relation algebra if 21 is a subalgebra of an equivalence relation algebra, and 21 is a representable relation algebra if it is isomorphic to a proper relation algebra. RRA is the class of representable relation algebras. The next theorem shows that these names are appropriate. Theorem 229. Every square relation algebra, every equivalence relation algebra, every proper relation algebra, and every representable relation algebra is a relation algebra, that is, (6.1)
Vf/(t/G V => me(U) G RA),
(6.2)
ME{E\E~l =EE V => 6b (E) 6 RA),
(6.3)
RRA C RA.
1. BOOLEAN RELATION ALGEBRAS
291
1. Boolean relation algebras The next theorem shows how every Boolean algebra can be extended to a relation algebra. Theorem 230. Suppose 03 = (B,+,~) e BA is a Boolean algebra with unit element 1. Define a binary operation ; on B and a unary operation " on B by letting x;y = x + y = x y and x = x for all x,y G B, i.e., ; = and " = B1. Then {B, +,~, ;, ", 1) is a Boolean relation algebra whose Boolean part is 03. PROOF. It is easy to check that the equations Ri-Rio and 1 = 1' are all valid i n ( B , + , - ;B\1).
We refer to the Boolean relation algebra (B, + , ~ , , B1, l) obtained from 03 € BA as the Boolean relation algebra of 03. Th. 230 provides a useful testing ground. For example, no equation can be derived from Ri-Rio unless the equation obtained from it by deleting " and replacing ; with and 1' with 1 is valid in all Boolean algebras. An algebra of relational type is Boolean if 1' = 1 (see also p. 294). Boolean relation algebras satisfy the following three identities: x;y = x y, x = x, and 1' = 1. Note that these identities together assert that the underlying relation algebra to which they refer is obtained from its Boolean part by the construction of the previous theorem. Theorem 231. The Boolean relation algebra obtained from 03t(f7) is isomorphic to &b (U1). PROOF.
The Boolean relation algebra obtained from 03[([7) is 21 := (56 (U), \Ju,~u,nu, (56 (U))\U) ,
and &b (U1) = {Sb (U1) ,Uvi,-ui,\ui,
~lv\Ul).
What remains is the (relatively simple) verification that the function (-)1 := (X 1 : X C U) , which sends X to X1 whenever X € 56 (U), is an isomorphism from 21 onto 6b (U1). D Theorem 232. Every Boolean relation algebra is representable. PROOF. Let 21 = (A, ) G RA be Boolean, so 1' = 1. By Th. 218, we know that 03t(2l) is isomorphic to a subalgebra of 23I([/) for some set U G V. The Boolean relation algebra of 03I(f7) is representable by Th. 231, and (as can be easily checked) it has 21 as a subalgebra, so 21 is also representable. For a more direct proof, one which enfolds the ultrafilter construction of a perfect extension, check that the map V
= ({(F, F):xeFe 1
embeds 21 into 6b (([//03) ).
E//21} : x e A)
282
8, RELATION ALGEBRAS
2. Group relation algebras An algebra 0 = (G, o, ~1, e) of group type is called a group if, for all x, y, z 6 G, (x o y) a z = x o (y a z)
o is associative
e o j = a; = 3;oe
e i s a n identity element for o
x~
OI=JOJ~
= e.
For every group (S there is a corresponding relation algebra whose universe is the set of all subsets of G. A subset of a group is called a complex (see Hall [87, p. 10]), so for every algebra © of group type, we let the complex algebra of (5 be the algebra (6.4)
Cm(e5):={S6(G),U,-,;,V}
where (Sh (G), U, ~} = 2$I (G) is the Boolean algebra of all subsets (or complexes) ofG, and, f o r a l l X , y CG, (6.5)
X;Y:={xoy.xeX,yeY},
(6.6)
X := {a;"1 : x € X},
(6.7)
1' := {e}.
We say that 21 is a group relation algebra if 21 is isomorphic to a subalgebra of a complex algebra of some group ©, that is, if Let GRA be the class of group relation algebras: GRA := IS{£m (&) : G is a group}. Parts of the following theorem originate with McKinsey, Jonsson, and Tarski; see J6nsson-Tkrski [119, 5.10-5.12]. Theorem 233. Let (8 = (G, o, ~1,es} be an algebra of group type. (i) The following statements are equivalent, (a) 0 is a group, (b) Cm (0) e RA, (c) £m(0)£*|C!Ke(G). (ii) Every group relation algebra is representable, GRA C RRA. PROOF. For part (i)(c), assume <& is a group, and let Check that tx is an injective homomorphism that embeds €m (&) into £Fte (G). Note that if x G G then a ({x}) is the permutation {{g, g o x) : g £ G} used in the proof of the Cayley representation theorem for groups, which states that every group is isomorphic to a group of permutations. The Cayley representation has a property not required by the notion of representation commonly used in group theory, but which is required by the relation algebraic setting, namely, that the permutations associated with {a;} and {y} must be disjoint (as sets) whenever i / j / , simply
3, NA, WA, AND SA
293
because {x} n {y} = 0 and this fact must be reflected in any representation. Indeed, if (g, h) € {a;} n {y} t h e n h = go% = goy,
hence x = g~* o h = y,
D
Groups can also be defined as a kind of groupoid, but the axioms are accordingly more complicated. Indeed, one can say that © is a group if (a) 0 = (G,o), (b) o is an associative binary operation on G, and (c) 3eVa;(e a x — x — x o e /\3y(y o x — x o y = e)) for every i £ G , Under this definition, the complex algebra of <3 still has the form and the binary operation ; is defined as above, but the definitions of X and 1' require considerable rewriting, since ~x denotes an operation whose very existence is a nontrivial consequence of (b) and (c). 3. NA, WA, and SA We say that SI is a nonassociative relation algebra if SI is an algebra of relational type in which R1-R3 and R5-R10 hold. Let NA be the class of nonassociative relation algebras. The subclasses WA and SA of NA are obtained by adding special cases of associativity. We say that St is a weakly associative relation algebra if 21 € NA and, for all x 6 A, and that SI is a semiassociative relation algebra if 2t € NA and, for all x 6 A, Let WA be the class of weakly associative relation algebras and let SA be the class of semiassociative relation algebras. Equation (6.8) is the weak associative law, which appeared earlier as equation (0.2). Equation (6.9) is the semiassociative law. It appeared earlier in (0.1) and was formalized in (1.76). The same name was also applied to (the formalization of) one its consequences, namely (BIV'). By Th. 275 below the equation 1;1 = 1 holds in every NA, so we could use simpler equations that are not special cases of associativity to define WA and SA, such as (6.10) (6.11)
((a:-r);l);l = (a:-r);l, (a;;l);l = a;;l.
Furthermore, the equation (a;;l);l > a;;l is valid in NA, so (6.9) could even be replaced by (a;;l);l < x;l. The converse duals of these equations can also be used; see Th. 276. Theorem 234 (Maddux [139, 7(1), 8(1)]). (i) NA, WA, SA, and RA are finitely based equational classes.
(ii) IfK is NA, WA, SA, or RA, then K = \K = SK = HK = PK. (iii) RA C SA C WA C NA.
284
8, RELATION ALGEBRAS
For part (iii), note that (6.8) is a special case of (6.9) and (6.9) is a special case of R4. All the inclusions in part (iii) are proper. McKinsey's algebra (p. 357) is in WA but not in SA. For other algebras in WA~ SA, see Th. 368 and Th. 447. For an algebra in NA that is not in WA see §27. For algebras in SA that are not in RA see Th. 448. We will define some special properties of algebras that, although most meaningful for nonassociative relation algebras, apply whenever SI = {A,+,~,;, w ,l'} is an arbitrary algebra of relational type. We say that the algebra 21 is trivial if |A| = 1, Boolean if V = 1, commutative if x;y = y;x for all x,y € A, and symmetric if x = x for every x G A. An element x G A is a zero-divisor if x ^ 0 there exists some y € A such that y ^ 0 and x;y = 0. The algebra St is integral if it is nontrivial and has no zero-divisors. None of these properties follows from the axioms R1-R10, as shown in the following theorem. Theorem 235. (i) 9te (0) and 9te (1) ore Boolean, symmetric, commutative, and have no zero-divisors. (ii) JRe (0) is trivial and not integral. (iii) 9te (1) is nontrivial and integral. (iv) If U E V is a set with two or more elements, then 9te (U) is nontrivial, not Boolean, not symmetric, not commutative, and not integral, and 9te (17) has zero-divisors. The next theorem summarizes what can be said with equations in !Ee (17) about the cardinality of the underlying set U. Theorem 236. Let U e V be a set.
(i) \U\ = 0 iffme(U) \= 0 = 1 iffme(U) |= 0 = 1'. (ii) jj/j < 1 iff^t{U) |= 0 = 0' iff^t{U) \= V = 1. (iii) |J7| < 2 iff «e(Z7) |= 1' = 0';0\ (iv) \U\ < 3 iffme(U) \= 0 = 0' 0 ! ;0\
4. Special kinds of elements Here we define many different kinds elements in an algebra of relational type. Some of the definitions are simply algebraic translations of standard set-theoretical definitions. For an extensive study of various kinds of elements in relation algebras see Chin-Tarski [49]. Let us consider a fixed but arbitrary algebra of relational type 21 = (A, +,~,",, ", 1!), and an arbitrary element x 6 A. 4.1. Domain, range, ideal, square, rectangular. (6.12)
Dm% := {x : x; 1 = x G A},
(6.13)
RnVL:={x:l;x =
(6.14)
x€A},
l e a := {a; : x;l = l;x = x€A}
= DmSin RnSi.
- x is a domain element or right-ideal element if a; € Dm 21, - x is a range element or left-ideal element if x € i?«2l, - x is an ideal element if % £ leSl,
4. SPECIAL KINDS OP ELEMENTS
298
- x is a square if x = x; 1;ai, - x is a rectangle if a; = x;l]x. The domain and range elements of 3te (U) are the relations of the form X x U and U x X, respectively, where X C U, Domain and range elements in 9te (U) are thus entirely determined by their domains and ranges, and provide two (out of many) algebraic ways to refer to sets via relations. The only ideal elements of 9te(?7) are 0 and f7a. For every equivalence relation E, the ideal elements of &b (E) are the unions of direct squares of equivalence classes of E; l£le&b(E) o I = E\I\E O / =
(6.15)
\J
(x/E)2.
The squares of 9U (U) are relations of the form X x X with X C U, and the rectangles of JRe (U) are relations of the form X x Y with X, Y C U. See Jonsson [114] and Givant [76] for extensive studies of squares and rectangles. 4.2. Reflexive, symmetric, transitive, equivalence. Rf%:={x:x;(V
x) = (V x)\x = x € A},
%Sl := {a; : x < x £ A}, Tr%:= {x : x;x < x € A}, -
m is x is x is a; is x is x is
reflexive if x £ ii/Sl, symmetric if a; € SrSt, antisymmetric if x x < 1', symmetric-reflexive if x £ SrSl, transitive if a; € TVSt, an equivalence element if x £
R is a reflexive, symmetric, transitive, or equivalence element of fUe (U) iff R C V2 and H is a reflexive, symmetric, transitive, or equivalence relation, respectively. In case SI is a relation algebra, we could use an alternative definition of Tarski-Givant [225, p. 110], that x is reflexive iff 1' (x;l + l;x) < x. 4.3. Functional, permutational, difunctional. Fn3l:={x:x-(x}V) Pm% :={x:x-
= x £ A}, 1
(^f ') = x (V }x) = x e A},
- x is functional if a; 6 -FnSt, - x is permutational or bifunctional if a; € Pm%, - x is difunctional if x = x;x;x. R is a functional element of !He (U) iff R : X —¥ U for some X C.U. For nonassociative relation algebras, an alternative definition of functional element is that x £ i*Vi2l iff x;x < 1', and x is permutational if both a; and x are functional. Regarding difunctional elements, see the remarks after Th. 299.
296
6. RELATION ALGEBRAS
4.4. Atoms, subidentity. Atoms are defined for an algebra of relational type in the same way as for their Boolean reducts; see (5.27). (6.16) (6.17) (6.18)
Am : = { i : 8 / i e 4 , Vj,(y £ A => x
x-y = 0)},
: V >x £ AM},
Ato,%:={x:O'>x
- x is a subidentity element if x < V, - a; is an atom if a; € At%L, - a; is an identity atom if x < 1' and x £ - x is a diversity atom if a; < 0' and x £ At 21. When the Boolean part of 21 is a Boolean algebra, the domain xA and range a;r of an element (see (3.5)) are examples of subidentity elements, and if 21 is also Boolean, then all its elements are subidentity elements. 4.5. Singletons, points, pairs, twins. Sn%l : = {x : 0 / a ; £ A, a;;l;a; + a;;l;s; < 1'}, Pt2l := {x : 0 / x £ A, x;l;x < 1'}, Pr2l:= { i : 0 / s £ A , i ; 0 ' ; i ; ( l ' ; i ; < r } , TwVL := {x : x £ Pr% x y = 0 for every y £ Pt2l}. - x is a s i n g l e t o n i f O ^ a ; ; l ; a ; + a : ; l ; a ; < 1', - x is a point if 0 7^ a;; 1; x < 1', - x is a pair if 0 / a;; 0'; a;; 0'; x < V, - x is a twin if a; is a pair and x y = 0 for every point y. Some relations contain exactly one ordered pair. Such a relation is a set-theoretical singleton, having the form {(a,b)} for some a, 6 £ V. A relation is a singleton in IHe (U) iff it is a set-theoretical singleton and included in U2. A relation R in D\c (U) is a point iff R = {{a, a)} for some a £ U. A relation R in D\c(U) is a pair iff R = {(a, a), (6,6}} for some a,b £U (possibly with a = b). SHe (U) has no twins, but if we suppose that 21 is a subalgebra of SHe (U) and that R is a relation in 21, then R is a twin of 21 iff R = {{a, a), {b, b)} for distinct a, 6 £ U, and neither {(a, a)} nor {(6,6}} are elements of 21. Thus a and b are "twins" in the sense that they cannot be distinguished by 21. Let E £ V be a nonempty equivalence relation. Recall from (3.102) that PE = {p:PCE = E\p\E, p\E\p C Id}. In case E = U2, we have PE = Pt%. If E has at least two equivalence classes, then PE C Pt2l. 5. Axioms R7, Rs In this and the next several sections we deduce consequences of various combinations of axioms drawn from R1-R3, R5-R10 (the axioms for NA). In each theorem our tacit assumptions are that we are dealing with a fixed but arbitrary algebra 21 of relational type and x, y, and z are arbitrary elements of 21. For each theorem we assume that 21 satisfies one or more of the axioms R1-R10 and list those assumptions in parentheses at the beginning of the theorem. Each section
5. AXIOMS R 7 , R g
297
is devoted to some combination of axioms from R5-R10. First we consider what can be deduced from the chosen axiom or combination alone, and then what can be proved by also assuming R1-R3. In this section we show that an additive involutive function from a Boolean algebra to itself is nionotonic, self-conjugate, normal, dual-normal, self-dual, subtractive, completely and universally additive and multiplicative, and is a complete isomorphism of the Boolean algebra onto itself. We do this by proving consequences of R7, which states that " is involutive, and R8, which states that " is additive. Consequences of R7 alone are that conversion is one-to-one and onto, and the domain and range functions behave properly with respect to conversion. Theorem 237. (R7) x = y iff x = y. PROOF. If x = y then x = y. For the opposite direction, assume x = y. Then x = y, but x = x and y = y by R7, so x = y.
For the next theorem recall definition (3.5). Theorem 238. (R7) xd = xr and x' = xd. PROOF. xd = 1'
x;x = 1'
x;x = x' and x' = V
x;x = V
x;x = xd.
In the next theorem we show (again) that an additive operator is nionotonic. Theorem 239. (R8) (i) If x < y then x < y. (ii) If x € Sy% then x € Sy%. PROOF.
For part (i), x < y <S> x =>
<=> X
«
definition of <
y 5 + 2/)" = y + y =y
Rs
definition of <
(a
X
For part (ii), x 6 SySl <=>
X < X
definition of <
X+ X = X (~.
1 ™
" =
X+ X = X
<=> X
< X
x
R8
definition of <
x e Si1% D Theorem 240 (Chin-Tarski [49, 1.8]). (R7, R8) x < y iff x < y.
38
6. RELATION ALGEBRAS
PROOF.
x
=> x
Th. 239
=> I < §
Th. 239
>x
R,7
D Theorem 241. (R7, Rg) x < y iff x
Substitute x for x in Th. 240 and use R7.
The next two theorems show that " is normal and that the Boolean dual of is also normal. Theorem 242 (Chin-Tarski [49, 1.6]). (R1-R3, R7, R8) 0 = 0 G Sy%. PROOF.
0 = 0+ 0
R1-R3
= 6+ 6
R7
= (0 + 0)"
R8
= 6 = 0
R1-R3 R7 D
Theorem 243 (Chin-Tarski [49, 1.7]). (R1-R3, R7, R8) 1 = 1 G Sy2L. PROOF.
1 = 1+ 1 = 1+ 1 = (1 + 1)" = 1
R1-R3 R7 Rs Ri—R3 D
Next is the Boolean dual of the assertion that " is self-conjugate. Theorem 244. (R1-R3, R7, Rg) x + y = 1 iffx + y = l. PROOF.
If x + y = 1, then x + y = x + ij = (x + y)" =1 = 1
R7 R8 x+y=1 Th. 243
5. AXIOMS R 7 , R 8
299
From (5.17), Th. 179, and Th. 244, we get the following corollary. Theorem 245. (R1-R3, R7, Rs) The following statements are equivalent: x
y>x
x+y=y
x+ y=x
x+ y=1
x >y
V< x
x y=y
x-y = x
x y =0
x < 2/
y>x
x+y=y
x+y =x
x+y =1
The previous theorem could include several more statements since, as we see next, complementation and conversion commute. Theorem 246 (Chin-Tarski [49, 1.10]). (R1-R3, R7, Rs) I = t . PROOF.
First note that, for any y, x~
Th. 241 Th. 245
We need only two instances of these equivalences. When y is either x or x, we deduce that x < x and x < x, respectively, hence x = x. It follows from Th. 246 that " is self-dual. The multiplicativity of " is next. Theorem 247 (Chin-Tarski [49, 1.9]). (R1-R3, R7, Rs) (x yY = x y. PROOF.
(3-4)
(x -yY = (x + yY = (x + yY
Th. 246
= §"+1
Rs
= x+y
Th. 246
= x-y
(3.4)
The next theorem shows that conversion is self-conjugate. Theorem 248. (R1-R3, R7, Rs) x y = 0 <£> x y = 0. PROOF.
x y = 0 <^> (x yY = 0
I y=0 > x
y = 0
R7
Th. 242, Th. 247 R7
D By Th. 208(ii), self-conjugate functions on Boolean algebras are completely additive, so " is completely additive when R1-R3, R7, Rs hold. A slightly different proof of this follows.
300
6. RELATION ALGEBRAS
T h e o r e m 249 (Chin-Tarski [49, 1.11]). (R1-R3, R7, Rg) The operator " is completely additive. PROOF. Assume X C A and J ^ X exists. We will show that ($^X)" is the least upper bound of {x : x E X } . Since x <^X for every x E X, Th. 239 implies x < ($^X)" for every x G X. Thus (52 X)" is an upper bound. Now let y be any upper bound, i.e., x < y for every x G X. Then Th. 241 implies x < y for every x € X, so y is an upper bound of X, i.e., J ^ X < y. But then (%2X)" < y by Th. 241, so ($^X)" is the feast upper bound. T h e o r e m 250 (Chin-Tarski [49, 1.12]). (R1-R3, R7, Rs) The operator " is completely multiplicative. On the basis of theorems proved so far we can say that is a complete Boolean isomorphism, and that this can be deduced solely from axioms R1-R3, R7, Rg. One consequence of this observation is that " maps atoms to atoms, an observation first made for relation algebras by Jonsson-Tarski [119, 4.3(xii)]. T h e o r e m 251 (Maddux [142, 3.4]). (R1-R3, R7, Rg) If x G AM then x G
AM. PROOF. Let x G AM. Then My(y £ A => y < xV x y = ti) and x ^ 0. Prom the latter we x ^ 0 by Th. 242, while from the former we obtain Vy(y E A => y < x V x y = 0) by Th. 241 and Th. 248. Hence x E AM. D Summarized next axe those properties of symmetric elements that are derivable from R1-R3, R7, and Rg. T h e o r e m 252. (R1-R3, R 7 , Rs) (6.19)
x G Sy%
x = x,
(6.20)
0,lESy%
(6.21)
x + xeSy%
(6.22)
Sy% = Ra({x + x : x £
(6.23)
x E Sy% => x E Sy%
A)),
(6.24)
x € Sy'A- ^ x €
(6.25)
x,y G Sy% ^ x + y G Sy%,
Sy%
(6.26)
x, y E 5j/St => x y E Sty21.
The last four items can be strengthened to the following equations:
(6.27) (6.28)
Sty2l+* Sy%=Sy% Sy**Sy*=Sy%
(6.29)
(Sy*r
(6.30)
5y2l = Sty 21.
= Sy%
6. AXIOM R 5
301
6. Axiom R,5 Axiom R5 says that for every z the function (-); z is additive. It follows that (-); z is also monotonic. The details can be given this way: T h e o r e m 2 5 3 . ( R s ) If x < y then x;z < y;z. PROOF.
x
definition of < R5 definition of <
T h e o r e m 2 5 4 . ( R 5 ) If x,y £ Dm% then x + y € Dm'A. P R O O F . If x = x;l a n d y = y;l t h e n x + y = x;l + y;l = (x + y);l b y R 5 ,
so x + y e Bm%. T h e B o o l e a n d u a l of R 5 a s s e r t s t h a t f is d i s t r i b u t i v e over
from t h e r i g h t .
T h e o r e m 2 5 5 ( C h i n - T a r s k i [ 4 9 , 1.16]). ( R 1 - R 3 , R s ) {x-y)\z
=
{x\z)-
(l/t*)PROOF.
(x
y)]z =x y ; z
definition of f
= (x + y);z
R1-R3
= x;~z-\-y;~z
R5
= 'x;^-y;'z
R1-R3
= (x f z) (y f z)
definition of f
D The next theorem requires, besides the Boolean axioms R1-R3, only R5 for its proof. It therefore leads to a considerable generalization of the modular law for normal subgroups; see Chin-Tarski [49, p. 356,383]. Its corollary, Th. 297 below, requires more axioms for its proof, specifically R7-RioTheorem 256 (Chin-Tarski [49, 2.18]). (R1-R3, R5) If x\z < x andx;z < x then x y;z = (x y);z. PROOF.
(x-y);z < x;z-y;z
Th. 253
<x-y;z
x;z < x, R1-R3
< x- (x-y + x);z
R1-R3, Th. 253
= x (x y ) \ z + x x ; z
R5, R1-R3
= x (x -y);z
~x\z <~x, R 1 - R 3
8, RELATION ALGEBRAS <(x-y);z
Ri^Rs
7. Axioms R7, Kg, R 9 Theorem 257. (R8, Ri0
(i) Ifx e !7Va then x 6 TrVL. (ii) IfxeEgSL then xG Eq%. PROOF.
For part (i), x G Tr% & x; as <x definition of <
=J. x; a; + X = X
=> (x;s
+ xY = x w
= > ( s n ;a;) + x — x
Rs
X + X =X
R9
definition of <
=* as; X < X
Part (ii) follows from the first by Th. 239. Theorem 258. (R7, R8, Rg)
(i) Ifx,y G Sy%. then (x;y G Sy%. O i ; y = y;x). (ii) Every symmetric NA is commutative. PROOF, (i): Suppose x,y e SySi. By (6.19), 1 = x and j / = y. If x;y 6 SySI then, by (6.19) and R9, x;y = (x;y)" = y;a1 = y;x. Conversely, if x\y = y;x, then (*;»)" = »;* = Vix = xWi s o X\V 6 5ySt(ii): If 21 G NA and SI is symmetric, then %2l = A, hence SI is commutative by part (i).
If R7 and Rg hold, then is a complete Boolean automorphism, so the Boolean dual of Rg holds whenever R9 holds. Next is an elementary statement and computational proof of this fact. Theorem 259 (Chin-Tarski [49, 1.18]). (R1-R3, R7-R9) {x^y)" = y^st. PROOF.
(x f yY = (?\y~Y
definition of f
= (x;yY
Th. 246
= y;x
Rg
= f ;i = yfx
Th. 246 definition of f D
Use the previous theorem to show
8. AXIOMS R 5 , R 7 , R 8 , Rg
T h e o r e m 260. (R1-R3, R 7 - R 9 ) I f x , y £
SyVl
303
t h e n ( x ] y £ S y $ i <£> x ] y =
vU)8. Axioms R5, R7, Rg, Rg While axiom R5 says t h a t for every z t h e function (-);z is additive, its converse dual says t h a t z; (-) is additive. The proof of the converse dual of R5 is a specific example of the general method of proving converse duals using of R7-R9. T h e o r e m 261 (Chin-Tarski [49, 1.21]). (R 8 , R7-R9) z;(x + y) = z;x + z;y. PROOF.
z;(x + y) = ((z;(x + y)yy
R7
= {{x + yy-,zy
R9
= ((x + y);Sy
R8
= (x;z + y;zy
R5
= ((z;xy+(z;yyy = ((z;x + z;yyy
Rg R8
= z; x + z; y
R7
Using this we get the monotonicity of z; (-) and the distributivity of f over from the left. Theorem 262 (Chin-Tarski [49, 1.22]). (R8, R7-R9) If
x
< V t h e n z ; x< z ; y .
Theorem 263 (Chin-Tarski [49, 1.16]). (R1-R3, Rs, R7-R9) z\{x-y)
=
(z-\x)-(z-\y).
PROOF.
z\(x
y) = z ; x y
definition of f
= z;(x + y)
R1-R3
= z;x + z;y = ~z;x-~z;y = (z f a;) (z f y)
Th. 261 R1-R3 definition of f
Theorem 264. (RB, R7-R9) (i) / / x,y G i?n21 then x + y £ i?n21.
(ii) PROOF,
Ifx,y ( i ) :I fx = l ; x a n d y = l ; y t h e n x + y = l ; x + l ; y = l ; ( x + y ) b y
Th. 261, so x + y e Rn%.
D
The next two theorems express the monotonicity of ; and f in both variables.
304
8, RELATION ALGEBRAS
Theorem 265. (Ri, Rs, R7-R9) If v < w and x < y, then v;x < w;y. PROOF. Use Th. 253, Th. 262, and the transitivity of <, which follows from Ri alone; see Th. 178. Theorem 266. (Ri-Rs, Rg, R7-R9) If v <w and x < y then v\x < wfy. PROOF. If v < w and x < y then w < v and f < x by Th. 179, so w;y < v;x
by Th. 265, so « ; T < w;f, i.e., v\x <w\y.
D
Prom Th. 265 we get some closure properties of Sy%, Tr% and Theorem 267. (Ri, R s , R T ^ R S )
(i) Ifx e SySl then x;x G SyfU. (ii) //a; e TrSi then x;x € (iii) //a; e BgSt ifeen a;;a; g PROOF, (i): Assume a; < a;. Then a;;a; is symmetric because (x;xY = x;x < x;x by R 9 and Th. 265. (ii): Assume x is transitive. Then x;x is also transitive because from 5c;x < x we get (a;;a;);(a;;a;) < x;x by Th.265. Theorem 268. (Ri^Rs, RB, R T ^ R S )
(i) Ifx,y
(ii) IfXC
e I¥Sl tfeen E y £ TrSL.
Tr%. and ]JX exists then "[{X €
( i i i ) If x,y £ S g S l t f e e n x-y
£ SgSl.
(iv) J / X C Bga and ]JX exists then ]JX £ PROOF, (i): If x;x
< E and j/;y < y then (E j/);(a;
y) < i;a: < x and
(a; y); (a; y) < y ;y < y by Th. 265, so (a; y); (x y) < x y by R1-R3.
D
The meet of two transitive elements is transitive, but the join of two transitive elements may not be transitive. In fact, TV"2l is not in general closed under ~, + , ;, or f- For example, in 9te(3), if x = {(0,0), (1,1)} and y = {{0,0), (0,1), (1, 2), (2,2) , (2,0)} then none of x, x + y, x;y, or x f y is transitive. It is easy to find examples where x,y € Eq% but x + y ^ Eq%. 9. Axioms Re, R7, R.9 Theorem 269 (Ghin-Tarski [49, 1.5]). (Re, RT, Rs)
r = r e Sy% n PROOF.
Note that 1' 6 Tr% by R6. f=f;l'
Re
= f;f'
R7
= f = 1'
Re RT
10. AXIOMS Ra, a 7 , Hg, R 9
308
D The distinguished element 1' is a right identity for ; in any model of Re- The converse dual of Re (that V is a left identity for ;) can be easily derived from Ra itself with the help of RT and Rg. The same is true of many equations. On the other hand, some equations are equivalent to their converse duals. This is true of R4 (the associative law for ;) and Rg. Theorem 270 (Chin-Tarski [49, 1.4]). (Re, R 7 , R9) x = V ;x. PROOF.
V;x = V;x
Th. 269, Rr
= {st;l'T
RQ
= st
Re
= x
Rr
D Theorem 271 (Chin-Tarski [49, 1.17]). (R1-R3, Re, RT, R S )
xfO' = i = 0'fa;P R O O F . Use R i ^ F i s , T h . 2 7 0 , a n d R B t o get asfO' = x;V O'jx= l r - I = i = a;.
= I
= x and D
10. Axioms Re, Rr, Rs, R9 While Re, R7, R9 are enough to show 1' = 1 ! , we need also Rg to do this for Theorem 272. ( Ri^Rs, Rf 5^R9) 0' = 0' e %si. PROOF.
0!
=¥ =f =¥ = 0'
definition of 0! Th. 246 Th. 269 definition of 0'
A further interesting property of the symmetric elements is that they form a subalgebra in any commutative algebra. The proof of this requires Re and Rg as well as Rr and Rg. We need Ra in the proof because any subalgebra of SI must contain V, and Rg is needed to treat closure under relative multiplication. Theorem 273. (R1-R3, Rg-Rg) /f2l is commutative then 5|/2l is the universe of a subalgebra of SI.
306
6. RELATION ALGEBRAS
PROOF. Assume 21 is commutative and x, y £ Sy$l. Then x = x and y = y, so Sy% is closed under + because (x + y)" = x + y = x + j / b y R g , under ~~ because x = x by Th. 246, under " because x = x = x by R7, and under ; because (x;y)" = y;x = y;x = x;y by Hg and commutativity. Finally, 1' E Syll because 1' = 1' by Th. 269. 11. A x i o m s R B , R.6, R7, R-9 Next we show 1;(-) is expanding when R5-R7, Rg hold. For (-);1 we also need Rg; see Th. 277 below. T h e o r e m 274. (R1-R3, R B - R T , R9) x < l;x. PROOF. We have 1' < 1 by R1-R3. Then x = V ;x < l;x by Th. 270 and Th. 253. T h e o r e m 275 (Chin-Tarski [49, 2.6]). (R1-R3, R5-R7, R9) 1;1 = 1 6 Tr%. PROOF. Put x = 1 in Th. 274 and note that 1;1 < 1 by R1-R3. Th. 275 has a corollary mentioned earlier, that if 1 = 1; 1 then (6.8) and (6.9) are equivalent to (6.10) and (6.11), respectively. T h e o r e m 276. Let 21 be an algebra of relational type. (i) 21 £ WA iff'21 £ NA and one of the following equations is valid in 21:
(ii) 2t £ SA iff 21 £ NA and one of the following the equations is valid in 21:
12. A x i o m s R 5 , R 6 , R 7 , R 8 , R 9 By adding Rs we can get the converse dual of Th. 274. T h e o r e m 277 (Chin-Tarski [49, 2.5]). (R1-R3, R5-R9) x < x ; l . PROOF,
X = x;V
< x ; l , by R 6 , 1' < 1, and Th. 262.
T h e o r e m 278. (R1-R3, R B - R 9 ) x < ( l ; x ) ; l , x < l ; ( x ; l ) , ( O f x ) t O < x, and Ot(xfO) < x. PROOF.
By Th. 274 and Th. 277.
13, AXIOM H l o WITH OTHERS
307
Prom these theorems we now know that the functions 1; (-), (-); 1, 1; (-); 1, and 1;((-);1) are expanding whenever R1-R3, R5-R9 hold in an algebra of relational type. This is true, in particular, in every NA, although Rio is not needed to prove it. Prom Rg and Th. 261 we know that these operators are also additive (and therefore monotonic). They will be normal if Rio also holds (see (6.31) below) and idempotent whenever the semiassociative law (6.9) also holds; see Th. 276. Thus, in particular, these functions are topological closure operators in every SA. 13. Axiom Rio with others Next consider the as yet unused Rio in combination with other axioms. Theorem 279 (Chin-Tarski [49, 2.12]). (Ri^Ets, Rio) x;(xjO) = x;aiiT = 0. PROOF. Use Rio with y = l.
D
Theorem 280. (R1-R3, Rio) x;(W-\y) < y. PROOF. x;(x^y)
= x;x~fij <:fi = y.
The converse dual of Rio is obtained with the help of R7-R9. Theorem 281 (Chin-Tarski [49, 1.23]). (Ri^R3, RT^RIO) y~\x\£ < y. PROOF.
f]x;x
= y;x;z
R7 x
R9, (246)
Rio,Th. 239
= y
Th. 246, RT
n These last two theorems correspond to (2.148). See (2.149)^(2.153) for more variations that could be proved here from R1-R3, R7-R10. T h e o r e m 282 (Chin-Tarski [49, 2.12]). (Re, Rio)
x;x<0'.
PROOF.
x;x = x;x;V
Ra
Rio
= 0'
D Theorem 283. (Ri^Rs, RB, RIO) f \x < 0'. PROOF. Substitute x for x in Th. 282 and use R1-R3, namely, x = x. Theorem 284. (R6, R7, Rio) x{i < 0!.
D
308
6. RELATION ALGEBRAS
PROOF.
Substitute x for x in Th. 282 and use R7.
Theorem 285. (R1-R3, Re-Rs, Rio) x;W < 0' andx;x < 0'. PROOF. We have x = x by Th. 246, so the first equation follows from Th. 284, and the second follows from the first since x = x.
The preceding theorems and the following corollary are abstract algebraic versions of the identity laws (2.192)-(2.195) and the diversity laws (2.196)-(2.199); see also Peirce's Th. 21. V
Theorem 286. (R1-R3, Re-Rs, Rio) 1' < tfa;, 1' < xjx, <x\x.
V < a;ft, and
Next we see that ; is normal in both variables, and its Boolean dual f is dual-normal in both arguments. Theorem 287 (Chin-Tarski [49, 2.4]). (R1-R3, R5, R7-R10) (6.31) (6.32)
x;0 = 0,
(6.33)
oe
x-\l
Tr%nEq% 0;x = 0, ljx = 1
(6.34) (6.35) PROOF.
= 1,
(6.31): x;0 < i ; i TT
Th. 265
= i ; i TT < T
Th. 243 Rio
= 0
R1-R3
(6.34): 0;x == 0;x
Th. 242, R7
=0
Rg
=0
Th.6.31 Th. 242
=0
The last theorem of this section uses all the axioms for NA. T h e o r e m 288. (R1-R3, R5-R10) x = 0 iff x;l = 0 iff \\x = 0. PROOF.
By Th. 274, Th. 277, Th. 6.31,
and Th. 6.34.
14, THEOREM K AND THE CYCLE LAW
309
14. Theorem K and the cycle law De Morgan's Theorem K, the cycle law, and the many variations on these results are characteristic and crucial in the theory of NA. They do not require the identity axiom Re. De Morgan stated his Theorem K as a Rule for Changing Places De Morgan [65]. We gave it earlier in (2.147) as a formula in the calculus of relations. Here we quote De Morgan and use current notation in brackets to explain De Morgan's meaning. In what follows, De Morgan uses "))" to mean the same as " < " or " C " . If a compound relation [ x;y ] be contained in [ < ] another relation [ z ], by the nature of the relations and not by casualty of the predicate [ x; y < z ], the same may be said [ that some compound relation is contained in another ] when either component [ x or y ] ia converted [ into x or y, respectively ], and the contrary of the other component [yorx, respectively ] and of the compound [ z ] change places [ yielding x\~z <1~z or "z;y < x, respectively ]. That is if, be Z whatever it may, every L of M of Z be an N of Z, say
LM))N, then L-1n))m, and sM" 1 ))!. If LM))N, then n))lM'
and nM~1))lM'M-1. But an I of every M of an M~ x of Z must be an I of Z: hence nM~^))l. Again, if LM))N, then n))L/ro, whence L~1n))L~1 Lira. But an L-1 of an L of none but ms of Z must be an m of Z; whence L~1n))m. . . . I shall call this result theorem K, in remembrance of the office of that letter in Baroko and Bokardo; it is the theorem on which the formation of what I called opponent syllogisms is founded. De Morgan [66, p. 224] T h e o r e m 289 (De Morgan's Theorem K). (R1-R3, R 5 , Rr-Rio) If x;y < z then %;~z
De Morgan knew that all three formulas are equivalent (see De Morgan [66, pp. 186-187]), so we restate them that way, as was done earlier in (2.147). Theorem 290 (De Morgan's equivalences). (R1-R3, Rg, R7-R10) x;y < z
> x\z < y O ~z;y < x.
P R O O F . We have just proved x;y < z x\z
310
6. RELATION ALGEBRAS
Further substitutions of converses and complements into De Morgan's equivalences, together with transformations of them by Boolean algebraic methods, yield an enormous variety of additional equivalences. Here are three versions of De Morgan's equivalences included by Tarski [225, Th. 11-13] in his course on relation algebras in the early 1970's. The second version occurs already in the 1943 manuscript (see (2.166) and Tarski [227, 8.10]). Theorem 291 (Tarski's equivalences). (R1-R3, R5, R7-R10) (6.36)
x ; y <~z < ^ > x ; z < y
(6.37)
x ; y < z <^> z ; x < y ^
(6.38)
x;y
z = 0 «=> z ; x
<^> z ; y < x
<=$ z ; x < y <=$ y ; z < x < ^ > y ; x < z ,
y;z < x,
y = 0 «=> y ; z
x =0
De Morgan's equivalences do not appear in any of the papers that Peirce published during his lifetime. However, Peirce was well aware of De Morgan's equivalences, for his unpublished papers reveal the following version, taken from Peirce [200, Vol.4, "1879-1884", p. 341]. Theorem 292 (Peirce's equivalences). (R1-R3, R5, R 7 -Ri 0 ) "Hence the rule is that having a formula of the form x;y < z, the three letters may be cyclically advanced one place in the order of writing, those which are carried We from one side of the copula to the other being both negatived and converted. have, then, the following twelve propositions, all equivalent. x\y
y;z~<x~
f;x
~z<x]y
x
y
y;x
~z;y <x
x\~z
~z
x < z]y
y^z^z
There are in all 64 such sets of 12 equivalent
propositions".
Schroder [215, p.242f] presented four of Peirce's 64 sets of equivalent statements. He used the one given above plus the following three others. Theorem 293 (Schroder's equivalences). (R1-R3, R5, R7-R10) (i) The following y;z
statements
are
equivalent:
<x
z;x
x;y <~z
z
y<
z;ij <x
x;z
y;x <~z
z <sfy
y<
(ii) The following
statements
are
y
~z<x\y
y;x~
x^z^y
y<x]z
~z
x;y < z
(iii) The following
x
statements
y < z]~x x
y<~ ~\z
are
~z<x]y ~z
^]y
X <
f; ~z<\y z; X
<\y
Tj<x y;
~Z < X
equivalent: y;x < z
x
X <
equivalent:
^
x
tz ~zt X X
x;y
x; ~z<\y ~z\X
<\y
v<% y; z<x
Schroder went on to point out that each of these sets of 12 can be expanded to a set of 60 equivalent formulas. Each formula in a group of 12 is equivalent to 4 others. For example, the formula x;y < z, the first one in Peirce's list, is also e q u i v a l e n t t o 1 < x ^ y + z , x ; y -~z < 0 , x ; y z = x ; y , a n d x ; y + z = z .
14. THEOREM K AND THE CYCLE LAW
Next is a version of De Morgan's equivalences, called the cycle law, illustrated by an oriented triangle in its six positions. Starting with the formula and its triangle in standard position,
x;y-z
=0
we add to it the other five equivalent formulas along with the corresponding images of the triangle. The six equivalent statements in the cycle law match up with the six positions of the triangle. Theorem 294 (cycle law, Chin-Tarski [49, 2.1]). (R1-R3, Rs, R7-R10) The following
statements
z;x-y
are equivalent:
=0
y;x-z = 0
y;z-x =
Th. 291, Th. 292, Th. 293, and Th. 294 may be proved directly from Th. 290 using R7 and some elementary consequences of R1-R3, such as the law of double negation. We will derive some of their consequences by an alternative route. First we apply Th. 209 to obtain the following result about the functions *;(-), «;(-), {-);%, and (-);T that arise in algebras of relational type. T h e o r e m 295. Let SI be a Boolean algebra with operators of relational type. (i) For every x € A, the following statements are equivalent: (a) The functions x;(-) and %;(-) are conjugates of each other. (b) x;y z = 0 iff x\z y = 0 for ally,z € A. (c) x;(y-x;z)<x;y-z and x;{z-x\y) < x\z -y for all y,z G A. (d) x;0 = 0 and for all y,z € A, x;y z < x;(y x;z), and x;z y < x;(z-x;y). (ii) Furthermore, the following statements are equivalent for every x £ A. (a) The functions (-);x and (-);x are conjugates of each other. (b) y;x z = 0 4*- z;x y = 0 for all y,z € A. (c) (y z;x);x < y;x z and (z -yjx);x < z;x -y for all y,z € A, (d) 0;x = 0 and for all y,z £ A, y;x z < (y z;x);x, and z;x y < (z-y;x);x.
312
6. RELATION ALGEBRAS
Since all parts of Th. 295 hold whenever R1-R3, R5, R7-R10 hold, we obtain the following corollary, in which parts (6.44)-(6.48) are called, collectively, "rotation"; see (2.168)-(2.172). Theorem 296 (rotation, Chin-Tarski [49, 2.3, 2.7]). (R1-R3, Rs, R7-R10) (i)
The functions
x;(-)
and x;(-)
are conjugates
of each
other,
(ii) The functions x;(-) and x;(-) are completely additive, (iii) the functions (-);x and (-);x are conjugates of each other, (iv) the functions (-);x and (-);x are completely additive, and the following
identities
(6.39)
x;(y
x;z) <x ; y
(6.40)
x;{z-~xjy)
(6.41)
x;0 = 0 = 0;x,
(6.42)
(y z ; x ) ; x < y ; x - z ,
(6.43)
(z-y\x);x
hold:
<
~z,
x;z-y,
(6.44)
x\y z
(6.45)
x;z-y < x;(z x;y),
(6.46)
y;x z <{y
z;x);x,
(6.47)
z;x-y<
y;x);x,
(6.48)
x ; y z < ( x - z;y);(y
-x;z),
(6.49)
x ; y - z =x;(y-x;z)
z = {x z ; y ) ; y
<x;(y-x;z),
(z
z = (x z ; y ) ; { y
x;z)
z.
PROOF. From R1-R3, R5, R7-R10 we conclude, by Th. 294 (the cycle law), that conditions (i)(b) and (ii)(b) of Th. 295 hold, so all of the conditions listed in Th. 295 hold. This yields proofs for most of the parts of the theorem. For complete additivity, apply Th. 208. The next theorem was suggested by Jonsson in 1949: see Chin-Tarski [49, p. 356], where it is treated as a corollary of Th. 256. T h e o r e m 297 (Chin-Tarski [49, 2.19]). (R1-R3, R5, R7-R10) If x;z < x and
x;z < x then
x
y;z = (x
y);z.
PROOF.
< x; z-y-z
Th. (i)
<x-
x;z
<(y
y\z x\z)\z
<x
(6.46)
<(y
Th. (i)
— (T
R1-R3
15. SPECIAL ELEMENTS IN NA
313
15. Special elements in NA This section is concerned with some of those basic properties of various special kinds and elements that can be proved to hold in all NA's; the proofs require no form of the associative law for relative multiplication. The last two parts of the next theorem occur in Tarski's course notes as results about relation algebras, but they hold for NA. Theorem 298 (Tarski-Givant [225, p. 60]). Let 21 € NA. Then (6.50) (6..51)
X
(6..52)
X
< y < ^ 1' <x]y = 0 <=> x;y < 0' = 0 <=> x ; y < 0'
X
PROOF.
x;y < 0' < => <=> <=> < <
V <^\y V =0
R1-R3 R1-R3 Th. 294
= 0
y
y x =0 X
R6
R1-R3
Here are some general formulas involving repeated products, first proved by Chin-Tarski [49] for relation algebras. Theorem 299 (Chin-Tarski [49, 2.9]). Let a <E NA. Then x < (x;x);x and x < x;(x;x). PROOF.
x = x; 1' x
R6
<x;(V-x;x)
(6.44)
<x;(x;x)
Th. 265
x = V;x-x <(V
-x;x);x
<(x;x);x
Th. 270 (6.46)
Th. 265.
D Because of Th. 299, in any NA an element x that satisfies the opposite inclusions x > (x;x);x and x > x;(x;x) will also satisfy the equations x = (x;x);x and x = x;(x;x). Such an element is called difunctional (see Riguet [208, 209, 210]). The elements x;x and x;x are always symmetric, by R7, R9, and the reflexivity of < . In any RA, if a: = (x;x);x then these elements are also transitive,
because x = ((x;x);x)" = x;(x;x)" = x;(x;x), hence (6.53)
(x;x);(x;x) = x;{x;{x;x)) = x;x,
314
6. RELATION ALGEBRAS
(6.54)
(x;x);(x;x)
= (x;(x;x));x
= x;x.
T h u s x;x a n d x;x are equivalence elements. It seems likely t h a t (6.53) a n d (6.54), which use associativity, fail in some SA. T h e o r e m 300 (Chin-Tarski [49, 2.10]). L e i S l e N A . Then x-y-z and x y z < x;(y;z). PROOF. (x;y);z.
B yT h . 2 9 9 a n d T h . 2 6 5 , x
y z < ((x y z);(x
y
<
(x;y);z
z)") ; ( x - y - z ) <
There are 14 versions for each part of the next theorem, depending on how parentheses are added. They all have proofs similar to the proofs of Th. 299 and Th. 300. Theorem 301. Let 2( 6 NA. Then (6.55)
x <
(6.56)
v w x y z <
x;x;x;x;x,
v;w;x;y;z.
15.1. Subidentity elements. Parts of the following theorem appear in Maddux [147, Lem. 5] and many other papers. Theorem 302. Let 21 £ NA and assume u.v
Then
u = «,
v = u;v,
V,
(6.59)
u \x
(6.60)
X ;u
(6.61)
u x = u u;x ;u = u
(6.62)
u ;(u;x) = u;]
(6.63)
X
(6.64)
u \x\v = u; (x ;v),
(6.65)
u ;l;v = u;ff;
(6.66)
V, ;x
(6.67)
X
(6.68)
y = y =
u
x
1 ;u
;v,;v, = 1 ; M -
y = u;x
u;y,
x -y; v, = x;u
y;u,
x
v=
u;
u;(x
;u),
: = u;x, x =- xyu, - u
V,
V < u,
;u-V
V, =
;! y =
x
d U
=
r U .
P R O O F . (6.57): We have
u <<. u;u;u
Th. 299 hyp., Th. 265
u.;«;«
=u <1
Th. 270, R 6 Th. 299 RT
hyp ., Th. 240, Th. 265
15. SPECIAL ELEMENTS IN NA
= u
315
Th. 269, Th. 270, R 6
so ii = ii. ( 6 . 5 8 ) : F o r o n e d i r e c t i o n , u v < (u a n d , f o r t h e o t h e r , u;v < V ;v u;V = u (6.59): G e t (6.69)
v); (u v.
u;x = x
«)";(«
v) < u; (V
l')";w =
u;v
M;1
as follows. u;x
hyp., Th. 265 Th. 270
(6.44)
hyp., Th. 240, Th. 265
= u;x
Th. 269, Th. 270
Applying (6.69) several times gives us u;x
y = x
(u;x)
u;l
y = x
(w;y)= (x
u ; y ,
u ; l ) ( u ; l y) = x
u;l
y .
(6.60) is the converse dual of (6.59). (6.61): By Th. 274, Th. 277, and (6.69) we have u
x = u
and, similarly, u x = u
u ; l x
l ; u= u
u ; x l ; u= u
u ; x ; u
u;(x;u).
(6.62): Part of this is (6.69), which we can use to deduce the rest, as follows. u;x
= u;x
1
= u;x
M;1
(6.69)
(6.69)
= u;(u;x)-l = u](u;x) (6.63) is the converse dual of (6.62). (6.64): u ; x ; v = u ; x l;v
converse dual of (6.69)
= u;l-x-\;v
(6.69)
= w;l x;v
converse dual of (6.69)
= u\{x\v) ( 6 . 6 5 ) : U s i n g ( 6 . 5 8 ) i n t h e l a s t s t e p , w e g e t u\\\v u;V);v
= ( w ; 0 ' + u);v
= u;0'
( 6 . 6 6 ) : B y ( 6 . 5 9 ) , u;x
;v + u;v V = u;x
= u;0' u;V
( 6 . 6 8 ) : B y ( 3 . 5 ) , ( 6 . 5 7 ) , ( 6 . 5 8 ) , a n d u<
= M ; ( 0 ' + V);v
;v + u
< u;V
=
u.
V, u6 = V-u;u
u. T h e o r e m 3 0 3 . Let 21 G N A . ( i ) 2 1 i s B o o l e a n iff x ; y = x
= (M;0'+
v.
Then y f o r allx , y£ A ,
= V-u;u
= V-u-u
= D
316
6. RELATION ALGEBRAS
(ii) if 21 is Boolean then 21 is a symmetric commutative relation algebra. P R O O F , (i): If 21 is Boolean, then 1' = 1, so x;y = x y by (6.58). For the converse, just note that 1 = 1; 1' by R6 and 1 1' = 1' by R1-R3, we get 1 = 1' as a special case of the assumption that x;y = x y for all x,y £ A. (ii): Assume 21 is Boolean. Then ; and are the same operation by part (i). Therefore, 21 is commutative and associative. 21 is symmetric by (6.57). 15.2. D o m a i n and range operators. The domain and range of an element in an NA are defined in (3.5). Theorem 304. Let 21 G NA and x G A.
Then
(6.70)
x66 = x6,
(6.71)
x" = x',
(6.72)
x = x6;x = x;x',
(6.73)
x d= V - x ; l = V - l ; x ,
(6.74)
x '= V - l ; x = V
x;l.
PROOF. (6.70) and (6.71) follow from (6.68) and x6 + x' < V. For (6.72), x = V ; x x < (V x ; x ) ; x = x d ; x < V ; x = x , a n d x = x ; V x < x ; ( V x ; x ) = x ; x ' < x ; V = x. For (6.73), use (6.49) to get V - x ; l = V - x ; ( l - x ; V ) = V - x ; x =
x6.
15.3. Domain, range, and ideal elements. Theorem 305. Let 21 € NA. Then (i) If x € Dm% then x e £>m2l. (ii) IfxeRnVL then x G RnVL. (iii) If x G 7e2l then x G 7e2l. PROOF, (i): If x = x; 1 then 0 = x -x = x;l -x = x;l -x, so 0 = aJ; 1 a; by Th. 294, hence x; 1 < x. We have x < x; 1 by Th. 277. Since 7e2t, 7?n2t, and Dm 21 are closed under ~ and +, they are universes of Boolean algebras that are subalgebras of the Boolean part of 21. In fact, the Boolean algebra of all subsets of U is isomorphic to the Boolean algebra of domain elements of Dlt(U), and it is also isomorphic to the Boolean algebra of range elements of 9te(f7). On the other hand, SHe([/) has exactly two ideal elements whenever \U\ > 1. Recall that x € 7e21 iff x is an ideal element of2tiffa; = l;a; = a;;l. A crucial fact about an ideal element x is that the function x (-) is a homomorphism; see Th. 372. Part of this observation is made in the next theorem. Theorem 306 (Chin-Tarski [49, 3.27,4.1]). Let 21 G NA. (i) 7e2lC SyVl. ( i i ) x e 7 e 2 l iff x y ; z = (x y ) ; ( x
z ) f o r all y , z £ A .
15. SPECIAL ELEMENTS IN NA
317
P R O O F , ( i ) : I f x = x ; l = l ; x t h e n x < x ; x ; x < l ; x ; l = x , so x = x . T h u s every ideal element is symmetric. (ii): Assume x € Je2l. For any y, z €. A we have x
y ; z= x y ; ( z y ; x )
(6.49)
<x-y;(z-l;x)
Th. 265
= x y;(z x) = x
(y
x; (z
x €. 7e2l x)");
(z
x)
(6.49)
<(yx;l);(z-x)
Th. 265
= (y x); (z x)
x £ 7e2t
T h . 265
= £-y;«
a; £ / e 21
For t h e converse, a s s u m e x y;z = (x y); (x z) for all y,z £ A . W e a p p l y t h i s w i t h y = x a n d z = 1, a s follows. x;l
x < (x x ; l ) ; 1 = ((a;- s);(a; 1));1
hyp.
= (0;(x-l));l = 0. This gives us x;l < x. But x < x;l, so x = x;l.
Similarly, x = l;x.
D
15.4. Integral algebras. Jonsson-Tarski [119, 4.17] proved conditions in the next theorem are equivalent for relation algebras, are also equivalent to the condition that every nonzero functional atom. The parts of this result that hold for NA are gathered in the For parts that hold in SA see Th. 353 below.
that the three and that they element is an next theorem.
Theorem 307 (Maddux [144, Th. 2]). Let 21 G NA. (i) 21 is integral iff Q ^ I and x / 0 implies x; 1 = 1 for all x e A. (ii) //2t is integral, then V is an atom of Si. P R O O F , (i): Suppose 21 is integral. By definition, this implies 21 is nontrivial, so 0 / 1. We have x;x;l = 0 by Rio, so i = 0 or a;;l = 0 since 21 is integral. But if x / 0 then x / 0, so we must have x;l = 1. (Similarly, we get l;x = 1 whenever x / 0.) For t h e converse, assume 21 is nontrivial and x;l = 1 whenever x / 0. To show t h a t 21 has no zero-divisors, we assume x / 0 / y and show t h a t x;y / 0, We get x # 0 from a; / 0, so x; 1 = 1 by assumption. Hence 0 / J / = 1-J/ = £ ; 1 - J / , so 0 / x; y by t h e cycle law. (ii): To prove t h e contrapositive of (ii), we suppose 1' is not an atom and show t h a t 21 is not integral. If 1' = 0 then l = l ; l ' = l ; 0 = 0, hence 21 is trivial and therefore not integral. We may therefore assume 1' / 0. Then, since 1' is not an atom, there are x,y €. A such t h a t 0 = x -y, 0 ^ x, 0 ^ y, and x + y = V. B u t x;y = x y by (6.58), so x;y = 0. Thus 21 has zero-divisors a n d is therefore not integral.
318
6. RELATION ALGEBRAS
McKinsey's algebra (p. 357) is a nontrivial WA with zero-divisors in which 1' is an atom, so the converse of the second part can fail. 15.5. Equivalence elements. The Chin-Tarski characterization of equivalence elements in RA, which generalizes Th. 24, can be further generalized to NA. Theorem 308 (Chin-Tarski [49, 3.2,3.3]). Let 21 E NA. Then the following statements are equivalent: (i) (ii) (iii) (iv) (v) (vi) (vii)
xGEqVL, x;x < x < x, x;x = x = x, x;x = x, x;x = x, x ; x < x and x ; x < x , x ; x < x and x ; x < x .
PROOF. For the equivalence of the last two statements, x ; x < x a n dx ; x< x <S>
x ; x x = 0 a n dx ; x x = 0
<S>
x ; x x = 0 a n d x ;x x = 0
<S>
x ; x< x a n dx ; x< x
Others parts can be proved by imitating t h e proof of Th. 24. The following theorem implies t h a t equation 0';0';(0';0') = 0';0' holds in every NA. However, t h e related equation 0';0';0';0' = 0';0' fails in some NA. In fact, it fails in some WA but holds in every SA; see Th. 356. T h e o r e m 309 (Maddux [143, 14(1)]). / / 2 t 6 NA then 0';0' e EqVL. P R O O F . Since (0';0')" = 0';0' = O';O\ we need only show (0';0');(0';0') < 0';0'. (0';0');(0';0') = ( 0 ' ; 0 ' - ( r + 0 ' ) ) ; ( 0 ' ; 0 ' ( r + 0 ' ) ) = (0' ;0' 1'); (0' ;0' 1') + (0' ;0' 0'); (0' ;0' 1') + (0';0' - r ) ; ( 0 ' ; 0 ' 0') + (0';0 ! - 0 ' ) ; ( 0 ' ; 0 ' - 0 ' ) < l ' ; ( 0 ' ; 0 ' ) + ( 0 ' ; 0 ' ) ; r + 1';(0';0') + 0';0'
D 15.6. Points, pairs, and twins. The most interesting properties of points, pairs, and twins can be proved only for SA and RA, but some basic facts can already be established to hold in every NA.
16. CHARACTERIZATIONS OF NA AND RA
319
T h e o r e m 310. Let 21 £ NA. Then every point, pair, and twin is a subidentity element. Furthermore, (6.75)
Tu;2lUP£2lCPr2t,
(6.76)
P*2tnTu;2l = 0,
(6.77)
Pi2l C Sto21.
PROOF. If x € P i 21 then x;l;x < V, so x is a subidentity element since x < x;x;x < x;l;x < V. If x € Pr21 then a;;0';x;0';x < 1', so a; = x V + x 0' < 1' + (a;-0');(a;-0')";(a;-0');(a;-0')";(a;-0') < 1' +x;0';x;0';x
(6.55)
< 1' Thus points and pairs are subidentity elements. A twin is just a pair with no points below it, so every twin is also a subidentity element, and we have the trivial inclusion Tiv2l C Pr2l. Suppose x € Pt%. Then a ; ; 0 ' ; a ; < a ; ; l ; a ; < r and, since every point is a subidentity element, a;;0' ;x < 1' ;0' ;1' = 0', so a;;0' ;x = 0. This implies x;0';x;0';x < 0;0';x = 0 < 1', so x E Pr%. Thus every point is pair. If point were also a twin it would be both nonzero and disjoint from itself, so Pt2l n Tw% = 0. Finally, if x € P£2l then x = x since x < V, so x;l;x + x;l;x = x;l;x < V, which shows that x £ Sn21. 16. Characterizations of NA and RA First we present the Chin-Tarski characterization of " in terms of ; and 0', first proved for relation algebras, but also true for NA. T h e o r e m 311 (Chin-Tarski [49, 2.14]). / / 21 € NA and x € A, then x = PROOF. It suffices to show y < x < = > J / ; x < 0 ' , which holds because the following statements are equivalent: y <x y<x y;V
Th. 241 <x
y,x<0'
Re Th. 290
Next we obtain a characterization of NA that is sometimes used as a definition, and a similar characterization of RA due to Chin-Tarski [49]. Parts of the original proof of the Chin-Tarski Theorem have been isolated in the following two theorems. T h e o r e m 312. Let 21 be a Boolean algebra with operators of relational type, and assume (i) x = x;V,
320
6. RELATION ALGEBRAS (ii) x;y
for
all x,y,z
z = 0 iff x;z
y = 0,
6 A. Then the equation x = x is valid in 21.
PROOF. Note that
x
x - y= 0
&
x;V-y
= 0
(i)
<S>
x ; y V = 0
(ii)
x;V-y = 0
(ii)
x y = 0
(i)
x < y Taking y = x yields x < x, a n d t a k i n g y = x yields x < x, so R7 is valid in 2t. T h e o r e m 313. Assume type such that
% is a Boolean
algebra with operators
of
relational
(i) x = x;V, (ii) x;y z = 0 iff x;z y = 0, (iii) x;(y;z) = (x;y);z, for all x,y,z valid in 21.
E A.
Then the equations
V = V, x = V;x, and (x;y)"
= y;x are
PROOF. For the third equation (which is Rg), observe that for every z E A, 0 = (x;y)w
z
0 = (x;yY;V
z
(i)
O= ( x ; y ) ; z - V
(ii)
<*
O= x ; ( y ; z ) - V
(iii)
<S>
0= x ; V y ; z
(ii)
<5
0 = y;z-x
(i)
<=>
0= y ; x z
(ii)
It follows that R9 is valid in 21. By Th.312, R7 is also valid in 21. Therefore, by Th. 269 and Th. 270, the first two equations are also valid in 21. The following characterization of NA differs slightly from the Chin-Tarski characterization of RA; it does not include the associative law for relative multiplication, of course, but does include the (possibly redundant) converse dual of ReTheorem 314. 21 £ NA iff 21 is a Boolean algebra with operators of relational type such that (i) x = V;x, (ii) x = x;V,
16. CHARACTERIZATIONS OP NA AND RA
321
( i i i ) x ; y - z = 0 <=> x \ z y = 0 , ( i v ) x ; y z = 0 <=> z ; y x = 0 , / o r aH x,y,z
E A.
PROOF. Assume 21 € NA. Then R1-R3, R5-R10 hold. We obtain 331(21) € BA from R1-R3, x = V ;x and x = x;V from R 6 , R7, Rg via Th. 270, and the cycle law from R1-R3, R5, R7-R10 via Th. 294. For the converse, assume 21 is a Boolean algebra with operators of relational type satisfying (i)-(iv). Then R1-R3 are valid in 21 since Q3[(2l) £ BA, so we need only show R5-R10. Right relative multiplication has a conjugate by (iv) and is therefore completely additive, so R5 holds. R6 is (ii). For R7, use Th. 312. For Rs, R9, Rio we give derivations. First, we show conversion is self-conjugate. x
y = 0
=>
x;V-y
= 0
(ii)
=>
x;y
V = 0
(iii)
=>
V ;y
x = 0
(iv)
=>
y
x = 0
(i)
Since conversion is self-conjugate, it is completely additive, so Rs is valid in 21. Next we prove Rg. For every z £ A, y;x
z = 0
<=>
y; z
x = 0
(iii)
<=>
x; z
y = 0
(iv)
<=>
x; y z = 0
(iii)
<=>
(x;j/)"-2: = 0
so Rg follows by R 1 - R 3 .
is self-conjugate
Finally, for R i o , we n o t e t h a t x;y
x;x~yy y = 0, hence x;xjy < y.
~xyy = 0, hence
D
Can either one of the first two conditions be deleted from the previous theorem? From this characterization of N A we get the Chin-Tarski characterization of relation algebras. T h e o r e m 315 (Chin-Tarski [49, 2.2]). 21 £ RA iff 21 is a Boolean algebra with operators
of relational
(ii) x\y-
for
z = 0 & x;z-y
(iii)
x;y
(iv)
x;{y;z)
all x,y,z
type such
z = 0 <=> z;y =
that
= 0, x = 0,
(x;y);z.
£ A.
PROOF. From (i), (ii), and (iv) it follows by Th. 312 and Th. 313 that x = V ;x is valid in 21. Therefore 21 £ NA by Th. 314. Since ; is associative by (iv), we conclude that 21 £ RA.
322
6. RELATION ALGEBRAS
A variation on this characterization is obtained by replacing the associative law with an equivalence similar to the others. Theorem 316 (Frias-Maddux [75, Lem. 2.2]). 21 6 RA iff 21 is a Boolean algebra with operators of relational type such that (i) x = x;V, (ii)
for
x ; y z = 0 -O- x ; z y = 0 ,
(iii) x ; y z = 0 <=> z ; y x = 0 , ( i v ) v \ x w ; y = 0 <S> i>;w x ; y = 0 . all x , y , z 6 A .
The next two theorems are additional characterizations of NA. First we observe that one of the equivalences in Th. 314 can be relaxed to an implication. type
T h e o r e m 317. 21 £ NA iff 21 is a Boolean satisfying (i) (ii) (iii) (iv)
algebra with operators
of
relational
x = V ;x, x = x;V, x;y z = 0 <S> x;z y = 0, x;y-z = 0 => 2;g/-a; = O.
P R O O F . It suffices t o prove t h a t z;y x = 0 implies x\y z = 0. By (ii), (iii), a n d T h . 312, y = y. A s s u m e z;y-x = 0. T h e n x;y-z = 0 by (iv), so x;y-z = 0. T h e n e x t characterization is easy t o o b t a i n w i t h t h e help of T h . 295. T h e o r e m 318 ( M a d d u x [139, 1(22)]). 21 6 NA iff 21 is a Boolean with operators of relational type satisfying (i) x = V ;x = x;V, (ii) 0 = 0;x = x;0, (iii)
x ; y z = x;(y
(iv)
x ; y z = (x
x;z) z;y);y
algebra
z, z,
(v) x = x. 17.
Duality for NA
The converse dual of an equation is obtained by replacing every subterm of the form x;yhyy;x. For example, Th. 261 is the dual of RB (left-distributivity of ; over + is dual to right-distributivity). If an equation is valid in a nonassociative relation algebra 21, then so is its dual equation. This is easy to show with the help of R7-R9, as illustrated by the proof of Th. 261. T h e o r e m 319. Assume 21 = {A, +,~, ;,", V) € NA. Define some operators by setting x o y = y/x, x y = y] x, and x~ = x for all x,y E A. three more algebras as follows.
21 : = (A,
, 0'),
a-:=
.
Define
18. COMPLETIONS
Then the algebras 21, 21, 21, and 21" are isomorphic. In fact, the operations ", ~, and ~ are involutions that serve as isomorphisms among these algebras as follows. 21^21
21 ^
21
21 <-^- 2 t
Tarski observed that many laws involving relative operations becomes a correct law for Boolean algebras when f, ;, ", 1', and 0' are replaced by +, , ~, 1, and 0, respectively, and wondered whether there is a characterization of the cases for which this happens. For example, x;x < 0' becomes x x < 0. It would be nice to get a postulate system that reflects this duality and is independent. For more on this connection see Brink [42] and Brink-Gabbay-Ohlbach [43].
18. Completions Suppose that 21 = {A, +,~, ;, ", 1') is a Boolean algebra with operators of relational type, that is, 581(21) = (^4,+,~) is a Boolean algebra, ; is a binary operator and is a unary operator on A. Recall that £ is a completion of 21 if £ is a Boolean algebra with operators similar to 21, the Boolean algebra 5B((<£) is a (Boolean) completion of 58 [(2t), and the operators of C are the "upward" extensions of the corresponding operators of 21, that is, if So and B replace A and C, respectively, in (5.65) and (5.67), then <£ = ^Q3l(<£), },", 1'}, or, in more detail, (6.78)
21 is a subalgebra of £,
(6.79)
C is complete and A is a dense subset of C,
(6.80)
if c , c ' G C t h e n c;c = ^ £ { o ; a ' :c>a£A,
(6.81)
if c G C then c = ^
£
c > a €A } ,
{ o : c > a <E A}.
If £ is a completion of 21, then the density of A in C implies that all joins are preserved and every element of £ is represented as the join of elements of 21 below it, that is, x exists t h e n
(6.82)
i f X C i and J^
(6.83)
for every ceC, c = ^
;
YT
X
= Z ^ X>
{o : c > a € A}.
Theorem 320. Let 21, £ 6 NA. Then € is a completion o/2l iff (i) 21 is a subalgebra of <£, (ii) 931 (C) is a completion of 581 (21), PROOF. If conditions (i) and (ii) hold, then (6.82) and (6.83) hold by the density of A in 21. Then (6.80) and (6.81) follow from (6.83) since C e NA and so ; is completely 2-additive (in fact, ; is completely additive in each variable) and is completely additive. Next is the uniqueness theorem for completions, followed by the existence theorem.
324
6. RELATION ALGEBRAS
Theorem 321. Suppose 21, C, and £' are Boolean algebras with operators. (i) / / C and £' are completions of 21, then € is isomorphic to £' by an isomorphism which leaves 21 fixed. (ii) If € is a completion o/2l and 21 is finite, then € = 21. Theorem 322 (Monk [181]). Suppose 21 is a Boolean algebra with operators of relational type. Then there is an algebra € of relational type such that (i) £ is a completion of 21,
(ii) €e NA iff 21 G NA, (iii) ffeWA iffKeWA, (iv) ceSA iff a eSA, (v) £ e RA iff 21 G RA. PROOF. This theorem follows from Th. 226 and the fact that the equations in Th.318 and the equations (6.8), (6.9), and R4 involve only o;-additive operators.
By Th.322, NA, WA, SA, and RA are closed under completions. Monk [181] asked whether RRA is closed under completions. This long-standing problem of Monk [181] was finally solved by I. Hodkinson. Theorem 323 (Hodkinson [101]). There is an atomic RRA whose completion is not representable. Thus RRA is not closed under completions. For other proofs of this theorem, see Hirsch-Hodkinson [98, 99].
19. Perfect extensions Suppose 21 and ^3 are Boolean algebras with operators of relational type. Recall (from p. 273, p. 274, and p. 288) that
21 is a subalgebra of «P,
(6.85)
?p is complete and atomic,
(6.86)
if X C A and J ^ VJ
(6.87)
x
= 1,
then
Y = 1 for some finite subset Y C X,
if c, c are distinct atoms of ?P, then there is an element a € A such that c < a and c a = 0,
that is, Aty$
:={[[X:X
i fx , y € P t h e n x ; y =
^ ^
(
J J *
x>ceC, y>c'eC c
(6.89)
if x € P then x = J^
( I I ^ ")
x>c£C c
a ; a ) ,
19. PERFECT EXTENSIONS
338
The first four items assert that 051 (^J) is a perfect extension of 051(21.). It follows from Th. 227 that (6.88) and (6.89) can be replaced by (6.90)
if c, c' E Atty then e;c' =
J}
a;a,
e
(6.91)
if c E Atty then c = TT a.
In the next theorem we see that, for nonassociative relation algebras, however, two of these conditions can be omitted. Theorem 324 (Maddux [142, 4.1]). Suppose SI, ^J G NA. Then ^ is a perfect extension of Si iff
(i) ac
c = c\V = c; ^ ^ { e : 1' > e € A«p} = ^ ^ { e j e : 1' > e 6 so c = c;e for some c £ 7a!P, hence, by (6.88), c = c;e = TT { a ; a ' ; c < a 6 A, e < a' € A}, but {«;a' : c < a £ i , e < a' £ A} C {a : c < a E A}, for if c < a G A and e < a' € J4., then c < c;e <. a;a' £ A, so c = J J ^ a i a ' :c
e < a e A} > Y]9{a
:c
The opposite inequality holds trivially, so we have c = Y[^{a
:c
for all atoms c G j4i?p. This last equation is enough to show that (6.87) holds, and it implies (6.91) since is a completely multiplicative operator in ^J 6 NA; c = f J J {a : c < a E -AH" = J^[ {a : c < a E J4J.
Next are the uniqueness and existence theorems for perfect extensions. Theorem 325. Suppose 31, $p, o«d V' ore Boolean algebras with operators. (i) /f ?P and ?P' are perfect extensions of 21, &en ?P »s isomorphic to ?p' &y an isomorphism which leaves 21 fixed. (ii) If ^ is a perfect extension of St and 21 is finite, then ?p = 21. In connection with the following theorem, see the remarks in §6.36 regarding the notation U5i+".
6. RELATION ALGEBRAS
Theorem 326 (Jonsson-Tarski [118, 119]). Suppose 21 is a Boolean algebra with operators of relational type. Then there is an algebra 2l+ of relational type such that (i) 2l+ is a perfect extension of 21, (ii) 21+ G NA p e NA, (iii) 2t+ E WA iff We SNA, (iv) 21+ GSA iffSleSA, (v) 21+ G RA iff 21 G RA. PROOF. This theorem follows from Th. 228 and the fact that the equations in Th. 318 and the equations (6.8), (6.9), and R4 involve only w-additive operators.
By Th.326, NA, WA, SA, and RA are closed under the formation of perfect extensions. Such classes are called canonical. Monk proved that RRA is canonical. This was first reported by McKenzie [165, p.66]. The first published proof is in Maddux [143] (see Th. 419 below). 20. Matrices of elements Let 21 6 NA and assume n is a nonzero ordinal such that if n is infinite then 21 is complete. This assumption avoids the situation in which n > w, 21 is incomplete, and statements of results are complicated with hypotheses on the existence of relevant meets and joins. A function that maps n2 into A is called an n-hy-n matrix of 21, or simply an n-matrix. Let Mn2t be the set of n-matrices of elements of 21, that is, Mn2l = n A = {a :
A}.
An n-by-n matrix of elements of 21 is just a function from n into A, but for such functions we use matrix notation and terminology. For example, if a is an n-by-n matrix of elements of 21 and 1 < n < u, then ooo
Ooi
002
OO.ti- 1
0.10
an
012
fll,n-
1
O20
021
022
O2,n-
1
1-1,0
In—1,1
ttn-1,2
ffln—l.n
Here we make a few remarks on the intuition underlying matrices of elements. For additional remarks, see §7.7. An element of a relation algebra is an abstract algebraic object that corresponds to a binary relation. In fact, if the algebra is proper then its elements really are binary relations. Consider a binary relation R C U2 on a set U E V (so R is an element of the proper relation algebra 9\e ({/)). The statement that two objects x,y G U are related by R can be expanded into a somewhat redundant conjunction of similar statements. Specifically, if we know (x,y) G R then we also know (x,x) G Do(R), (y,y) G Ra(R), and (y,x) G R'1.
20. MATRICES OP ELEMENTS
The four relations that appear in these statements may be assembled into the 2-by-2 matrix
We then regard the matrix a as a relation that holds between the sequence {x, y) and itself, in the sense that (x,y) E R, {x,x} E Do(R), (y,y) E Ra(R), and (y,x) € R~x. More generally, if a G MnUie(U), relation t h a t holds between a n n - a r y sequence (xo,
in c a s e (xi,Xj)
t h e n a represents a b i n a r y xn-\) EnU a n d itself j u s t
E aij for all i,j < n.
Prom matrices a and b in Mn2l we may form new ones, denoted by a, a-b, and a; 6. These matrices represent additional statements that may be deduced from the hypotheses that an n-ary sequence is related to itself by a and also by 6. We say that a is the converse oi a, a-b is the intersection of a and b, and a; b is the relative product of a and 6. These matrices are defined by the following equations, which hold for all i,j < n. (a)ij = (ajiY, (a-b)ij
= dij
bij,
k
The last equation illustrates the assumption that 21 is complete in case n is infinite. Assuming 21 is complete guarantees that the join always exists. To illustrate relative multiplication of matrices, consider a,b E M22I. Then , faoo a;b= |aio
aoil ; [fooo 601 onj
[010
ttio ;6oo i n ;6io
On
an;6n
aio;6oi
For 1-by-l matrices, intersection of matrices and relative multiplication of matrices are the same. Intersection of matrices is commutative and associative, but relative multiplication of matrices is neither commutative nor associative in general. Counterexamples can be found among 2-by-2 matrices of elements of *He (3). For example, if I = 3 1 = {(0, 0), (1,1) , (2, 2)},
[7 {(0,1)}] [
[ / {(0,2)}] [{(1,0), (2,0)} I J'
then
lib-a = b, i.e., bij < a^ for all i,j < n, then we say that a contains 6, and symbolize this by writing 6 < a or a > b. We write 6 < a or a > 6 in case b < a and b / a. The relation < is a partial ordering on Mn$l, in which the greatest lower bound of the two matrices a and b is a-b. An n-by-n matrix a is path-consistent if a < a;a, i.e., aij < aik\akj for all i,j, k < n. A matrix a is
32S
8, RELATION ALGEBRAS
symmetric if a = a. A matrix can be path-consistent without being symmetric. For example, if [ {(0,0), (2,2}} a = [{{1,0}, {3,2}, {1,2}}
{{0,1} ,{2,3), (0,3)}] {{1,1} ,{3,3}} J
then a = a;a but a ^ a. A matrix is closed if it is both path-consistent and symmetric, that is, a = a = a; a. A matrix a satisfies the diagonal condition iff a» < 1' for all i < n, and it satisfies the off-diagonal condition iff ay < 0' whenever i ^ j < n. The largest matrix satisfying the diagonal condition is the identity matrix T 1 1" i r l lk:= . . .1 1 1'. the largest matrix satisfying the off-diagonal condition is 0'
0! 1
0r 0'
0'
0!
1.
and the smallest matrix altogether is the n-by-n zero matrix '0
0
0"
0
0
0
0 0
0
0»:=
A matrix a G MnSl is atomic if every ay is an atom of SI. We say that a matrix a € Mn%l is a basic matrix or atom matrix iff it is closed, atomic, and satisfies the diagonal condition. Let Bn% be the set of n-by-n basic matrices of 21. Thus SB2l is the set of those n-by-n matrices of atoms of SI which satisfy the following conditions for all i, j , k
a»»
(6.93)
ay = etji,
(6.94)
Oik < a>ij\ajk.
The definition of Bn2l appears in Maddux [139, 10(9)] (where it is called Mn2l), [146, Def.2(i)], [148, Def.46], [150, Def.34(i)], and [151, p. 1217]. Basic matrices appear in algebraic topology; see Eilenberg-MacLane [69, §2], where basic matrices form the cells of simplicial complexes over an arbitrary group. A matrix a € MB% satisfies the triangle condition if 0
k
whenever i, j < n. It is easy to show that a matrix in Mn% is basic matrix iff it is atomic and satisfies the triangle condition.
20. MATRICES OF ELEMENTS
329
If a £ Mn2l and TT : m —> n is any function mapping a nonzero ordinal m into n, then an is the matrix in M m 2l defined by aTTjj = a^j^y) for all i, j < m. It is easy to check that air is also a basic matrix, so air € -Bm2l- In particular, a[i,j] and a[«/i] a r e basic matrices, where [i,j] and [i/j] are the functions mapping n to n such that [ljJi\j>—3>
L V J J W ~ J>
[*I J I C " ) = fc if fc / « , i ,
[*/i](fc) = k if k ^ i.
The next theorem contains a few elementary facts about matrices in an arbitrary NA. Theorem 327. Let 21 G NA and a,b e Mn2t. Then (i) a satisfies the diagonal condition iff a < l'n, (ii) if a < l' n then a;a
((a-6)")jj = ((a-b)jiY = (ajj
6ji)"
= (ajiY
(bjiY
def. def.
Th. 247
= aij
bij
def.
= (a
6) ij
def.
Proof of (vi): ((a ; bY)ij = ((a ; b)jiY =
(]__[ajk \bki)
def. def.
k
= Y[(ajk;bkiy
Th. 250
k
]__[ (okiY',(ijkY
R9
*!
= _Q 6ife; akj fc
def.
330
6. RELATION ALGEBRAS
= (b; a)ij
def.
Proof of (vii): (a
a)ij = dij
aij
def.
= «ij-((«y)T a
= ( jiT = (dji
R-7
(ajiY
def.
CLji)"
Th. 247
= ((a-d)jiY
def.
= ((a-aY)ij
def.
D 21. Bases Let 21 £ NA and assume n is a nonzero ordinal such that if n is infinite then 21 is complete. Let k,l < n. We say that two basic matrices a, b E B n 2l agree u p to k if dij = bij whenever k ^ i,j < n, and we say that they agree u p t o k,l if Oy = bij whenever k,l ^ i,j < n. For any i,j < n let TT(2l) := {(a, 6) € (B n 2t) 2 : a and 6 agree up to i}, ££(2t) := {a E BnK : al3 < 1'}. Consider the following seven statements about N and 21. (6.95)
0 ^ N C B n 2l.
(6.96)
(atom cover) For every atom a; £ Ai2l there is some a € N such that aoi = x.
(6.97)
(extension) If a £ iV, j , j ,fe< n, j , j ^ k, x,y £ At%, and ay <x;y, then for some b £ N, bik = x, 6^- = ?/, and (o,fo)£ T^*(2l).
(6.98)
(cycle cover) If x,y,z £ Af>&. and a; < y;z, then for some a £ N, aoi = x, ao2 = y, and ai\ = z.
(6.99)
(amalgamation) If o,c £ N, i,j < n, i ^ j , and o agrees with c up to i , i , then for some b £ N, (a,b) £ T " ( a ) , and (fo,c) £ T"(2l).
(6.100)
(face) If o £ iV and j , j < n then a[i/j] £ N.
(6.101)
(permutation) If a 6 N and i,j
then a[i, j] £ N.
Note that in order for the condition (6.98) to apply to a given N C B n 2l, we need to assume n > 3, while (6.96) applies if n > 2. We say that iV is an - n-dimensional relational basis for 21 if n > 2, (6.95), (6.96), and (6.97), - n-dimensional cylindric basis for 21 if n > 3, (6.95), (6.98), (6.99), and (6.100), - n-dimensional semantical basis for 21 if n > 3, (6.95), (6.98), (6.99), (6.100), and (6.101).
22. ELEMENTARY ARITHMETIC IN WA
331
For example, if U € V then Bn9ie (U) is a relational basis for *Re (U) whenever n > 2, and Bn£Re (f) is a cylindric and semantical basis for d\t (U) whenever n > 3. The notions of relational, cylindric, and semantical basis were derived from concepts originally formulated for cylindric algebras by Henkin [90], who denned an algebraic interpretation to be a special kind of homomorphism from a free ndimensional cylindric algebra of formulas in Fm + (£) to an n-dimensional cylindric algebra. Cylindric algebras of dimension n are an algebraic abstraction of the theory of n-ary relations, just as relation algebras are an algebraic abstraction of the theory of binary relations. Bases bridge the gap between binary and n-ary. Cylindric bases were invented for constructing cylindric algebras, semantical bases for algebraic semantics. If 21 has no atoms, then i?n2l = 0. This is why the notion of n-dimensional cylindric basis was first denned only for atomic 21 € SA and n > 3 in Maddux [139, 10(11), pp. 140-141], where it was called simply "n-dimensional basis". The notion of semantical basis was also defined (but not named) in [139, p. 200]. The notion of relational basis was denned in [143, §2] for atomic 21 £ SA and 3 < n < u>, where it was also called simply "n-dimensional basis". The same definition of relational basis was adopted for n > 2 and arbitrary 21 € NA in [146, Def. 3] and in [150, Def. 34(iii)]. The definition of cylindric basis was extended in [146, Def. 4] to an arbitrary 21 € NA with n > 3. However, it is only under the assumption 21 £ WA that the notion of cylindric basis has all of its intended consequences. This can be seen from Th. 335 below and the discussion in Hirsch-Hodkinson [99, §12.6]. 22. Elementary arithmetic in WA We consider what can be proved from the axioms of N A by adding the weak associative law (6.10). One can make an algebra in NA with an element x that produces a strictly increasing sequence x-V
< ( x - l ' ) ; K (a;-r);l;l < ...
To test whether this was also true for WA, Richard L. Kramer applied Th. 488 below and discovered that the equation a;; 1; 1 = x ; l ; l ; l holds in every WA. This identity is included in the first part of the next theorem. Theorem 328 (Maddux [150, Th. 11]). / / 2 l <E WA and x,y <E A then (6.102)
x ; l ; l = a ; ; l ; l ; l = a; d ;l,
(6.103)
l;a;r = l;(l; a ;) = l ; ( l ; ( l ; a ; ) ) ,
(6.104)
a;d = ( z ; l ) d ,
(6.105)
x' = (l;x)',
(6.106)
x
(6.107)
x < l ; y => x < y .
=> xA
6. RELATION ALGEBRAS PROOF.
(6.102): x ; l ; 1 < x; 1;1;1
Th. 277
II
(6.72) Th. 265
< x d ;i
Th.276
VI
xd
(3.5)
1
= (I <x;l;l
Th. 265
(6.104): (x;l) d = l ' - a ; ; l ; l
(6.73)
d
= l'-x ;l
(6.102)
dd
(6.73)
A
(6.70)
= a; = x (6.106): Assume x < y;l. xd<(y,l)d = y6.
Then, by (6.104), Th. 265, a n d Th. 240, we have
T h e o r e m 329 (Maddux [147, Lem. 6]). Assume A. Ifu,v< V then
21 £ WA and u,v,x,y,z
(6.108)
(u;x);y = u;(x;y),
(6.109)
(x;y);u = x;{y;u),
(6.110)
(x;u);y = x;(u;y),
(6.111)
(x;u);(v;y) =x \ { u -v);y =x;((u -v);y),
(6.112)
u;{v;y)
=
(6.113)
(x;u);v
=x;(u v),
(6.114)
u;x-v;y
(6.115)
x;u-y;v = (x-y)-(u-v),
(6.116)
u-(x;y);z
{u-v);y,
= (u
v);(x-y),
= u-x;(y;z).
PROOF. (6.108):
(u;x);y
Th. 265
= u;l-x;y
Th. 276(i), Th. 270
= u;(x;y)
(6.62)
= u;l-x;y
(6.62)
<(x-u;l;y);y
(6.46)
< (x-u;l;l);y
Th. 265
<(x-u;l);y
Th. 276(i)
= (u;x);y
(6.62)
£
22. ELEMENTARY ARITHMETIC IN WA
(6.109): By converse duality from (6.108). (6.110): We need only prove (x;u);y < x;(u;y) inclusion by converse duality. (x;u); V < x;u;{y(x;uy;l) < x;u;(y-u;x;l) <
and obtain the opposite (6.44) Rg
x;u;{y-u;x;\)
(6. 57)
<x;V;(yu;l;l)
Th .265
=
Re , Th. 276(i) (6. 62)
x;(yu;l)
= x;(u;y) (6.111): (z;i
>)\{v\y) = =
x;(u;(v;y)) x;{{u;v);y)
=
x;((u-v);y)
(6.58)
=
(x;(u-v));y
(6.110)
(6.110) (6.108)
Obtain (6.112) and (6.113) from (6.111) with x = V or y = 1'. (6.114): u;x -v\y =: x
(6.59)
-u;(v;y)
(6.112)
x - ( u - v);y
< (u-v);(y-
(6.44)
(u-vj;x)
<,{u-v);{x-y) <. u:x v:y
Th.265, (6.57), Th. 270 Th. 265
(6.115) follows from (6.114) by converse duality. (6.116): u- (x;y);z
= u- (x;y
u;z);z
< u- {x\y
z);l
(6.49) u< V
< u- ((x
z;y);y);l
(6.46) Th. 265
(6.102)
A
= u- (x
z\y) \\ A
< u- (x
(6.66)
z\y)
= u-V
(x
= u- V
(x-
z; y); (x
z; y)"
z;y);(x-y;z)
The opposite inclusion follows by converse duality.
Th. 247, R 7 , Rg Th. 265
334
6. RELATION ALGEBRAS
The next theorem shows what more can be deduced if the elements in question are also atoms. For example, the inclusion in the conclusion of (6.106) can be replaced by equality, according to part (iii). x,y,z
Theorem 330 (Maddux [142, 3.5, 5.12], [150, 12]). Assume 21 £ WA and 6 Af$l. eAt2L. xd,x' If x;y ^ 0 then x' = yd. If x < y\\ then xd = yd If x < \\y then x' = y'. If x < y;z then xd = yd, x' = z', and y' = zd. The following statements are equivalent: (a) v = x', (b) v < V and x < x;v, (c) v < V and x;v = x. (vii) The following statements are equivalent: (a) u = x6, (b) u < V and x < u;x, (c) u < V and u;x = x. (i) (ii) (iii) (iv) (v) (vi)
P R O O F , (i): A s s u m e x A -y 0. T h i s m e a n s t h a t x;x-V -y 0, w h i c h i m p l i e s (1' y);x x ^ 0 b y t h e cycle l a w . B u t t h e n x < (V y);x since x is a n a t o m . Hence x
= x ; x 1
<{V
-y);x-x-V
= (V-y);(x;x)-V
(6.108)
< 1' y
(6.66)
This establishes that xA y ^ 0 implies xd < y for every y, which means that xd is an atom. (ii): If x-y ^ 0 then (x;x');(yd;y) ^ 0 by (6.72), so x;(x' yd);y ^ 0 by d (6.111). This implies x' y ^ 0, but x' and yd are cycles, so x' = yd. (iii): Suppose x < y;l. Using (6.72), (6.108), and (6.114) we obtain 0 ^ x = xd;x
yd;y;l = x d ; x - yd;(y;l) = (xd yd);(x
y ; l ) ,s o 0 ^ i
d
- y d , hence x
d
=y
d
.
(v): Use (ii), (iii), and (iv). The following theorem is an abstract equational version of Th. 31. The first part fails in the very nonassociative relation algebra; see Maddux [142, 3.7(2)] or §6.27. The second part was first proved for relation algebras by Monk [175]. Theorem 331 (Maddux [143, Th. 13]). / / 2 l e WA and x,y e A then (6.117)
(x^yy-(x^y)
< x ; x + (V
(6.118)
x,y € Fn2l => x*\y £
y);y + y;(V
y),
22. ELEMENTARY ARITHMETIC IN WA
338
Let z = x f y. Then z;x
(6.119)
and we also have (6.120)
z-x
since x = x;V
Re
= x ; ( V -y)+x;(V < 1;(1'
-y)
+x;y
Th. 261 T h . 265
Therefore, (6.121)
z\{z-x)
Th.265
(6.119), (6.120)
= y-l;(V-y)
Th.276
= y;(V-y)
(6.62)
and, by converse duality, t 1 991
{% .
5- <" (V . « ^ - «
We therefore obtain z;z = (J (E + »));(« (a; + 5)) = (z x);(z + (z -W);(z
x) + (z x);(z x) + (z -W);(z
Ri-Rs, Th. 246 -x)
-x)
R 5 , T h . 261
< x ; x + z ; ( z - x ) + (z - x ) ; z + z ; ( z - x )
Th. 265
<x;x
(6.121), (6.122)
+ y ; ( V y) + (V -y);y
<x;x + y;y
Th.265
For every matrix a £ MBSl, let a2 := a; a. Theorem 332 (Ladkin-Maddux [127]). Let 21 e WA and a e M s a . J/ a = a < 1» i/ien (a 2 ) 2 is closed. PROOF.
Let
r"aoi;aii;ai2;a22;a2o b = a- an;ai2;a22;a2o;aoo La22;a2i;an;aio;aoo
aoo;ao2;a22;a2i;aii aio;aoo;ao2;a22;a2i a22;a2o;aoo;aoi;an
aoo;aoi;an;ai2;a an;aio;aoo;ao2;a a2o;aoo;aoi;an;a
Since a satisfies the diagonal condition it follows by Th. 329 that all ways of inserting parentheses into the terms denoting the entries in 6 produce the same
336
6. RELATION ALGEBRAS
result. This is crucial for many computational steps that come later in this proof, but will not be mentioned again. Notice that b is symmetric, since, for example, 612 = (621)" = (021
a22;a2o;aoo;ooi ; o u ) "
= (021)" (022 ;o2o;ooo;ooi ; « n ) " = (021)" ( a n ) " ; (aoi)";(aoo)";(ffl2o)"; (0122)" =
o i 2 - a i i ; a i o ;aoo ;ao2 5022
=
o i 2 - a n ; a i o ;aoo ;ao2 5022
= 612.
Next we show 6 is path-consistent, i.e., b < b2. The computations are all similar, but fall into different types, depending on whether subscripts are distinct or repeated. Out of 27 computations we present four that illustrate the various types. 601 = 001 aoo; ao2; 822; fl2i; a n = aoi
(aoo;ao2
aoi ;(a22;a2i ; « n ) " ) ; (a22;a2i ; a n
< (aoo;ao2
«oi; («22;ffl2i ;aii)");(ffl22;«2i ; « n
= (ooo;oo2
a o i ; a n ;ai25022)5(022 5021 ; o n
= (002
aoo ; a o i ; a n ; a i 2 ;a22); (a22 ;a2i
= (002
aoo;aoi ; « n ;ai2;a22);(a2i
(aoo;0-02)";aoi)
(aoo; 002)"; aoi)
020;ao
a2o ;aoo ;aoi ;
a22;a2o;aoo;ao
= 6025621-
This first computation can be used to shorten the next one. 610 = 610 = (601)" < (6025621)" = (621)"; (602)" = 6125620 = 6125620600 = aoo
aoi ; a n ;ai2 5022 5020
< (aoi
aoo 5 ( a n 5012 5022 5020)") 5 ( a n ;ai2 5022 5020
= (aoi
aoo ;ao2 ;a22 ; o 2 i ; o i i ) ; ( f l i i ; o i 2 ;a22 ;a2o
= (aoi
aoo;ao2;a22;a2i ; a n ) ; ( a n ; a i 2 ;a22 ;a2o;aoo
(aoi)";aoo)
010 ;aoo) fflio)
= 601;6io-
Finally, 600 < aoo < 1' by the diagonal condition on a, so 600 = 600 -6oo = 600; 600 We may conclude that 6 satisfies the diagonal condition and is closed, since 6 is both symmetric and path-consistent. From 6 < a it follows that 62 < a2. But 6 is path-consistent, so 6 = 62 < a2. This in turn implies b2 < (a2)2, so, using the path-consistency of 6 again, we get 6 < (a 2 ) 2 . Next we show (a 2 ) 2 < a. Again, we only give a sample computation. The others are similar. We have ((a2)2)oi < aoi by Th. 327, and ((a 2 f)oi <(a 2 ) 0 2 ;(a 2 ) 2 i = (aoo;ao2
aoi ;ai2
ao2\a-22);(020;aoi
< (aoo ;ao2
ao2 5022); (021 ; a n )
«2i ; « n
022 ;
22. ELEMENTARY ARITHMETIC IN WA
0
1 2
3
4
5
337
6
FIGURE 1. Picture of relational matrix m = (ao2 ooo ;oo2 5022); (0,21 ; < aoo; 0,02', 0,22 ;o2i ; o n , 2 2
so ((a ) )oi < aoi aoo;ao2;a22;a2i ;on = 601 Thus we have b = (a 2 ) 2 . Since 6 is closed, so is (a 2 ) 2 , as desired. Th. 332 fails for 4-matrices, even if 21 £ RRA. For an example showing this, define a matrix TO02
moo —1
(mis
'
1
(w), 77122
77123
(m 2 3)~
by setting, for all i,j < 4, Hi = {(P, i)
A(p) = i, X(q) = j}
where f0 1 A«fc,/» = 2 13
if A; is even and I is even if k is odd and / is even if k is odd and / is odd if A; is even and I is odd
Let ao := 77i, and a^+i := (aj;)2 for k £ a;. In Figure 1, the set a;2 (= a; x a;) is arranged and each pair p 6 w2 is labelled with A(p). For all i, j < 4, m,j is the set of all pairs (p, g) £ (w2)2 such that A(p) = i, X(q) = j , and either p = q or else there is a horizontal, vertical, or diagonal line segment connecting p with q. Thus, for example, moo consists of all those pairs (p,p) such that X(p) = 0. Elements of w2 connected by a line segment will be called adjacent. Hence moi consists of those pairs {p, q) such that p and q are adjacent, X(p) = 0, and X(q) = 1. It is straightforward to verify that ao > a\ > 02 > 03 > . To get started, notice that all the adjacent pairs in the first column of Figure 1 belong to
338
8, RELATION ALGEBRAS
or mio. All the ones in wioi are excluded from either fno3|nisi or moalmai. But (m2)oi C (mo3|m3i) n (mo2|ro2i), so all such pairs are also excluded from (m2)oi. Similarly, adjacent pairs in the first column which belong to mio do not belong to (wi2)io- None of the adjacent pairs in the first column appear in any entry of m 2 . Pairs of the form (p,p) are in m 2 , except when p = {0,0) since {0,0) ^ moa|mao. All adjacent pairs eventually disappear. 23. Properties of bases We can now prove some properties of bases using results from the previous section. The next theorem contains various useful facts. Bn%
Theorem 333 (Maddux [146, Lem.6]). Suppose 3 < n < w, SI £ NA, N C (6.99) holds, and (6.100) holds. Let Ni := Tf (SI) n N2 for every i < n. (i) Mi'1 =Ni= Ni\Ni for all i < n. (ii) JVi|iV,- = N§\Ni for all i,j < n. (iii) Ifn
( v i ) Ifio,...,i/3-i,j,k
< n , » 0 , . . . , * / 3 - i , i , f e are distinct,
7 = [*0/j] o
o
[ip-i/j], and a-y Nk b, then there is some c € N such that c Nk a and cy = b. a ^ ^ (3c) y PROOF, (ii): It suffices to show that Nj\Ni C Ni\Nj for any i, j < n. This is obviously true if i = j , so assume i =£ j and a iV)|iVj c. Then a agrees with c up to *, j . By (6.99), there is some be N such that a Ni\Nj c. (iii): Assume
(6.123)
<% = b^ for all «,j < 2.
Define a function 7 : n —> n by J
7 = [2/0] o
fl \0
if & = 1 if Jfe = 0 , 2 , 3 , . . . , n - l ,
o [n - 1/0] = [n - l/0]|
|[2/0].
23. PROPERTIES OF BASES
339
T h e n , b y (6.123) a n d (6.100), 0 7 = bj, a N2 a[2/0]
N3 o [ 2 / 0 ] [ 3 / 0 ] JV4
6 N2 6 [ 2 / 0 ] Ni 6 [ 2 / 0 ] [ 3 / 0 ] Ni
Nn-2 Nn-2
o[2/0][3/0] 6[2/0][3/0]
2/0] iVn_! 0 7 , - 2/0] A ^ _ i 67,
so
aN2\---\Nn-1\(N2\---\Nn-1)-1b, but N2,...,
JVn_i are commuting equivalence relations by (i) and (ii), so N2\
\Nn-!\(N2\
l A ^ - i ) " 1 = N2\
\Nn-!
hence a N2\ \Nn-i b. (iv): From aij = bij we get aji = (ciij)" = (bij)" = bji by (6.93). We have aij < an;a,ij by (6.94), an < 1' by (6.92), and 21 e WA by hypothesis, so an = (a^)6 = V 0^5(0^)" by (3.5), (6.93), and Th. 330(vii). Similarly, bn = (bij) . From aij = bij we conclude that an = bn. A dual argument shows a
jj
= bjj
(v): Since a Ni a[i/j], by hypothesis, a[i/j] Nk b, it follows that a and 6 agree up to i, k. By (6.99) there is some c E N such that c Nk a and c Ni b. We must now show c[i/j] = b. Since c Ni b, we assume i ^ l,m < n and note that c[i/j]im = cim = bim, so what remains is to deal with arguments involving i. For this we need some equations involving only 6. We have 6 j m = 6;m since bjm
(6.94)
(6.92), Th. 265
= blm
Th. 270
(6.94)
(6.92), Th. 265
= bjm
Th. 270
By a similar calculation, involving R,6 instead of its dual Th. 270, we also get bij =bn. Therefore,
= bjm
cNib,
i ^ j ,m
340
6. RELATION ALGEBRAS
Finally, c[i/j]u = Cjj = djj
c Nk a, k / j
= ba (vi): By induction from (v).
a[i/j] Nkb, k
Some interconnections among the notions of semantical, cylindric and relational bases are given next. We will show that for an atomic WA, every cylindric basis is a relational basis, and the converse holds if n is 3 or 4. The first of these implications fails for NA. See Hirsch-Hodkinson [99, Ex. 12.6(5)] for examples of algebras in NA ~ WA which have, for every n > 3, an n-dimensional cylindric basis but no n-dimensional relational basis. The simplest case of their construction is presented in §6.27. For further discussion of bases, see Hirsch-Hodkinson [99, Ch. 12]. Theorem 334. Assume 21 G NA, 2 < n, and N C Bn2l. (i) If N is an n-dimensional semantical basis, then N is an n-dimensional cylindric basis. (ii) / / n > 3, 21 G WA, and N is an n-dimensional cylindric basis for 21, then N is an n-dimensional relational basis for 21. (iii) / / n G {3,4}, 21 G WA, and N is an n-dimensional relational basis for 21, then N is an n-dimensional cylindric basis for 21. PROOF. Part (i) is a trivial consequence of the definitions. Part (ii) follows immediately from part (iii) and either part (i) or part (ii) of Th. 335 below. Part (iii) follows from Th. 335(iv)(v)(vi) below.
Theorem 335. Assume 21 G NA, 2 < n, and N C Bn2t. (i) Ifn > 3, 21 is atomic, and (6.98), then (6.96). (ii) Ifn > 3, 21 G WA, and (6.98), then (6.96). (iii) Ifn > 3, 21 G WA, (6.98), (6.99), and (6.100), then (6.97). (iv) / / (6.97) then (6.100). (v) Ifn>3, (6.96), and (6.97), then (6.98). (vi) Ifn€ {3,4}, 21 G WA, and (6.97), then (6.99). (vii) Ifn > 3, 21 is atomic, (6.96), and (6.97), then 21 G SA. (viii) Ifn > 4, 21 is atomic, (6.96), and (6.97), then 21 G RA. Let Nt := 17(2!) n N2 for every I < n. (i): Let x G AfVL. Since 21 is atomic, we have
PROOF.
0 ^ x = x;V = x;
2_, l'>u£AtSi
u=
T j x;u. l'>u£AtSi
Hence there is some u G AttH such that u < V and x x;u ^ 0. But x is an atom, so x < x;u. We may now apply (6.98) to get some a G N such that aoi = x, 0.02 = x, and 021 = u.
23. PROPERTIES OF BASES
(ii): Let x £ Am. Then x = x6;x by (6.72) and x6 G Am by Th.330(i). By (6.98), there is some a 6 N such that aoi = x, ao2 = x6, and a-ii = x. (iii): (Hirsch-Hodkinson [99, 12.36]) Our assumptions are 21 6 WA, (6.98), (6.99), (6.100), and n > 3. For now we also assume that either n > 4 or i = j . The case in which n = 3 and i ^ j will be handled later. Suppose a 6 N, i,j, k < n, i,j ^ k, x, y E Ai2l, and a^- < x;y. We wish to find some b E N such that a iVjt fe, bik = x, and 6fcj = y. We start by applying (6.98) to obtain some c € N such that coi = aij < x;y, co2 = x, and c 2 i = y. Next we need some general observations about composing substitutions with functions that are not onto. Suppose a : n —> n and Ra (a) C n (a is not onto). Choose k < n with k £ Ra(a). Then, for any distinct i,j E Ra(a), we have o"|[j'/fc]|[i/j]|[fc/i] = o"|[*,j] and Ra(a\[i,j]) = Ra(a). Every permutation of Ra(a) can be obtained by composing transpositions [i,j] with distinct i,j £ Ra(a). It follows that if -K : n —> n and vr permutes Ra(a) then there is some function T : n —¥ n, which can be obtained by composing substitutions on n, such that (T\T = (T\K. From this observation it is easy to prove that every function which maps n onto a proper subset of n can be obtained by composing substitutions. Choose I E n ~{i, j , k}, which is possible since i = j or n > 4. Then {«, j , k} C Ra ([l/k]) C n. Let TT : n — n be the permutation determined by these conditions:
TT(J)
< 7r(j) & i ^ j ,
7r(m) = in it in E n ~{i, j , fe}. Since the range of [l/k] is a proper subset of n, there is some r obtained by composing substitutions on n such that [Z/&]|r = [l/k]\w. Let
f0 One can now check that a(i) = 0, o{k) = 2, and a(j) = < [1
if i = j . Clearly a iii^j
can be obtained by composing substitutions on n. By (6.100), from c £ N we get co £ JV. Note that if i ^ j then (ca)ij = ca^)a(j) = coi = ai:(- < x;y, (ca)ik = cCT(i)
= c 2 i = y.
Suppose i = j . Then coi = By = OJJ < 1', so coi < coo;coi < coo;l' = coo, which implies coi = coo since coi and coo are atoms. Similarly, y = C21 < C2o;coi < C2o;l' = C20, so y = C2o- Hence (ca)ij = coo = coi < x;y, (ca)ik
= C02 =
x,
(ar)kj
= C20 = y-
6. RELATION ALGEBRAS
1. 2. 3. 4. 5. 6.
i 0 0 1 1 2 2
j 1 2 0 2 0 1
fe
aij
2 1 2 0 1 0
aoi
<
a02
< x;y
aio
<
x;y
ai2
<
x;y
ci2o <
x;y
a
x\y
TABLE
2i
&01
bo2
&21
aoi
X
x < ao2',y
X
ao2
y y
aOi < y;x x < y;a2i
Ooi
y y
X
y < ao2 ;x y < x;a,2i
y y
«02
X
X
0,21
<x;y
<
x;y
«oi <
x;y
X
C121
1. Part of the proof of Th. 335 (iii)
We have (ca)ij = ciij, hence also (ca)ji = ciji. Since 21 £ WA, we also get (ca)a = an, and (ca)jj = ajj by Th.333(iv). Thus a and ca agree on all arguments \Nn-! c by Th. 333(iii). By Th. 333(ii) the relainvolving i and j , hence a N2\ tions JV(_) are commuting equivalence relations, so we may rearrange them to get \Nmr c, where {mi,m,2, mr} = n~{i,j,k}. Consequently a Nk\Nmi |iV m2 | \Nmr {ca). there is some basic matrix b £ N such that a Nk b and b Nmi |iVm2 | The latter statement implies 6^ = (cxr)n. = x and bkj = (co~)kj = y- This completes the proof of (iii) under the assumption that n > 4 or i = j . We now assume n = 3 and i ^ j . In this case we have {«, j , k} = 3, x, y £ At%, and dij < x;y. We wish to find 6 6 N with a Nk b, bn, = x, and bkj = y. Table 1 shows what to do according to the values of i and j . For example, line 4 in Table 1 deals with the case i = 1 and j = 2. These values are given in the i-column and j-column. The hypothesis ciij < x;y is repeated for this case in the fifth column: ai2 < x;y. The sixth column contains a statement equivalent to the one in the fifth column. In line 4, the hypothesis ai2 < x;y is equivalent by (6.150) to x < y;ci2i. We apply (6.98) to this inclusion and conclude that there is some b £ N such that &oi = x, 602 = y, and 621 = 021, as specified in the last three columns of Table 1. Recall that we want a Nk b, bn- = x, and bkj = y. In line 4 we have k = 0, so we want to know is that a No b, bio = x, and 602 = y- We already have 602 = y and we get 610 = x from 601 = x. From 621 = 021 we get bi2 = ai2, 622 = (I22, and fen = an by Th. 333(iv) since 21 e WA, hence a No b. This argument happens to also show that (6.98) implies (6.101) when n = 3. (iv): Let a £ N, i,j < n. If i = j then a[i/j] = a £ N, as desired. Assume i ^ j . Then ajj <
bji = ajj,
an
d &ij = ajj. But then we also have ba < bij ;bji = ajj ;ajj = ajj by
(6.58), so bu = ajj. We have shown a Ni b. (v): Suppose n > 3, x,y,z £ At%, and x < y;z. By (6.96) there is some a £ N such that aoi = x. By (6.97) with i = 0, j = 1, and k = 2, there is some fe £ N such that a N2 b, 602 = y, and 621 = z. The first of these last three statements gives us 601 = aoi = x. (vi): Assume a,c £ N, i,j < n, i ^ j , and a agrees with c up to i,j. We wish to show that there is some fe £ N such that a Ni fe Nj c. Since n is 3 or 4, we may choose k,l £ n ~{i, j} so that n = {i, j , k, I}, where k = I iff n = 3. We have aui = CM < Cki ;cu, so by (6.97) there is some d £ N such that a Ni d, dki = Cki,
23. PROPERTIES OF BASES
343
and dn = cu. Since 21 £ WA, b y Th.333(iv) we also have dik = Cik, du = cu, da = cu, dkk = Ckk, du = CJJ. Since a iV, d, a agrees with c u p t o i,j, a n d k, I are distinct from i,j, we also have dki = aki = cki, dik = aik = cik, dkk = akk = ckk, and du = an = cu. The last fifteen equations establish that d Nj c, so we may simply let b = d. (vii): ([150, Th. 35]) To show 21 € SA it is enough, by Th. 182 and Th. 276, to show that p; 1; 1 < p; 1 for every p G A, for which it suffices to prove that every atom below p; 1; 1 is also below p;l. Suppose (6.124)
v < p ; l ; l and v £ At%.
In every NA, left and right relative multiplication by a fixed element are completely additive functions (see Th. 296), so
Th. 182 ;x :p>w€
At%,x € A i 2 l } ; ^ A i 2 l
Th. 296
w;x >y€ At%,p > w £ At%x € Am}; ^ >z
w x
i iV)z
AM
^ At2l,y < w;x,w < p)
Th. 182 T h . 296
It follows t h a t there are w, x,y,z € At$l such t h a t (6.125)
v
y<w;x,
w
Since N is a relational basis and v £ At%i, by (6.96) there is some a £ N such that aOi = v.
(6.126)
Thus ooi < y,z- By the extension condition (6.97), there is some b E N such that (6.127)
602 = y,
621 =z,
aN2 b.
Similarly, 602 < w;x, so by (6.97) there is some c £ N such that (6.128)
cOi=w,
C12 = x,
b JVi c.
By (6.127), (6.128), (6.93), and (6.94), (6.129)
aoo = boo = coo < coi;cio = w;w.
Note that w is also an atom by Th. 251. By (6.129) and the extension condition (6.97) there is some d £ N such that (6.130)
do2 = w,
dio = w, and a N2 d.
Using (6.126), (6.130), Th. 262, and Th. 179(i) we get (6.131)
v = aoi = doi < do2',d2i
= w;d2i
Steps (6.124)—(6.131) show that v < p; 1 whenever v < p; 1; 1 and v £ At%i. Since 21 is atomic, this shows p; 1; 1 < p; 1.
344
6. RELATION ALGEBRAS
(viii): ([143, T h . 5]) To prove 21 £ RA it is enough t o show t h a t p;q;r < p;(q;r) for all p,q,r E A , a n d for this it is enough t o show t h a t every a t o m below p;q;r is also below p;(q;r). Suppose v
(6.132)
and v G AM.
By Th. 182 and Th. 296 we have v
At%}; ^{x
;x :p;q>wG
: r > x E At%}
At% r>xG
Am],
so there are atoms w,x 6 Af2[ such that (6.133)
v<w;x,
x < r.
w
Since N is a relational basis and v € AtQl, by (6.96) there is some a £ N such that (6.134)
ooi = v.
From (6.133) and (6.134) we have aoi < w;x. By the extension condition (6.97), there is some b E N such that (6.135)
bo2 = w,
a N-2 b.
621 = x,
Using (6.133), Th. 182, and Th. 296 we get w
>z& Am},
J2 so there are a t o m s y,z E At% such t h a t W
(6.136)
V < P,
z
< Q-
Since 602 = w < y;z we conclude by (6.97) that there is some c £ N such that (6.137)
C03 = y,
C32
= z,
b N3 c.
Then v = aQ1
(6.134)
= 601
(6.135)
= Coi
(6.137)
< C03 S(C32 ; c 2 i )
(6.94), Th. 265
=
(6.137), (6. 135)
y\{z;x)
(6.136), (6. 133), Th. 265
24, »-DIMENSIONAL RELATION ALGEBRAS
348
24. n-dimensional relation algebras Following Maddux [146, Def. 3(ii)], [150, Def.34(iv)], and Hirsch-Hodkinson [99, Def. 12.30], we say for every n > 2 that 21 is a relation algebra of dimension n if 21 is a subalgebra of a complete atomic NA that has an n-dimensional relational basis. RA» is the class of relation algebras of dimension n. These classes fall into a chain. Theorem 336. Ifn<m
then RAro D RAK.
PROOF. Suppose n < m and let 21 E RAm. Then SI C 95 for some complete atomic 58 6 NA which has an m-dimensional relational basis M C Bm?B. Let N := {(a,ij : i,j
The definition of RA» differs from that of MA» in Maddux [143, p. 82] where, for n > 3, 21 g MA» iff 21 is a subalgebra of some complete atomic SA (not merely NA) which has an n-dimensional relational basis. Allowing any NA has the following effect: Theorem 337 (Hirsch-Hodkinson [99, Ex. 12.3(10)]). RA2 = NA. It is easy to check that B»2l satisfies the face condition (6.100) and the permutation condition (6.101) whenever SI E NA. In the next theorem we see that BnSi also satisfies the atom cover condition (6.96) whenever St 6 WA, even if 21 is not atomic. Theorem 338 (Maddux [150, 49]). 1/21 € WA and x g AM then X
If2
X
then there is some a E Bn2l such that aoi = x. \xd x~\ „ r . Using only the assumption that SI E NA, we
Let b =
PROOF.
\_x
x J
conclude that b is symmetric since
\x<* I X
X'\
\_X
X'
and b is path-consistent since, by (6.72) and (6.58), ,
,
\xA \_x
xd
x~\ x \
x;x x x
\xA \_x
x~\ x \
\x ,x x ; x \_x;x x , x
x x 1 _ IV x' x;x\ \_x
x ,x-x;x' x;x-x,x
a;l _ , x'\
From x G At2l we get x G At2l using only that SI E NA, but to conclude xd,x' E j4iSl from Th. 330(i) we also need to know SI E WA. Hence b E BaSl- For a given n > 2 let a = bw where w : n — 2, TT(O) = 0, and ir(i) = 1 whenever 1 < i < n. Then a € Bn3l and aoi ^ 6?roi = ft^-rowm ^ 601 ^ x. D
346
6. RELATION ALGEBRAS
Theorem 339 (Maddux [139, Th. 10(18)(20)], [143, Th.4,5], [150, Th.35]). Suppose 21 € WA and 2t is atomic. (i) The following statements are equivalent: (a) 21GSA,
(b) B32I is a 3-dimensional semantical basis for 21, (c) the extension condition (6.97) holds for B32I. (ii) The following statements are equivalent: (a) 21 e RA,
(b) B42I is a 4-dimensional semantical basis for 21, (c) the extension condition (6.97) holds for Bt%. PROOF. For any n > 2, if N = Bn%. then clearly (6.95) holds, and it is easy to check that (6.100) and (6.101) also hold. Thus Bn2l is a relational basis for 21 iff the extension condition (6.97) holds, and Bn2t is a semantical basis for 21 iff the amalgamation condition (6.99) holds. By Th. 334, the notions of relational, cylindric, and semantical basis coincide when n = 3 or n = 4, so all we need to do for both parts is show that the semiassociative holds in 21 iff the extension condition holds for #321, and that the associative law holds iff the extension condition holds for B42I. (i): Assume 21 €. SA. We will verify the extension condition (6.97) in case i = 0 = j and k = 1. The cases in which i / j do not require 21 € SA. Suppose
5.138)
flOO
101
flO2
aid
011
ai2
0,20
021
€B 3 2t.
Assume x,y € Ai2t and aoo < £;3/- We wish to find some b € -B32I such that a and 6 agree up to 1, 601 = x, and 610 = y. First we have 0 / aoo = aoo
x\y
< x;(y
x;aoo)
rot
<x;(y-x;V)
000 < 1'
= x;(y-x)
R6
It follows by t h e n o r m a l i t y of ; t h a t 0 / y x, b u t y a n d x are a t o m s , so y = x. Hence also x' = y6. Notice t h a t aoo < 0025020 < a o 2 ; l by (6.94) since a G B32I, a n d aoo < x;y < x;l by a s s u m p t i o n . We therefore have 0 / aoo < x;l
ao2;l
^ (ao2 ( - E i l ) ) ! ) ? !
^ot
= (002 - a ; ; l ) ; l
21 G SA
< (s;(^;ao2));l
rot
24. rc-DIMENSIONAL RELATION ALGEBRAS
Hence there is an atom z < x;ao2- Let (6.139)
faoo
x
002
6 = 2 /
x'
z
\jl20
Z O,22_
Clearly a and 6 agree up to 1, 601 = x, and 610 = y. It is easy to check that 6 E B 3 2t. For the converse, assume B32I satisfies the extension condition (6.97). We need only show ( p ; l ) ; l < p ; l for every p E A. Suppose ( p ; l ) ; l > x E At%. We are assuming 21 E WA, so by (6.104) we get
y;z. p>y<EAt<2l
Hence t h e r e a r e a t o m s y,z € At$l such t h a t xA < y;z, y < p, a n d z < p. Let r d
x
x
x
X
X
X
£
x'
x'
Then a G B^A by Th. 338, so by the extension condition (6.97), it follows from ^ V\z that there is some 6 6 B3IH such that a and 6 agree up to 2, 602 = y, and 620 = z. Consequently
a;d
6 =
X
y'
X
x'
612
z
621
622
and x = boi < bo2',b2i = J/;&2i < p ; l , as desired. (ii): For one direction, we assume 21 E RA and verify the extension condition (6.97) for B42I in case i = 0, j = 1, and k = 2. Suppose 0,00
aoi
ao2
aio
an
ai2
ao3
ai3
020
fl2i
022
023
030
031
032
033
Assume 1 , 5 6 At% and aoi < x;y. We wish to find 6 £ i?42l such that a and 6 agree up to 2, 602 = a;, and 621 = y- We have a o i < x;y
ao3;a3i
< x;(y =
rot
x;(aO3;a3i))
21 E RA
x;(y-(x;aO3);a,3i)
< x;((x;a03
rot
y;ai3);a3i)
so there is an atom z < x;ao3 y,ai3.
Let
aoo aio
aoi ttii
x y
x
y
x'
z
030
031
z
033
6 =
003 ^13
348
6. RELATION ALGEBRAS
Clearly a and b agree up to 2, bo2 = x, and 621 = y- What remains is to show that 6 6 B^%. This is easy but there are many cases to check. For some of them it helps to note that 622 = x' = yd £ AVOk. In other cases the defining conditions on z are involved. For example, 623 = z < x;ao3 = 620; 603 For the converse, we assume that Bn% satisfies the extension condition (6.97) and show that 21 is associative. Suppose p,q,r £ A and (p;q);r > x £ At%. We wish to show x
x<(p;q);r=
^2 (P;?);J/, r>y£At<&
so there is an atom y £ At$l such that y < r and
x<(p;q);y= so t h e r e i s a s o m e a t o m z £ At$l
z y
Yl
''
s u c h t h a t x < z;y a n d
z
Yl
u;v,
p>u£Atm, q>v£At<&
so there are atoms u, v £ Ai2l such that u
X
X
X
x' x' x'
x' x' x'
x' x' x'
Then a 6 B^% by Th. 338. Since aoi = x < z;y, we may apply the extension condition (6.97) to get some 6 £ B^% such that a and 6 agree up to 2, 602 = 2, and 621 = y- Since 602 = z < u;v, we may apply the extension condition again to obtain c £ B42I such that 6 and c agree up to 3, C03 = u, and C32 = v. Then we have x = aoi = 601 = coi < Co3;c3i = u;c3i < M; (0325021) = u;(v;b2i) u v
\i \y)
=
^Pj(QrJr); a s desired.
Now we may characterize SA as the class of 3-dimensional relation algebras, and RA as the class of 4-dimensional relation algebras. Theorem 340 (Maddux [143, Th.6]). (i) RA3 = SA; (ii) RA4 = RA. PROOF. Proof of (i): If 21 £ SA then 21 C 21+ £ SA by Th.326, 21+ is complete
and atomic, and 2l+ has a 3-dimensional semantical (hence relational) basis by Th. 339. Proof of (ii): If 21 £ RA then 21 C 21+ £ RA by Th. 326, 21+ is complete and atomic, and 2l+ has a 4-dimensional semantical (hence relational) basis by Th. 339. Theorem 341. (i) (J), (L), and (M) hold in every atomic RA that has a 5-dimensional relational basis. (ii) RA5 |=
24. n-DIMBNSIONAL RELATION ALGEBRAS
349
PROOF. Proof of (i): Assume 21 is an atomic RA and N is a 5-dimensional relational basis for 21. We show only that (M) holds. Let £01, £02, £03, £32, £21, £24, £41
G
^"
Following Lyndon's notational convention, we let Z30 = (£03)" and x\\ = (s4i)". Since 21 is atomic, it suffices, by Th. 182, to show for every atom poi £ At$L that if (6.140)
poi < £01 (^02
£03 52:32) 5(221 2:24 ;
then (6.141) poi < £03; ((£30; £01 '£32; £21); x 14 -£32 ;»24 -£30; (#01 ;£i4 -£02 52:24)) ;am-
From (6.140) it follows by Th. 182 and Th. 296 there are additional atoms P02,P03,P32,P21,P24,P41 £ At01.
(6.142)
such that p02 < xO2, P03 < xO3, P32 < a;32, P21 < £21, P24 < x24, pa < £41, and (6.143)
0 / poi < (P02 P03 ;P32); (P21 P24 ;p4i).
This implies poi < P02JP21- By Th. 335(v) the cycle cover condition (6.98) holds, so we may apply it to obtain some a £ N such that (6.144) ooi=poi, aO2=po2, 021=^21From (6.143) we know that 0 7^ P02 -po3',P32 and 0 7^ P21 -p24;p4i, but P02 and P21 are atoms, so (6.145)
O02 =P02 < P03JP32,
(6.146)
a 2 i =P2i < P245P41-
By applying the extension condition (6.97) to (6.145) we obtain some b € N such that (6.147) a and 6 agree up to 3, &03=P03, Since a and b agree up to 3, (6.146) gives us
632=^32-
(6.148) 621
C32;C24
C30;C04); C41
< co3;((c3o;coi
0325021);ci4
0325024
0305004)5041
< C03;((0305001
0325021)5014
0325024
C3o;(coi;ci4
= &03 5 ((6305001
&32;O2l);Cl4 ' &32 5C24
= P03 5 ((P30 5P01
P32 ;P2l) ;P14
< £03; ((s3o;a;oi
a;32;K2i);a;i4
P32 5P24
C025024))5041
63O;(aoi!Cl4
O02 5 C24)) 5 C41
P30 5 (poi 5P14
£32;s;24 ' a;3o;(a;oi ; £ i 4
P02 5P24)) 5P41 £02 ^ 2 4 ) ) ; £ 4 i
350
6. RELATION ALGEBRAS
Proof of (ii): If 21 G RA5 then 21 is a subalgebra of such an atomic 93 G RA with a 5-dimensional relational basis. Then 03 |= (J), (L), (M), but (L) and (M) are equations and (J) is a universal sentence, so they hold in all subalgebras of 03, including 21. The next theorem gives a useful sufficient condition for the existence of a semantical basis. The condition (Dn) is called the n-diamond condition. Theorem 342 (Maddux [146, Th. 7]). Suppose 3 < n < ui, 21 € WA, 21 is atomic, and (Dn)
7 / 0 ^ x i , . . . ,xn-2,yi,..
,2/rc-2 < 0', then 0 ^
n-2 ]J k=i
xk;yk.
Then fln2l is an n-dimensional semantical basis for 21. It is easy to find many examples of finite relation algebras (such as 9k (U) with \U\ < co) which have semantical bases even though they do not satisfy (D n ). However, it is shown in Th. 471 that "almost all" finite integral relation algebras satisfy (Dn). On the other hand, (Dn) will fail for essentially all nonintegral relation algebras. Here is a generalization of Th. 342 which applies to all relation algebras, including the nonintegral ones. Theorem 343 (Maddux [146, Th. 8]). Suppose 3 < n < ui, 21 G WA, 21 is atomic, and (D'n)
7 / 0 ^ xi,.. n-2
then 0 ^ n
. , x n - 2 , 2/i,...,2/n-2
< 0 ' , and 0 ^
n-2 Yl fc=i
xk;l;xk;yk;l;yk,
x
k; Vk
fc=i
Then Bn2l is an n-dimensional semantical basis for 21. It can also be shown that almost all finite relation algebras satisfy (D'n). 25. Cycles of atoms If the cycle law (Th. 294) is restricted to atoms, it can be restated as follows. Theorem 344. (R1-R3, R 5 , R7-R10) Assume x,y,z (6.150)
e At%.
Then
x ; y > z < = > x ; z > y <£=> z \ y > x <£=> z ; x > y < = > y \ x > z < = > y ; z > x .
PROOF. If x;y > z, then z = x;y z, but z ^ 0 since z is an atom, so 0 ^ x;y-z. By the cycle law, we get five more inequalities: 0 ^ x;z-y, 0 ^= z;y-x, 0 ^ z;x y, 0 ^ y;x z, and 0 ^ y;z x. Since y and x are also atoms, the first two of these statements yield y < x;z and x < z;y. By Th. 251, x, y, and z are also atoms, so the last three statements give us y z;x, z < y ;x, and x < y;z. The six equivalent conditions listed in the cycle law or in Th. 344 are equivalent conditions on triples of atoms, each condition stating membership or nonmembership in a particular ternary relation that we now define. Let 21 be a
25. CYCLES OP ATOMS
351
Boolean algebra with operators of relational type. The cycle structure of 21 is the ternary relation Cy(2l) := {(x,y,z)
: x,y,z € At%Ax;y
> z}.
This relation is empty if 21 is atomless. To conveniently express the equivalent conditions in Th. 294 or Th. 344 we define, for any atoms x,y,z £ At$l, a set of triples of atoms, (6.151)
[x, y, z] := {{x, y, z), (x, z, y), (y, z, x), (y, x, z), (z, x, y), (z, y, x)}.
The set [x, y, z] of triples of atoms is called a cycle. Note that the definition of [x,y,z] depends only on At% and the function": At% —> Atf&., and the definition applies to any algebra of relational type that satisfies R1-R3, R7, and Rs- If, in addition, 21 also satisfies R5, R9, and Rio, then, by the cycle law, the cycle structure of 21 is the union of cycles; every cycle is either contained in or is disjoint from the cycle structure. These two possibilities are distinguished as follows. We say that [x, y, z] is a forbidden cycle of 21 if [x, y, z] fl Cy(%V) = 0, and a cycle of 21 if [x, y, z] C CyipVj. A cycle [x, y, z] is said to be an identity cycle if one (or, equivalently, all) of its triples contains an identity atom, and a diversity cycle if all of the elements in its triples are diversity atoms. Lyndon [133, p. 710] suggested that a triple of atoms (x, y, z) be called a cycle if x;y > z. Any such triple also satisfies the conditions y;z > x, z;x > y, y;x > z, %\z > y, and z;y > x. We have used the condition x;y > z instead of Lyndon's suggested condition x;y > z, because Cj/(2l) is the relation which occurs in the Jonsson-Tarski Representation Theorem [118, Th. 3.10]; see Th. 352 below. Note that a triple (x, y, z) is a cycle in Lyndon's sense iff (x, y, z) is a cycle in the sense followed here. As we see next, if 21 G NA is atomic, then the operations ; and " are completely determined by the cycle structure of 21. When dealing with a ternary relation T, for brevity we will frequently write Txyz instead of (x, y, z) 6 T. Theorem 345. Assume 21 £ NA and 21 is atomic. Let (6.152)
T := Cy(fH),
(6.153)
U := {x : 3y3z(Txyz V Tyxz V Tyzx)},
(6.154)
S := {(0,6) : a,6 £ U,VxVv((Taxy
(6.155)
I := {a:ae
U,VxVv((TaxyV
<S> Tbyx) A (Txay «
Txay)
=> x = y)}.
Then (6.156)
U = At%
(6.157)
V a (a e U => 3bSab),
(6.158)
V a (a eU => 3i(i el A Tiaa)),
and for all atoms a,b G At%, (6.159) (6.160)
Sab O a = b, oe/»a
Tybx))},
352
8, RELATION ALGEBRAS
If x,y € A then (6.161) (6.162) (6.163)
x;y = ^ { c ;x>a€U,y>b€ x = ^{b
U,Tabc},
: x > a 6 U, Sab},
l'=^J.
PROOF. Proof of (6.156): Clearly T C {At%f, so we know ?7 C At a . Suppose a G AtSL. Since SI is atomic we have 1' = 52i'>i1e.Ata'tt> n e n c e 0 / a = a;l' = a;
a £ At 21, Re Jj
« w
St is atomic Th.296(ii)
Consequently there must be some atom w £ At SI such that 1' > w and 0 / a;«. But then a;« < a;l ! = a, hence 0 ^ a;« = a;u a, so {a,u,a) € Cty(Sl). This implies that a eU, and completes the proof that U = At%.. We happen to have also shown that (6.164)
AM = {a : 3«(r > it e A i » , {0,11,(1) g C»(St))}.
Proof of (6.159): Note that So* holds iff, for all x,y e AM, we have (6.165)
a;x-y / 0
&;j/a; / 0,
a;;a j / / 0
y;&- x / 0,
If a = 6 then (6.165) holds by the cycle law. For the converse, we assume (6.165) and show a = b. We saw above that there is some n £ At9l such that « < 1' and 0 / a;n a. From the latter statement we get b;a u / 0 by (6.165), so n;a b / 0 by the cycle law. Since 6 is an atom and u < V, this gives us b < u\a < 1! ;a = a. However, a is also an atom by Th. 251, so we conclude that b = a, as desired. Proof of (6.160): Note that a g I iff for all x,y e At% (6.166)
(a;x- j / / 0 Vx;a- j / / 0) => x = y.
Next we prove that if a < 1' then (6.166) holds for all atoms i , y € At^L. Suppose a;x - i ( / 0 . Then 0 ^ a;x y < 1' \x y = x y, hence x = y since x and y are atoms. Similarly, if x;a y ^ 0 then x = y. Thus a £ I whenever a < 1'. For the converse, assume a £ I. As we showed above, there is some atom n € AtSl such that w < 1' and 0 / a;ti a. Since a G / , this gives us « = a by (6.166), but w < V, so a < 1', as desired. Proof of (6.158): This follows from (6.156), (6.160), and (6.164). Proof of (6.157): This follows from (6.156), (6.159), and the fact that the converse of an atom in an NA is again as atom. Proof of (6.161): We use the complete additivity of left and right relative multiplication, the assumption that atoms are dense, and the definitions of U and T:
x;y = (J2& ; l ^ e E / l ) ; ( Z ^ 6: » > & £ t/})
Th
-182
25. CYCLES OP ATOMS
353
{a;b :x>aeU,y>beU}
Th. 296 Th. 182
: a;b > c 6 U, x > a g U, y > 6 6 U} :m>aeU,y>b£U,
Tabc}
Proof of (6.162): Similarly, we have
* = (y2{a :x>ae
I/})"
= ^{a :x>aeU} = J2& : x -
Th. 182 Th. 249
a e U Sab
' }
(6.159),
and (6.163) follows from (6.160) by Th. 182. In view of Th. 345, it is clear that a multiplication table listing the products of all the pairs of atoms of a given finite relation algebra is nothing more than a (rather redundant) list of its cycles and therefore completely determines that algebra. Lyndon [133] observed that the identity atoms can be characterized among all atoms as those which satisfy ti;w = u. Thus, he noted, a finite relation algebra may be characterized by specifying the mapping " from atoms to atoms and giving a list of cycles. We will specify finite relation algebras in the following way. We list the identity atoms, the symmetric diversity atoms, the pairs of antisymmetric atoms, and the cycles. We usually use notation for the atoms that helps to specify the identity atoms and the action of ". For example, suppose t, e, a, r, and r are the five atoms in a certain finite relation algebra 21 with 32 elements, whose cycles are [i,i,i], [e,e,e], [i,a,a], [i,r,r], [r,e,r], [a,r,r], [a,a,a]. The notation for the atoms tells us the structure of w. We have i = i, e = e, a = a, (r)" = r, (r)" = r. The convention is that since a is listed as an atom, but "a" does not appear in the list of atoms, then a = a. Since r and r are both listed, they are distinct and are converses of each other. We need to know " in order to correctly interpret the notation used to specify the cycles. For example, we know from (6.151) that (6.167)
[a, a, a] ;= {{a, a, a), (a, a, a), (a, a, a), (a, a, a), (a, a, a), (a, a, a)},
but, since a = a, we actually have (6.168)
[a,a,a]:={(a,a,a)}.
To determine that 1' = « + e we must use the list of cycles, (6.155), and (6.160). There is an isomorphism p that embeds the relation algebra 21 thus specified into £He (4). In fact, St is isomorphic to the subalgebra of 9te (4) which is generated by the relation {(0,3), (1,3), (2,3)}. The isomorphic embedding p of 21 into ffte (4) takes these values on the atoms of St:
6. RELATION ALGEBRAS
p{a) = {(0,1) , (1, 0}, (0, 2}, (2, 0 ) , (1,2), (2,1)}, p ( r ) = {<(), 3 ) , < 1 , 3 > , ( 2 , 3 > } , p(r) = { ( 3 , 0 ) , ( 3 , l ) , ( 3 , 2 ) } .
26. Complex algebras of ternary relations In §6.25 we obtained a ternary relation from an atomic NA. In this section we reverse the procedure and start with a ternary relation. Suppose that T £ V is a ternary relation. Let U be the field of T as a ternary relation, that is, (6.153) holds. We use T to construct an algebra of relational type whose universe is Sb (U). First, define a binary operation ; on the powerset of U, by letting, for any X,YCU, X;Y := {c : 3x3y(x € X,y £ Y,Txyc)}. Define the binary relation 5 C U2 by (6.154). Note that S must be a symmetric relation because of the form of its definition. More specifically, (a,b) € S &VxVy((Taxy
<=> Tbyx) A (Txay <=> Tybx)),
{b,a) G S <^VxVy{{Tbxy « Tayx) A (Txby «
Tyax)),
and the two formulas on the right are clearly equivalent. Next we use S to define X C U for every subset X C U by X := {b : 3x(Sxb,x£ X)} = S*(X). Finally, define the subset / C U by (6.155). The operations ; and " along with the distinguished subset / are enough to define, starting from the Boolean algebra of all subsets of U, an algebra of relational type called the complex algebra of T. Cm(T) := (Sb (f/),U,- ; , " , / > . The Boolean part of £m (T) is 581 ({/), the complete atomic Boolean algebra of all subsets of the field of T. The complex algebra Cm (T) is a relation algebra when certain elementary conditions are satisfied by T, as stated in the next theorem. Theorem 346 (Maddux [142, 2.2, 2.6]). Suppose T e V is a ternary relation. Define U, S, and I by (6.153), (6.154), and (6.155). Consider the following six statements. (6.169)
V o (a € U => 3bSab),
(6.170)
V o ( a € ( / ^ 3t(i el A Tiaa)),
(6.171)
VxVyVzVaVb(Txyz ATzab => 3c{Txcb A Tyac)),
(6.172)
VxVyVzVaVb(Txyz ATzab => 3cTxcb),
(6.173)
VxVyVzVaVb(Txyz ATzab A Ix => 3cTxcb),
(6.174)
VxVzVa\/b(TxzzATzabAlx
=> Txbb).
Then (i) <£m (T) is an algebra of relational type,
28, COMPLEX ALGEBRAS OP TERNARY RELATIONS
358
(ii) the Boolean part of £tn (T) is a complete atomic Boolean algebra, (iii) the operators ; and " are normal and completely u-additive (in fac^ 1-additive, and 2-additivel respectively), (iv) if (6.169) and (6.170) then S is an involution, i.e., S : U -* V and S(S(x)) = x for all xeU, (v) Cm(T) g NA iff (6.169) and (6.170), (vi) £m(T) G RA iff (6.169), (6.170), and (6.171), (vii) Cm(T) g SA iff (6.169), (6.170), and (6.172), (viii) Cm(T) g WA iff (6.169), (6.170), and either (6.173) or (6.174). PROOF, (iv) and (v): Assume (6.169) and (6.170). We show that S is an involution. For any a € U we may apply (6.169) to obtain b € U such that Sab. So far this shows Do (S) = U. To show S is functional, suppose there is some c £ U such that Sac. Apply (6.170) to a, obtaining i G I such that Tiaa. By (6.154), the latter condition implies Tabi since Sab, which in turn implies Tcib since Sac, but from i € / and (6.155) it follows that c = b. Therefore S is functional. We already saw that S is symmetric, so 5 is an involution. We may therefore use functional notation with S. From (6.154) we get (6.175)
(a;, y, z) g T
» (Sx, z,y)eT
{Stfl S i , Sz)eT
«
(y, Sz, Sx)eT
(Sx, a;, Sj/} g T «
»
(», % , a;) 6 T
for all x,y,z € [/. It follows directly from (6.175) and the definitions of ; and in Cm (T) that the third and fourth conditions of Th. 314 are satisfied in Cm (T). Note that I;X C X for all X C U by (6.155). The opposite inclusion follows directly from (6.170). Hence the first condition of Th. 314 holds, namely, the equation x = V ;x is valid in Cm(T). To show that the equation x = x;V is valid in €m(T), first note that I ; / C I for all X C U. For the opposite inclusion, let a e X. By (6.170), there is some * g I such that («, Sa, Sa) € T. Applying (6.175) twice, we obtain {a, i, a) g T, hence a € X;I. By Th. 314, Cm (T) 6 NA. The conditions required for £tn(T) G RA in the previous theorem can be expressed less formally. (6.170) says that every a g U has a left identity i g I, (6.169) says that every a G U has a converse b G E7, and (6.171) (the associativity of ;) says that, under the right interpretation, two lines intersecting at a point z determine a plane, as illustrated in Figure 2. Part of the diagram uses oriented labelled triangles, as was done for the cycle law, Th. 294, and the rest shows that the associativity condition (6.171) holds in Euclidean geometry when Txyz is interpreted, in case x, y, and z are distinct points, as "the directed line segment from x to y contains z". The identity element of the complex algebra of T is an atom just in case / is a singleton, i.e., I = {e} for some e 6 U. Whenever this is the case, (6.170) takes on the following simpler form, (6.176)
\ta(a £ U =4- Teaa).
By Th. 307, 1' is an atom in every integral NA. The converse does not hold for nonassociative relation algebras because McKinsey's algebra has zero-divisors and
RELATION ALGEBRAS
TxyzhTzab => 3c(TxcbATyac))
FIGURE 2. Associativity
yet 1' is an atom, but if the identity element of a semiassociative relation algebra is an atom, then the algebra is integral; see Th. 353. Every square relation algebra on a set is a complex algebra, for if U is an arbitrary set and T = {{(a, b), (b, c), {a, c)) : a,b,c € [/}, then the complex algebra Cm (T) is equal (and not just isomorphic) to the square relation algebra on U: me (CO = €m ({{(a,b),
(b,c), {a,e» :a,b,ce
U}).
At this point we have two ways to construct the complex algebra of a group (one is (6.4)), but they produce the same result. Let & = (G, o, ~1, e) be a group. The complex algebra £m(<&) was first defined above by using all three of o, ~1, and e. However, we get another complex algebra from © by using only the binary operation o. Since o is a binary operation, it is a set of ordered pairs, each of whose left side is an ordered pair in G2 and whose right side is an element of G, but every such ordered pair is an ordered triple, since (x, y, z) = ((x, y) ,z). Thus 0 is a ternary relation. Indeed, o = {{x, y, z) : x, y, z £ G, x o y = z}. Define S C G 2 a n d ICG according t o (6.154) a n d (6.155). T h e n S = " 1 a n d 1 = {e}, so £m(o) = £m(0).
28.
27.
MCKINSEY'S ALGEBRA IN WA ~ SA
357
The very nonassociative algebra in NA ~ WA
For an example of an algebra in NA that is not in WA (from Maddux [142, 3.6]), suppose i, e, a £ V are distinct, let T = {{i, i, i), (e, e, e ) , (i, a, a), (a, i, a), (a, a, i), (e, a, a), (a, e, a), (a, a, e)}. Then Cm (T) £ NA and if assume U, S, and I are defined according to (6.153), (6.154), and (6.155), then U = {i,e,a}, S = {(i,i) , (e,e), (a,a)}, and I = {i,e}. We have Cm (T) g WA since (6.173) fails, as follows. We have i £ I, {i,a,a) £ T, and (a, a, e) £ T, but there is no atom c £ {i, e, o} such that (i, c, e) £ T. The very nonassociative relation algebra may also be succinctly specified, according to our notational conventions, by saying that its atoms are i, e, o, and its cycles are [»,»,«], [e,e,e], [i, o,a], and [e, o,a]. To show that the notions of cylindric and relational basis differ for algebras in NA, Hirsch-Hodkinson [99, Ex. 12.6(5)] give a general construction of an algebra in NA~WA from any relation algebra. Applied to £Hc (3), their construction produces the algebra 21 £ NA whose atoms are q, q, qo, qi, r, f, ro, r\, s, s, so, s\, a n d w h o s e cycles are [90,9,9], [q,qi,q], [ro,r,r], [r,n,r], [so,s,s], [s,si,s],
[r,s,q\.
The identity element is 1' = qo + qi + ro + ri + so + si. Let Qo q
q qi
q~ qi
.9 9i 9i. Then a £ .B32I and 001 = q < r;s. The extension condition (6.97) fails. There is no matrix 6 £ .B32I such that a and 6 agree up to 2, 602 = r, and 621 = s, because the last three conditions entail b:= so if 6 £ B32I then r = 602 < 6005602 = qo',r, but qo;r = 0, a contradiction. The atom cover condition (6.96) and cycle cover condition (6.98) hold for B32I while the extension condition (6.97) fails. In fact, 21 has no n-dimensional relational basis for every n > 3, but 21 does have an n-dimensional cylindric basis for every n> 3.
28.
McKinsey's algebra in WA ~ SA
The algebra described in the section was created by J. C. C. McKinsey around 1940 to show that the associative law is independent of the other axioms for relation algebras, that is, that R4 is not derivable from the remaining axioms R1-R3, R5-R10. Tarski also used McKinsey's algebra to show that the sentence of first-order logic which expresses the associative law for relative multiplication is not 3-provable; see Tarski-Givant [240, p. 68]. McKinsey's algebra is described in the Appendix of the unpublished monograph by Tarski [227, pp. 264-265] (the initial draft of Tarski-Givant [240]). This same algebra happens to have been used in Maddux [144], [147, p. 546]. Let T := {(V,V, ! ' ) , ( ! ' , a, a), (a, V, a), (a, a, ! ' ) , ( ! ' , 6,6), (6,1', 6), (6, 6,1')}
RELATION ALGEBRAS
i' a b
V V a b
a a V 0
b b 0 1'
TABLE 2. Multiplication table for McKinsey's algebra
McKinsey's algebra is €m(T), the complex algebra of T. If U (the field of T), S, and / are defined according to (6.153), (6.154), (6.155), respectively, then U = {V,a,b},
S = {(V,V),(a,a},(b,b)},
and I = {V}. McKinsey's algebra may
also be described as t h e 8-element algebra 21 £ NA with a t o m s V,a,b a n d cycles [1', 1', 1'], [ l ' , a , o ] , a n d [ l ' , 6 , &]. T h e multiplication t a b l e for a t o m s in McKinsey's algebra is shown in Table 2. Notice t h a t t h e identity element 1' is an a t o m , b u t McKinsey's algebra is not integral since 0 = a;b (see T h . 307). McKinsey's algebra is not associative since a;(b;b) = a;V = a ^ 0 = 0 ; 1 ' = (a;b);b. McKinsey's algebra is not in SA since a ; l = V + a ^ a ; l ; l = 1. O n t h e other h a n d , McKinsey's algebra is in WA, for if x V = 0 t h e n (V x);l;l = 0 = (V x);l, while if 1' < x t h e n x ; l = l = x ; l ; l . McKinsey's algebra is 1-generated by a a n d also by b, w i t h o u t t h e identity, since 1' = a;a a n d b = V + a.
29.
An algebra in SA~RA
Let 21 be t h e algebra with a t o m s V,a,r,r [ l ' , r , r ] , [r, l ' , r ] , [a,r,r], [r,a,a], a n d [r,r, a].
a n d cycles [ l ' , l ' , l ' ] , [ l ' , a , o ] , T h e n t h e equation x\(x\x) =
( x ; x ) ; x f a i l s w h e n x = r s i n c e r ; ( r ; r ) = r \ V = r b u t ( r ; r ) ; r = (a + l ' ) ; r a;r + r = a + r. This observation is used to prove Th. 545.
30.
=
Lyndon's nonrepresentable algebras in RA ~ RRA
Lyndon constructed several nonrepresentable relation algebras, the smallest with 52 atoms. The one published in Lyndon [133], presented next, has 56 atoms: - an and a'u for i £ {1, 2, 3, 4, 5}, - aij, a'ij, aik, a'ik,
- [alh an, au] where i <E {1, 2}, {k, 1} C {3, 4, 5}, k^l. Then Cm (T) 6 RA, but Cm (T) is not representable because it fails to satisfy Lyndon's condition C2, which states that if 0 / £02;£21 ' ^03;£31 2:04;£41 then 0 7^ X2o;£o3 X2i;xi3 (x2o;^o4 X2i;xi4);(x4o;a;o3 X4i;xi3). Condition C2 is an immediate consequence of equation (L) (see p. 30).
32, Lyndon'S ALGEBRAS FROM PHOJEOTIVE GEOMETRIES
359
31. Jdnsson's algebras from projective geometries A set L 6 V is a projective geometry, its elements are called lines, and elements of (J L are called points, if no point is a line, every line has at least two points, and (i) for every two points a and b there is exactly one line in L, called ab, such that a, b € ab 6 L1 (ii) if a, 6, and c are distinct points, 32 ^ db, x G cb, y € ac, and x ^ y, then Ty fl ofc ^ 0. It follows from (i) that the intersection of distinct lines contains at most one point, and (ii) is illustrated in Figure 2. Let L be a projective geometry in which every line contains at least three points. Let U = (J L U {e} for some e ^ \J L. Let T be the ternary relation on U consisting of all triples of distinct collinear points of L, plus all the triples of the form (e,a,a), {a,e,a}, and {a,a,e} with o f f / . In other words, if S = U1 then T contains the identity S-cycles and the 3-cycles of collinear points of L. Note that Cm (T) is symmetric and V = {e} is an atom of €m (T). In the case of a single line with exactly three points we get a representable relation algebra, for if L = {1} and \l\ = 3 then £m(T) ^ £m(Z 2 x Z 2 ), but otherwise we only have Cm (T) € SA. €m (T) ^ RA whenever some line has four or more points, for in that situation we have a,b,c,d(z I € L1 {a, 6, c, d}\ = 4, and {a, b, c), (c, &, d) £ T, but there is no x G (J L such that {a, as, d), {b, b, x) £ T. J6nsson [112, Th. 4] proved a lemma that gets around this difficulty: If T is a ternary relation with field U such that I = {e}, S is the identity relation on U, that is, S = (x : x £ U), and (6.170) and (6.169) hold, then T C T' for some ternary relation T' that satisfies (6.170), (6.169), and (6.171), i.e., €m(T') 6 RA, and an additional technical property. Then, supposing L is a non-Desarguesian projective plane, that is, it has two triangles that are centrally perspective but not axially perspective, J6nsson uses the lemma to choose an extension T' D T with €m (T') € RA. The three triangles that are centrally perspective but not axially perspective produce, by the additional technical property, a violation of formula (J) (see p. 30), which is valid in every representable relation algebra. A triangle is, by definition, a triple of distinct non-collinear points. The ternary relation T contains all triangles. Suppose a,b,c and n,v,w are triangles that are axially perspective (which means that audbv = bvC\cw = auHcw) but are not centrally perspective, which means that the three points ab D uv, ac n uw, and 6c n vw are not collinear. A violation of (J) arises by taking a;oi = abf) uv, %ca = a, &21 = b, X24 = c, a;o3 = u, xis = v, and £43 = w. To see this, draw the pictures in the style of the illustrations of (6.171). Therefore £tn(T") is a nonrepresentable relation algebra. It is also integral and symmetric and infinite. 32. Lyndon's algebras from projective geometries Lyndon's construction of a ternary relation T from a projective geometry differs from Jonsson's by the inclusion of all triples of the form {a, a, a). If L is (the set of points in) a projective geometry, U = (J L U {e} where e ^ (J L, and T is the ternary relation on U consisting of all triples of distinct collinear points
360
8, RELATION ALGEBRAS
of L, plus all the triples of the form {e,a,a}, {a,e,a}, {a,a,e}, and (a, a, a) with a , that is, T = {(a, b, c) : 3 = |{o, 6, c}|, {a, b,c} C\e L} e a u
U ^ > > °^> ^ e> a J' ^ a ' e J' ^ a ' a ^
then Cm (T) is the Lyndon algebra of L. Conversion in Cm (T) is trivial, so €m (T) is a symmetric algebra. The reason for restricting the next theorem to geometries with at least four points on every line is that if L has a line with exactly three points, say a, b, and c, then T contains the cycles [a, a, a] and [a, 6, c], but there is no point x such that [a, 6, a;] and [a,c, x\ are cycles, so Cm(T) ^ RA. Projective geometries with at least four points on every line create a class of relation algebras whose characterization is given in the next theorem. Theorem 347 (Lyndon [135]). St is the Lyndon algebra of a projective geometry with at least four points in every line iff 21 G RA, SI is complete, atomic, symmetric, V is an atom of SI, and a;a = a + V for every atom a. PROOF. The construction of an algebra from a geometry was described above. Conversely, to construct a geometry from an algebra St, let the set of points consist of the atoms distinct from 1', and let the line containing a, b be ab = {x :
a;b + a + b>x
e At%}.
D
The next theorem is Lyndon's key observation. Theorem 348 (Lyndon [135]). The Lyndon algebra of a projective geometry L is representable iff L is embeddable in a projective geometry with one dimension more than L. The representation of each point is the set of pairs of distinct points which, with the given point, make a collinear trio. For some informative diagrams and more explanations of this material from a cylindric algebraic point of view, see Monk [183], By Th. 348, the Lyndon algebra of a projective line of order n (which contains n + l points on a single line) is not representable whenever there does not exist a projective plane of order n. Since there is no projective plane of order 6, it follows that a particular symmetric integral relation algebra with 8 atoms is not representable. Whether this Lyndon algebra satisfies equations (M) or (L) (see p. 30) is not known. Lyndon's 8-atom nonrepresentable relation algebra was the smallest known algebra in RA ~ RRA when it was published in 1961. McKenzie found a 4-atom nonrepresentable RA for his dissertation in 1966. 33. McKenzie's nonrepresentable algebra McKenzie [166] found a 4-atom nonrepresentable relation algebra that turns out to be algebra 14a7 (algebra number 14 among the 37 algebras listed in Chapter 8 that have atoms I1, a, r, and r). Its atoms are V,a,r,r. This algebra's four identity cycles are [1', 1', 1'], [1',a,a), [r, l',r], and [1',r,r]. Its four diversity cycles are [r, r, r], [a, r, r], [r, a, r], and [r, a, a]. Its three forbidden diversity cycles
33.
McKenzie'S NONREPRESENTABLE ALGEBRA
1437
1' a r r
V V a r r
a a V +r + f a+r a+f
r r a+ r r 1
f f a+ r 1 f
TABLE 3. Multiplication table for McKenzie's nonrepresentable algebra
are [r, r, a], [r,r,r], and [a, o,a]. McKenzie's algebra is certainly not the smallest nonrepresentable relation algebra if size is measured by the number of atoms. Nor does it have the smallest number of cycles. It has four cycles, but so do the nonrepresentable algebras 2437, 2537, and 2737. But it does have the smallest cycle structure, containing only 28 triples, while the cycle structures of 2437, 2537, and 2737 contain 29, 30, and 31 triples, respectively. The relative multiplication table for the atoms is determined by the list of cycles, and is shown in Table 3. Let x = V+r. Then a; is transitive since x;x = ( l ' + r ) ; (V+r) = V+r+r;r = V+r = x and reflexive since x\(V x) = x;x = x and (1' -x)\x = x. Thus x is partial ordering element of I437. Note that x is antisymmetric since x-x = (V + r)-(V +r) = V. The corresponding incomparability element (corresponding to the notion and 2") is x x = (a + r) (a + r) = a. Suppose a representation exists, and that it correlates the nonempty binary relations / , A, R, and R'1 with the atoms 1', a, r, and r, respectively. A pair of distinct incomparable points p and q have an upper bound u and a lower bound I. This is expressed in the algebra by the Since inclusion a < r;f r;r, and in the representation by A C _R|_R-1 (~l R-1\R.
(p, q) £ A, there is some u and I such that (p, u) E R, (u,q) E R 1, (p,l) E R 1, and (l,q) G R, so (q,u) G R and (l,p) G R as well. The lower bound / is strictly below the upper bound u since (I, u) E R;R C R, but, by the inclusion r < a;a, there must be some element i that is incomparable with both u and I, that is, {i, u) £ A and {i, I) £ A. If i were above q it would be above /, while if i were below q, it would be below u, but i is incomparable with both I and u. Therefore i is incomparable with q. Similarly, i is incomparable with p. Since p and q are themselves incomparable, this gives us three mutually incomparable elements, namely p, q, and i. It follows that the relation An J4|A is not empty. On the other hand, a;a-a = 0, so we have a contradiction. There cannot be any representation. This argument is encapsulated by a single equation with only a single variable, due to Givant, McNulty, and Tarski; see Tarski-Givant [240, p. 55]. This equation, which holds in all representable relation algebras but fails in McKenzie's algebra when the lone variable x is assigned to the partial ordering element 1' + r, is 1 = l ; ( x f x + ( x ; x + V + ( x - x ) ; ( x - x ) - x ) - x+ x ' \ x ) ; l .
To show this equation holds in RRA, it suffices to prove that it holds in every 5Ke (U) (with M ^ I , since all equations hold in the trivial algebra £Re (0)), where it is equivalent t o 0 ^ x \ x + (x; x + V + (x x); (x x) -x) -x + x^x. Assume, t o t h e contrary, t h a t 0 = x f x + (x; x + V + (x x); ix x) x) x + x~ \ x. T h e n
362
6. RELATION ALGEBRAS
0 = x \ x = x f x = (x;x + V) x = (x x); (x x) (x x), so, letting a = x x, we get 1 = x;x = x;x, x;x + V < x, and 0 = a;a a. Note that x a s a partial ordering. Indeed, since x;x + V < x we know that x is transitive and reflexive on U. From 1 = x;x we have 0 ^ 1' D x;x, hence 0 ^ x x = a, so a pair of incomparable elements exist in U. From 1 = x;x we also have 1 = £;£, so every pair of elements has an upper and lower bound. Arguing as above, we deduce that there are at least 3 incomparable elements, contradicting the assumption that 0 = a;a a. For another proof of the nonrepresentability of 1437, note that (J) fails when £01 = (i, £02 = r, £21 = r, X03 = r, £31 = r, £24 = a, and £43 = a. This failure is
actually quite closely related to the arguments given so far. For yet another proof that McKenzie's algebra is not representable, it is enough to note that (M) fails when £02 = r, £21 = r, and £01 = £03 = £32 = £24 = £41 = a.
34. Allen's interval algebra An example of a representable relation algebra used in applications is the Interval Algebra, due to J. F. Allen [1, 2]. Let U be the set of "events", where an event is simply a pair of real numbers, the second larger than the first. The first number in an event is its "starting time", the second its "ending time". Seven binary relations on events are defined in the list below, where x,x',y,y' are real numbers (element of R), the relation < is the usual ordering of R, and (x,x'), {y,y') are events. "identity"
1' = {((£, x) , (y, y')) : x = y < x = y'}
"precedes"
p = {{{x, xlsj , (3/, j/')) : x < x' < y < y'}
"during"
d = {((x, x) , (y, y')) : y < x < x < y'}
"overlaps"
o = {((£, a;') , (3/, y')) x < y < x < y'}
"meets"
m = {((x, x) , (y, y')) : x < x = y < y'}
"starts"
s = { ( ( x , x') , (y, y')) :x =
y<x'
"finishes"
/ = {((x, x) , (y, y')) : y < x < x = y'}
The seven relations listed above are studied by van Benthem [246] and are used in some computer programs; see Allen-Koomen [5], Malik-Binford [160], and Simmons [217]. They generate a finite subalgebra of $Re (R), called the interval algebra. The interval algebra has 13 atoms, namely 1', p, p, d, d, o, o, ra, rh, s, s, / , and / . It turns out that p alone generates the interval algebra, as do each of the elements p, m, rh, o, and o; see Ladkin-Maddux [128, 127]. Starting with the rational numbers instead of the reals, or any dense linear ordering without endpoints, results in an algebra that is isomorphic to the interval algebra. But other infinite linear orderings produce relation algebras generated by 1', p, d, o, m, s, and / that are not finite, and the relations listed above are no longer atoms. This happens, for example, with the integers. If we start with a finite linear ordering, say < on a finite set U, then the subalgebra generated by 1', p, d, o, m, s, and / will be all of $Re ([/). Any relation algebra obtained in this way may be called an interval algebra (while Allen's interval algebra is obtained from the reals or
34. Allen'S INTERVAL ALGEBRA
V
P
P
d
d
o
6
1'
V
P
d
d
o
6
p
P
p
pdoms
P d
pdoms pdomf
P
V d
P 1
P 1 P
d
pdomf pdoms
P
P
P 1
pdomf
d
d
pdomf
Vddoossf f
d
dof
dos
o
o
P
pdoms pdoms
dos
pom
Vddoossf f
6
6
pdomf
P
dof
pdomf pdoms
Vddoossf f
pom
m
m
P
pdbms
dos
P
dos
rh
rh
pdomf
P
dof
P
P dof
s
s
pdomf
pom
P dof
8
8
f f
f f
P
P
P
d
pdomf
P
dof
d
dof
6
P
P
d
pdoms
dos
pom
P
pdoms
dos
d
o
dos
TABLE
4. Multiplication table for the interval algebra, first part
rationals). Allen's interval algebra has 75 cycles, written here without commas: [ l ' l T ] , [Vss], [Vmm], [Vpp], [l'oo], [Vff], [Vdd], [si's], [ml'm], [pVp], [ol'o], [/!'/]j [dl'rf], [sss], [smp], [spp], [som], [sop], [soo], [sfd], [sdd], [msm], [mmp], [mpp], [mop], [mfs], [mfo], [mfd], [mds], [mdo], [mdd], \psp], [pmp], [ppp], [pop], [p/s], [pfm], [pfp], [pfo], [pfd], [pds], [pdm], [pdp], [pdo], [pdd], [oso], [omp], [opp], [oom], [oop], [ooo], [ofs], [ofo], [ofd], [ods], [odo], [odd], [fsd], [fmm], [fpp], [fos], [foo], [fod], [ / / / ] , [fdd], [dsd], [dmp], [dpp], [dos], [dom], [dop], [doo], [dod], [dfd], [ddd].
The table of relative products of atoms of the interval algebra is given in two parts (see Tables 4 and 5). The + signs are omitted to save space. For example, pdoms = p + d + o + m + s. The table appeared first in Allen [2]. It not only shows relative products of atoms in the interval algebra, but also shows containments for the Allen-Hayes algebra [3, 4]. By the Allen-Hayes algebra we mean the direct product of "all" interval algebras, i.e., the direct product of an indexed system of algebras containing one algebra from each isomorphism type of interval algebra. The Allen-Hayes algebra contains the elements 1', p, p, d, d, o, 6, m, rh, s, s, f, and / . They form a partition, i.e., are pairwise disjoint and 1 =p+p + d + d + o + d + m + rh + s + s + f + f. Finally, the relative product of any two of them is contained in (and not necessarily equal to) the corresponding entry in the table.
6. RELATION ALGEBRAS
8
f f
/ /
P
pdoms
P
pdomf
P
P dos
d
pdomf
P d
pdoms
dof
d
dos
d
m
fh
s
3
r
m
fh
s
p
P
pdoms
P
P
P pdomf
P
d
P
d
dof
0
P dof
dos
0
dof
dos
pom
P
dof
pom
6
dos
P Vss
17/
m
m
dos
dof
P fh
s
P Vss
fh
d
pom
6 m fh
s
P
P fh
s
dof
m
Vss
s
6
d
f /
m
P dos
d
pom
f
0
d
17/
17/ /
TABLE
m
5. Multiplication table for the interval algebra, second part
35. Cycle structures of complex algebras The operation of forming a complex algebra from a ternary relation produces an algebra from which the original ternary relation may be recovered as a cycle structure. Theorem 349. Every ternary relation is isomorphic to the cycle structure of its complex algebra, that is, i / T e V and T C V3 then T9iCy(€m(T)). PROOF.
Note that {x,y,z) € T
{{x}, {y}, {z}) € Cy{£xn(T)).
U
Although the cycle structure determines the operations ; and " in every atomic 21 £ NA, it does not determine which joins of atoms of 21 exist. However, if every join of atoms exists, i.e., if 21 is complete, then 21 is completely determined by its cycle structure. This observation was first made in a far more general setting. Instead of a single ternary relation, let us consider an arbitrary relational structure, consisting of a set U together with a set of fmitary relations on U, whose complex algebra is the complete atomic Boolean algebra 031 (U) of all subsets of U augmented with the normal and completely additive (universally additive) operators determined by the relations on U. An (n+ l)-ary relation R C , Xn C U, Un+1 determines an n-ary operator / on U, where for any inputs X\, (6.177)
n)
= {u:
,un,u)
lr--
,un
36. REPRESENTATION BY COMPLEX ALGEBRAS
365
Jonsson-Tarski [119, Th. 3.9] observed that the complex algebra of a relational structure is a normal complete atomic Boolean algebra with completely additive operators, and, conversely, every normal complete atomic Boolean algebra 21 with completely additive operators is isomorphic to the complex algebra of a relational structure which is obtained from 21 in a manner that generalizes the way the cycle structure was obtained in case 21 £ NA. For the following theorem one need only note additionally that the operators in an NA are normal and completely additive. Theorem 350 (Jonsson-Tarski [119, 3.9], Maddux [142, 3.13]). 7/21 £ NA and 21 is complete and atomic, then 21 = Cm (C?/(2l)). The next theorem gathers some observations one can make in the somewhat more general setting of an atomic 21 £ NA that may not be complete. Theorem 351 (Maddux [142, 3.13]). Assume 21 £ NA and 21 is atomic. (i) 2l^|CCm(Cy(2l)). (ii) If Cm (C?/(2l)) £ RRA then 21 £ RRA. (iii) Cm (6*2/(21)) € NA. (iv) IfK is RA, SA, or WA, then Cm (6*2/(21)) £ K <s> 21 £ K. PROOF. For part (i), let / be the map that carries each element x of 21 to the set of atoms of 21 that lie below x. Then / is an embedding of 21 into £m(C?/(2l)). Part (ii) follows from part (i) and ISRRA = RRA. It follows from Th. 345 that (6.169) and (6.170) hold when T = C?/(2l), so by Th. 346 we conclude that Cm (C«/(2l)) £ NA. The converse of part (ii) may fail. Indeed, it is possible that 21 £ RRA and yet Cm (Cj/(2l)) f. RRA. Exceptions occur when 21 is both atomic and generated by its atoms, in which case it contains as few joins as possible. The complex algebra of the cycle structure of 21 contains all joins, that is, there is an element for every subset of At$l. The presence of these additional elements can cause nonrepresentability, as in Th. 323. Let us explore the reasons in more detail. Suppose 21 is an atomic RRA. Suppose a embeds 21 in 6 b {E). Define a : Sb (Am) -> 56 {E) by a (X) = U^ex a ( x )- Then a is a homomorphism of Cm (Cy(2l)) into 6 b (E) iff, for all X,Y C At% (6.178) (6.179) (6.180)
a(X\JY)=a(X)\Ja(Y), a(X) =a(X), a(X;Y)=a(X)\a(Y),
(6.181) The first and fourth equations always hold, while the second and third equations
hold iff a (AM) = \JaeAm a (a) = E. 36. Representation by complex algebras Let 21 £ NA. In view of the existence and uniqueness of perfect extensions, we could simply add a superscript "+" to "21" and denote a perfect extension of
366
6. RELATION ALGEBRAS
21 by 2l + , as was done in Th. 326. In contrast, recall that in case 03 € BA, we let 03+ be the Boolean algebra of all sets of ultrafilters of 03, an algebra which is naturally isomorphic to every perfect extension of 03. Here we extend this construction to NA. We obtain an algebra isomorphic to every perfect extension of 21 by constructing the complex algebra of the ternary relation T on the set £//2l of ultrafilters of 21 denned by T := {(F,G,H) : F,G,He
Uf%{f;g
3
= (*7/2l) n {{F, G, H) :F;*GC
: f € F,g € G} C H} H}.
Define a function £ : A —> 56 (t//2t) by e(x) :={F :x€
F £ 17/21}
for every x E A. We say that T is the ultrafilter structure of 21, and £ is the ultrafllter embedding. Let <£m2l:=£m(T). Then Ghn2l is the canonical embedding algebra of 21. This name was applied by Henkin-Monk-Tarski [93, 2.7.4] to the corresponding construction for cylindric algebras, which, by the way, was based on maximal proper ideals instead of ultrafilters. The version presented here appears in McKenzie [165, Th. 2.11]. The Jonsson-Tarski Representation Theorem [119, Th. 3.10] says that if 21 is a Boolean algebra with normal, completely additive operators, then 21 is isomorphic to an algebra that has the complex algebra of a relational structure as one of its perfect extensions. The proof proceeds by noting that 21 has a perfect extension 2l + , which, because it is complete, atomic, and has normal completely additive operators, is isomorphic to the complex algebra of a relational structure obtained by denning the appropriate relations on the atoms of 2l + . The next theorem is the NA version of the Jonsson-Tarski Representation Theorem, combined with a few additional observations. It is a consequence of Th. 326, Th. 350, and Th. 351. Theorem 352 (Jonsson-Tarski [119, 3.10]). Let 21 € NA. Then (i) <£m2le NA, (ii) if 21 is finite then 21 = £tn 21, (iii) ifK is RA, SA, or WA, then 21 e K <s> <£m2l e K, (iv) the ultrafilter embedding is an isomorphism from 21 onto a subalgebra 21' o/(£m2t, 21^21' C <£m2t, such that Ghn2l is a perfect extension o/2t'. 37. Elementary arithmetic in SA Jonsson-Tarski [119, 4.18(ii)] observed that every integral relation algebra is simple. Jonsson-Tarski [119, 4.17] also proved that a relation algebra is integral iff its identity element is an atom. In one direction this holds for NA. The other direction fails for WA but holds for SA. Theorem 353 (Maddux [147, Th.4]). Let 21 £ SA. Then 21 is integral iff V is an atom of 21.
37. ELEMENTARY ARITHMETIC IN SA
367
PROOF. One direction follows from the observation that if 21 is an integral NA then 1' is an atom, by Th. 307. For the converse, assume 21 £ SA and 1' £ At 21. By Th. 307, an NA is integral iff it has at least two elements and x\\ = \ whenever x 0. So we need only assume x 0 and show x ; l = 1. Now it follows from 1' £ At% and the definition of atom that 1' ^ 0, and this implies that 21 has at least two elements. By 1' £ At%, we also have either 1' x ; l = 0 or 1' x;l = V. However, if 1' x; 1 = 0, then 0 = x V ; 1 = x by the cycle law, contradicting our assumption that x ^ 0. Therefore 1' < x;l. But then, by Th. 276, 1 = 1';1 < a ; ; l ; l = x ; l < 1, so 1 = x; 1, as was to be shown. The assumption that 21 £ SA is essential, because McKinsey's algebra is a nonintegral 21 £ WA in which 1' is an atom. In McKinsey's algebra, the atoms are 1', a, b, and the cycles are [1', 1', 1'], [1', a, a], and [1',b,b]. Then 1' is an atom, but a;b = 0, so 21 is not integral. Next we show that many special cases of the associative law holds in every SA. The development culminates in Th. 365 below, which says that associativity may be freely applied to any relative product in which one of the factors is 1. T h e o r e m 354 (Maddux [150, Th. 13]). Assume 21 £ SA. For all x,y,z we have (6.182)
(x-y;z);l
=
(6.183)
l;(x-y;z)
= l;(z-y;x),
(6.184)
x;yl;z = x;(yl;z),
(6.185)
x;y-z;l
(6.186)
(x-l;y);z = x;(z-y;l),
(6.187)
(x;y);l=x;(y;l),
(6.188)
(l;x);y = l;(x;y),
=
(6.189)
(yx;z);l,
(x-z;l);y,
(x;y);(z;l)=x;(y;(z;l)),
(6.190)
((l;x);y);z = (l;x);(y;z),
(6.191)
x;(y;l);z = x;((y;l);z),
(6.192)
(x;(l;y));z = x;((l;y);z).
PROOF. Proof of (6.182): (x-y;z);l<((yx;z);z);l
Th. 265, (6.46)
<((yx;z);l);l
Th. 265
= (yx;z);l
Th. 276(ii)
<((x-y;z);z);l
Th. 265, (6.47)
<((x-y;z);l);l
Th. 265
= (x-y;z);l
Th. 276(ii)
Proof of (6.183): (6.183) follows from (6.182) by converse duality.
£ A,
6. RELATION ALGEBRAS
Proof of (6.184): 1 ;z
x;y
= x ;(y < X
! ; ( !
= x ;(y < X
;*))
(6.44)
;*))
Th. 265
x;(l
1 y\
Th. 276(ii) Th. 265
\y- i ; ( i ; l;z
Th. 276(ii)
= X ;«/
Proof of (6.185): (6.185) follows from (6.184) by converse duality. Proof of (6.186): (x -l;y);z
< (x l;y);(z
(x I;$)";!)
(6.44)
<x;{z-{y\l)\l)
Th. 265, Th. 239, Th. 243, R 7 , Rg
= x;(z-y;l)
Th. 276(ii)
<(x-l;(z-y;iy);(z-y;l)
(6.46)
< (x l\{\;y))\z
Th.265, Th. 239, Th. 243, R 9
= (x-l;y);z
Th. 276(ii)
Proof of (6.187): (x;y);l
= (1
x;y)\\
= (x-l;y);l
(6.182)
= x;(l-y;l)
(6.186)
(6.188) follows from (6.187) by converse duality. Proof of (6.189):
( T'lll
' (7 ' 1 ) — \(T'1I\''7\''\
I fl 1 S V ]
= (x;yl;z);l
(6.182)
= (i;(scl;z));l
(6.184)
= x;((yl;z);l)
(6.187)
= x;((l-y;z);l)
(6.182)
= x\{y\{z\\))
(6.187)
Proof of (6.191): (T- (ir 11V 7— ff T -nViV7
ffi 1 87")
= (x;y);l-l;z
(6.184)
= x\{y\l)-\;z
(6.187)
= x;(y;l-l;z)
(6.184)
37. ELEMENTARY ARITHMETIC IN SA
= a:;((y;l);a)
369
(6.184)
It is only in SA that ideal elements have Peirce's remarkable property (see p. W). Theorem 355. 7/SI e SA and xe A then (i) x;l G Dm% i j T G DmSl, (ii) I ; i 6 flnE, Ija; g TJnSt, (iii) l;a;;l 6 7e2t, I j ^ T e IeSi, (iv) DmSl is closed under x;(-), (v) 72n2t is closed under {-)",x, (vi) l;(a;tO),l;a;tO€7eStJ (vii) 0fa:;l,(0ta:);le/ea, (viii) 7e2t is closed under x;(-) and {-)\x, (ix) meets and joins of subsets o/TJmSl, Rn$l, and Ie% are again in Dm%, Rn%, and 7eSl, respectively. PROOF. Proof of (i): We obtain x;l G DmSl from the fact that the equation (x; 1); 1 = x; 1 is valid in SA (see Th. 276), hence i | T e Dm% by Th. 305. Proof of (ii): We get l;x € -Rn21 from the validity of l;(l;a;) = l;x in SA, so TJi e iJna by Th. 305. Proof of (iii): From (i) we have l;a;;l £ DmSL. By (6.187) or (6.188), 1;«;1 = l ; ( z ; l ) , hence l;a;;l € i?nSt by (ii). We therefore have l;a;;l € DmSln RnSl = Ie% and l;a;;l £ leSL Th.305. Proof of (iv): If y £ UmSl then x;y = E ; ( J / ; 1 ) = (x;y);l by (6.187), so x;y £ DmSl by (i). Proof of (v): If y £ Rn% then. y;x = {l;y);x = l;(y;x) by (6.188), so j/;a; e & I by (ii). Proof of (vi): We have a;fO = a;;l € TJmSt by (i), hence l;(a;fO) 6 -DrraSt by (iv). We also have l;(a;tO) G Rn% by (ii), so l;(a;tO) G JeSl. We have TJi £ Rn$l by (ii), so \\x\\ £ flnSl by (v). Also, \\x\\ G UmSl by (i), hence l;a:;l G Je2l. Finally, 1;x \0 = T ] E ; 1 G / e a by Th. 305. Proof of (vii): By (vi) and Th. 305. Proof of (viii): By (iv), (v), and Ie% = DmSl n RnSi. D The equation 0'; 0'; 0'; 0' = 0'; 0' was first proved for relation algebras by Julia RobinsonJ in 1945; see Chin-Tarski [49, p. 359]. As we prove next, it happens to hold in every SA but fails in some WA. The related equation 0' ;0'; (01 ;0') = 0' ;0' holds in every NA; see Th. 309. Theorem 356 (Chin-Tarski [49, 3.10], Maddux [143, 14(3)]). (i) 7 / a e S A ften((0!;0!);0!);0'=0';0\ (ii) There is a 3t 6 WA in which ((0!; 0 ! );0');0' # 0';0'. PROOF. Notice first that a;;0';0' < a;;l;l = x ; l = x ; ( l ' + 0 ' ) =x;l'+x;0' = a;+a;;0'. Let a; = 0'-0';0'. Then a; < 0';0' and a; < 0', soa;;0';0' < a;+a;;0' < 0';0'.
6. RELATION ALGEBRAS
1'
V V
a a
a b
a b
r +o
;
b b 0 1'
0
T A B L E 6 . A W Ai n w h i c h ( ( 0 ' ; 0 ' ) ; 0 ' ) ; 0 ' # 0 ' ; 0 '
Finally,
< (0' l;0');0'
For such a WA in which ((0'; 0'); 0'); 0' # 0'; 0', use an 8-element algebra with three symmetric atoms 1', a,6 whose cycles are [l',a, a], [V,b, b], and [a, a,a]. The table of relative products of atoms is shown in Table 6. Then 0' = a + 6, 0'; 0' = 1' + a, and (0';0');0 J = V +a + b= ((0';0');0');0\
38. Associativity in groupoids Let {A, ;} be a fixed groupoid. Let P be the function that maps finite sequences of elements of A to subsets of A,
\J An -+Sb(A),
P: such that, for all x\,..., P(xi,...
xn £ A,
,xn) = {y;z : y € P(xi,.. =
. ,xm-i),z
\^j 2<m
= P(xi);*P(x2,...
€ P{xm,.
P(xi,...,Xm-l);*P(xm,...,Xn)
,xn-i)\J
...
U P(X1, . . . ,Xm-l);*P(Xm,. U P(xi, . . .
,Xn-l);*P(xn).
The simplest cases of the definition of P are
= {xi};*{x2} =
. . ,Xn) U . . .
,xn),2
< m < n}
38. ASSOCIATIVITY IN GROUPOIDS
= {xi};*{x2;x3}
371
U {xi ;a;2};*{x3}
= {xi;(x 2 ;x 3 ), (xi;x 2 );x 3 }, P(xi,x 2 ,x 3 ,a;4) = {xi;((x 2 ;x 3 );x 4 ), xi;(x 2 ;(x 3 ;x 4 )), (xi;x 2 );(x 3 ;x 4 ), (xi;(x 2 ;x 3 ));x 4 , ((xi;x 2 );x 3 );x 4 }. If the groupoid (^4, ;} is absolutely freely generated by x £ A, then the cardinalities , are the Catalan numbers: C\ = 1, C2 = 2, C3 = 5, of P(x,x), P(x,x,x), CA = 14, C5 = 42, , respectively, where
for all k > 1. The function P has the following property, which can be used as an alternative definition. (6.193)
P ( x i , . . . , x
n
)
=
( J P ( % i , l<m
= P(xi;x2, U P ( n ,
U
x3,
,%m-i, x
; x
m
+ i , x
m
+2,
, x
n
)
,x n )
x 2 ; x 3 , xA,
U P(xi,
m
,xn)
,xn-2,
xn-i;xn).
The sets that occur in the definition of P are disjoint, while the sets in the alternative definition (6.193) are not disjoint. The latter fact is used in a later proof. We say that an element a £ A is 3-associative if \P(x,y, z)\ = 1 whenever a 6 {x,y,z} C A . S i n c e P(x,y,z) = {(x;y);z,x;(y;z)}, a ne l e m e n t a 6 A is 3-associative iff the two elements in P(x, y, z) coincide whenever a is either x, y, or z. This can be stated in three equations. Theorem 357. An element
a £ A is 3-associative
(6.194)
(a;x);y = a;(x;y),
(6.195)
(x;a);y = x;(a;y),
(6.196)
(x;y);a = x;(y;a).
iff, for all x,y £ A ,
We say that an element a £ A is 4-associative if \P(xi,X2,X3,XA)\ = 1 whenever a £ {X\,X2,X3,XA} C A. For any finite n > 4, the element a is said to be n-associative if |P(xi, , x n )| = 1 whenever a £ {xi, , xn} C A. The next theorem is an immediate consequence of these definitions. T h e o r e m 3 5 8 . F o r all x , y £ A , x ; y i s n - a s s o c i a t i v e if x o r y i s n + 1 a s s o c i a t i v e . I n p a r t i c u l a r , if x £ A i s ^ - a s s o c i a t i v e t h e n x ; y a n d x ; y a r e 3 associative. The next theorem shows that 3-associativity and n-associativity are independent for every n > 4. Theorem 359. Let n > 4. Then (i) 3-associativity does not imply n-associativity,
372
6. RELATION ALGEBRAS
a b c
a a b c
b c b c c b c
TABLE 7. Groupoid with a 3-associative but not 4-associative element
; a aa a(aa) (aa)a
oo
(aa)a oo
a aa
aa
a(aa)
a(aa)
00
00
00
(aa)a
oo
oo
oo
oo
oo oo oo
00
00
00
00
00
00
00
00
oo
oo
oo
oo
TABLE 8. Groupoid with a 4-associative but not 3-associative element
(ii) (n + 1)-associativity does not imply
n-associativity.
PROOF. The binary operation on {a,b,c} given in Table 7 yields a groupoid in which a is 3-associative but not 4-associative, since (a;6); (6;6) = b;c = b but a;((6;6);6) = o;(c;6) = a;c = c. Note that the entry occupied by can be replaced by either a, b, or c, because the product c;c is not used in these last two equations. In fact, any nonassociative groupoid with an identity element can be used for this proof, since the identity element (o in this case) is 3-associative but not 4-associative. For the second part, consider the groupoid with 5-element universe {o, aa, a(aa), (aa)a, oo} and operation ; defined in Table 8. The element a is 4-associative but not 3associative, so the result holds for n = 4. It is routine to extend this example to a sequence of groupoids that show (n + l)-associativity does not imply nassociativity. If a G A is 4-associative, then for all w,x,y =
G A,
(6.197)
((a;w);x);y
(6.198)
(x;(a;w));y = x;((a;w);y),
(6.199)
(x;(w;a));y = x;((w;a);y),
(6.200)
(x;y);(w;a)
=
(a;w);(x;y),
x;(y;(w;a)),
so an element that is both 3-associative and 4-associative satisfies (6.194)-(6.196) and (6.197)-(6.200). The converse is also true: if a satisfies (6.194)-(6.196) and (6.197)-(6.200) then a is both 3- and 4-associative, as shown by the following theorem.
39. INDEPENDENCE OF SEVEN WEAK ASSOCIATIVE LAWS
373
T h e o r e m 360. Assume a is a 3-associative element of the groupoid (A, ; ) . Then the following statements are equivalent: (i) a is ^-associative. (ii) for all w 6 A, a;w and w;a are 3-associative. (iii) (6.197)-(6.200) hold. PROOF. If a is 4-associative, then, by Th. 358, a;w and w;a are 3-associative for all w £ A. Next suppose that for all w, a;w and w;a are 3-associative. Derive (6.197) by applying (6.194) to a;w, derive (6.198) and (6.199) by applying (6.195) to a;w and w;a, respectively, and derive (6.200) by applying (6.196) tot»;a. Thus a satisfies (6.197)-(6.200). Finally, we assume a satisfies (6.197)-(6.200) and prove C A. We derive \P(w,x,y,z)\ = 1 by a is 4-associative. Suppose a E {w,x,y,z} showing that the five elements of P(w, x, y, z) coincide in each of the four cases w = a, x = a, y = a, and z = a. a;{x;(y;z)) = (a;x);(y;z) = ((a;x);y);z
(6.194) (6.197)
= {a;{x;y));z
(6.194)
= a;{{x;y);z)
(6.194)
((w;a);y);z = (w;(a;y));z
(6.195)
= w;((a;y);z)
(6.198)
= w;{a;{y;z))
(6.194)
= (w;a);{y;z)
(6.195)
w;(x;(a;z)) = w;((x;a);z)
(6.195)
= (w;(x;a));z
(6.199)
= ((w;x);a);z
(6.196)
= {w\x)\{a\z)
(6.195)
{{w;x);y);a = (w;x);(y;a)
(6.196)
= w;{x;(y;a))
(6.200)
= w;((x;y);a)
(6.196)
= (w;(x;y));a
(6.196).
39. Independence of seven weak associative laws In this section, let us say that an equation among (6.194)-(6.196), (6.197)(6.200) is independent if it fails in a groupoid in which the remaining six equations are valid. Every one of them is independent, as will be shown. Note that (6.197) and (6.200) are converse duals of each other, as are (6.194) and (6.196). Consequently, a left-right switch on any groupoid showing the independence of (6.194), (6.197), or (6.198), also shows the independence of (6.196), (6.200), or (6.199), respectively. Therefore, to obtain the independence of all seven equations,
6. RELATION ALGEBRAS
a b c TABLE
a a a a
b b b b
c b a a
; a b c
a a a a
b b b b
c a b a
9. The only 3-element groupoids for the independence of (6.197)
a b c 0
a 0 0 0 0
6 c 6 0 0
c 0 0 0 0
0 0 0 0 0
; a b c 0
a 0 0 0 0
6 c 0 0 0
c 0 c 0 0
0 0 0 0 0
TABLE 10. Groupoids for the independence of (6.194) and (6.195)
it suffices to show independence only for (6.194), (6.195), (6.197), and (6.198). The groupoid in the proof of Th. 359 does not show the independence of any one equation, since all three of (6.194)-(6.196) fail, while (6.197)-(6.200) are valid. Thus a is about as non-3-associative as it can get. No 2-element groupoid shows independence for any one of (6.194)-(6.196), (6.197)-(6.200), because, in every 2-element groupoid, either - (6.194)-(6.200) all hold, - (6.194)-(6.200) all fail, - (6.194), (6.196), (6.197) hold, the others fail, - (6.194), (6.196), (6.200) hold, the others fail. The only equations for which independence can be shown with 3-element groupoids are (6.197) and (6.200). There are (up to isomorphism) only two 3-element groupoids that show independence for (6.197). They are shown in Table 9. There are many 4-element groupoids that show the independence of (6.194) and (6.195). For example, to prove the independence of (6.194) and the independence of (6.195) we may use, respectively, these two groupoids: No 4-element groupoid shows the independence of (6.198) (or (6.199)), but the independence of (6.198) can be easily arranged in a larger groupoid using elements that are named after subterms of (6.198). Let G be the following 15-element set: G = {a, x, w, y, aw, xa, xaw, wy, xaw, awy, (xaw)y, awy, x(awy), x(awy), 0}. Define a binary operation ; on G so that a;w = aw, x;a = xa, x;aw = xaw, w;y = wy, xa;w = xaw,
aw;y = awy, xaw;y = ( a;wy = awy, x;awy = x(awy), xa;wy = x(awy),
18. EXTENDING BOOLEAN OPERATORS
276
l>aeS0
In this example, we chose a specific non-monotonie function, but the first few parts of following theorem show that any non-monotonic function would do. If 0 < m € w, we say that an element a of a Boolean algebra 58o is of height ra if it satisfies the following condition for every subset I C B j : if J^°' X exists and a < Yf X € Bo then there is a subset M C I o f cardinality m = \M\ such that a < J^° M. An element has height m iff it cannot be partitioned into more than m nonempty parts. Atoms are the elements of height 1, joins of pairs of atoms have height 2, and an element has height m iff it is the join of a set of m atoms. Height measured relative to some subset So C Bo is called So-height. An element x has So-height m if x is below the join of a, m-subset of every set of elements whose join contains x. We say that So is meet-compact if, whenever X is a subset of So whose meet JJ X is below an element b € So, X has a finite subset F whose meet is below 6, more formally, V&¥jf ((6 G So A X C So A J J ° X < &) = 3i?(F C X A F is finite A J}° F < 6)). We say that So is join-compact if, whenever X is a subset of So whose join ^2° X is above an element b g So, then X has a finite subset F whose join is above b, that is, G So A X C So A ^2°
x
>b C X A F is finite A ^ ° F > 6)).
Theorem 221. Assume !8o,58i g BA, 0 j4 So C B o , S i M complete, a : So —> S i , anrf CT a
o" W = I I
( ). * (*) = X ) °" (°) >
/or all a; G Bo- 2%en (i) CT and & are monotonic. (ii) For every x £ So,
(iii) (iv) (v) (vi)
If (T is monotonic and a; € So ffeenCT(a;) = a (x) = a {x). a is monotonic iff
276
5. BOOLEAN ALGEBRAS
(x) 7/0 < m G u; and every element of So is of height m then a is completely m-additive. PROOF. Proof of (i): Let x,y E Bo and assume x < y. By the transitivity of <, we have {a : y < a 6 So} C {a : s < a 6 So}. Applying a*, which preserves inclusions, yields <J*{a y < a G So} C a* {a : x < a G So}Applying Y[ changes C into >, so
d{x)= n 1 ff(o)< n x
1
y
Similarly, from x < y we get {a (a) : x > a G So} C {a (a) : y > a G So} so
( ) = Yl a (a) - Yl a(a) = ° (y)
& x
x>a£So
i/>aGSo
Proof of (ii): From i 6 So we get a (x) 6 {a (a) : x < a 6 So} and a (x) £ {a (a) : x > a E So}. It follows that a(x) = Y\
cr{a)
a (a) = a (x) .
x>aES0
x
Proof of (iii): Suppose a is monotonic and a: £ So. Then a (x) is a lower bound of {a (a) : x < a G So}, for if x < a G So then a (x) < a (a). Similarly, a (x) is an upper bound of {a (a) : x > a G So}. This gives us
a(x)= Y^ v(a)
£
Proof of (iv): This part follows immediately from parts (i) and (ii). Proof of (v): Additivity is the case m = 1, but we give proofs for both that differ only slightly. Note that, since So is closed under +, (5.62)
{a + b : x < a e S o , y < b e S o }
= { c : x+y < c e
So}.
To prove this for C, given a,b E So, let c = a + b; for D, given c e So, let a = b = c. Consequently, a (x + y) =
II
a (c)
definition of a
x+y
Yl TT
x
(
b)
a (a) + a (6)
V
(5.62) a is additive
18. EXTENDING BOOLEAN OPERATORS
= a (x) + a (y)
definition of a
Proof of (vi): a is m-additive because S(X! -\
\~ Xm+1)
n xi
1 a
^
..., xm + i
because So is closed under +
Y]
+am)-\
(
\-a(a2-\
\-am+i)
n
cr(a'm+i)
because a is m-additive
because So is closed under +
=
Yl x\-\
" («i) H
1"
\-xm
x2-t
h^ m + l
by Th. 189 =<7 ( x i +
Proof Y?d*{X) a(^°X), directions,
+ Xm) +
+a (X2 +
+ Xm + l)
of (vii): Suppose I C B 0 and Yl° X exists. We wish to show that = d{Y? X). For every x £ X we have x < £ ° X , hence a (x) < so ~Y^1 XIEX ® E) — ' ' ' ( l ^ 0 ^ ) - For a calculation that handles both let y = J^ X. Then y>a£So
y>a£So
- E1
a I V^ ( V^
u) I
5*o is dense in Q3o
j/>oes 0
(y ((
/ ,
i/>aGSo xEX a-x>u£So
^ ( u )))
" i s completely additive
5. BOOLEAN ALGEBRAS
°"(w))
( \J
see
note (a) below
Note (a): If x £ X then y > x, so the condition i > u 6 5o is equivalent to the existence of some a such that y > a £ So and a x > M £ SoProof of (viii): The key calculation, suitably altered:
since So is dense in 23 o 2J
a(ui +
\-um)))
since a is completely m-additive
=
E
(
E
ff{ui-\
h«m))
= E 1 ( E 1 "(«)) Ei,...,i m £X a;iH
h^m>wG5o
since So is closed under + =
^2
O-(Xl ~\
him)-
Proof of (ix): This part follows from Th. 199, but we also repeat the proof of that theorem in current notation. Since So = At^&o, we have
°(x)=
E
a a
()
for every x £ Bo. Assume X C Bo and Yl° X exists. Then
E 1 -(«)
19. COMPOSING EXTENDED BOOLEAN OPERATORS
y xeX
y
a (a)
see note (b) below
x>a£At
xdX
Note (b): Use the law E ^ U * ) = E 1 ( E 1 **) Proof of (x): This part generalizes the previous one, and its proof is essentially the same. Assume 0 < m £ w, every element of So is of height m, X C _B0, and E ° X exists. Then
a
(°)
a (a) v 7
the height of elements of So is m see note (b) above v7
D The hypothesis that So is dense cannot be omitted from part (viii). Suppose ©o is the 4-element Boolean algebra with universe Bo = {0,a,6,1}, 23i = 23o, So = {1}, and a is the identity on So- Then a is additive but a is not additive (and not completely additive) since
° (°) = y,
a (x) = V 0 = o = a- (6),
a (a) + a (6) = 0 ^ 1 = a (1) = a (a + b) . Part (iv) is no longer provable if complete additivity is replaced by additivity. It is possible that So is dense and a is additive, but a is not additive. Suppose ©i = ©o = 931 (w) = the Boolean algebra of all subsets of u, and So is the set of finite and cofinite subsets of a;. Suppose a maps the finite sets to 0 and the cofinite sets to OJ. Then a is additive but not completely additive. Partition w into two infinite sets x and y. Then the only elements of So included in x are finite sets, which are all mapped to 0 by a and join only to 0, hence a (x) = 0 = a (y), but the join of x and y is w, which contains all elements of So, so a (x + y) = a (UJ) = u. 19. Composing extended Boolean operators We now consider a sequence of maps among different algebras. The dependence of a and a on the underlying algebras and sets will have to be deduced from context. For example, the symbol ^ is used in the next theorem in three different ways.
5. BOOLEAN ALGEBRAS
Theorem 222. Assume Q30,Q3i,*B2 £ BA, So C Bo, Si C Bi, <8i and Q32 are complete, a : So —> Si, and r : Si —> B2:
_ B2
^ B2
Then (i) f(a (x)) < (alr^x) and f (a (x)) > (O-\T)~(X), for every x £ Bo(ii) Assume (a) So is closed under , (b) Si is meet-compact, (c) cr and T are monotonic. Then, for every x 6 Bo, (O"|T)~(:E) = f (a(x)). (iii) Assume (a) So is closed under + , (b) Si is join-compact, (c) a and T are monotonic. Then, for every x 6 Bo, (
:x
since this inclusion implies
r (?(«))=
If
r
S(x)
W ^ IT T(ff(a)) = H r » ) . x
Assume x < a 6 So. Then a (x) < a (a) < a (a) by Th. 221(i)(ii), and a (a) e Si, so a (a) £ {6 : o (x) < b € Si}, hence T (cr (o)) £ {T (6) : a (x) < b £ Si}. Similarly, for the other inclusion it suffices to show that (5.63)
{r (cr (o)) : x > a £ So} C {r (6) : a (x) > b £ Si}.
To see this, consider T(a(a)), where x > a 6 So- Then
f(a(x))=
Y?
r
(6)^E
2
r{a{a)) = {a\r)-{x).
19. COMPOSING EXTENDED BOOLEAN OPERATORS
281
Proof of (ii): It suffices to show that, for every x € A, every member of {r(b) :a{x) < b £ Si} is greater than or equal to a member of {T (
: x < a € So},
since this implies
r(a(x))=
^
T b
( ^ I T r(a(a)) = (a\rr(x).
S(x)
z
Accordingly, consider an arbitrary element of the first set, say T (fo), where a{x)= Y^
cr{a)
x
Note that {a (a) : x < a E So} is a subset of Si. By compactness of Si, there is a finite subset of {a (a) : x < a £ So} whose meet is included in b. So there is a finite subset F of {a : x < a € So} such that n 1 <**(F)
a(c) = a (H° F) KH1 a*(F)
(a (a;)) = r
since f is completely m-additive ^2
r(
h«r(am))
;>ai,...,a m G5o
since f and r agree on Si, Si is closed under +
since a and r are monotonic, Si is closed under + D
The next theorem is simply a binary version of the previous one, and has essentially the same proof.
282
5. BOOLEAN ALGEBRAS
Theorem 223. Assume 23o, 93i, 232, 233 £ BA, So C Bo, Si C Bi, S2 C B2, a : So -> Si, T : So -> S2, /3 : Si x S2 -> B3, Let 7 = H P " 1 n T I Q " 1 ) ^ .
(i) Then P(a (x),?(x)) <j(x) and f3(a (x) ,f (x)) >j(x) for all x € Bo. (ii) Assume (a) So is closed under , (b) Si and S2 are meet-compact, (c) P, a, and T are monotonic. Then, for every x € Bo, /3(
{P(a(a),r(a))
: x < a € So} C {/3(6) : {5(x),?(x))
< b £ Si x S2}
since this inclusion implies
p(B(x),?(x))=
^
/W)^ II 3 P(*(a),T(a))=j(x).
(9(x),?(x))
x
Assume x < a € So- Then a (x) < a (a) < a (a) and f(x) < f(o) < r (o) by Th. 221, so ( O - ( O ) , T ( O ) } € {b: {a(x),?{x))
< b € Si x S 2 } ,
hence P(a (a), r (a)) € {P(b) : < 6 £ Si x S 2 }. Proof of (ii): It suffices to show that, for every x £ Bo, every member of {P(b) : {a (x) ,T (x)} < b £ Si x S2} is greater than or equal to a member of {P(cr (a) , T (a)) : x < a € So} since this implies
P(a(x),f(x)) =
f]3 (9(x),T(x))
M)^ IT3 /3(«r(a),r(a))=7(x). x
Consider an arbitrary element of the first set, say /3(6i, 62), where
{a(x),?{x)) = / n ' ff(°)> I I 1 r(a)\ < (61,62) £ Si xS 2 . Note that {cr (a) : x < a G So} and {T (a) : x < a € So} are subsets of Si. By compactness of Si, there is a finite subset of {a (a) : x < a £ So} whose meet is included in 61, so there is a finite subset Fi of {a : x < a £ So} such that
20. EXTENDING OPERATORS WITHIN A BA
n 1 cr*(Fi) < 61. Let a = H° Fi. Then x < a since Fi C {o : x < a G So}, and, since So is closed under , we also have ci 6 So- Since a is monotonic, it follows that a (ci) = a (Y[ Fi) < Y[ °"*(-Fi) < &i- Similarly, there is some C2 G So such that T (c2) < b2, so (a (a), T (C2)> < {bi,b2), hence /3(
x>aES0
^(( C T ( a i) i r ( a i ) ) H
E
\- {cr{am) ,T(am)))
x>ai ,...,am £5o
since J3 is completely m-additive
since fi and /5 agree on S\ x 52, 5i x 52 is closed under + x>a£S0
since fi, a, and r are monotonic, Si x S2 is closed under + = 7(x). D 20. Extending operators writhin a BA Let 23O G BA. Assume that Q3o is complete. Assume 0 ^ So C Bo. Let (5.64)
C := {[[X : X C So} = H* Sb (So)
be the set of closed elements. All elements of So are closed (for if x € So then x = \[{x} and {x} C So). Let (5.65)
O:
be the set of open elements. All elements of So are open. Since they are also closed, they are clopen. Note that meets (in ©0 x Q3o) of subsets of So x So are elements of C x C, for if X C So x So, then Do (X), Ra (X) C So, hence n ° x ° X = ( n Do (X), n Ra (X)) e C x C, where n° X ° denotes meet in 23O x 23O. Therefore C xC = {[[0X0 X : X C So x So},
284
5. BOOLEAN ALGEBRAS
and, for similar reasons, OxO
= { ^ 0 X 0 X : X C So x So}.
Suppose that we have a binary operator on So, namely ft : So x So —> So, and a unary one, namely a : So —> So, and thus an algebra of Boolean type, namely {So, ft,0"). Extend a and /3 to open and closed elements (only, and not to all of Bo) as follows. For all closed x, y € C, let
(5.66)
a[x):=
\[ a (a),
ft{x,y)
:=
x
\[
0(o),
{z,y)
and, for all o p e n x,y 6 O, let (5.67)
a (x) := y^ a (a),
ft(x,y)
:=
^^
/?(a)-
Another way to say this is that
Y[
a(a) :x € C ) ,
x
ft:=(
f]
ft(a,b):{x,y)€CxC),
\{x,y)<{a,b)eSoxSo
x>aeS0
E
ft(a,b):{x,y)eOxo\.
So is closed under a, so the cr-image of a subset of So is a subset of So, hence the meet of the cr-image of a subset of So is closed. This shows that C is closed under a. Similarly, C is closed under ft, and O is closed under both a and ft. Therefore d-.C^C,
/3:CxC^C,
a-.O^-O,
ft.OxO^fO.
In this situation there are three algebras of Boolean type, namely (So,ft,(r), (C,ft,a} and (O,ft,a'). Thus ft and a generate a clone on So, ft and a generate a clone on C, and ft and a generate a clone on O. The next theorem is stated for Boolean algebras with a single binary and a single unary operation (with a distinguished element of So thrown in), but it holds for any number of operations of any (finite) rank. The first two parts follow from the earlier theorem that the operators and their extensions agree on SoTheorem 224. Assume Q30 G BA, «B0 is complete, 0 ^ So C Bo, ft : So x So —> So, ft is monotonic, a : So —> So, a is monotonic, and i E So- Define O, C, a, ft, a, and ft as m (5.64), (5.65), (5.66), and (5.67). (i) {So,ft,
21. PRESERVATION THEOREMS FOR COMPLETE EXTENSIONS
285
(ii) (So,/?,
vf = Pi n An+1
vf = P2 n An+1
(«(«i)) a = (Pi n An+1)\a
= Pi n cn+1
vi = P 2 n cn+1
(u(v!)f = (Pi n cn+1)\d
vf
so, by Th. 222 and Th. 223,
= = = =
((((Pi n A n+1 )|a)|p- 1 n (p2 n ^ n+1 )|Q (((Pi n A n + I )i5)|p- 1 n (P2 n An+1)iQ-1)|/3 (((Pi n cn+1)\a)\p-1 n (P2 n c n+1 )|Q- 1 )|/3 (b(u(v1),v2)f
Suppose an equation (to,*i) is valid in 21, where to,ti £ Fn, i.e., a t a = tf- Then (io,ii) is valid in C, since D
21. Preservation theorems for complete extensions Regarding the next two theorems see Monk [181, 1.9, 1.10], Givant-Venema [79, Cor. 31], Henkin-Monk-Tarski [93, Rem. 2.7.22]. Theorem 225. Assume 21, 25 € BA, 25 is a completion of 21, 0 : A2 -> A, a : A —> A, and I £ J 4 . Define O, a, and $ as in (5.65) and (5.67) with So = A. Then O = B and
286
5. BOOLEAN ALGEBRAS
(i) if (3 and a are monotonic, then (A,/3,a,t.) is a subalgebra of (B,(3,(T,L), (ii) if /3 and a are completely LJ- additive, then any equation which is valid in (A, (3, a, L) is also valid in (B, j3, a, t). Suppose that (^4, + ,~) is a Boolean algebra and 21 = {A, +,~,/3, a, ) is an We call such an algebra algebra of some type, where (3 : A2 —> A, a : A —> A, a Boolean algebra with operators (3, a, Note that we put no requirements on the operators. In particular, they need not be additive. Much of the literature differs in this respect from the convention adopted here. The algebra 231(21) := (A, +,~) is called the Boolean part or Boolean reduct of 21. Some terminology that applies to Boolean algebras will be extended to Boolean algebras with operators with the understanding that the terms apply to the Boolean part. Examples include atom, atomic, complete, and dense subset. Examples of notions for which we do not follow this custom are completion and perfect extension. The latter concepts apply to Boolean algebra with operators, but in those cases their meanings are supplemented with conditions that must be satisfied by the operators. Suppose that 23 = {B,+,~,j,T, ) is a Boolean algebra with operators and that 93 is similar to 21. We say that 23 is a completion of 21 if the Boolean algebra 231(23) is a (Boolean) completion of 931(21) and the operators of 23 are the upward extensions (taking So = A C B) of the corresponding operators of 21: 7 = /?,
T
= a,
Theorem 226 (Monk [181, 1.9], Givant-Venema [79, 31(i)]). 7/21 <= BA is a Boolean algebra with completely u-additive operators then 21 has a completion 21. Every equation that is valid in 21 and involves completely u-additive operators is valid in 21. For examples of non-preservation, see Givant-Venema [79, §4]. Theorem 227. Assume 21, 23 £ BA, 23 is a perfect extension of 21, /3 : A2 — A, a : A —> A, and i, £ A. Define C, a, and (3 as in (5.64) and (5.66) with So = A. Then At*B C C, and (i) if j3 and a are monotonic, then (A,/3,cr,i) is a subalgebra of (C,J3,a,LJ, (ii) if ft and a are monotonic, then any equation which is valid in {A,/3, a, i) is also valid in (C,t3,a,bj. Define O, j3 and a as in (5.65) and (5.67) with So = C, replacing j3 and a with (3 and a. Then B = O and (iii) (C,J3,(r,i) is a subalgebra of (B,j3,ct,i), (iv) (Jonsson-Tarski [118, Lem. 2.4], Henkin [91, Lem. 2.14], Jonsson [116, Lem. 2.2]) if 0 < m £ u, a is m-additive, Hm is the set of elements of height m, and x £ C, then
(v) if P and a are co-additive, then fi and a are completely co-additive,
21, PRESERVATION THEOREMS FOR COMPLETE EXTENSIONS
287
(vi) if (3 and a are completely u -additive, then any equation which is valid in (A, /3, a, i) is also valid in (B, J3,CT,I) . P R O O F . TWO key properties of 58 as a perfect extension of St are that (vii) if X C A and £ B X = 1, then Yf Y = 1 for some finite subset Y CX, (viii) if 0 ^ b, b' G At%$ then there is some a £ i such that b < a and b' a = 0.
It follows from (viii) implies that the atoms of 58 are closed, that is, At*8 C C = {JJX : X C A}, and (vii), the compactness of 1, implies both the joincompactness and meet-compactness of A. Indeed, if Yf6 X > a € A far some X C A and a G A, then ^ B (JfU{S}) > a + a = 1, so by (vii) we have jf* Y = 1 for some finite subset Y C XU{5}, hence 53 (^ ""{<*}) ^ & a n ( i ^ ~{5} is a finite subset of X. If the operators j3,a are monotonic, then by Th. 224(i), {A,fl, a, t) is a subalgebra of (C,f3,a,i), and, by Th. 224(iii), every equation that valid in (A, /3, a, i) is also valid in {C, /3, a, i). Every element of OS is the join of atoms of 58, all of which are in C, so B = O. By Th. 221(i), /3 and ff are monotonic, so (C,0,ff,i) is a subalgebra of (B,P,&,i) by Th.224(ii). Assume 0 < m 6 w, a is ro-additive, Hm is the set of elements of height m, and x G C. We show next that
Prom just the monotonicity of a we get one inclusion, namely
Since ?8 is atomic it suffices to show that every atom of © below cr (x) is also below the join on right hand side. So assume p € At%$ and p < <x (a;). Let 0" = {a ; a: < a 6 A} and F = {a : o e A, p < f f (a)}. Note that U CV C.A and E7 is a filter, although V need not be closed under . Choose a filter W C A that is maximal with respect to the property that U CW CV, and let w = ]J W. We will show that x > w g i? ra and p < a (w). Since a; is closed, x = ]J U, so from U C W, we get z = Y[U ">JJW = w. For every a e A such that tw = f[W < a there is, by the meet-compactness of A, a finite subset E C W such that [ J E < o , so that if e = Y\E then e < a, and e € W since W is closed under , hence also a (e) < a (a) by the monotonicity of a. Therefore,
What remains is to show that w has height m. Suppose w contains m + 1 distinct atoms of 35. Then it can be shown, using (iv), that there is a set Z of m + 1 pairwise disjoint elements of A with J^ Z = 1 and w z ^ 0 for every z € Z, For every z € Z, we have I £ A, and ~z $ W, for if z € W, then 7 > n W = w, so0 = 2 - 2 > 2 : - w . By the maximality of W, there is some yt G W such that 0 = p a {ys 1). Let y = Ylsez
yB £ W, so that 0 = p a (y). For every z G Z
5. BOOLEAN ALGEBRAS
we have 0 = p a (y ^2{Z ~{z})) since y "^{Z ~{«}) < yz ~z- But then, by the m-additivity of a, we have zez so there is some z €. Z such that p < a (y ^2{Z ~{z})), a contradiction. Thus w G Hm- It follows from (iv) that, for every b G B, b x w
v( )= Yl °( )= Y b>x£C
b>x>w£Hm
${w)= Y °( )' b>weHm
and so a is completely m-additive by Th. 221(x). If j3 and a are w-additive, then J3 and a completely w-additive and agree with /3 and a on C, so, by Th. 224(v), any equation valid in (A, /3, a, i) is also valid in {B, J3, IT, t). D Suppose that (^4,+,~) is a Boolean algebra and 21 = {A, +,~, (3, a, is an algebra of some type, where j3 : A2 —¥ A, a : A —> A, , and 25 = {B, +,~,7,r, ) is another Boolean algebra with operators that is similar to 21. We say that 03 is a perfect extension of 21 if the Boolean algebra 031(03) is a (Boolean) perfect extension of 231(21) (see p. 273 and p. 274) and the operators of 23 are obtained from those of 21 in the manner described in Th. 227, that is, 7 = /3, T = a, etc. Citations for the following theorem are Jonsson-Tarski [118, 2.15, 2.18], Henkin [91, 3.8], Jonsson [116, 3.11] Theorem 228. // 21 is a Boolean algebra with ui-additive operators then 21 has a perfect extension. Every equation that is valid in 21 and involves Lv-additive operators is valid in every perfect extension o/2t. Jonsson [116, Ex.3] mentions that a (x) =x => K = 0 is not preserved in the passage from an algebra to a complete extension of that algebra. A similar example x=0 Vx=l Vx=V. This is true in the from Kramer-Maddux [124] is x;x < x finite-cofinite subuniverse of the complex algebra of a countable Abelian group, but fails in every complete extension. See also Jonsson [116, Ex. 2].
CHAPTER 6
Relation algebras 0.1. Equational axioms Ri Rio. We say that 21 is a relation algebra if 21 is an algebra of relational type, i.e., there are sets + , " , ; , " , ! ' € V such that 21 = {A,+,-,;,",V),
+:A*-->
1' e A ,
; : A
2
A,
: A -> A,
--> A,
" : A —> A,
and for all x, y,z £ A, Ri
R2
R3 R4 Rs Re RT Rg
R9 Rio
x + y = y + x, x + (y + z) = (x + y) + z, x + y + x + y = x, x;(y;z) = {x;y);z, (x + y);z = x;z + y ; z , x;V
=x, X =
X,
(x + yY = x + y, \^',y)
— y\^i
X-gyy + y = y
+- commutativity +-associativity Huntington's axiom ;-associativity ;-distributivity identity law "-involution "-distributivity "-involutive distributivity Tarski/De Morgan axiom
Let RA be the the class of relation algebras. Identities R1-R3, due to Edward V. Huntington [104, 105], assert that the Boolean reduct of 21 is a Boolean algebra, so that 21 is a Boolean algebra with operators. If R1-R3 are valid in 21, then the law of double negation, x = x, is valid in 21. The definition of relative addition and the law of double negation have these three consequences:
Axiom R5 asserts that the operation ; distributes over + from the right, while distributes over + according to Rg. Axioms R4, R6, R7, R9 assert that the relative part of 21 is a monoid with a special unary operation (with no particular name, so far as I know). Axioms R4 and R6 say that {A, ;, 1') is a semigroup in which 1' is a right identity element. With the help of R7 and R9, it can be shown that 1' is also a left identity, so (^4, ;, 1') is actually a monoid. Axiom R6 could be extended to assert that 1' is an identity element. The resulting axiom set would be more symmetrical but also more redundant.
290
6. RELATION ALGEBRAS
Axiom Rio is equivalent to x;x;y < y, since < is defined so that x < y <S> x + y = y. Rio is also equivalent to x;xjy y = 0, but proving this requires the help of R1-R3. Rio is the link between the Boolean and relative parts of 21. As we shall see, it follows from R1-R3, R7, Rg, that J is an additive operator on the Boolean part (A,+,~), that " is self-dual (x = x), that " is self-conjugate (x y = 0 iff x y = 0), and that """ is, in fact, an isomorphism of the Boolean part onto itself that preserves all joins and meets. 0.2. Duality. Because relation algebras have Boolean algebras as reducts, the principle of duality for Boolean algebras also applies to relation algebras. If (A, +,~) is a Boolean algebra then (A, -,~) is also a Boolean algebra, called the Boolean dual of (^4, + , ~ ) . Every Boolean algebra is isomorphic to its Boolean dual via the map that takes an element to its complement, ~~ : A —> A. All this is due to R1-R3. Adding R7, Rs, Rg, produces another form of duality, called converse duality, from which it follows that an equation involving ; is satisfied iff the corresponding converse dual equation is satisfied. The converse dual equation is obtained from the given equation by replacing terms of the form x\y by y;x. For example, if R5 holds in 21, we conclude that 21 also satisfies x;(y + z) = x;y + x;z (the converse dual of R5), and if R6 holds in 21, then 21 also satisfies V ;x = x (the converse dual of Re). There are in total four duality principles. The last one is Boolean converse duality, which combines Boolean duality with converse duality; see Th. 319. 0.3. Proper relation algebras satisfy axioms R-i— R,io- For the next theorem, recall some definitions from §3.11. The Boolean algebra of subsets of U is m(U):={Sb(U),Uu,-u), the square relation algebra on U is 9te (U) := (Sb (U2) , U C 7 2 , - c / 2 , \V2, - ^ , U1), and the equivalence relation algebra on E is 6b (E) := (Sb (E), UE,-E,
\E,
~1E, Id n E) .
An algebra 21 of relational type is a proper relation algebra if 21 is a subalgebra of an equivalence relation algebra, and 21 is a representable relation algebra if it is isomorphic to a proper relation algebra. RRA is the class of representable relation algebras. The next theorem shows that these names are appropriate. Theorem 229. Every square relation algebra, every equivalence relation algebra, every proper relation algebra, and every representable relation algebra is a relation algebra, that is, (6.1)
Vf/(t/G V => me(U) G RA),
(6.2)
ME{E\E~l =EE V => 6b (E) 6 RA),
(6.3)
RRA C RA.
1. BOOLEAN RELATION ALGEBRAS
291
1. Boolean relation algebras The next theorem shows how every Boolean algebra can be extended to a relation algebra. Theorem 230. Suppose 03 = (B,+,~) e BA is a Boolean algebra with unit element 1. Define a binary operation ; on B and a unary operation " on B by letting x;y = x + y = x y and x = x for all x,y G B, i.e., ; = and " = B1. Then {B, +,~, ;, ", 1) is a Boolean relation algebra whose Boolean part is 03. PROOF. It is easy to check that the equations Ri-Rio and 1 = 1' are all valid i n ( B , + , - ;B\1).
We refer to the Boolean relation algebra (B, + , ~ , , B1, l) obtained from 03 € BA as the Boolean relation algebra of 03. Th. 230 provides a useful testing ground. For example, no equation can be derived from Ri-Rio unless the equation obtained from it by deleting " and replacing ; with and 1' with 1 is valid in all Boolean algebras. An algebra of relational type is Boolean if 1' = 1 (see also p. 294). Boolean relation algebras satisfy the following three identities: x;y = x y, x = x, and 1' = 1. Note that these identities together assert that the underlying relation algebra to which they refer is obtained from its Boolean part by the construction of the previous theorem. Theorem 231. The Boolean relation algebra obtained from 03t(f7) is isomorphic to &b (U1). PROOF.
The Boolean relation algebra obtained from 03[([7) is 21 := (56 (U), \Ju,~u,nu, (56 (U))\U) ,
and &b (U1) = {Sb (U1) ,Uvi,-ui,\ui,
~lv\Ul).
What remains is the (relatively simple) verification that the function (-)1 := (X 1 : X C U) , which sends X to X1 whenever X € 56 (U), is an isomorphism from 21 onto 6b (U1). D Theorem 232. Every Boolean relation algebra is representable. PROOF. Let 21 = (A, ) G RA be Boolean, so 1' = 1. By Th. 218, we know that 03t(2l) is isomorphic to a subalgebra of 23I([/) for some set U G V. The Boolean relation algebra of 03I(f7) is representable by Th. 231, and (as can be easily checked) it has 21 as a subalgebra, so 21 is also representable. For a more direct proof, one which enfolds the ultrafilter construction of a perfect extension, check that the map V
= ({(F, F):xeFe 1
embeds 21 into 6b (([//03) ).
E//21} : x e A)
282
8, RELATION ALGEBRAS
2. Group relation algebras An algebra 0 = (G, o, ~1, e) of group type is called a group if, for all x, y, z 6 G, (x o y) a z = x o (y a z)
o is associative
e o j = a; = 3;oe
e i s a n identity element for o
x~
OI=JOJ~
= e.
For every group (S there is a corresponding relation algebra whose universe is the set of all subsets of G. A subset of a group is called a complex (see Hall [87, p. 10]), so for every algebra © of group type, we let the complex algebra of (5 be the algebra (6.4)
Cm(e5):={S6(G),U,-,;,V}
where (Sh (G), U, ~} = 2$I (G) is the Boolean algebra of all subsets (or complexes) ofG, and, f o r a l l X , y CG, (6.5)
X;Y:={xoy.xeX,yeY},
(6.6)
X := {a;"1 : x € X},
(6.7)
1' := {e}.
We say that 21 is a group relation algebra if 21 is isomorphic to a subalgebra of a complex algebra of some group ©, that is, if Let GRA be the class of group relation algebras: GRA := IS{£m (&) : G is a group}. Parts of the following theorem originate with McKinsey, Jonsson, and Tarski; see J6nsson-Tkrski [119, 5.10-5.12]. Theorem 233. Let (8 = (G, o, ~1,es} be an algebra of group type. (i) The following statements are equivalent, (a) 0 is a group, (b) Cm (0) e RA, (c) £m(0)£*|C!Ke(G). (ii) Every group relation algebra is representable, GRA C RRA. PROOF. For part (i)(c), assume <& is a group, and let Check that tx is an injective homomorphism that embeds €m (&) into £Fte (G). Note that if x G G then a ({x}) is the permutation {{g, g o x) : g £ G} used in the proof of the Cayley representation theorem for groups, which states that every group is isomorphic to a group of permutations. The Cayley representation has a property not required by the notion of representation commonly used in group theory, but which is required by the relation algebraic setting, namely, that the permutations associated with {a;} and {y} must be disjoint (as sets) whenever i / j / , simply
3, NA, WA, AND SA
293
because {x} n {y} = 0 and this fact must be reflected in any representation. Indeed, if (g, h) € {a;} n {y} t h e n h = go% = goy,
hence x = g~* o h = y,
D
Groups can also be defined as a kind of groupoid, but the axioms are accordingly more complicated. Indeed, one can say that © is a group if (a) 0 = (G,o), (b) o is an associative binary operation on G, and (c) 3eVa;(e a x — x — x o e /\3y(y o x — x o y = e)) for every i £ G , Under this definition, the complex algebra of <3 still has the form and the binary operation ; is defined as above, but the definitions of X and 1' require considerable rewriting, since ~x denotes an operation whose very existence is a nontrivial consequence of (b) and (c). 3. NA, WA, and SA We say that SI is a nonassociative relation algebra if SI is an algebra of relational type in which R1-R3 and R5-R10 hold. Let NA be the class of nonassociative relation algebras. The subclasses WA and SA of NA are obtained by adding special cases of associativity. We say that St is a weakly associative relation algebra if 21 € NA and, for all x 6 A, and that SI is a semiassociative relation algebra if 2t € NA and, for all x 6 A, Let WA be the class of weakly associative relation algebras and let SA be the class of semiassociative relation algebras. Equation (6.8) is the weak associative law, which appeared earlier as equation (0.2). Equation (6.9) is the semiassociative law. It appeared earlier in (0.1) and was formalized in (1.76). The same name was also applied to (the formalization of) one its consequences, namely (BIV'). By Th. 275 below the equation 1;1 = 1 holds in every NA, so we could use simpler equations that are not special cases of associativity to define WA and SA, such as (6.10) (6.11)
((a:-r);l);l = (a:-r);l, (a;;l);l = a;;l.
Furthermore, the equation (a;;l);l > a;;l is valid in NA, so (6.9) could even be replaced by (a;;l);l < x;l. The converse duals of these equations can also be used; see Th. 276. Theorem 234 (Maddux [139, 7(1), 8(1)]). (i) NA, WA, SA, and RA are finitely based equational classes.
(ii) IfK is NA, WA, SA, or RA, then K = \K = SK = HK = PK. (iii) RA C SA C WA C NA.
284
8, RELATION ALGEBRAS
For part (iii), note that (6.8) is a special case of (6.9) and (6.9) is a special case of R4. All the inclusions in part (iii) are proper. McKinsey's algebra (p. 357) is in WA but not in SA. For other algebras in WA~ SA, see Th. 368 and Th. 447. For an algebra in NA that is not in WA see §27. For algebras in SA that are not in RA see Th. 448. We will define some special properties of algebras that, although most meaningful for nonassociative relation algebras, apply whenever SI = {A,+,~,;, w ,l'} is an arbitrary algebra of relational type. We say that the algebra 21 is trivial if |A| = 1, Boolean if V = 1, commutative if x;y = y;x for all x,y € A, and symmetric if x = x for every x G A. An element x G A is a zero-divisor if x ^ 0 there exists some y € A such that y ^ 0 and x;y = 0. The algebra St is integral if it is nontrivial and has no zero-divisors. None of these properties follows from the axioms R1-R10, as shown in the following theorem. Theorem 235. (i) 9te (0) and 9te (1) ore Boolean, symmetric, commutative, and have no zero-divisors. (ii) JRe (0) is trivial and not integral. (iii) 9te (1) is nontrivial and integral. (iv) If U E V is a set with two or more elements, then 9te (U) is nontrivial, not Boolean, not symmetric, not commutative, and not integral, and 9te (17) has zero-divisors. The next theorem summarizes what can be said with equations in !Ee (17) about the cardinality of the underlying set U. Theorem 236. Let U e V be a set.
(i) \U\ = 0 iffme(U) \= 0 = 1 iffme(U) |= 0 = 1'. (ii) jj/j < 1 iff^t{U) |= 0 = 0' iff^t{U) \= V = 1. (iii) |J7| < 2 iff «e(Z7) |= 1' = 0';0\ (iv) \U\ < 3 iffme(U) \= 0 = 0' 0 ! ;0\
4. Special kinds of elements Here we define many different kinds elements in an algebra of relational type. Some of the definitions are simply algebraic translations of standard set-theoretical definitions. For an extensive study of various kinds of elements in relation algebras see Chin-Tarski [49]. Let us consider a fixed but arbitrary algebra of relational type 21 = (A, +,~,",, ", 1!), and an arbitrary element x 6 A. 4.1. Domain, range, ideal, square, rectangular. (6.12)
Dm% := {x : x; 1 = x G A},
(6.13)
RnVL:={x:l;x =
(6.14)
x€A},
l e a := {a; : x;l = l;x = x€A}
= DmSin RnSi.
- x is a domain element or right-ideal element if a; € Dm 21, - x is a range element or left-ideal element if x € i?«2l, - x is an ideal element if % £ leSl,
4. SPECIAL KINDS OP ELEMENTS
298
- x is a square if x = x; 1;ai, - x is a rectangle if a; = x;l]x. The domain and range elements of 3te (U) are the relations of the form X x U and U x X, respectively, where X C U, Domain and range elements in 9te (U) are thus entirely determined by their domains and ranges, and provide two (out of many) algebraic ways to refer to sets via relations. The only ideal elements of 9te(?7) are 0 and f7a. For every equivalence relation E, the ideal elements of &b (E) are the unions of direct squares of equivalence classes of E; l£le&b(E) o I = E\I\E O / =
(6.15)
\J
(x/E)2.
The squares of 9U (U) are relations of the form X x X with X C U, and the rectangles of JRe (U) are relations of the form X x Y with X, Y C U. See Jonsson [114] and Givant [76] for extensive studies of squares and rectangles. 4.2. Reflexive, symmetric, transitive, equivalence. Rf%:={x:x;(V
x) = (V x)\x = x € A},
%Sl := {a; : x < x £ A}, Tr%:= {x : x;x < x € A}, -
m is x is x is a; is x is x is
reflexive if x £ ii/Sl, symmetric if a; € SrSt, antisymmetric if x x < 1', symmetric-reflexive if x £ SrSl, transitive if a; € TVSt, an equivalence element if x £
R is a reflexive, symmetric, transitive, or equivalence element of fUe (U) iff R C V2 and H is a reflexive, symmetric, transitive, or equivalence relation, respectively. In case SI is a relation algebra, we could use an alternative definition of Tarski-Givant [225, p. 110], that x is reflexive iff 1' (x;l + l;x) < x. 4.3. Functional, permutational, difunctional. Fn3l:={x:x-(x}V) Pm% :={x:x-
= x £ A}, 1
(^f ') = x (V }x) = x e A},
- x is functional if a; 6 -FnSt, - x is permutational or bifunctional if a; € Pm%, - x is difunctional if x = x;x;x. R is a functional element of !He (U) iff R : X —¥ U for some X C.U. For nonassociative relation algebras, an alternative definition of functional element is that x £ i*Vi2l iff x;x < 1', and x is permutational if both a; and x are functional. Regarding difunctional elements, see the remarks after Th. 299.
296
6. RELATION ALGEBRAS
4.4. Atoms, subidentity. Atoms are defined for an algebra of relational type in the same way as for their Boolean reducts; see (5.27). (6.16) (6.17) (6.18)
Am : = { i : 8 / i e 4 , Vj,(y £ A => x
x-y = 0)},
: V >x £ AM},
Ato,%:={x:O'>x
- x is a subidentity element if x < V, - a; is an atom if a; € At%L, - a; is an identity atom if x < 1' and x £ - x is a diversity atom if a; < 0' and x £ At 21. When the Boolean part of 21 is a Boolean algebra, the domain xA and range a;r of an element (see (3.5)) are examples of subidentity elements, and if 21 is also Boolean, then all its elements are subidentity elements. 4.5. Singletons, points, pairs, twins. Sn%l : = {x : 0 / a ; £ A, a;;l;a; + a;;l;s; < 1'}, Pt2l := {x : 0 / x £ A, x;l;x < 1'}, Pr2l:= { i : 0 / s £ A , i ; 0 ' ; i ; ( l ' ; i ; < r } , TwVL := {x : x £ Pr% x y = 0 for every y £ Pt2l}. - x is a s i n g l e t o n i f O ^ a ; ; l ; a ; + a : ; l ; a ; < 1', - x is a point if 0 7^ a;; 1; x < 1', - x is a pair if 0 / a;; 0'; a;; 0'; x < V, - x is a twin if a; is a pair and x y = 0 for every point y. Some relations contain exactly one ordered pair. Such a relation is a set-theoretical singleton, having the form {(a,b)} for some a, 6 £ V. A relation is a singleton in IHe (U) iff it is a set-theoretical singleton and included in U2. A relation R in D\c (U) is a point iff R = {{a, a)} for some a £ U. A relation R in D\c(U) is a pair iff R = {(a, a), (6,6}} for some a,b £U (possibly with a = b). SHe (U) has no twins, but if we suppose that 21 is a subalgebra of SHe (U) and that R is a relation in 21, then R is a twin of 21 iff R = {{a, a), {b, b)} for distinct a, 6 £ U, and neither {(a, a)} nor {(6,6}} are elements of 21. Thus a and b are "twins" in the sense that they cannot be distinguished by 21. Let E £ V be a nonempty equivalence relation. Recall from (3.102) that PE = {p:PCE = E\p\E, p\E\p C Id}. In case E = U2, we have PE = Pt%. If E has at least two equivalence classes, then PE C Pt2l. 5. Axioms R7, Rs In this and the next several sections we deduce consequences of various combinations of axioms drawn from R1-R3, R5-R10 (the axioms for NA). In each theorem our tacit assumptions are that we are dealing with a fixed but arbitrary algebra 21 of relational type and x, y, and z are arbitrary elements of 21. For each theorem we assume that 21 satisfies one or more of the axioms R1-R10 and list those assumptions in parentheses at the beginning of the theorem. Each section
5. AXIOMS R 7 , R g
297
is devoted to some combination of axioms from R5-R10. First we consider what can be deduced from the chosen axiom or combination alone, and then what can be proved by also assuming R1-R3. In this section we show that an additive involutive function from a Boolean algebra to itself is nionotonic, self-conjugate, normal, dual-normal, self-dual, subtractive, completely and universally additive and multiplicative, and is a complete isomorphism of the Boolean algebra onto itself. We do this by proving consequences of R7, which states that " is involutive, and R8, which states that " is additive. Consequences of R7 alone are that conversion is one-to-one and onto, and the domain and range functions behave properly with respect to conversion. Theorem 237. (R7) x = y iff x = y. PROOF. If x = y then x = y. For the opposite direction, assume x = y. Then x = y, but x = x and y = y by R7, so x = y.
For the next theorem recall definition (3.5). Theorem 238. (R7) xd = xr and x' = xd. PROOF. xd = 1'
x;x = 1'
x;x = x' and x' = V
x;x = V
x;x = xd.
In the next theorem we show (again) that an additive operator is nionotonic. Theorem 239. (R8) (i) If x < y then x < y. (ii) If x € Sy% then x € Sy%. PROOF.
For part (i), x < y <S> x =>
<=> X
«
definition of <
y 5 + 2/)" = y + y =y
Rs
definition of <
(a
X
For part (ii), x 6 SySl <=>
X < X
definition of <
X+ X = X (~.
1 ™
" =
X+ X = X
<=> X
< X
x
R8
definition of <
x e Si1% D Theorem 240 (Chin-Tarski [49, 1.8]). (R7, R8) x < y iff x < y.
38
6. RELATION ALGEBRAS
PROOF.
x
=> x
Th. 239
=> I < §
Th. 239
>x
R,7
D Theorem 241. (R7, Rg) x < y iff x
Substitute x for x in Th. 240 and use R7.
The next two theorems show that " is normal and that the Boolean dual of is also normal. Theorem 242 (Chin-Tarski [49, 1.6]). (R1-R3, R7, R8) 0 = 0 G Sy%. PROOF.
0 = 0+ 0
R1-R3
= 6+ 6
R7
= (0 + 0)"
R8
= 6 = 0
R1-R3 R7 D
Theorem 243 (Chin-Tarski [49, 1.7]). (R1-R3, R7, R8) 1 = 1 G Sy2L. PROOF.
1 = 1+ 1 = 1+ 1 = (1 + 1)" = 1
R1-R3 R7 Rs Ri—R3 D
Next is the Boolean dual of the assertion that " is self-conjugate. Theorem 244. (R1-R3, R7, Rg) x + y = 1 iffx + y = l. PROOF.
If x + y = 1, then x + y = x + ij = (x + y)" =1 = 1
R7 R8 x+y=1 Th. 243
5. AXIOMS R 7 , R 8
299
From (5.17), Th. 179, and Th. 244, we get the following corollary. Theorem 245. (R1-R3, R7, Rs) The following statements are equivalent: x
y>x
x+y=y
x+ y=x
x+ y=1
x >y
V< x
x y=y
x-y = x
x y =0
x < 2/
y>x
x+y=y
x+y =x
x+y =1
The previous theorem could include several more statements since, as we see next, complementation and conversion commute. Theorem 246 (Chin-Tarski [49, 1.10]). (R1-R3, R7, Rs) I = t . PROOF.
First note that, for any y, x~
Th. 241 Th. 245
We need only two instances of these equivalences. When y is either x or x, we deduce that x < x and x < x, respectively, hence x = x. It follows from Th. 246 that " is self-dual. The multiplicativity of " is next. Theorem 247 (Chin-Tarski [49, 1.9]). (R1-R3, R7, Rs) (x yY = x y. PROOF.
(3-4)
(x -yY = (x + yY = (x + yY
Th. 246
= §"+1
Rs
= x+y
Th. 246
= x-y
(3.4)
The next theorem shows that conversion is self-conjugate. Theorem 248. (R1-R3, R7, Rs) x y = 0 <£> x y = 0. PROOF.
x y = 0 <^> (x yY = 0
I y=0 > x
y = 0
R7
Th. 242, Th. 247 R7
D By Th. 208(ii), self-conjugate functions on Boolean algebras are completely additive, so " is completely additive when R1-R3, R7, Rs hold. A slightly different proof of this follows.
300
6. RELATION ALGEBRAS
T h e o r e m 249 (Chin-Tarski [49, 1.11]). (R1-R3, R7, Rg) The operator " is completely additive. PROOF. Assume X C A and J ^ X exists. We will show that ($^X)" is the least upper bound of {x : x E X } . Since x <^X for every x E X, Th. 239 implies x < ($^X)" for every x G X. Thus (52 X)" is an upper bound. Now let y be any upper bound, i.e., x < y for every x G X. Then Th. 241 implies x < y for every x € X, so y is an upper bound of X, i.e., J ^ X < y. But then (%2X)" < y by Th. 241, so ($^X)" is the feast upper bound. T h e o r e m 250 (Chin-Tarski [49, 1.12]). (R1-R3, R7, Rs) The operator " is completely multiplicative. On the basis of theorems proved so far we can say that is a complete Boolean isomorphism, and that this can be deduced solely from axioms R1-R3, R7, Rg. One consequence of this observation is that " maps atoms to atoms, an observation first made for relation algebras by Jonsson-Tarski [119, 4.3(xii)]. T h e o r e m 251 (Maddux [142, 3.4]). (R1-R3, R7, Rg) If x G AM then x G
AM. PROOF. Let x G AM. Then My(y £ A => y < xV x y = ti) and x ^ 0. Prom the latter we x ^ 0 by Th. 242, while from the former we obtain Vy(y E A => y < x V x y = 0) by Th. 241 and Th. 248. Hence x E AM. D Summarized next axe those properties of symmetric elements that are derivable from R1-R3, R7, and Rg. T h e o r e m 252. (R1-R3, R 7 , Rs) (6.19)
x G Sy%
x = x,
(6.20)
0,lESy%
(6.21)
x + xeSy%
(6.22)
Sy% = Ra({x + x : x £
(6.23)
x E Sy% => x E Sy%
A)),
(6.24)
x € Sy'A- ^ x €
(6.25)
x,y G Sy% ^ x + y G Sy%,
Sy%
(6.26)
x, y E 5j/St => x y E Sty21.
The last four items can be strengthened to the following equations:
(6.27) (6.28)
Sty2l+* Sy%=Sy% Sy**Sy*=Sy%
(6.29)
(Sy*r
(6.30)
5y2l = Sty 21.
= Sy%
6. AXIOM R 5
301
6. Axiom R,5 Axiom R5 says that for every z the function (-); z is additive. It follows that (-); z is also monotonic. The details can be given this way: T h e o r e m 2 5 3 . ( R s ) If x < y then x;z < y;z. PROOF.
x
definition of < R5 definition of <
T h e o r e m 2 5 4 . ( R 5 ) If x,y £ Dm% then x + y € Dm'A. P R O O F . If x = x;l a n d y = y;l t h e n x + y = x;l + y;l = (x + y);l b y R 5 ,
so x + y e Bm%. T h e B o o l e a n d u a l of R 5 a s s e r t s t h a t f is d i s t r i b u t i v e over
from t h e r i g h t .
T h e o r e m 2 5 5 ( C h i n - T a r s k i [ 4 9 , 1.16]). ( R 1 - R 3 , R s ) {x-y)\z
=
{x\z)-
(l/t*)PROOF.
(x
y)]z =x y ; z
definition of f
= (x + y);z
R1-R3
= x;~z-\-y;~z
R5
= 'x;^-y;'z
R1-R3
= (x f z) (y f z)
definition of f
D The next theorem requires, besides the Boolean axioms R1-R3, only R5 for its proof. It therefore leads to a considerable generalization of the modular law for normal subgroups; see Chin-Tarski [49, p. 356,383]. Its corollary, Th. 297 below, requires more axioms for its proof, specifically R7-RioTheorem 256 (Chin-Tarski [49, 2.18]). (R1-R3, R5) If x\z < x andx;z < x then x y;z = (x y);z. PROOF.
(x-y);z < x;z-y;z
Th. 253
<x-y;z
x;z < x, R1-R3
< x- (x-y + x);z
R1-R3, Th. 253
= x (x y ) \ z + x x ; z
R5, R1-R3
= x (x -y);z
~x\z <~x, R 1 - R 3
8, RELATION ALGEBRAS <(x-y);z
Ri^Rs
7. Axioms R7, Kg, R 9 Theorem 257. (R8, Ri0
(i) Ifx e !7Va then x 6 TrVL. (ii) IfxeEgSL then xG Eq%. PROOF.
For part (i), x G Tr% & x; as <x definition of <
=J. x; a; + X = X
=> (x;s
+ xY = x w
= > ( s n ;a;) + x — x
Rs
X + X =X
R9
definition of <
=* as; X < X
Part (ii) follows from the first by Th. 239. Theorem 258. (R7, R8, Rg)
(i) Ifx,y G Sy%. then (x;y G Sy%. O i ; y = y;x). (ii) Every symmetric NA is commutative. PROOF, (i): Suppose x,y e SySi. By (6.19), 1 = x and j / = y. If x;y 6 SySI then, by (6.19) and R9, x;y = (x;y)" = y;a1 = y;x. Conversely, if x\y = y;x, then (*;»)" = »;* = Vix = xWi s o X\V 6 5ySt(ii): If 21 G NA and SI is symmetric, then %2l = A, hence SI is commutative by part (i).
If R7 and Rg hold, then is a complete Boolean automorphism, so the Boolean dual of Rg holds whenever R9 holds. Next is an elementary statement and computational proof of this fact. Theorem 259 (Chin-Tarski [49, 1.18]). (R1-R3, R7-R9) {x^y)" = y^st. PROOF.
(x f yY = (?\y~Y
definition of f
= (x;yY
Th. 246
= y;x
Rg
= f ;i = yfx
Th. 246 definition of f D
Use the previous theorem to show
8. AXIOMS R 5 , R 7 , R 8 , Rg
T h e o r e m 260. (R1-R3, R 7 - R 9 ) I f x , y £
SyVl
303
t h e n ( x ] y £ S y $ i <£> x ] y =
vU)8. Axioms R5, R7, Rg, Rg While axiom R5 says t h a t for every z t h e function (-);z is additive, its converse dual says t h a t z; (-) is additive. The proof of the converse dual of R5 is a specific example of the general method of proving converse duals using of R7-R9. T h e o r e m 261 (Chin-Tarski [49, 1.21]). (R 8 , R7-R9) z;(x + y) = z;x + z;y. PROOF.
z;(x + y) = ((z;(x + y)yy
R7
= {{x + yy-,zy
R9
= ((x + y);Sy
R8
= (x;z + y;zy
R5
= ((z;xy+(z;yyy = ((z;x + z;yyy
Rg R8
= z; x + z; y
R7
Using this we get the monotonicity of z; (-) and the distributivity of f over from the left. Theorem 262 (Chin-Tarski [49, 1.22]). (R8, R7-R9) If
x
< V t h e n z ; x< z ; y .
Theorem 263 (Chin-Tarski [49, 1.16]). (R1-R3, Rs, R7-R9) z\{x-y)
=
(z-\x)-(z-\y).
PROOF.
z\(x
y) = z ; x y
definition of f
= z;(x + y)
R1-R3
= z;x + z;y = ~z;x-~z;y = (z f a;) (z f y)
Th. 261 R1-R3 definition of f
Theorem 264. (RB, R7-R9) (i) / / x,y G i?n21 then x + y £ i?n21.
(ii) PROOF,
Ifx,y ( i ) :I fx = l ; x a n d y = l ; y t h e n x + y = l ; x + l ; y = l ; ( x + y ) b y
Th. 261, so x + y e Rn%.
D
The next two theorems express the monotonicity of ; and f in both variables.
304
8, RELATION ALGEBRAS
Theorem 265. (Ri, Rs, R7-R9) If v < w and x < y, then v;x < w;y. PROOF. Use Th. 253, Th. 262, and the transitivity of <, which follows from Ri alone; see Th. 178. Theorem 266. (Ri-Rs, Rg, R7-R9) If v <w and x < y then v\x < wfy. PROOF. If v < w and x < y then w < v and f < x by Th. 179, so w;y < v;x
by Th. 265, so « ; T < w;f, i.e., v\x <w\y.
D
Prom Th. 265 we get some closure properties of Sy%, Tr% and Theorem 267. (Ri, R s , R T ^ R S )
(i) Ifx e SySl then x;x G SyfU. (ii) //a; e TrSi then x;x € (iii) //a; e BgSt ifeen a;;a; g PROOF, (i): Assume a; < a;. Then a;;a; is symmetric because (x;xY = x;x < x;x by R 9 and Th. 265. (ii): Assume x is transitive. Then x;x is also transitive because from 5c;x < x we get (a;;a;);(a;;a;) < x;x by Th.265. Theorem 268. (Ri^Rs, RB, R T ^ R S )
(i) Ifx,y
(ii) IfXC
e I¥Sl tfeen E y £ TrSL.
Tr%. and ]JX exists then "[{X €
( i i i ) If x,y £ S g S l t f e e n x-y
£ SgSl.
(iv) J / X C Bga and ]JX exists then ]JX £ PROOF, (i): If x;x
< E and j/;y < y then (E j/);(a;
y) < i;a: < x and
(a; y); (a; y) < y ;y < y by Th. 265, so (a; y); (x y) < x y by R1-R3.
D
The meet of two transitive elements is transitive, but the join of two transitive elements may not be transitive. In fact, TV"2l is not in general closed under ~, + , ;, or f- For example, in 9te(3), if x = {(0,0), (1,1)} and y = {{0,0), (0,1), (1, 2), (2,2) , (2,0)} then none of x, x + y, x;y, or x f y is transitive. It is easy to find examples where x,y € Eq% but x + y ^ Eq%. 9. Axioms Re, R7, R.9 Theorem 269 (Ghin-Tarski [49, 1.5]). (Re, RT, Rs)
r = r e Sy% n PROOF.
Note that 1' 6 Tr% by R6. f=f;l'
Re
= f;f'
R7
= f = 1'
Re RT
10. AXIOMS Ra, a 7 , Hg, R 9
308
D The distinguished element 1' is a right identity for ; in any model of Re- The converse dual of Re (that V is a left identity for ;) can be easily derived from Ra itself with the help of RT and Rg. The same is true of many equations. On the other hand, some equations are equivalent to their converse duals. This is true of R4 (the associative law for ;) and Rg. Theorem 270 (Chin-Tarski [49, 1.4]). (Re, R 7 , R9) x = V ;x. PROOF.
V;x = V;x
Th. 269, Rr
= {st;l'T
RQ
= st
Re
= x
Rr
D Theorem 271 (Chin-Tarski [49, 1.17]). (R1-R3, Re, RT, R S )
xfO' = i = 0'fa;P R O O F . Use R i ^ F i s , T h . 2 7 0 , a n d R B t o get asfO' = x;V O'jx= l r - I = i = a;.
= I
= x and D
10. Axioms Re, Rr, Rs, R9 While Re, R7, R9 are enough to show 1' = 1 ! , we need also Rg to do this for Theorem 272. ( Ri^Rs, Rf 5^R9) 0' = 0' e %si. PROOF.
0!
=¥ =f =¥ = 0'
definition of 0! Th. 246 Th. 269 definition of 0'
A further interesting property of the symmetric elements is that they form a subalgebra in any commutative algebra. The proof of this requires Re and Rg as well as Rr and Rg. We need Ra in the proof because any subalgebra of SI must contain V, and Rg is needed to treat closure under relative multiplication. Theorem 273. (R1-R3, Rg-Rg) /f2l is commutative then 5|/2l is the universe of a subalgebra of SI.
306
6. RELATION ALGEBRAS
PROOF. Assume 21 is commutative and x, y £ Sy$l. Then x = x and y = y, so Sy% is closed under + because (x + y)" = x + y = x + j / b y R g , under ~~ because x = x by Th. 246, under " because x = x = x by R7, and under ; because (x;y)" = y;x = y;x = x;y by Hg and commutativity. Finally, 1' E Syll because 1' = 1' by Th. 269. 11. A x i o m s R B , R.6, R7, R-9 Next we show 1;(-) is expanding when R5-R7, Rg hold. For (-);1 we also need Rg; see Th. 277 below. T h e o r e m 274. (R1-R3, R B - R T , R9) x < l;x. PROOF. We have 1' < 1 by R1-R3. Then x = V ;x < l;x by Th. 270 and Th. 253. T h e o r e m 275 (Chin-Tarski [49, 2.6]). (R1-R3, R5-R7, R9) 1;1 = 1 6 Tr%. PROOF. Put x = 1 in Th. 274 and note that 1;1 < 1 by R1-R3. Th. 275 has a corollary mentioned earlier, that if 1 = 1; 1 then (6.8) and (6.9) are equivalent to (6.10) and (6.11), respectively. T h e o r e m 276. Let 21 be an algebra of relational type. (i) 21 £ WA iff'21 £ NA and one of the following equations is valid in 21:
(ii) 2t £ SA iff 21 £ NA and one of the following the equations is valid in 21:
12. A x i o m s R 5 , R 6 , R 7 , R 8 , R 9 By adding Rs we can get the converse dual of Th. 274. T h e o r e m 277 (Chin-Tarski [49, 2.5]). (R1-R3, R5-R9) x < x ; l . PROOF,
X = x;V
< x ; l , by R 6 , 1' < 1, and Th. 262.
T h e o r e m 278. (R1-R3, R B - R 9 ) x < ( l ; x ) ; l , x < l ; ( x ; l ) , ( O f x ) t O < x, and Ot(xfO) < x. PROOF.
By Th. 274 and Th. 277.
13, AXIOM H l o WITH OTHERS
307
Prom these theorems we now know that the functions 1; (-), (-); 1, 1; (-); 1, and 1;((-);1) are expanding whenever R1-R3, R5-R9 hold in an algebra of relational type. This is true, in particular, in every NA, although Rio is not needed to prove it. Prom Rg and Th. 261 we know that these operators are also additive (and therefore monotonic). They will be normal if Rio also holds (see (6.31) below) and idempotent whenever the semiassociative law (6.9) also holds; see Th. 276. Thus, in particular, these functions are topological closure operators in every SA. 13. Axiom Rio with others Next consider the as yet unused Rio in combination with other axioms. Theorem 279 (Chin-Tarski [49, 2.12]). (Ri^Ets, Rio) x;(xjO) = x;aiiT = 0. PROOF. Use Rio with y = l.
D
Theorem 280. (R1-R3, Rio) x;(W-\y) < y. PROOF. x;(x^y)
= x;x~fij <:fi = y.
The converse dual of Rio is obtained with the help of R7-R9. Theorem 281 (Chin-Tarski [49, 1.23]). (Ri^R3, RT^RIO) y~\x\£ < y. PROOF.
f]x;x
= y;x;z
R7 x
R9, (246)
Rio,Th. 239
= y
Th. 246, RT
n These last two theorems correspond to (2.148). See (2.149)^(2.153) for more variations that could be proved here from R1-R3, R7-R10. T h e o r e m 282 (Chin-Tarski [49, 2.12]). (Re, Rio)
x;x<0'.
PROOF.
x;x = x;x;V
Ra
Rio
= 0'
D Theorem 283. (Ri^Rs, RB, RIO) f \x < 0'. PROOF. Substitute x for x in Th. 282 and use R1-R3, namely, x = x. Theorem 284. (R6, R7, Rio) x{i < 0!.
D
308
6. RELATION ALGEBRAS
PROOF.
Substitute x for x in Th. 282 and use R7.
Theorem 285. (R1-R3, Re-Rs, Rio) x;W < 0' andx;x < 0'. PROOF. We have x = x by Th. 246, so the first equation follows from Th. 284, and the second follows from the first since x = x.
The preceding theorems and the following corollary are abstract algebraic versions of the identity laws (2.192)-(2.195) and the diversity laws (2.196)-(2.199); see also Peirce's Th. 21. V
Theorem 286. (R1-R3, Re-Rs, Rio) 1' < tfa;, 1' < xjx, <x\x.
V < a;ft, and
Next we see that ; is normal in both variables, and its Boolean dual f is dual-normal in both arguments. Theorem 287 (Chin-Tarski [49, 2.4]). (R1-R3, R5, R7-R10) (6.31) (6.32)
x;0 = 0,
(6.33)
oe
x-\l
Tr%nEq% 0;x = 0, ljx = 1
(6.34) (6.35) PROOF.
= 1,
(6.31): x;0 < i ; i TT
Th. 265
= i ; i TT < T
Th. 243 Rio
= 0
R1-R3
(6.34): 0;x == 0;x
Th. 242, R7
=0
Rg
=0
Th.6.31 Th. 242
=0
The last theorem of this section uses all the axioms for NA. T h e o r e m 288. (R1-R3, R5-R10) x = 0 iff x;l = 0 iff \\x = 0. PROOF.
By Th. 274, Th. 277, Th. 6.31,
and Th. 6.34.
14, THEOREM K AND THE CYCLE LAW
309
14. Theorem K and the cycle law De Morgan's Theorem K, the cycle law, and the many variations on these results are characteristic and crucial in the theory of NA. They do not require the identity axiom Re. De Morgan stated his Theorem K as a Rule for Changing Places De Morgan [65]. We gave it earlier in (2.147) as a formula in the calculus of relations. Here we quote De Morgan and use current notation in brackets to explain De Morgan's meaning. In what follows, De Morgan uses "))" to mean the same as " < " or " C " . If a compound relation [ x;y ] be contained in [ < ] another relation [ z ], by the nature of the relations and not by casualty of the predicate [ x; y < z ], the same may be said [ that some compound relation is contained in another ] when either component [ x or y ] ia converted [ into x or y, respectively ], and the contrary of the other component [yorx, respectively ] and of the compound [ z ] change places [ yielding x\~z <1~z or "z;y < x, respectively ]. That is if, be Z whatever it may, every L of M of Z be an N of Z, say
LM))N, then L-1n))m, and sM" 1 ))!. If LM))N, then n))lM'
and nM~1))lM'M-1. But an I of every M of an M~ x of Z must be an I of Z: hence nM~^))l. Again, if LM))N, then n))L/ro, whence L~1n))L~1 Lira. But an L-1 of an L of none but ms of Z must be an m of Z; whence L~1n))m. . . . I shall call this result theorem K, in remembrance of the office of that letter in Baroko and Bokardo; it is the theorem on which the formation of what I called opponent syllogisms is founded. De Morgan [66, p. 224] T h e o r e m 289 (De Morgan's Theorem K). (R1-R3, R 5 , Rr-Rio) If x;y < z then %;~z
De Morgan knew that all three formulas are equivalent (see De Morgan [66, pp. 186-187]), so we restate them that way, as was done earlier in (2.147). Theorem 290 (De Morgan's equivalences). (R1-R3, Rg, R7-R10) x;y < z
> x\z < y O ~z;y < x.
P R O O F . We have just proved x;y < z x\z
310
6. RELATION ALGEBRAS
Further substitutions of converses and complements into De Morgan's equivalences, together with transformations of them by Boolean algebraic methods, yield an enormous variety of additional equivalences. Here are three versions of De Morgan's equivalences included by Tarski [225, Th. 11-13] in his course on relation algebras in the early 1970's. The second version occurs already in the 1943 manuscript (see (2.166) and Tarski [227, 8.10]). Theorem 291 (Tarski's equivalences). (R1-R3, R5, R7-R10) (6.36)
x ; y <~z < ^ > x ; z < y
(6.37)
x ; y < z <^> z ; x < y ^
(6.38)
x;y
z = 0 «=> z ; x
<^> z ; y < x
<=$ z ; x < y <=$ y ; z < x < ^ > y ; x < z ,
y;z < x,
y = 0 «=> y ; z
x =0
De Morgan's equivalences do not appear in any of the papers that Peirce published during his lifetime. However, Peirce was well aware of De Morgan's equivalences, for his unpublished papers reveal the following version, taken from Peirce [200, Vol.4, "1879-1884", p. 341]. Theorem 292 (Peirce's equivalences). (R1-R3, R5, R 7 -Ri 0 ) "Hence the rule is that having a formula of the form x;y < z, the three letters may be cyclically advanced one place in the order of writing, those which are carried We from one side of the copula to the other being both negatived and converted. have, then, the following twelve propositions, all equivalent. x\y
y;z~<x~
f;x
~z<x]y
x
y
y;x
~z;y <x
x\~z
~z
x < z]y
y^z^z
There are in all 64 such sets of 12 equivalent
propositions".
Schroder [215, p.242f] presented four of Peirce's 64 sets of equivalent statements. He used the one given above plus the following three others. Theorem 293 (Schroder's equivalences). (R1-R3, R5, R7-R10) (i) The following y;z
statements
are
equivalent:
<x
z;x
x;y <~z
z
y<
z;ij <x
x;z
y;x <~z
z <sfy
y<
(ii) The following
statements
are
y
~z<x\y
y;x~
x^z^y
y<x]z
~z
x;y < z
(iii) The following
x
statements
y < z]~x x
y<~ ~\z
are
~z<x]y ~z
^]y
X <
f; ~z<\y z; X
<\y
Tj<x y;
~Z < X
equivalent: y;x < z
x
X <
equivalent:
^
x
tz ~zt X X
x;y
x; ~z<\y ~z\X
<\y
v<% y; z<x
Schroder went on to point out that each of these sets of 12 can be expanded to a set of 60 equivalent formulas. Each formula in a group of 12 is equivalent to 4 others. For example, the formula x;y < z, the first one in Peirce's list, is also e q u i v a l e n t t o 1 < x ^ y + z , x ; y -~z < 0 , x ; y z = x ; y , a n d x ; y + z = z .
14. THEOREM K AND THE CYCLE LAW
Next is a version of De Morgan's equivalences, called the cycle law, illustrated by an oriented triangle in its six positions. Starting with the formula and its triangle in standard position,
x;y-z
=0
we add to it the other five equivalent formulas along with the corresponding images of the triangle. The six equivalent statements in the cycle law match up with the six positions of the triangle. Theorem 294 (cycle law, Chin-Tarski [49, 2.1]). (R1-R3, Rs, R7-R10) The following
statements
z;x-y
are equivalent:
=0
y;x-z = 0
y;z-x =
Th. 291, Th. 292, Th. 293, and Th. 294 may be proved directly from Th. 290 using R7 and some elementary consequences of R1-R3, such as the law of double negation. We will derive some of their consequences by an alternative route. First we apply Th. 209 to obtain the following result about the functions *;(-), «;(-), {-);%, and (-);T that arise in algebras of relational type. T h e o r e m 295. Let SI be a Boolean algebra with operators of relational type. (i) For every x € A, the following statements are equivalent: (a) The functions x;(-) and %;(-) are conjugates of each other. (b) x;y z = 0 iff x\z y = 0 for ally,z € A. (c) x;(y-x;z)<x;y-z and x;{z-x\y) < x\z -y for all y,z G A. (d) x;0 = 0 and for all y,z € A, x;y z < x;(y x;z), and x;z y < x;(z-x;y). (ii) Furthermore, the following statements are equivalent for every x £ A. (a) The functions (-);x and (-);x are conjugates of each other. (b) y;x z = 0 4*- z;x y = 0 for all y,z € A. (c) (y z;x);x < y;x z and (z -yjx);x < z;x -y for all y,z € A, (d) 0;x = 0 and for all y,z £ A, y;x z < (y z;x);x, and z;x y < (z-y;x);x.
312
6. RELATION ALGEBRAS
Since all parts of Th. 295 hold whenever R1-R3, R5, R7-R10 hold, we obtain the following corollary, in which parts (6.44)-(6.48) are called, collectively, "rotation"; see (2.168)-(2.172). Theorem 296 (rotation, Chin-Tarski [49, 2.3, 2.7]). (R1-R3, Rs, R7-R10) (i)
The functions
x;(-)
and x;(-)
are conjugates
of each
other,
(ii) The functions x;(-) and x;(-) are completely additive, (iii) the functions (-);x and (-);x are conjugates of each other, (iv) the functions (-);x and (-);x are completely additive, and the following
identities
(6.39)
x;(y
x;z) <x ; y
(6.40)
x;{z-~xjy)
(6.41)
x;0 = 0 = 0;x,
(6.42)
(y z ; x ) ; x < y ; x - z ,
(6.43)
(z-y\x);x
hold:
<
~z,
x;z-y,
(6.44)
x\y z
(6.45)
x;z-y < x;(z x;y),
(6.46)
y;x z <{y
z;x);x,
(6.47)
z;x-y<
y;x);x,
(6.48)
x ; y z < ( x - z;y);(y
-x;z),
(6.49)
x ; y - z =x;(y-x;z)
z = {x z ; y ) ; y
<x;(y-x;z),
(z
z = (x z ; y ) ; { y
x;z)
z.
PROOF. From R1-R3, R5, R7-R10 we conclude, by Th. 294 (the cycle law), that conditions (i)(b) and (ii)(b) of Th. 295 hold, so all of the conditions listed in Th. 295 hold. This yields proofs for most of the parts of the theorem. For complete additivity, apply Th. 208. The next theorem was suggested by Jonsson in 1949: see Chin-Tarski [49, p. 356], where it is treated as a corollary of Th. 256. T h e o r e m 297 (Chin-Tarski [49, 2.19]). (R1-R3, R5, R7-R10) If x;z < x and
x;z < x then
x
y;z = (x
y);z.
PROOF.
< x; z-y-z
Th. (i)
<x-
x;z
<(y
y\z x\z)\z
<x
(6.46)
<(y
Th. (i)
— (T
R1-R3
15. SPECIAL ELEMENTS IN NA
313
15. Special elements in NA This section is concerned with some of those basic properties of various special kinds and elements that can be proved to hold in all NA's; the proofs require no form of the associative law for relative multiplication. The last two parts of the next theorem occur in Tarski's course notes as results about relation algebras, but they hold for NA. Theorem 298 (Tarski-Givant [225, p. 60]). Let 21 € NA. Then (6.50) (6..51)
X
(6..52)
X
< y < ^ 1' <x]y = 0 <=> x;y < 0' = 0 <=> x ; y < 0'
X
PROOF.
x;y < 0' < => <=> <=> < <
V <^\y V =0
R1-R3 R1-R3 Th. 294
= 0
y
y x =0 X
R6
R1-R3
Here are some general formulas involving repeated products, first proved by Chin-Tarski [49] for relation algebras. Theorem 299 (Chin-Tarski [49, 2.9]). Let a <E NA. Then x < (x;x);x and x < x;(x;x). PROOF.
x = x; 1' x
R6
<x;(V-x;x)
(6.44)
<x;(x;x)
Th. 265
x = V;x-x <(V
-x;x);x
<(x;x);x
Th. 270 (6.46)
Th. 265.
D Because of Th. 299, in any NA an element x that satisfies the opposite inclusions x > (x;x);x and x > x;(x;x) will also satisfy the equations x = (x;x);x and x = x;(x;x). Such an element is called difunctional (see Riguet [208, 209, 210]). The elements x;x and x;x are always symmetric, by R7, R9, and the reflexivity of < . In any RA, if a: = (x;x);x then these elements are also transitive,
because x = ((x;x);x)" = x;(x;x)" = x;(x;x), hence (6.53)
(x;x);(x;x) = x;{x;{x;x)) = x;x,
314
6. RELATION ALGEBRAS
(6.54)
(x;x);(x;x)
= (x;(x;x));x
= x;x.
T h u s x;x a n d x;x are equivalence elements. It seems likely t h a t (6.53) a n d (6.54), which use associativity, fail in some SA. T h e o r e m 300 (Chin-Tarski [49, 2.10]). L e i S l e N A . Then x-y-z and x y z < x;(y;z). PROOF. (x;y);z.
B yT h . 2 9 9 a n d T h . 2 6 5 , x
y z < ((x y z);(x
y
<
(x;y);z
z)") ; ( x - y - z ) <
There are 14 versions for each part of the next theorem, depending on how parentheses are added. They all have proofs similar to the proofs of Th. 299 and Th. 300. Theorem 301. Let 2( 6 NA. Then (6.55)
x <
(6.56)
v w x y z <
x;x;x;x;x,
v;w;x;y;z.
15.1. Subidentity elements. Parts of the following theorem appear in Maddux [147, Lem. 5] and many other papers. Theorem 302. Let 21 £ NA and assume u.v
Then
u = «,
v = u;v,
V,
(6.59)
u \x
(6.60)
X ;u
(6.61)
u x = u u;x ;u = u
(6.62)
u ;(u;x) = u;]
(6.63)
X
(6.64)
u \x\v = u; (x ;v),
(6.65)
u ;l;v = u;ff;
(6.66)
V, ;x
(6.67)
X
(6.68)
y = y =
u
x
1 ;u
;v,;v, = 1 ; M -
y = u;x
u;y,
x -y; v, = x;u
y;u,
x
v=
u;
u;(x
;u),
: = u;x, x =- xyu, - u
V,
V < u,
;u-V
V, =
;! y =
x
d U
=
r U .
P R O O F . (6.57): We have
u <<. u;u;u
Th. 299 hyp., Th. 265
u.;«;«
=u <1
Th. 270, R 6 Th. 299 RT
hyp ., Th. 240, Th. 265
15. SPECIAL ELEMENTS IN NA
= u
315
Th. 269, Th. 270, R 6
so ii = ii. ( 6 . 5 8 ) : F o r o n e d i r e c t i o n , u v < (u a n d , f o r t h e o t h e r , u;v < V ;v u;V = u (6.59): G e t (6.69)
v); (u v.
u;x = x
«)";(«
v) < u; (V
l')";w =
u;v
M;1
as follows. u;x
hyp., Th. 265 Th. 270
(6.44)
hyp., Th. 240, Th. 265
= u;x
Th. 269, Th. 270
Applying (6.69) several times gives us u;x
y = x
(u;x)
u;l
y = x
(w;y)= (x
u ; y ,
u ; l ) ( u ; l y) = x
u;l
y .
(6.60) is the converse dual of (6.59). (6.61): By Th. 274, Th. 277, and (6.69) we have u
x = u
and, similarly, u x = u
u ; l x
l ; u= u
u ; x l ; u= u
u ; x ; u
u;(x;u).
(6.62): Part of this is (6.69), which we can use to deduce the rest, as follows. u;x
= u;x
1
= u;x
M;1
(6.69)
(6.69)
= u;(u;x)-l = u](u;x) (6.63) is the converse dual of (6.62). (6.64): u ; x ; v = u ; x l;v
converse dual of (6.69)
= u;l-x-\;v
(6.69)
= w;l x;v
converse dual of (6.69)
= u\{x\v) ( 6 . 6 5 ) : U s i n g ( 6 . 5 8 ) i n t h e l a s t s t e p , w e g e t u\\\v u;V);v
= ( w ; 0 ' + u);v
= u;0'
( 6 . 6 6 ) : B y ( 6 . 5 9 ) , u;x
;v + u;v V = u;x
= u;0' u;V
( 6 . 6 8 ) : B y ( 3 . 5 ) , ( 6 . 5 7 ) , ( 6 . 5 8 ) , a n d u<
= M ; ( 0 ' + V);v
;v + u
< u;V
=
u.
V, u6 = V-u;u
u. T h e o r e m 3 0 3 . Let 21 G N A . ( i ) 2 1 i s B o o l e a n iff x ; y = x
= (M;0'+
v.
Then y f o r allx , y£ A ,
= V-u;u
= V-u-u
= D
316
6. RELATION ALGEBRAS
(ii) if 21 is Boolean then 21 is a symmetric commutative relation algebra. P R O O F , (i): If 21 is Boolean, then 1' = 1, so x;y = x y by (6.58). For the converse, just note that 1 = 1; 1' by R6 and 1 1' = 1' by R1-R3, we get 1 = 1' as a special case of the assumption that x;y = x y for all x,y £ A. (ii): Assume 21 is Boolean. Then ; and are the same operation by part (i). Therefore, 21 is commutative and associative. 21 is symmetric by (6.57). 15.2. D o m a i n and range operators. The domain and range of an element in an NA are defined in (3.5). Theorem 304. Let 21 G NA and x G A.
Then
(6.70)
x66 = x6,
(6.71)
x" = x',
(6.72)
x = x6;x = x;x',
(6.73)
x d= V - x ; l = V - l ; x ,
(6.74)
x '= V - l ; x = V
x;l.
PROOF. (6.70) and (6.71) follow from (6.68) and x6 + x' < V. For (6.72), x = V ; x x < (V x ; x ) ; x = x d ; x < V ; x = x , a n d x = x ; V x < x ; ( V x ; x ) = x ; x ' < x ; V = x. For (6.73), use (6.49) to get V - x ; l = V - x ; ( l - x ; V ) = V - x ; x =
x6.
15.3. Domain, range, and ideal elements. Theorem 305. Let 21 € NA. Then (i) If x € Dm% then x e £>m2l. (ii) IfxeRnVL then x G RnVL. (iii) If x G 7e2l then x G 7e2l. PROOF, (i): If x = x; 1 then 0 = x -x = x;l -x = x;l -x, so 0 = aJ; 1 a; by Th. 294, hence x; 1 < x. We have x < x; 1 by Th. 277. Since 7e2t, 7?n2t, and Dm 21 are closed under ~ and +, they are universes of Boolean algebras that are subalgebras of the Boolean part of 21. In fact, the Boolean algebra of all subsets of U is isomorphic to the Boolean algebra of domain elements of Dlt(U), and it is also isomorphic to the Boolean algebra of range elements of 9te(f7). On the other hand, SHe([/) has exactly two ideal elements whenever \U\ > 1. Recall that x € 7e21 iff x is an ideal element of2tiffa; = l;a; = a;;l. A crucial fact about an ideal element x is that the function x (-) is a homomorphism; see Th. 372. Part of this observation is made in the next theorem. Theorem 306 (Chin-Tarski [49, 3.27,4.1]). Let 21 G NA. (i) 7e2lC SyVl. ( i i ) x e 7 e 2 l iff x y ; z = (x y ) ; ( x
z ) f o r all y , z £ A .
15. SPECIAL ELEMENTS IN NA
317
P R O O F , ( i ) : I f x = x ; l = l ; x t h e n x < x ; x ; x < l ; x ; l = x , so x = x . T h u s every ideal element is symmetric. (ii): Assume x € Je2l. For any y, z €. A we have x
y ; z= x y ; ( z y ; x )
(6.49)
<x-y;(z-l;x)
Th. 265
= x y;(z x) = x
(y
x; (z
x €. 7e2l x)");
(z
x)
(6.49)
<(yx;l);(z-x)
Th. 265
= (y x); (z x)
x £ 7e2t
T h . 265
= £-y;«
a; £ / e 21
For t h e converse, a s s u m e x y;z = (x y); (x z) for all y,z £ A . W e a p p l y t h i s w i t h y = x a n d z = 1, a s follows. x;l
x < (x x ; l ) ; 1 = ((a;- s);(a; 1));1
hyp.
= (0;(x-l));l = 0. This gives us x;l < x. But x < x;l, so x = x;l.
Similarly, x = l;x.
D
15.4. Integral algebras. Jonsson-Tarski [119, 4.17] proved conditions in the next theorem are equivalent for relation algebras, are also equivalent to the condition that every nonzero functional atom. The parts of this result that hold for NA are gathered in the For parts that hold in SA see Th. 353 below.
that the three and that they element is an next theorem.
Theorem 307 (Maddux [144, Th. 2]). Let 21 G NA. (i) 21 is integral iff Q ^ I and x / 0 implies x; 1 = 1 for all x e A. (ii) //2t is integral, then V is an atom of Si. P R O O F , (i): Suppose 21 is integral. By definition, this implies 21 is nontrivial, so 0 / 1. We have x;x;l = 0 by Rio, so i = 0 or a;;l = 0 since 21 is integral. But if x / 0 then x / 0, so we must have x;l = 1. (Similarly, we get l;x = 1 whenever x / 0.) For t h e converse, assume 21 is nontrivial and x;l = 1 whenever x / 0. To show t h a t 21 has no zero-divisors, we assume x / 0 / y and show t h a t x;y / 0, We get x # 0 from a; / 0, so x; 1 = 1 by assumption. Hence 0 / J / = 1-J/ = £ ; 1 - J / , so 0 / x; y by t h e cycle law. (ii): To prove t h e contrapositive of (ii), we suppose 1' is not an atom and show t h a t 21 is not integral. If 1' = 0 then l = l ; l ' = l ; 0 = 0, hence 21 is trivial and therefore not integral. We may therefore assume 1' / 0. Then, since 1' is not an atom, there are x,y €. A such t h a t 0 = x -y, 0 ^ x, 0 ^ y, and x + y = V. B u t x;y = x y by (6.58), so x;y = 0. Thus 21 has zero-divisors a n d is therefore not integral.
318
6. RELATION ALGEBRAS
McKinsey's algebra (p. 357) is a nontrivial WA with zero-divisors in which 1' is an atom, so the converse of the second part can fail. 15.5. Equivalence elements. The Chin-Tarski characterization of equivalence elements in RA, which generalizes Th. 24, can be further generalized to NA. Theorem 308 (Chin-Tarski [49, 3.2,3.3]). Let 21 E NA. Then the following statements are equivalent: (i) (ii) (iii) (iv) (v) (vi) (vii)
xGEqVL, x;x < x < x, x;x = x = x, x;x = x, x;x = x, x ; x < x and x ; x < x , x ; x < x and x ; x < x .
PROOF. For the equivalence of the last two statements, x ; x < x a n dx ; x< x <S>
x ; x x = 0 a n dx ; x x = 0
<S>
x ; x x = 0 a n d x ;x x = 0
<S>
x ; x< x a n dx ; x< x
Others parts can be proved by imitating t h e proof of Th. 24. The following theorem implies t h a t equation 0';0';(0';0') = 0';0' holds in every NA. However, t h e related equation 0';0';0';0' = 0';0' fails in some NA. In fact, it fails in some WA but holds in every SA; see Th. 356. T h e o r e m 309 (Maddux [143, 14(1)]). / / 2 t 6 NA then 0';0' e EqVL. P R O O F . Since (0';0')" = 0';0' = O';O\ we need only show (0';0');(0';0') < 0';0'. (0';0');(0';0') = ( 0 ' ; 0 ' - ( r + 0 ' ) ) ; ( 0 ' ; 0 ' ( r + 0 ' ) ) = (0' ;0' 1'); (0' ;0' 1') + (0' ;0' 0'); (0' ;0' 1') + (0';0' - r ) ; ( 0 ' ; 0 ' 0') + (0';0 ! - 0 ' ) ; ( 0 ' ; 0 ' - 0 ' ) < l ' ; ( 0 ' ; 0 ' ) + ( 0 ' ; 0 ' ) ; r + 1';(0';0') + 0';0'
D 15.6. Points, pairs, and twins. The most interesting properties of points, pairs, and twins can be proved only for SA and RA, but some basic facts can already be established to hold in every NA.
16. CHARACTERIZATIONS OF NA AND RA
319
T h e o r e m 310. Let 21 £ NA. Then every point, pair, and twin is a subidentity element. Furthermore, (6.75)
Tu;2lUP£2lCPr2t,
(6.76)
P*2tnTu;2l = 0,
(6.77)
Pi2l C Sto21.
PROOF. If x € P i 21 then x;l;x < V, so x is a subidentity element since x < x;x;x < x;l;x < V. If x € Pr21 then a;;0';x;0';x < 1', so a; = x V + x 0' < 1' + (a;-0');(a;-0')";(a;-0');(a;-0')";(a;-0') < 1' +x;0';x;0';x
(6.55)
< 1' Thus points and pairs are subidentity elements. A twin is just a pair with no points below it, so every twin is also a subidentity element, and we have the trivial inclusion Tiv2l C Pr2l. Suppose x € Pt%. Then a ; ; 0 ' ; a ; < a ; ; l ; a ; < r and, since every point is a subidentity element, a;;0' ;x < 1' ;0' ;1' = 0', so a;;0' ;x = 0. This implies x;0';x;0';x < 0;0';x = 0 < 1', so x E Pr%. Thus every point is pair. If point were also a twin it would be both nonzero and disjoint from itself, so Pt2l n Tw% = 0. Finally, if x € P£2l then x = x since x < V, so x;l;x + x;l;x = x;l;x < V, which shows that x £ Sn21. 16. Characterizations of NA and RA First we present the Chin-Tarski characterization of " in terms of ; and 0', first proved for relation algebras, but also true for NA. T h e o r e m 311 (Chin-Tarski [49, 2.14]). / / 21 € NA and x € A, then x = PROOF. It suffices to show y < x < = > J / ; x < 0 ' , which holds because the following statements are equivalent: y <x y<x y;V
Th. 241 <x
y,x<0'
Re Th. 290
Next we obtain a characterization of NA that is sometimes used as a definition, and a similar characterization of RA due to Chin-Tarski [49]. Parts of the original proof of the Chin-Tarski Theorem have been isolated in the following two theorems. T h e o r e m 312. Let 21 be a Boolean algebra with operators of relational type, and assume (i) x = x;V,
320
6. RELATION ALGEBRAS (ii) x;y
for
all x,y,z
z = 0 iff x;z
y = 0,
6 A. Then the equation x = x is valid in 21.
PROOF. Note that
x
x - y= 0
&
x;V-y
= 0
(i)
<S>
x ; y V = 0
(ii)
x;V-y = 0
(ii)
x y = 0
(i)
x < y Taking y = x yields x < x, a n d t a k i n g y = x yields x < x, so R7 is valid in 2t. T h e o r e m 313. Assume type such that
% is a Boolean
algebra with operators
of
relational
(i) x = x;V, (ii) x;y z = 0 iff x;z y = 0, (iii) x;(y;z) = (x;y);z, for all x,y,z valid in 21.
E A.
Then the equations
V = V, x = V;x, and (x;y)"
= y;x are
PROOF. For the third equation (which is Rg), observe that for every z E A, 0 = (x;y)w
z
0 = (x;yY;V
z
(i)
O= ( x ; y ) ; z - V
(ii)
<*
O= x ; ( y ; z ) - V
(iii)
<S>
0= x ; V y ; z
(ii)
<5
0 = y;z-x
(i)
<=>
0= y ; x z
(ii)
It follows that R9 is valid in 21. By Th.312, R7 is also valid in 21. Therefore, by Th. 269 and Th. 270, the first two equations are also valid in 21. The following characterization of NA differs slightly from the Chin-Tarski characterization of RA; it does not include the associative law for relative multiplication, of course, but does include the (possibly redundant) converse dual of ReTheorem 314. 21 £ NA iff 21 is a Boolean algebra with operators of relational type such that (i) x = V;x, (ii) x = x;V,
16. CHARACTERIZATIONS OP NA AND RA
321
( i i i ) x ; y - z = 0 <=> x \ z y = 0 , ( i v ) x ; y z = 0 <=> z ; y x = 0 , / o r aH x,y,z
E A.
PROOF. Assume 21 € NA. Then R1-R3, R5-R10 hold. We obtain 331(21) € BA from R1-R3, x = V ;x and x = x;V from R 6 , R7, Rg via Th. 270, and the cycle law from R1-R3, R5, R7-R10 via Th. 294. For the converse, assume 21 is a Boolean algebra with operators of relational type satisfying (i)-(iv). Then R1-R3 are valid in 21 since Q3[(2l) £ BA, so we need only show R5-R10. Right relative multiplication has a conjugate by (iv) and is therefore completely additive, so R5 holds. R6 is (ii). For R7, use Th. 312. For Rs, R9, Rio we give derivations. First, we show conversion is self-conjugate. x
y = 0
=>
x;V-y
= 0
(ii)
=>
x;y
V = 0
(iii)
=>
V ;y
x = 0
(iv)
=>
y
x = 0
(i)
Since conversion is self-conjugate, it is completely additive, so Rs is valid in 21. Next we prove Rg. For every z £ A, y;x
z = 0
<=>
y; z
x = 0
(iii)
<=>
x; z
y = 0
(iv)
<=>
x; y z = 0
(iii)
<=>
(x;j/)"-2: = 0
so Rg follows by R 1 - R 3 .
is self-conjugate
Finally, for R i o , we n o t e t h a t x;y
x;x~yy y = 0, hence x;xjy < y.
~xyy = 0, hence
D
Can either one of the first two conditions be deleted from the previous theorem? From this characterization of N A we get the Chin-Tarski characterization of relation algebras. T h e o r e m 315 (Chin-Tarski [49, 2.2]). 21 £ RA iff 21 is a Boolean algebra with operators
of relational
(ii) x\y-
for
z = 0 & x;z-y
(iii)
x;y
(iv)
x;{y;z)
all x,y,z
type such
z = 0 <=> z;y =
that
= 0, x = 0,
(x;y);z.
£ A.
PROOF. From (i), (ii), and (iv) it follows by Th. 312 and Th. 313 that x = V ;x is valid in 21. Therefore 21 £ NA by Th. 314. Since ; is associative by (iv), we conclude that 21 £ RA.
322
6. RELATION ALGEBRAS
A variation on this characterization is obtained by replacing the associative law with an equivalence similar to the others. Theorem 316 (Frias-Maddux [75, Lem. 2.2]). 21 6 RA iff 21 is a Boolean algebra with operators of relational type such that (i) x = x;V, (ii)
for
x ; y z = 0 -O- x ; z y = 0 ,
(iii) x ; y z = 0 <=> z ; y x = 0 , ( i v ) v \ x w ; y = 0 <S> i>;w x ; y = 0 . all x , y , z 6 A .
The next two theorems are additional characterizations of NA. First we observe that one of the equivalences in Th. 314 can be relaxed to an implication. type
T h e o r e m 317. 21 £ NA iff 21 is a Boolean satisfying (i) (ii) (iii) (iv)
algebra with operators
of
relational
x = V ;x, x = x;V, x;y z = 0 <S> x;z y = 0, x;y-z = 0 => 2;g/-a; = O.
P R O O F . It suffices t o prove t h a t z;y x = 0 implies x\y z = 0. By (ii), (iii), a n d T h . 312, y = y. A s s u m e z;y-x = 0. T h e n x;y-z = 0 by (iv), so x;y-z = 0. T h e n e x t characterization is easy t o o b t a i n w i t h t h e help of T h . 295. T h e o r e m 318 ( M a d d u x [139, 1(22)]). 21 6 NA iff 21 is a Boolean with operators of relational type satisfying (i) x = V ;x = x;V, (ii) 0 = 0;x = x;0, (iii)
x ; y z = x;(y
(iv)
x ; y z = (x
x;z) z;y);y
algebra
z, z,
(v) x = x. 17.
Duality for NA
The converse dual of an equation is obtained by replacing every subterm of the form x;yhyy;x. For example, Th. 261 is the dual of RB (left-distributivity of ; over + is dual to right-distributivity). If an equation is valid in a nonassociative relation algebra 21, then so is its dual equation. This is easy to show with the help of R7-R9, as illustrated by the proof of Th. 261. T h e o r e m 319. Assume 21 = {A, +,~, ;,", V) € NA. Define some operators by setting x o y = y/x, x y = y] x, and x~ = x for all x,y E A. three more algebras as follows.
21 : = (A,
, 0'),
a-:=
.
Define
18. COMPLETIONS
Then the algebras 21, 21, 21, and 21" are isomorphic. In fact, the operations ", ~, and ~ are involutions that serve as isomorphisms among these algebras as follows. 21^21
21 ^
21
21 <-^- 2 t
Tarski observed that many laws involving relative operations becomes a correct law for Boolean algebras when f, ;, ", 1', and 0' are replaced by +, , ~, 1, and 0, respectively, and wondered whether there is a characterization of the cases for which this happens. For example, x;x < 0' becomes x x < 0. It would be nice to get a postulate system that reflects this duality and is independent. For more on this connection see Brink [42] and Brink-Gabbay-Ohlbach [43].
18. Completions Suppose that 21 = {A, +,~, ;, ", 1') is a Boolean algebra with operators of relational type, that is, 581(21) = (^4,+,~) is a Boolean algebra, ; is a binary operator and is a unary operator on A. Recall that £ is a completion of 21 if £ is a Boolean algebra with operators similar to 21, the Boolean algebra 5B((<£) is a (Boolean) completion of 58 [(2t), and the operators of C are the "upward" extensions of the corresponding operators of 21, that is, if So and B replace A and C, respectively, in (5.65) and (5.67), then <£ = ^Q3l(<£), },", 1'}, or, in more detail, (6.78)
21 is a subalgebra of £,
(6.79)
C is complete and A is a dense subset of C,
(6.80)
if c , c ' G C t h e n c;c = ^ £ { o ; a ' :c>a£A,
(6.81)
if c G C then c = ^
£
c > a €A } ,
{ o : c > a <E A}.
If £ is a completion of 21, then the density of A in C implies that all joins are preserved and every element of £ is represented as the join of elements of 21 below it, that is, x exists t h e n
(6.82)
i f X C i and J^
(6.83)
for every ceC, c = ^
;
YT
X
= Z ^ X>
{o : c > a € A}.
Theorem 320. Let 21, £ 6 NA. Then € is a completion o/2l iff (i) 21 is a subalgebra of <£, (ii) 931 (C) is a completion of 581 (21), PROOF. If conditions (i) and (ii) hold, then (6.82) and (6.83) hold by the density of A in 21. Then (6.80) and (6.81) follow from (6.83) since C e NA and so ; is completely 2-additive (in fact, ; is completely additive in each variable) and is completely additive. Next is the uniqueness theorem for completions, followed by the existence theorem.
324
6. RELATION ALGEBRAS
Theorem 321. Suppose 21, C, and £' are Boolean algebras with operators. (i) / / C and £' are completions of 21, then € is isomorphic to £' by an isomorphism which leaves 21 fixed. (ii) If € is a completion o/2l and 21 is finite, then € = 21. Theorem 322 (Monk [181]). Suppose 21 is a Boolean algebra with operators of relational type. Then there is an algebra € of relational type such that (i) £ is a completion of 21,
(ii) €e NA iff 21 G NA, (iii) ffeWA iffKeWA, (iv) ceSA iff a eSA, (v) £ e RA iff 21 G RA. PROOF. This theorem follows from Th. 226 and the fact that the equations in Th.318 and the equations (6.8), (6.9), and R4 involve only o;-additive operators.
By Th.322, NA, WA, SA, and RA are closed under completions. Monk [181] asked whether RRA is closed under completions. This long-standing problem of Monk [181] was finally solved by I. Hodkinson. Theorem 323 (Hodkinson [101]). There is an atomic RRA whose completion is not representable. Thus RRA is not closed under completions. For other proofs of this theorem, see Hirsch-Hodkinson [98, 99].
19. Perfect extensions Suppose 21 and ^3 are Boolean algebras with operators of relational type. Recall (from p. 273, p. 274, and p. 288) that
21 is a subalgebra of «P,
(6.85)
?p is complete and atomic,
(6.86)
if X C A and J ^ VJ
(6.87)
x
= 1,
then
Y = 1 for some finite subset Y C X,
if c, c are distinct atoms of ?P, then there is an element a € A such that c < a and c a = 0,
that is, Aty$
:={[[X:X
i fx , y € P t h e n x ; y =
^ ^
(
J J *
x>ceC, y>c'eC c
(6.89)
if x € P then x = J^
( I I ^ ")
x>c£C c
a ; a ) ,
19. PERFECT EXTENSIONS
338
The first four items assert that 051 (^J) is a perfect extension of 051(21.). It follows from Th. 227 that (6.88) and (6.89) can be replaced by (6.90)
if c, c' E Atty then e;c' =
J}
a;a,
e
(6.91)
if c E Atty then c = TT a.
In the next theorem we see that, for nonassociative relation algebras, however, two of these conditions can be omitted. Theorem 324 (Maddux [142, 4.1]). Suppose SI, ^J G NA. Then ^ is a perfect extension of Si iff
(i) ac
c = c\V = c; ^ ^ { e : 1' > e € A«p} = ^ ^ { e j e : 1' > e 6 so c = c;e for some c £ 7a!P, hence, by (6.88), c = c;e = TT { a ; a ' ; c < a 6 A, e < a' € A}, but {«;a' : c < a £ i , e < a' £ A} C {a : c < a E A}, for if c < a G A and e < a' € J4., then c < c;e <. a;a' £ A, so c = J J ^ a i a ' :c
e < a e A} > Y]9{a
:c
The opposite inequality holds trivially, so we have c = Y[^{a
:c
for all atoms c G j4i?p. This last equation is enough to show that (6.87) holds, and it implies (6.91) since is a completely multiplicative operator in ^J 6 NA; c = f J J {a : c < a E -AH" = J^[ {a : c < a E J4J.
Next are the uniqueness and existence theorems for perfect extensions. Theorem 325. Suppose 31, $p, o«d V' ore Boolean algebras with operators. (i) /f ?P and ?P' are perfect extensions of 21, &en ?P »s isomorphic to ?p' &y an isomorphism which leaves 21 fixed. (ii) If ^ is a perfect extension of St and 21 is finite, then ?p = 21. In connection with the following theorem, see the remarks in §6.36 regarding the notation U5i+".
6. RELATION ALGEBRAS
Theorem 326 (Jonsson-Tarski [118, 119]). Suppose 21 is a Boolean algebra with operators of relational type. Then there is an algebra 2l+ of relational type such that (i) 2l+ is a perfect extension of 21, (ii) 21+ G NA p e NA, (iii) 2t+ E WA iff We SNA, (iv) 21+ GSA iffSleSA, (v) 21+ G RA iff 21 G RA. PROOF. This theorem follows from Th. 228 and the fact that the equations in Th. 318 and the equations (6.8), (6.9), and R4 involve only w-additive operators.
By Th.326, NA, WA, SA, and RA are closed under the formation of perfect extensions. Such classes are called canonical. Monk proved that RRA is canonical. This was first reported by McKenzie [165, p.66]. The first published proof is in Maddux [143] (see Th. 419 below). 20. Matrices of elements Let 21 6 NA and assume n is a nonzero ordinal such that if n is infinite then 21 is complete. This assumption avoids the situation in which n > w, 21 is incomplete, and statements of results are complicated with hypotheses on the existence of relevant meets and joins. A function that maps n2 into A is called an n-hy-n matrix of 21, or simply an n-matrix. Let Mn2t be the set of n-matrices of elements of 21, that is, Mn2l = n A = {a :
A}.
An n-by-n matrix of elements of 21 is just a function from n into A, but for such functions we use matrix notation and terminology. For example, if a is an n-by-n matrix of elements of 21 and 1 < n < u, then ooo
Ooi
002
OO.ti- 1
0.10
an
012
fll,n-
1
O20
021
022
O2,n-
1
1-1,0
In—1,1
ttn-1,2
ffln—l.n
Here we make a few remarks on the intuition underlying matrices of elements. For additional remarks, see §7.7. An element of a relation algebra is an abstract algebraic object that corresponds to a binary relation. In fact, if the algebra is proper then its elements really are binary relations. Consider a binary relation R C U2 on a set U E V (so R is an element of the proper relation algebra 9\e ({/)). The statement that two objects x,y G U are related by R can be expanded into a somewhat redundant conjunction of similar statements. Specifically, if we know (x,y) G R then we also know (x,x) G Do(R), (y,y) G Ra(R), and (y,x) G R'1.
20. MATRICES OP ELEMENTS
The four relations that appear in these statements may be assembled into the 2-by-2 matrix
We then regard the matrix a as a relation that holds between the sequence {x, y) and itself, in the sense that (x,y) E R, {x,x} E Do(R), (y,y) E Ra(R), and (y,x) € R~x. More generally, if a G MnUie(U), relation t h a t holds between a n n - a r y sequence (xo,
in c a s e (xi,Xj)
t h e n a represents a b i n a r y xn-\) EnU a n d itself j u s t
E aij for all i,j < n.
Prom matrices a and b in Mn2l we may form new ones, denoted by a, a-b, and a; 6. These matrices represent additional statements that may be deduced from the hypotheses that an n-ary sequence is related to itself by a and also by 6. We say that a is the converse oi a, a-b is the intersection of a and b, and a; b is the relative product of a and 6. These matrices are defined by the following equations, which hold for all i,j < n. (a)ij = (ajiY, (a-b)ij
= dij
bij,
k
The last equation illustrates the assumption that 21 is complete in case n is infinite. Assuming 21 is complete guarantees that the join always exists. To illustrate relative multiplication of matrices, consider a,b E M22I. Then , faoo a;b= |aio
aoil ; [fooo 601 onj
[010
ttio ;6oo i n ;6io
On
an;6n
aio;6oi
For 1-by-l matrices, intersection of matrices and relative multiplication of matrices are the same. Intersection of matrices is commutative and associative, but relative multiplication of matrices is neither commutative nor associative in general. Counterexamples can be found among 2-by-2 matrices of elements of *He (3). For example, if I = 3 1 = {(0, 0), (1,1) , (2, 2)},
[7 {(0,1)}] [
[ / {(0,2)}] [{(1,0), (2,0)} I J'
then
lib-a = b, i.e., bij < a^ for all i,j < n, then we say that a contains 6, and symbolize this by writing 6 < a or a > b. We write 6 < a or a > 6 in case b < a and b / a. The relation < is a partial ordering on Mn$l, in which the greatest lower bound of the two matrices a and b is a-b. An n-by-n matrix a is path-consistent if a < a;a, i.e., aij < aik\akj for all i,j, k < n. A matrix a is
32S
8, RELATION ALGEBRAS
symmetric if a = a. A matrix can be path-consistent without being symmetric. For example, if [ {(0,0), (2,2}} a = [{{1,0}, {3,2}, {1,2}}
{{0,1} ,{2,3), (0,3)}] {{1,1} ,{3,3}} J
then a = a;a but a ^ a. A matrix is closed if it is both path-consistent and symmetric, that is, a = a = a; a. A matrix a satisfies the diagonal condition iff a» < 1' for all i < n, and it satisfies the off-diagonal condition iff ay < 0' whenever i ^ j < n. The largest matrix satisfying the diagonal condition is the identity matrix T 1 1" i r l lk:= . . .1 1 1'. the largest matrix satisfying the off-diagonal condition is 0'
0! 1
0r 0'
0'
0!
1.
and the smallest matrix altogether is the n-by-n zero matrix '0
0
0"
0
0
0
0 0
0
0»:=
A matrix a G MnSl is atomic if every ay is an atom of SI. We say that a matrix a € Mn%l is a basic matrix or atom matrix iff it is closed, atomic, and satisfies the diagonal condition. Let Bn% be the set of n-by-n basic matrices of 21. Thus SB2l is the set of those n-by-n matrices of atoms of SI which satisfy the following conditions for all i, j , k
a»»
(6.93)
ay = etji,
(6.94)
Oik < a>ij\ajk.
The definition of Bn2l appears in Maddux [139, 10(9)] (where it is called Mn2l), [146, Def.2(i)], [148, Def.46], [150, Def.34(i)], and [151, p. 1217]. Basic matrices appear in algebraic topology; see Eilenberg-MacLane [69, §2], where basic matrices form the cells of simplicial complexes over an arbitrary group. A matrix a € MB% satisfies the triangle condition if 0
k
whenever i, j < n. It is easy to show that a matrix in Mn% is basic matrix iff it is atomic and satisfies the triangle condition.
20. MATRICES OF ELEMENTS
329
If a £ Mn2l and TT : m —> n is any function mapping a nonzero ordinal m into n, then an is the matrix in M m 2l defined by aTTjj = a^j^y) for all i, j < m. It is easy to check that air is also a basic matrix, so air € -Bm2l- In particular, a[i,j] and a[«/i] a r e basic matrices, where [i,j] and [i/j] are the functions mapping n to n such that [ljJi\j>—3>
L V J J W ~ J>
[*I J I C " ) = fc if fc / « , i ,
[*/i](fc) = k if k ^ i.
The next theorem contains a few elementary facts about matrices in an arbitrary NA. Theorem 327. Let 21 G NA and a,b e Mn2t. Then (i) a satisfies the diagonal condition iff a < l'n, (ii) if a < l' n then a;a
((a-6)")jj = ((a-b)jiY = (ajj
6ji)"
= (ajiY
(bjiY
def. def.
Th. 247
= aij
bij
def.
= (a
6) ij
def.
Proof of (vi): ((a ; bY)ij = ((a ; b)jiY =
(]__[ajk \bki)
def. def.
k
= Y[(ajk;bkiy
Th. 250
k
]__[ (okiY',(ijkY
R9
*!
= _Q 6ife; akj fc
def.
330
6. RELATION ALGEBRAS
= (b; a)ij
def.
Proof of (vii): (a
a)ij = dij
aij
def.
= «ij-((«y)T a
= ( jiT = (dji
R-7
(ajiY
def.
CLji)"
Th. 247
= ((a-d)jiY
def.
= ((a-aY)ij
def.
D 21. Bases Let 21 £ NA and assume n is a nonzero ordinal such that if n is infinite then 21 is complete. Let k,l < n. We say that two basic matrices a, b E B n 2l agree u p to k if dij = bij whenever k ^ i,j < n, and we say that they agree u p t o k,l if Oy = bij whenever k,l ^ i,j < n. For any i,j < n let TT(2l) := {(a, 6) € (B n 2t) 2 : a and 6 agree up to i}, ££(2t) := {a E BnK : al3 < 1'}. Consider the following seven statements about N and 21. (6.95)
0 ^ N C B n 2l.
(6.96)
(atom cover) For every atom a; £ Ai2l there is some a € N such that aoi = x.
(6.97)
(extension) If a £ iV, j , j ,fe< n, j , j ^ k, x,y £ At%, and ay <x;y, then for some b £ N, bik = x, 6^- = ?/, and (o,fo)£ T^*(2l).
(6.98)
(cycle cover) If x,y,z £ Af>&. and a; < y;z, then for some a £ N, aoi = x, ao2 = y, and ai\ = z.
(6.99)
(amalgamation) If o,c £ N, i,j < n, i ^ j , and o agrees with c up to i , i , then for some b £ N, (a,b) £ T " ( a ) , and (fo,c) £ T"(2l).
(6.100)
(face) If o £ iV and j , j < n then a[i/j] £ N.
(6.101)
(permutation) If a 6 N and i,j
then a[i, j] £ N.
Note that in order for the condition (6.98) to apply to a given N C B n 2l, we need to assume n > 3, while (6.96) applies if n > 2. We say that iV is an - n-dimensional relational basis for 21 if n > 2, (6.95), (6.96), and (6.97), - n-dimensional cylindric basis for 21 if n > 3, (6.95), (6.98), (6.99), and (6.100), - n-dimensional semantical basis for 21 if n > 3, (6.95), (6.98), (6.99), (6.100), and (6.101).
22. ELEMENTARY ARITHMETIC IN WA
331
For example, if U € V then Bn9ie (U) is a relational basis for *Re (U) whenever n > 2, and Bn£Re (f) is a cylindric and semantical basis for d\t (U) whenever n > 3. The notions of relational, cylindric, and semantical basis were derived from concepts originally formulated for cylindric algebras by Henkin [90], who denned an algebraic interpretation to be a special kind of homomorphism from a free ndimensional cylindric algebra of formulas in Fm + (£) to an n-dimensional cylindric algebra. Cylindric algebras of dimension n are an algebraic abstraction of the theory of n-ary relations, just as relation algebras are an algebraic abstraction of the theory of binary relations. Bases bridge the gap between binary and n-ary. Cylindric bases were invented for constructing cylindric algebras, semantical bases for algebraic semantics. If 21 has no atoms, then i?n2l = 0. This is why the notion of n-dimensional cylindric basis was first denned only for atomic 21 € SA and n > 3 in Maddux [139, 10(11), pp. 140-141], where it was called simply "n-dimensional basis". The notion of semantical basis was also defined (but not named) in [139, p. 200]. The notion of relational basis was denned in [143, §2] for atomic 21 £ SA and 3 < n < u>, where it was also called simply "n-dimensional basis". The same definition of relational basis was adopted for n > 2 and arbitrary 21 € NA in [146, Def. 3] and in [150, Def. 34(iii)]. The definition of cylindric basis was extended in [146, Def. 4] to an arbitrary 21 € NA with n > 3. However, it is only under the assumption 21 £ WA that the notion of cylindric basis has all of its intended consequences. This can be seen from Th. 335 below and the discussion in Hirsch-Hodkinson [99, §12.6]. 22. Elementary arithmetic in WA We consider what can be proved from the axioms of N A by adding the weak associative law (6.10). One can make an algebra in NA with an element x that produces a strictly increasing sequence x-V
< ( x - l ' ) ; K (a;-r);l;l < ...
To test whether this was also true for WA, Richard L. Kramer applied Th. 488 below and discovered that the equation a;; 1; 1 = x ; l ; l ; l holds in every WA. This identity is included in the first part of the next theorem. Theorem 328 (Maddux [150, Th. 11]). / / 2 l <E WA and x,y <E A then (6.102)
x ; l ; l = a ; ; l ; l ; l = a; d ;l,
(6.103)
l;a;r = l;(l; a ;) = l ; ( l ; ( l ; a ; ) ) ,
(6.104)
a;d = ( z ; l ) d ,
(6.105)
x' = (l;x)',
(6.106)
x
(6.107)
x < l ; y => x < y .
=> xA
6. RELATION ALGEBRAS PROOF.
(6.102): x ; l ; 1 < x; 1;1;1
Th. 277
II
(6.72) Th. 265
< x d ;i
Th.276
VI
xd
(3.5)
1
= (I <x;l;l
Th. 265
(6.104): (x;l) d = l ' - a ; ; l ; l
(6.73)
d
= l'-x ;l
(6.102)
dd
(6.73)
A
(6.70)
= a; = x (6.106): Assume x < y;l. xd<(y,l)d = y6.
Then, by (6.104), Th. 265, a n d Th. 240, we have
T h e o r e m 329 (Maddux [147, Lem. 6]). Assume A. Ifu,v< V then
21 £ WA and u,v,x,y,z
(6.108)
(u;x);y = u;(x;y),
(6.109)
(x;y);u = x;{y;u),
(6.110)
(x;u);y = x;(u;y),
(6.111)
(x;u);(v;y) =x \ { u -v);y =x;((u -v);y),
(6.112)
u;{v;y)
=
(6.113)
(x;u);v
=x;(u v),
(6.114)
u;x-v;y
(6.115)
x;u-y;v = (x-y)-(u-v),
(6.116)
u-(x;y);z
{u-v);y,
= (u
v);(x-y),
= u-x;(y;z).
PROOF. (6.108):
(u;x);y
Th. 265
= u;l-x;y
Th. 276(i), Th. 270
= u;(x;y)
(6.62)
= u;l-x;y
(6.62)
<(x-u;l;y);y
(6.46)
< (x-u;l;l);y
Th. 265
<(x-u;l);y
Th. 276(i)
= (u;x);y
(6.62)
£
22. ELEMENTARY ARITHMETIC IN WA
(6.109): By converse duality from (6.108). (6.110): We need only prove (x;u);y < x;(u;y) inclusion by converse duality. (x;u); V < x;u;{y(x;uy;l) < x;u;(y-u;x;l) <
and obtain the opposite (6.44) Rg
x;u;{y-u;x;\)
(6. 57)
<x;V;(yu;l;l)
Th .265
=
Re , Th. 276(i) (6. 62)
x;(yu;l)
= x;(u;y) (6.111): (z;i
>)\{v\y) = =
x;(u;(v;y)) x;{{u;v);y)
=
x;((u-v);y)
(6.58)
=
(x;(u-v));y
(6.110)
(6.110) (6.108)
Obtain (6.112) and (6.113) from (6.111) with x = V or y = 1'. (6.114): u;x -v\y =: x
(6.59)
-u;(v;y)
(6.112)
x - ( u - v);y
< (u-v);(y-
(6.44)
(u-vj;x)
<,{u-v);{x-y) <. u:x v:y
Th.265, (6.57), Th. 270 Th. 265
(6.115) follows from (6.114) by converse duality. (6.116): u- (x;y);z
= u- (x;y
u;z);z
< u- {x\y
z);l
(6.49) u< V
< u- ((x
z;y);y);l
(6.46) Th. 265
(6.102)
A
= u- (x
z\y) \\ A
< u- (x
(6.66)
z\y)
= u-V
(x
= u- V
(x-
z; y); (x
z; y)"
z;y);(x-y;z)
The opposite inclusion follows by converse duality.
Th. 247, R 7 , Rg Th. 265
334
6. RELATION ALGEBRAS
The next theorem shows what more can be deduced if the elements in question are also atoms. For example, the inclusion in the conclusion of (6.106) can be replaced by equality, according to part (iii). x,y,z
Theorem 330 (Maddux [142, 3.5, 5.12], [150, 12]). Assume 21 £ WA and 6 Af$l. eAt2L. xd,x' If x;y ^ 0 then x' = yd. If x < y\\ then xd = yd If x < \\y then x' = y'. If x < y;z then xd = yd, x' = z', and y' = zd. The following statements are equivalent: (a) v = x', (b) v < V and x < x;v, (c) v < V and x;v = x. (vii) The following statements are equivalent: (a) u = x6, (b) u < V and x < u;x, (c) u < V and u;x = x. (i) (ii) (iii) (iv) (v) (vi)
P R O O F , (i): A s s u m e x A -y 0. T h i s m e a n s t h a t x;x-V -y 0, w h i c h i m p l i e s (1' y);x x ^ 0 b y t h e cycle l a w . B u t t h e n x < (V y);x since x is a n a t o m . Hence x
= x ; x 1
<{V
-y);x-x-V
= (V-y);(x;x)-V
(6.108)
< 1' y
(6.66)
This establishes that xA y ^ 0 implies xd < y for every y, which means that xd is an atom. (ii): If x-y ^ 0 then (x;x');(yd;y) ^ 0 by (6.72), so x;(x' yd);y ^ 0 by d (6.111). This implies x' y ^ 0, but x' and yd are cycles, so x' = yd. (iii): Suppose x < y;l. Using (6.72), (6.108), and (6.114) we obtain 0 ^ x = xd;x
yd;y;l = x d ; x - yd;(y;l) = (xd yd);(x
y ; l ) ,s o 0 ^ i
d
- y d , hence x
d
=y
d
.
(v): Use (ii), (iii), and (iv). The following theorem is an abstract equational version of Th. 31. The first part fails in the very nonassociative relation algebra; see Maddux [142, 3.7(2)] or §6.27. The second part was first proved for relation algebras by Monk [175]. Theorem 331 (Maddux [143, Th. 13]). / / 2 l e WA and x,y e A then (6.117)
(x^yy-(x^y)
< x ; x + (V
(6.118)
x,y € Fn2l => x*\y £
y);y + y;(V
y),
22. ELEMENTARY ARITHMETIC IN WA
338
Let z = x f y. Then z;x
(6.119)
and we also have (6.120)
z-x
since x = x;V
Re
= x ; ( V -y)+x;(V < 1;(1'
-y)
+x;y
Th. 261 T h . 265
Therefore, (6.121)
z\{z-x)
Th.265
(6.119), (6.120)
= y-l;(V-y)
Th.276
= y;(V-y)
(6.62)
and, by converse duality, t 1 991
{% .
5- <" (V . « ^ - «
We therefore obtain z;z = (J (E + »));(« (a; + 5)) = (z x);(z + (z -W);(z
x) + (z x);(z x) + (z -W);(z
Ri-Rs, Th. 246 -x)
-x)
R 5 , T h . 261
< x ; x + z ; ( z - x ) + (z - x ) ; z + z ; ( z - x )
Th. 265
<x;x
(6.121), (6.122)
+ y ; ( V y) + (V -y);y
<x;x + y;y
Th.265
For every matrix a £ MBSl, let a2 := a; a. Theorem 332 (Ladkin-Maddux [127]). Let 21 e WA and a e M s a . J/ a = a < 1» i/ien (a 2 ) 2 is closed. PROOF.
Let
r"aoi;aii;ai2;a22;a2o b = a- an;ai2;a22;a2o;aoo La22;a2i;an;aio;aoo
aoo;ao2;a22;a2i;aii aio;aoo;ao2;a22;a2i a22;a2o;aoo;aoi;an
aoo;aoi;an;ai2;a an;aio;aoo;ao2;a a2o;aoo;aoi;an;a
Since a satisfies the diagonal condition it follows by Th. 329 that all ways of inserting parentheses into the terms denoting the entries in 6 produce the same
336
6. RELATION ALGEBRAS
result. This is crucial for many computational steps that come later in this proof, but will not be mentioned again. Notice that b is symmetric, since, for example, 612 = (621)" = (021
a22;a2o;aoo;ooi ; o u ) "
= (021)" (022 ;o2o;ooo;ooi ; « n ) " = (021)" ( a n ) " ; (aoi)";(aoo)";(ffl2o)"; (0122)" =
o i 2 - a i i ; a i o ;aoo ;ao2 5022
=
o i 2 - a n ; a i o ;aoo ;ao2 5022
= 612.
Next we show 6 is path-consistent, i.e., b < b2. The computations are all similar, but fall into different types, depending on whether subscripts are distinct or repeated. Out of 27 computations we present four that illustrate the various types. 601 = 001 aoo; ao2; 822; fl2i; a n = aoi
(aoo;ao2
aoi ;(a22;a2i ; « n ) " ) ; (a22;a2i ; a n
< (aoo;ao2
«oi; («22;ffl2i ;aii)");(ffl22;«2i ; « n
= (ooo;oo2
a o i ; a n ;ai25022)5(022 5021 ; o n
= (002
aoo ; a o i ; a n ; a i 2 ;a22); (a22 ;a2i
= (002
aoo;aoi ; « n ;ai2;a22);(a2i
(aoo;0-02)";aoi)
(aoo; 002)"; aoi)
020;ao
a2o ;aoo ;aoi ;
a22;a2o;aoo;ao
= 6025621-
This first computation can be used to shorten the next one. 610 = 610 = (601)" < (6025621)" = (621)"; (602)" = 6125620 = 6125620600 = aoo
aoi ; a n ;ai2 5022 5020
< (aoi
aoo 5 ( a n 5012 5022 5020)") 5 ( a n ;ai2 5022 5020
= (aoi
aoo ;ao2 ;a22 ; o 2 i ; o i i ) ; ( f l i i ; o i 2 ;a22 ;a2o
= (aoi
aoo;ao2;a22;a2i ; a n ) ; ( a n ; a i 2 ;a22 ;a2o;aoo
(aoi)";aoo)
010 ;aoo) fflio)
= 601;6io-
Finally, 600 < aoo < 1' by the diagonal condition on a, so 600 = 600 -6oo = 600; 600 We may conclude that 6 satisfies the diagonal condition and is closed, since 6 is both symmetric and path-consistent. From 6 < a it follows that 62 < a2. But 6 is path-consistent, so 6 = 62 < a2. This in turn implies b2 < (a2)2, so, using the path-consistency of 6 again, we get 6 < (a 2 ) 2 . Next we show (a 2 ) 2 < a. Again, we only give a sample computation. The others are similar. We have ((a2)2)oi < aoi by Th. 327, and ((a 2 f)oi <(a 2 ) 0 2 ;(a 2 ) 2 i = (aoo;ao2
aoi ;ai2
ao2\a-22);(020;aoi
< (aoo ;ao2
ao2 5022); (021 ; a n )
«2i ; « n
022 ;
22. ELEMENTARY ARITHMETIC IN WA
0
1 2
3
4
5
337
6
FIGURE 1. Picture of relational matrix m = (ao2 ooo ;oo2 5022); (0,21 ; < aoo; 0,02', 0,22 ;o2i ; o n , 2 2
so ((a ) )oi < aoi aoo;ao2;a22;a2i ;on = 601 Thus we have b = (a 2 ) 2 . Since 6 is closed, so is (a 2 ) 2 , as desired. Th. 332 fails for 4-matrices, even if 21 £ RRA. For an example showing this, define a matrix TO02
moo —1
(mis
'
1
(w), 77122
77123
(m 2 3)~
by setting, for all i,j < 4, Hi = {(P, i)
A(p) = i, X(q) = j}
where f0 1 A«fc,/» = 2 13
if A; is even and I is even if k is odd and / is even if k is odd and / is odd if A; is even and I is odd
Let ao := 77i, and a^+i := (aj;)2 for k £ a;. In Figure 1, the set a;2 (= a; x a;) is arranged and each pair p 6 w2 is labelled with A(p). For all i, j < 4, m,j is the set of all pairs (p, g) £ (w2)2 such that A(p) = i, X(q) = j , and either p = q or else there is a horizontal, vertical, or diagonal line segment connecting p with q. Thus, for example, moo consists of all those pairs (p,p) such that X(p) = 0. Elements of w2 connected by a line segment will be called adjacent. Hence moi consists of those pairs {p, q) such that p and q are adjacent, X(p) = 0, and X(q) = 1. It is straightforward to verify that ao > a\ > 02 > 03 > . To get started, notice that all the adjacent pairs in the first column of Figure 1 belong to
338
8, RELATION ALGEBRAS
or mio. All the ones in wioi are excluded from either fno3|nisi or moalmai. But (m2)oi C (mo3|m3i) n (mo2|ro2i), so all such pairs are also excluded from (m2)oi. Similarly, adjacent pairs in the first column which belong to mio do not belong to (wi2)io- None of the adjacent pairs in the first column appear in any entry of m 2 . Pairs of the form (p,p) are in m 2 , except when p = {0,0) since {0,0) ^ moa|mao. All adjacent pairs eventually disappear. 23. Properties of bases We can now prove some properties of bases using results from the previous section. The next theorem contains various useful facts. Bn%
Theorem 333 (Maddux [146, Lem.6]). Suppose 3 < n < w, SI £ NA, N C (6.99) holds, and (6.100) holds. Let Ni := Tf (SI) n N2 for every i < n. (i) Mi'1 =Ni= Ni\Ni for all i < n. (ii) JVi|iV,- = N§\Ni for all i,j < n. (iii) Ifn
( v i ) Ifio,...,i/3-i,j,k
< n , » 0 , . . . , * / 3 - i , i , f e are distinct,
7 = [*0/j] o
o
[ip-i/j], and a-y Nk b, then there is some c € N such that c Nk a and cy = b. a ^ ^ (3c) y PROOF, (ii): It suffices to show that Nj\Ni C Ni\Nj for any i, j < n. This is obviously true if i = j , so assume i =£ j and a iV)|iVj c. Then a agrees with c up to *, j . By (6.99), there is some be N such that a Ni\Nj c. (iii): Assume
(6.123)
<% = b^ for all «,j < 2.
Define a function 7 : n —> n by J
7 = [2/0] o
fl \0
if & = 1 if Jfe = 0 , 2 , 3 , . . . , n - l ,
o [n - 1/0] = [n - l/0]|
|[2/0].
23. PROPERTIES OF BASES
339
T h e n , b y (6.123) a n d (6.100), 0 7 = bj, a N2 a[2/0]
N3 o [ 2 / 0 ] [ 3 / 0 ] JV4
6 N2 6 [ 2 / 0 ] Ni 6 [ 2 / 0 ] [ 3 / 0 ] Ni
Nn-2 Nn-2
o[2/0][3/0] 6[2/0][3/0]
2/0] iVn_! 0 7 , - 2/0] A ^ _ i 67,
so
aN2\---\Nn-1\(N2\---\Nn-1)-1b, but N2,...,
JVn_i are commuting equivalence relations by (i) and (ii), so N2\
\Nn-!\(N2\
l A ^ - i ) " 1 = N2\
\Nn-!
hence a N2\ \Nn-i b. (iv): From aij = bij we get aji = (ciij)" = (bij)" = bji by (6.93). We have aij < an;a,ij by (6.94), an < 1' by (6.92), and 21 e WA by hypothesis, so an = (a^)6 = V 0^5(0^)" by (3.5), (6.93), and Th. 330(vii). Similarly, bn = (bij) . From aij = bij we conclude that an = bn. A dual argument shows a
jj
= bjj
(v): Since a Ni a[i/j], by hypothesis, a[i/j] Nk b, it follows that a and 6 agree up to i, k. By (6.99) there is some c E N such that c Nk a and c Ni b. We must now show c[i/j] = b. Since c Ni b, we assume i ^ l,m < n and note that c[i/j]im = cim = bim, so what remains is to deal with arguments involving i. For this we need some equations involving only 6. We have 6 j m = 6;m since bjm
(6.94)
(6.92), Th. 265
= blm
Th. 270
(6.94)
(6.92), Th. 265
= bjm
Th. 270
By a similar calculation, involving R,6 instead of its dual Th. 270, we also get bij =bn. Therefore,
= bjm
cNib,
i ^ j ,m
340
6. RELATION ALGEBRAS
Finally, c[i/j]u = Cjj = djj
c Nk a, k / j
= ba (vi): By induction from (v).
a[i/j] Nkb, k
Some interconnections among the notions of semantical, cylindric and relational bases are given next. We will show that for an atomic WA, every cylindric basis is a relational basis, and the converse holds if n is 3 or 4. The first of these implications fails for NA. See Hirsch-Hodkinson [99, Ex. 12.6(5)] for examples of algebras in NA ~ WA which have, for every n > 3, an n-dimensional cylindric basis but no n-dimensional relational basis. The simplest case of their construction is presented in §6.27. For further discussion of bases, see Hirsch-Hodkinson [99, Ch. 12]. Theorem 334. Assume 21 G NA, 2 < n, and N C Bn2l. (i) If N is an n-dimensional semantical basis, then N is an n-dimensional cylindric basis. (ii) / / n > 3, 21 G WA, and N is an n-dimensional cylindric basis for 21, then N is an n-dimensional relational basis for 21. (iii) / / n G {3,4}, 21 G WA, and N is an n-dimensional relational basis for 21, then N is an n-dimensional cylindric basis for 21. PROOF. Part (i) is a trivial consequence of the definitions. Part (ii) follows immediately from part (iii) and either part (i) or part (ii) of Th. 335 below. Part (iii) follows from Th. 335(iv)(v)(vi) below.
Theorem 335. Assume 21 G NA, 2 < n, and N C Bn2t. (i) Ifn > 3, 21 is atomic, and (6.98), then (6.96). (ii) Ifn > 3, 21 G WA, and (6.98), then (6.96). (iii) Ifn > 3, 21 G WA, (6.98), (6.99), and (6.100), then (6.97). (iv) / / (6.97) then (6.100). (v) Ifn>3, (6.96), and (6.97), then (6.98). (vi) Ifn€ {3,4}, 21 G WA, and (6.97), then (6.99). (vii) Ifn > 3, 21 is atomic, (6.96), and (6.97), then 21 G SA. (viii) Ifn > 4, 21 is atomic, (6.96), and (6.97), then 21 G RA. Let Nt := 17(2!) n N2 for every I < n. (i): Let x G AfVL. Since 21 is atomic, we have
PROOF.
0 ^ x = x;V = x;
2_, l'>u£AtSi
u=
T j x;u. l'>u£AtSi
Hence there is some u G AttH such that u < V and x x;u ^ 0. But x is an atom, so x < x;u. We may now apply (6.98) to get some a G N such that aoi = x, 0.02 = x, and 021 = u.
23. PROPERTIES OF BASES
(ii): Let x £ Am. Then x = x6;x by (6.72) and x6 G Am by Th.330(i). By (6.98), there is some a 6 N such that aoi = x, ao2 = x6, and a-ii = x. (iii): (Hirsch-Hodkinson [99, 12.36]) Our assumptions are 21 6 WA, (6.98), (6.99), (6.100), and n > 3. For now we also assume that either n > 4 or i = j . The case in which n = 3 and i ^ j will be handled later. Suppose a 6 N, i,j, k < n, i,j ^ k, x, y E Ai2l, and a^- < x;y. We wish to find some b E N such that a iVjt fe, bik = x, and 6fcj = y. We start by applying (6.98) to obtain some c € N such that coi = aij < x;y, co2 = x, and c 2 i = y. Next we need some general observations about composing substitutions with functions that are not onto. Suppose a : n —> n and Ra (a) C n (a is not onto). Choose k < n with k £ Ra(a). Then, for any distinct i,j E Ra(a), we have o"|[j'/fc]|[i/j]|[fc/i] = o"|[*,j] and Ra(a\[i,j]) = Ra(a). Every permutation of Ra(a) can be obtained by composing transpositions [i,j] with distinct i,j £ Ra(a). It follows that if -K : n —> n and vr permutes Ra(a) then there is some function T : n —¥ n, which can be obtained by composing substitutions on n, such that (T\T = (T\K. From this observation it is easy to prove that every function which maps n onto a proper subset of n can be obtained by composing substitutions. Choose I E n ~{i, j , k}, which is possible since i = j or n > 4. Then {«, j , k} C Ra ([l/k]) C n. Let TT : n — n be the permutation determined by these conditions:
TT(J)
< 7r(j) & i ^ j ,
7r(m) = in it in E n ~{i, j , fe}. Since the range of [l/k] is a proper subset of n, there is some r obtained by composing substitutions on n such that [Z/&]|r = [l/k]\w. Let
f0 One can now check that a(i) = 0, o{k) = 2, and a(j) = < [1
if i = j . Clearly a iii^j
can be obtained by composing substitutions on n. By (6.100), from c £ N we get co £ JV. Note that if i ^ j then (ca)ij = ca^)a(j) = coi = ai:(- < x;y, (ca)ik = cCT(i)
= c 2 i = y.
Suppose i = j . Then coi = By = OJJ < 1', so coi < coo;coi < coo;l' = coo, which implies coi = coo since coi and coo are atoms. Similarly, y = C21 < C2o;coi < C2o;l' = C20, so y = C2o- Hence (ca)ij = coo = coi < x;y, (ca)ik
= C02 =
x,
(ar)kj
= C20 = y-
6. RELATION ALGEBRAS
1. 2. 3. 4. 5. 6.
i 0 0 1 1 2 2
j 1 2 0 2 0 1
fe
aij
2 1 2 0 1 0
aoi
<
a02
< x;y
aio
<
x;y
ai2
<
x;y
ci2o <
x;y
a
x\y
TABLE
2i
&01
bo2
&21
aoi
X
x < ao2',y
X
ao2
y y
aOi < y;x x < y;a2i
Ooi
y y
X
y < ao2 ;x y < x;a,2i
y y
«02
X
X
0,21
<x;y
<
x;y
«oi <
x;y
X
C121
1. Part of the proof of Th. 335 (iii)
We have (ca)ij = ciij, hence also (ca)ji = ciji. Since 21 £ WA, we also get (ca)a = an, and (ca)jj = ajj by Th.333(iv). Thus a and ca agree on all arguments \Nn-! c by Th. 333(iii). By Th. 333(ii) the relainvolving i and j , hence a N2\ tions JV(_) are commuting equivalence relations, so we may rearrange them to get \Nmr c, where {mi,m,2, mr} = n~{i,j,k}. Consequently a Nk\Nmi |iV m2 | \Nmr {ca). there is some basic matrix b £ N such that a Nk b and b Nmi |iVm2 | The latter statement implies 6^ = (cxr)n. = x and bkj = (co~)kj = y- This completes the proof of (iii) under the assumption that n > 4 or i = j . We now assume n = 3 and i ^ j . In this case we have {«, j , k} = 3, x, y £ At%, and dij < x;y. We wish to find 6 6 N with a Nk b, bn, = x, and bkj = y. Table 1 shows what to do according to the values of i and j . For example, line 4 in Table 1 deals with the case i = 1 and j = 2. These values are given in the i-column and j-column. The hypothesis ciij < x;y is repeated for this case in the fifth column: ai2 < x;y. The sixth column contains a statement equivalent to the one in the fifth column. In line 4, the hypothesis ai2 < x;y is equivalent by (6.150) to x < y;ci2i. We apply (6.98) to this inclusion and conclude that there is some b £ N such that &oi = x, 602 = y, and 621 = 021, as specified in the last three columns of Table 1. Recall that we want a Nk b, bn- = x, and bkj = y. In line 4 we have k = 0, so we want to know is that a No b, bio = x, and 602 = y- We already have 602 = y and we get 610 = x from 601 = x. From 621 = 021 we get bi2 = ai2, 622 = (I22, and fen = an by Th. 333(iv) since 21 e WA, hence a No b. This argument happens to also show that (6.98) implies (6.101) when n = 3. (iv): Let a £ N, i,j < n. If i = j then a[i/j] = a £ N, as desired. Assume i ^ j . Then ajj <
bji = ajj,
an
d &ij = ajj. But then we also have ba < bij ;bji = ajj ;ajj = ajj by
(6.58), so bu = ajj. We have shown a Ni b. (v): Suppose n > 3, x,y,z £ At%, and x < y;z. By (6.96) there is some a £ N such that aoi = x. By (6.97) with i = 0, j = 1, and k = 2, there is some fe £ N such that a N2 b, 602 = y, and 621 = z. The first of these last three statements gives us 601 = aoi = x. (vi): Assume a,c £ N, i,j < n, i ^ j , and a agrees with c up to i,j. We wish to show that there is some fe £ N such that a Ni fe Nj c. Since n is 3 or 4, we may choose k,l £ n ~{i, j} so that n = {i, j , k, I}, where k = I iff n = 3. We have aui = CM < Cki ;cu, so by (6.97) there is some d £ N such that a Ni d, dki = Cki,
23. PROPERTIES OF BASES
343
and dn = cu. Since 21 £ WA, b y Th.333(iv) we also have dik = Cik, du = cu, da = cu, dkk = Ckk, du = CJJ. Since a iV, d, a agrees with c u p t o i,j, a n d k, I are distinct from i,j, we also have dki = aki = cki, dik = aik = cik, dkk = akk = ckk, and du = an = cu. The last fifteen equations establish that d Nj c, so we may simply let b = d. (vii): ([150, Th. 35]) To show 21 € SA it is enough, by Th. 182 and Th. 276, to show that p; 1; 1 < p; 1 for every p G A, for which it suffices to prove that every atom below p; 1; 1 is also below p;l. Suppose (6.124)
v < p ; l ; l and v £ At%.
In every NA, left and right relative multiplication by a fixed element are completely additive functions (see Th. 296), so
Th. 182 ;x :p>w€
At%,x € A i 2 l } ; ^ A i 2 l
Th. 296
w;x >y€ At%,p > w £ At%x € Am}; ^ >z
w x
i iV)z
AM
^ At2l,y < w;x,w < p)
Th. 182 T h . 296
It follows t h a t there are w, x,y,z € At$l such t h a t (6.125)
v
y<w;x,
w
Since N is a relational basis and v £ At%i, by (6.96) there is some a £ N such that aOi = v.
(6.126)
Thus ooi < y,z- By the extension condition (6.97), there is some b E N such that (6.127)
602 = y,
621 =z,
aN2 b.
Similarly, 602 < w;x, so by (6.97) there is some c £ N such that (6.128)
cOi=w,
C12 = x,
b JVi c.
By (6.127), (6.128), (6.93), and (6.94), (6.129)
aoo = boo = coo < coi;cio = w;w.
Note that w is also an atom by Th. 251. By (6.129) and the extension condition (6.97) there is some d £ N such that (6.130)
do2 = w,
dio = w, and a N2 d.
Using (6.126), (6.130), Th. 262, and Th. 179(i) we get (6.131)
v = aoi = doi < do2',d2i
= w;d2i
Steps (6.124)—(6.131) show that v < p; 1 whenever v < p; 1; 1 and v £ At%i. Since 21 is atomic, this shows p; 1; 1 < p; 1.
344
6. RELATION ALGEBRAS
(viii): ([143, T h . 5]) To prove 21 £ RA it is enough t o show t h a t p;q;r < p;(q;r) for all p,q,r E A , a n d for this it is enough t o show t h a t every a t o m below p;q;r is also below p;(q;r). Suppose v
(6.132)
and v G AM.
By Th. 182 and Th. 296 we have v
At%}; ^{x
;x :p;q>wG
: r > x E At%}
At% r>xG
Am],
so there are atoms w,x 6 Af2[ such that (6.133)
v<w;x,
x < r.
w
Since N is a relational basis and v € AtQl, by (6.96) there is some a £ N such that (6.134)
ooi = v.
From (6.133) and (6.134) we have aoi < w;x. By the extension condition (6.97), there is some b E N such that (6.135)
bo2 = w,
a N-2 b.
621 = x,
Using (6.133), Th. 182, and Th. 296 we get w
>z& Am},
J2 so there are a t o m s y,z E At% such t h a t W
(6.136)
V < P,
z
< Q-
Since 602 = w < y;z we conclude by (6.97) that there is some c £ N such that (6.137)
C03 = y,
C32
= z,
b N3 c.
Then v = aQ1
(6.134)
= 601
(6.135)
= Coi
(6.137)
< C03 S(C32 ; c 2 i )
(6.94), Th. 265
=
(6.137), (6. 135)
y\{z;x)
(6.136), (6. 133), Th. 265
24, »-DIMENSIONAL RELATION ALGEBRAS
348
24. n-dimensional relation algebras Following Maddux [146, Def. 3(ii)], [150, Def.34(iv)], and Hirsch-Hodkinson [99, Def. 12.30], we say for every n > 2 that 21 is a relation algebra of dimension n if 21 is a subalgebra of a complete atomic NA that has an n-dimensional relational basis. RA» is the class of relation algebras of dimension n. These classes fall into a chain. Theorem 336. Ifn<m
then RAro D RAK.
PROOF. Suppose n < m and let 21 E RAm. Then SI C 95 for some complete atomic 58 6 NA which has an m-dimensional relational basis M C Bm?B. Let N := {(a,ij : i,j
The definition of RA» differs from that of MA» in Maddux [143, p. 82] where, for n > 3, 21 g MA» iff 21 is a subalgebra of some complete atomic SA (not merely NA) which has an n-dimensional relational basis. Allowing any NA has the following effect: Theorem 337 (Hirsch-Hodkinson [99, Ex. 12.3(10)]). RA2 = NA. It is easy to check that B»2l satisfies the face condition (6.100) and the permutation condition (6.101) whenever SI E NA. In the next theorem we see that BnSi also satisfies the atom cover condition (6.96) whenever St 6 WA, even if 21 is not atomic. Theorem 338 (Maddux [150, 49]). 1/21 € WA and x g AM then X
If2
X
then there is some a E Bn2l such that aoi = x. \xd x~\ „ r . Using only the assumption that SI E NA, we
Let b =
PROOF.
\_x
x J
conclude that b is symmetric since
\x<* I X
X'\
\_X
X'
and b is path-consistent since, by (6.72) and (6.58), ,
,
\xA \_x
xd
x~\ x \
x;x x x
\xA \_x
x~\ x \
\x ,x x ; x \_x;x x , x
x x 1 _ IV x' x;x\ \_x
x ,x-x;x' x;x-x,x
a;l _ , x'\
From x G At2l we get x G At2l using only that SI E NA, but to conclude xd,x' E j4iSl from Th. 330(i) we also need to know SI E WA. Hence b E BaSl- For a given n > 2 let a = bw where w : n — 2, TT(O) = 0, and ir(i) = 1 whenever 1 < i < n. Then a € Bn3l and aoi ^ 6?roi = ft^-rowm ^ 601 ^ x. D
346
6. RELATION ALGEBRAS
Theorem 339 (Maddux [139, Th. 10(18)(20)], [143, Th.4,5], [150, Th.35]). Suppose 21 € WA and 2t is atomic. (i) The following statements are equivalent: (a) 21GSA,
(b) B32I is a 3-dimensional semantical basis for 21, (c) the extension condition (6.97) holds for B32I. (ii) The following statements are equivalent: (a) 21 e RA,
(b) B42I is a 4-dimensional semantical basis for 21, (c) the extension condition (6.97) holds for Bt%. PROOF. For any n > 2, if N = Bn%. then clearly (6.95) holds, and it is easy to check that (6.100) and (6.101) also hold. Thus Bn2l is a relational basis for 21 iff the extension condition (6.97) holds, and Bn2t is a semantical basis for 21 iff the amalgamation condition (6.99) holds. By Th. 334, the notions of relational, cylindric, and semantical basis coincide when n = 3 or n = 4, so all we need to do for both parts is show that the semiassociative holds in 21 iff the extension condition holds for #321, and that the associative law holds iff the extension condition holds for B42I. (i): Assume 21 €. SA. We will verify the extension condition (6.97) in case i = 0 = j and k = 1. The cases in which i / j do not require 21 € SA. Suppose
5.138)
flOO
101
flO2
aid
011
ai2
0,20
021
€B 3 2t.
Assume x,y € Ai2t and aoo < £;3/- We wish to find some b € -B32I such that a and 6 agree up to 1, 601 = x, and 610 = y. First we have 0 / aoo = aoo
x\y
< x;(y
x;aoo)
rot
<x;(y-x;V)
000 < 1'
= x;(y-x)
R6
It follows by t h e n o r m a l i t y of ; t h a t 0 / y x, b u t y a n d x are a t o m s , so y = x. Hence also x' = y6. Notice t h a t aoo < 0025020 < a o 2 ; l by (6.94) since a G B32I, a n d aoo < x;y < x;l by a s s u m p t i o n . We therefore have 0 / aoo < x;l
ao2;l
^ (ao2 ( - E i l ) ) ! ) ? !
^ot
= (002 - a ; ; l ) ; l
21 G SA
< (s;(^;ao2));l
rot
24. rc-DIMENSIONAL RELATION ALGEBRAS
Hence there is an atom z < x;ao2- Let (6.139)
faoo
x
002
6 = 2 /
x'
z
\jl20
Z O,22_
Clearly a and 6 agree up to 1, 601 = x, and 610 = y. It is easy to check that 6 E B 3 2t. For the converse, assume B32I satisfies the extension condition (6.97). We need only show ( p ; l ) ; l < p ; l for every p E A. Suppose ( p ; l ) ; l > x E At%. We are assuming 21 E WA, so by (6.104) we get
y;z. p>y<EAt<2l
Hence t h e r e a r e a t o m s y,z € At$l such t h a t xA < y;z, y < p, a n d z < p. Let r d
x
x
x
X
X
X
£
x'
x'
Then a G B^A by Th. 338, so by the extension condition (6.97), it follows from ^ V\z that there is some 6 6 B3IH such that a and 6 agree up to 2, 602 = y, and 620 = z. Consequently
a;d
6 =
X
y'
X
x'
612
z
621
622
and x = boi < bo2',b2i = J/;&2i < p ; l , as desired. (ii): For one direction, we assume 21 E RA and verify the extension condition (6.97) for B42I in case i = 0, j = 1, and k = 2. Suppose 0,00
aoi
ao2
aio
an
ai2
ao3
ai3
020
fl2i
022
023
030
031
032
033
Assume 1 , 5 6 At% and aoi < x;y. We wish to find 6 £ i?42l such that a and 6 agree up to 2, 602 = a;, and 621 = y- We have a o i < x;y
ao3;a3i
< x;(y =
rot
x;(aO3;a3i))
21 E RA
x;(y-(x;aO3);a,3i)
< x;((x;a03
rot
y;ai3);a3i)
so there is an atom z < x;ao3 y,ai3.
Let
aoo aio
aoi ttii
x y
x
y
x'
z
030
031
z
033
6 =
003 ^13
348
6. RELATION ALGEBRAS
Clearly a and b agree up to 2, bo2 = x, and 621 = y- What remains is to show that 6 6 B^%. This is easy but there are many cases to check. For some of them it helps to note that 622 = x' = yd £ AVOk. In other cases the defining conditions on z are involved. For example, 623 = z < x;ao3 = 620; 603 For the converse, we assume that Bn% satisfies the extension condition (6.97) and show that 21 is associative. Suppose p,q,r £ A and (p;q);r > x £ At%. We wish to show x
x<(p;q);r=
^2 (P;?);J/, r>y£At<&
so there is an atom y £ At$l such that y < r and
x<(p;q);y= so t h e r e i s a s o m e a t o m z £ At$l
z y
Yl
''
s u c h t h a t x < z;y a n d
z
Yl
u;v,
p>u£Atm, q>v£At<&
so there are atoms u, v £ Ai2l such that u
X
X
X
x' x' x'
x' x' x'
x' x' x'
Then a 6 B^% by Th. 338. Since aoi = x < z;y, we may apply the extension condition (6.97) to get some 6 £ B^% such that a and 6 agree up to 2, 602 = 2, and 621 = y- Since 602 = z < u;v, we may apply the extension condition again to obtain c £ B42I such that 6 and c agree up to 3, C03 = u, and C32 = v. Then we have x = aoi = 601 = coi < Co3;c3i = u;c3i < M; (0325021) = u;(v;b2i) u v
\i \y)
=
^Pj(QrJr); a s desired.
Now we may characterize SA as the class of 3-dimensional relation algebras, and RA as the class of 4-dimensional relation algebras. Theorem 340 (Maddux [143, Th.6]). (i) RA3 = SA; (ii) RA4 = RA. PROOF. Proof of (i): If 21 £ SA then 21 C 21+ £ SA by Th.326, 21+ is complete
and atomic, and 2l+ has a 3-dimensional semantical (hence relational) basis by Th. 339. Proof of (ii): If 21 £ RA then 21 C 21+ £ RA by Th. 326, 21+ is complete and atomic, and 2l+ has a 4-dimensional semantical (hence relational) basis by Th. 339. Theorem 341. (i) (J), (L), and (M) hold in every atomic RA that has a 5-dimensional relational basis. (ii) RA5 |=
24. n-DIMBNSIONAL RELATION ALGEBRAS
349
PROOF. Proof of (i): Assume 21 is an atomic RA and N is a 5-dimensional relational basis for 21. We show only that (M) holds. Let £01, £02, £03, £32, £21, £24, £41
G
^"
Following Lyndon's notational convention, we let Z30 = (£03)" and x\\ = (s4i)". Since 21 is atomic, it suffices, by Th. 182, to show for every atom poi £ At$L that if (6.140)
poi < £01 (^02
£03 52:32) 5(221 2:24 ;
then (6.141) poi < £03; ((£30; £01 '£32; £21); x 14 -£32 ;»24 -£30; (#01 ;£i4 -£02 52:24)) ;am-
From (6.140) it follows by Th. 182 and Th. 296 there are additional atoms P02,P03,P32,P21,P24,P41 £ At01.
(6.142)
such that p02 < xO2, P03 < xO3, P32 < a;32, P21 < £21, P24 < x24, pa < £41, and (6.143)
0 / poi < (P02 P03 ;P32); (P21 P24 ;p4i).
This implies poi < P02JP21- By Th. 335(v) the cycle cover condition (6.98) holds, so we may apply it to obtain some a £ N such that (6.144) ooi=poi, aO2=po2, 021=^21From (6.143) we know that 0 7^ P02 -po3',P32 and 0 7^ P21 -p24;p4i, but P02 and P21 are atoms, so (6.145)
O02 =P02 < P03JP32,
(6.146)
a 2 i =P2i < P245P41-
By applying the extension condition (6.97) to (6.145) we obtain some b € N such that (6.147) a and 6 agree up to 3, &03=P03, Since a and b agree up to 3, (6.146) gives us
632=^32-
(6.148) 621
C32;C24
C30;C04); C41
< co3;((c3o;coi
0325021);ci4
0325024
0305004)5041
< C03;((0305001
0325021)5014
0325024
C3o;(coi;ci4
= &03 5 ((6305001
&32;O2l);Cl4 ' &32 5C24
= P03 5 ((P30 5P01
P32 ;P2l) ;P14
< £03; ((s3o;a;oi
a;32;K2i);a;i4
P32 5P24
C025024))5041
63O;(aoi!Cl4
O02 5 C24)) 5 C41
P30 5 (poi 5P14
£32;s;24 ' a;3o;(a;oi ; £ i 4
P02 5P24)) 5P41 £02 ^ 2 4 ) ) ; £ 4 i
350
6. RELATION ALGEBRAS
Proof of (ii): If 21 G RA5 then 21 is a subalgebra of such an atomic 93 G RA with a 5-dimensional relational basis. Then 03 |= (J), (L), (M), but (L) and (M) are equations and (J) is a universal sentence, so they hold in all subalgebras of 03, including 21. The next theorem gives a useful sufficient condition for the existence of a semantical basis. The condition (Dn) is called the n-diamond condition. Theorem 342 (Maddux [146, Th. 7]). Suppose 3 < n < ui, 21 € WA, 21 is atomic, and (Dn)
7 / 0 ^ x i , . . . ,xn-2,yi,..
,2/rc-2 < 0', then 0 ^
n-2 ]J k=i
xk;yk.
Then fln2l is an n-dimensional semantical basis for 21. It is easy to find many examples of finite relation algebras (such as 9k (U) with \U\ < co) which have semantical bases even though they do not satisfy (D n ). However, it is shown in Th. 471 that "almost all" finite integral relation algebras satisfy (Dn). On the other hand, (Dn) will fail for essentially all nonintegral relation algebras. Here is a generalization of Th. 342 which applies to all relation algebras, including the nonintegral ones. Theorem 343 (Maddux [146, Th. 8]). Suppose 3 < n < ui, 21 G WA, 21 is atomic, and (D'n)
7 / 0 ^ xi,.. n-2
then 0 ^ n
. , x n - 2 , 2/i,...,2/n-2
< 0 ' , and 0 ^
n-2 Yl fc=i
xk;l;xk;yk;l;yk,
x
k; Vk
fc=i
Then Bn2l is an n-dimensional semantical basis for 21. It can also be shown that almost all finite relation algebras satisfy (D'n). 25. Cycles of atoms If the cycle law (Th. 294) is restricted to atoms, it can be restated as follows. Theorem 344. (R1-R3, R 5 , R7-R10) Assume x,y,z (6.150)
e At%.
Then
x ; y > z < = > x ; z > y <£=> z \ y > x <£=> z ; x > y < = > y \ x > z < = > y ; z > x .
PROOF. If x;y > z, then z = x;y z, but z ^ 0 since z is an atom, so 0 ^ x;y-z. By the cycle law, we get five more inequalities: 0 ^ x;z-y, 0 ^= z;y-x, 0 ^ z;x y, 0 ^ y;x z, and 0 ^ y;z x. Since y and x are also atoms, the first two of these statements yield y < x;z and x < z;y. By Th. 251, x, y, and z are also atoms, so the last three statements give us y z;x, z < y ;x, and x < y;z. The six equivalent conditions listed in the cycle law or in Th. 344 are equivalent conditions on triples of atoms, each condition stating membership or nonmembership in a particular ternary relation that we now define. Let 21 be a
25. CYCLES OP ATOMS
351
Boolean algebra with operators of relational type. The cycle structure of 21 is the ternary relation Cy(2l) := {(x,y,z)
: x,y,z € At%Ax;y
> z}.
This relation is empty if 21 is atomless. To conveniently express the equivalent conditions in Th. 294 or Th. 344 we define, for any atoms x,y,z £ At$l, a set of triples of atoms, (6.151)
[x, y, z] := {{x, y, z), (x, z, y), (y, z, x), (y, x, z), (z, x, y), (z, y, x)}.
The set [x, y, z] of triples of atoms is called a cycle. Note that the definition of [x,y,z] depends only on At% and the function": At% —> Atf&., and the definition applies to any algebra of relational type that satisfies R1-R3, R7, and Rs- If, in addition, 21 also satisfies R5, R9, and Rio, then, by the cycle law, the cycle structure of 21 is the union of cycles; every cycle is either contained in or is disjoint from the cycle structure. These two possibilities are distinguished as follows. We say that [x, y, z] is a forbidden cycle of 21 if [x, y, z] fl Cy(%V) = 0, and a cycle of 21 if [x, y, z] C CyipVj. A cycle [x, y, z] is said to be an identity cycle if one (or, equivalently, all) of its triples contains an identity atom, and a diversity cycle if all of the elements in its triples are diversity atoms. Lyndon [133, p. 710] suggested that a triple of atoms (x, y, z) be called a cycle if x;y > z. Any such triple also satisfies the conditions y;z > x, z;x > y, y;x > z, %\z > y, and z;y > x. We have used the condition x;y > z instead of Lyndon's suggested condition x;y > z, because Cj/(2l) is the relation which occurs in the Jonsson-Tarski Representation Theorem [118, Th. 3.10]; see Th. 352 below. Note that a triple (x, y, z) is a cycle in Lyndon's sense iff (x, y, z) is a cycle in the sense followed here. As we see next, if 21 G NA is atomic, then the operations ; and " are completely determined by the cycle structure of 21. When dealing with a ternary relation T, for brevity we will frequently write Txyz instead of (x, y, z) 6 T. Theorem 345. Assume 21 £ NA and 21 is atomic. Let (6.152)
T := Cy(fH),
(6.153)
U := {x : 3y3z(Txyz V Tyxz V Tyzx)},
(6.154)
S := {(0,6) : a,6 £ U,VxVv((Taxy
(6.155)
I := {a:ae
U,VxVv((TaxyV
<S> Tbyx) A (Txay «
Txay)
=> x = y)}.
Then (6.156)
U = At%
(6.157)
V a (a e U => 3bSab),
(6.158)
V a (a eU => 3i(i el A Tiaa)),
and for all atoms a,b G At%, (6.159) (6.160)
Sab O a = b, oe/»a
Tybx))},
352
8, RELATION ALGEBRAS
If x,y € A then (6.161) (6.162) (6.163)
x;y = ^ { c ;x>a€U,y>b€ x = ^{b
U,Tabc},
: x > a 6 U, Sab},
l'=^J.
PROOF. Proof of (6.156): Clearly T C {At%f, so we know ?7 C At a . Suppose a G AtSL. Since SI is atomic we have 1' = 52i'>i1e.Ata'tt> n e n c e 0 / a = a;l' = a;
a £ At 21, Re Jj
« w
St is atomic Th.296(ii)
Consequently there must be some atom w £ At SI such that 1' > w and 0 / a;«. But then a;« < a;l ! = a, hence 0 ^ a;« = a;u a, so {a,u,a) € Cty(Sl). This implies that a eU, and completes the proof that U = At%.. We happen to have also shown that (6.164)
AM = {a : 3«(r > it e A i » , {0,11,(1) g C»(St))}.
Proof of (6.159): Note that So* holds iff, for all x,y e AM, we have (6.165)
a;x-y / 0
&;j/a; / 0,
a;;a j / / 0
y;&- x / 0,
If a = 6 then (6.165) holds by the cycle law. For the converse, we assume (6.165) and show a = b. We saw above that there is some n £ At9l such that « < 1' and 0 / a;n a. From the latter statement we get b;a u / 0 by (6.165), so n;a b / 0 by the cycle law. Since 6 is an atom and u < V, this gives us b < u\a < 1! ;a = a. However, a is also an atom by Th. 251, so we conclude that b = a, as desired. Proof of (6.160): Note that a g I iff for all x,y e At% (6.166)
(a;x- j / / 0 Vx;a- j / / 0) => x = y.
Next we prove that if a < 1' then (6.166) holds for all atoms i , y € At^L. Suppose a;x - i ( / 0 . Then 0 ^ a;x y < 1' \x y = x y, hence x = y since x and y are atoms. Similarly, if x;a y ^ 0 then x = y. Thus a £ I whenever a < 1'. For the converse, assume a £ I. As we showed above, there is some atom n € AtSl such that w < 1' and 0 / a;ti a. Since a G / , this gives us « = a by (6.166), but w < V, so a < 1', as desired. Proof of (6.158): This follows from (6.156), (6.160), and (6.164). Proof of (6.157): This follows from (6.156), (6.159), and the fact that the converse of an atom in an NA is again as atom. Proof of (6.161): We use the complete additivity of left and right relative multiplication, the assumption that atoms are dense, and the definitions of U and T:
x;y = (J2& ; l ^ e E / l ) ; ( Z ^ 6: » > & £ t/})
Th
-182
25. CYCLES OP ATOMS
353
{a;b :x>aeU,y>beU}
Th. 296 Th. 182
: a;b > c 6 U, x > a g U, y > 6 6 U} :m>aeU,y>b£U,
Tabc}
Proof of (6.162): Similarly, we have
* = (y2{a :x>ae
I/})"
= ^{a :x>aeU} = J2& : x -
Th. 182 Th. 249
a e U Sab
' }
(6.159),
and (6.163) follows from (6.160) by Th. 182. In view of Th. 345, it is clear that a multiplication table listing the products of all the pairs of atoms of a given finite relation algebra is nothing more than a (rather redundant) list of its cycles and therefore completely determines that algebra. Lyndon [133] observed that the identity atoms can be characterized among all atoms as those which satisfy ti;w = u. Thus, he noted, a finite relation algebra may be characterized by specifying the mapping " from atoms to atoms and giving a list of cycles. We will specify finite relation algebras in the following way. We list the identity atoms, the symmetric diversity atoms, the pairs of antisymmetric atoms, and the cycles. We usually use notation for the atoms that helps to specify the identity atoms and the action of ". For example, suppose t, e, a, r, and r are the five atoms in a certain finite relation algebra 21 with 32 elements, whose cycles are [i,i,i], [e,e,e], [i,a,a], [i,r,r], [r,e,r], [a,r,r], [a,a,a]. The notation for the atoms tells us the structure of w. We have i = i, e = e, a = a, (r)" = r, (r)" = r. The convention is that since a is listed as an atom, but "a" does not appear in the list of atoms, then a = a. Since r and r are both listed, they are distinct and are converses of each other. We need to know " in order to correctly interpret the notation used to specify the cycles. For example, we know from (6.151) that (6.167)
[a, a, a] ;= {{a, a, a), (a, a, a), (a, a, a), (a, a, a), (a, a, a), (a, a, a)},
but, since a = a, we actually have (6.168)
[a,a,a]:={(a,a,a)}.
To determine that 1' = « + e we must use the list of cycles, (6.155), and (6.160). There is an isomorphism p that embeds the relation algebra 21 thus specified into £He (4). In fact, St is isomorphic to the subalgebra of 9te (4) which is generated by the relation {(0,3), (1,3), (2,3)}. The isomorphic embedding p of 21 into ffte (4) takes these values on the atoms of St:
6. RELATION ALGEBRAS
p{a) = {(0,1) , (1, 0}, (0, 2}, (2, 0 ) , (1,2), (2,1)}, p ( r ) = {<(), 3 ) , < 1 , 3 > , ( 2 , 3 > } , p(r) = { ( 3 , 0 ) , ( 3 , l ) , ( 3 , 2 ) } .
26. Complex algebras of ternary relations In §6.25 we obtained a ternary relation from an atomic NA. In this section we reverse the procedure and start with a ternary relation. Suppose that T £ V is a ternary relation. Let U be the field of T as a ternary relation, that is, (6.153) holds. We use T to construct an algebra of relational type whose universe is Sb (U). First, define a binary operation ; on the powerset of U, by letting, for any X,YCU, X;Y := {c : 3x3y(x € X,y £ Y,Txyc)}. Define the binary relation 5 C U2 by (6.154). Note that S must be a symmetric relation because of the form of its definition. More specifically, (a,b) € S &VxVy((Taxy
<=> Tbyx) A (Txay <=> Tybx)),
{b,a) G S <^VxVy{{Tbxy « Tayx) A (Txby «
Tyax)),
and the two formulas on the right are clearly equivalent. Next we use S to define X C U for every subset X C U by X := {b : 3x(Sxb,x£ X)} = S*(X). Finally, define the subset / C U by (6.155). The operations ; and " along with the distinguished subset / are enough to define, starting from the Boolean algebra of all subsets of U, an algebra of relational type called the complex algebra of T. Cm(T) := (Sb (f/),U,- ; , " , / > . The Boolean part of £m (T) is 581 ({/), the complete atomic Boolean algebra of all subsets of the field of T. The complex algebra Cm (T) is a relation algebra when certain elementary conditions are satisfied by T, as stated in the next theorem. Theorem 346 (Maddux [142, 2.2, 2.6]). Suppose T e V is a ternary relation. Define U, S, and I by (6.153), (6.154), and (6.155). Consider the following six statements. (6.169)
V o (a € U => 3bSab),
(6.170)
V o ( a € ( / ^ 3t(i el A Tiaa)),
(6.171)
VxVyVzVaVb(Txyz ATzab => 3c{Txcb A Tyac)),
(6.172)
VxVyVzVaVb(Txyz ATzab => 3cTxcb),
(6.173)
VxVyVzVaVb(Txyz ATzab A Ix => 3cTxcb),
(6.174)
VxVzVa\/b(TxzzATzabAlx
=> Txbb).
Then (i) <£m (T) is an algebra of relational type,
28, COMPLEX ALGEBRAS OP TERNARY RELATIONS
358
(ii) the Boolean part of £tn (T) is a complete atomic Boolean algebra, (iii) the operators ; and " are normal and completely u-additive (in fac^ 1-additive, and 2-additivel respectively), (iv) if (6.169) and (6.170) then S is an involution, i.e., S : U -* V and S(S(x)) = x for all xeU, (v) Cm(T) g NA iff (6.169) and (6.170), (vi) £m(T) G RA iff (6.169), (6.170), and (6.171), (vii) Cm(T) g SA iff (6.169), (6.170), and (6.172), (viii) Cm(T) g WA iff (6.169), (6.170), and either (6.173) or (6.174). PROOF, (iv) and (v): Assume (6.169) and (6.170). We show that S is an involution. For any a € U we may apply (6.169) to obtain b € U such that Sab. So far this shows Do (S) = U. To show S is functional, suppose there is some c £ U such that Sac. Apply (6.170) to a, obtaining i G I such that Tiaa. By (6.154), the latter condition implies Tabi since Sab, which in turn implies Tcib since Sac, but from i € / and (6.155) it follows that c = b. Therefore S is functional. We already saw that S is symmetric, so 5 is an involution. We may therefore use functional notation with S. From (6.154) we get (6.175)
(a;, y, z) g T
» (Sx, z,y)eT
{Stfl S i , Sz)eT
«
(y, Sz, Sx)eT
(Sx, a;, Sj/} g T «
»
(», % , a;) 6 T
for all x,y,z € [/. It follows directly from (6.175) and the definitions of ; and in Cm (T) that the third and fourth conditions of Th. 314 are satisfied in Cm (T). Note that I;X C X for all X C U by (6.155). The opposite inclusion follows directly from (6.170). Hence the first condition of Th. 314 holds, namely, the equation x = V ;x is valid in Cm(T). To show that the equation x = x;V is valid in €m(T), first note that I ; / C I for all X C U. For the opposite inclusion, let a e X. By (6.170), there is some * g I such that («, Sa, Sa) € T. Applying (6.175) twice, we obtain {a, i, a) g T, hence a € X;I. By Th. 314, Cm (T) 6 NA. The conditions required for £tn(T) G RA in the previous theorem can be expressed less formally. (6.170) says that every a g U has a left identity i g I, (6.169) says that every a G U has a converse b G E7, and (6.171) (the associativity of ;) says that, under the right interpretation, two lines intersecting at a point z determine a plane, as illustrated in Figure 2. Part of the diagram uses oriented labelled triangles, as was done for the cycle law, Th. 294, and the rest shows that the associativity condition (6.171) holds in Euclidean geometry when Txyz is interpreted, in case x, y, and z are distinct points, as "the directed line segment from x to y contains z". The identity element of the complex algebra of T is an atom just in case / is a singleton, i.e., I = {e} for some e 6 U. Whenever this is the case, (6.170) takes on the following simpler form, (6.176)
\ta(a £ U =4- Teaa).
By Th. 307, 1' is an atom in every integral NA. The converse does not hold for nonassociative relation algebras because McKinsey's algebra has zero-divisors and
RELATION ALGEBRAS
TxyzhTzab => 3c(TxcbATyac))
FIGURE 2. Associativity
yet 1' is an atom, but if the identity element of a semiassociative relation algebra is an atom, then the algebra is integral; see Th. 353. Every square relation algebra on a set is a complex algebra, for if U is an arbitrary set and T = {{(a, b), (b, c), {a, c)) : a,b,c € [/}, then the complex algebra Cm (T) is equal (and not just isomorphic) to the square relation algebra on U: me (CO = €m ({{(a,b),
(b,c), {a,e» :a,b,ce
U}).
At this point we have two ways to construct the complex algebra of a group (one is (6.4)), but they produce the same result. Let & = (G, o, ~1, e) be a group. The complex algebra £m(<&) was first defined above by using all three of o, ~1, and e. However, we get another complex algebra from © by using only the binary operation o. Since o is a binary operation, it is a set of ordered pairs, each of whose left side is an ordered pair in G2 and whose right side is an element of G, but every such ordered pair is an ordered triple, since (x, y, z) = ((x, y) ,z). Thus 0 is a ternary relation. Indeed, o = {{x, y, z) : x, y, z £ G, x o y = z}. Define S C G 2 a n d ICG according t o (6.154) a n d (6.155). T h e n S = " 1 a n d 1 = {e}, so £m(o) = £m(0).
28.
27.
MCKINSEY'S ALGEBRA IN WA ~ SA
357
The very nonassociative algebra in NA ~ WA
For an example of an algebra in NA that is not in WA (from Maddux [142, 3.6]), suppose i, e, a £ V are distinct, let T = {{i, i, i), (e, e, e ) , (i, a, a), (a, i, a), (a, a, i), (e, a, a), (a, e, a), (a, a, e)}. Then Cm (T) £ NA and if assume U, S, and I are defined according to (6.153), (6.154), and (6.155), then U = {i,e,a}, S = {(i,i) , (e,e), (a,a)}, and I = {i,e}. We have Cm (T) g WA since (6.173) fails, as follows. We have i £ I, {i,a,a) £ T, and (a, a, e) £ T, but there is no atom c £ {i, e, o} such that (i, c, e) £ T. The very nonassociative relation algebra may also be succinctly specified, according to our notational conventions, by saying that its atoms are i, e, o, and its cycles are [»,»,«], [e,e,e], [i, o,a], and [e, o,a]. To show that the notions of cylindric and relational basis differ for algebras in NA, Hirsch-Hodkinson [99, Ex. 12.6(5)] give a general construction of an algebra in NA~WA from any relation algebra. Applied to £Hc (3), their construction produces the algebra 21 £ NA whose atoms are q, q, qo, qi, r, f, ro, r\, s, s, so, s\, a n d w h o s e cycles are [90,9,9], [q,qi,q], [ro,r,r], [r,n,r], [so,s,s], [s,si,s],
[r,s,q\.
The identity element is 1' = qo + qi + ro + ri + so + si. Let Qo q
q qi
q~ qi
.9 9i 9i. Then a £ .B32I and 001 = q < r;s. The extension condition (6.97) fails. There is no matrix 6 £ .B32I such that a and 6 agree up to 2, 602 = r, and 621 = s, because the last three conditions entail b:= so if 6 £ B32I then r = 602 < 6005602 = qo',r, but qo;r = 0, a contradiction. The atom cover condition (6.96) and cycle cover condition (6.98) hold for B32I while the extension condition (6.97) fails. In fact, 21 has no n-dimensional relational basis for every n > 3, but 21 does have an n-dimensional cylindric basis for every n> 3.
28.
McKinsey's algebra in WA ~ SA
The algebra described in the section was created by J. C. C. McKinsey around 1940 to show that the associative law is independent of the other axioms for relation algebras, that is, that R4 is not derivable from the remaining axioms R1-R3, R5-R10. Tarski also used McKinsey's algebra to show that the sentence of first-order logic which expresses the associative law for relative multiplication is not 3-provable; see Tarski-Givant [240, p. 68]. McKinsey's algebra is described in the Appendix of the unpublished monograph by Tarski [227, pp. 264-265] (the initial draft of Tarski-Givant [240]). This same algebra happens to have been used in Maddux [144], [147, p. 546]. Let T := {(V,V, ! ' ) , ( ! ' , a, a), (a, V, a), (a, a, ! ' ) , ( ! ' , 6,6), (6,1', 6), (6, 6,1')}
RELATION ALGEBRAS
i' a b
V V a b
a a V 0
b b 0 1'
TABLE 2. Multiplication table for McKinsey's algebra
McKinsey's algebra is €m(T), the complex algebra of T. If U (the field of T), S, and / are defined according to (6.153), (6.154), (6.155), respectively, then U = {V,a,b},
S = {(V,V),(a,a},(b,b)},
and I = {V}. McKinsey's algebra may
also be described as t h e 8-element algebra 21 £ NA with a t o m s V,a,b a n d cycles [1', 1', 1'], [ l ' , a , o ] , a n d [ l ' , 6 , &]. T h e multiplication t a b l e for a t o m s in McKinsey's algebra is shown in Table 2. Notice t h a t t h e identity element 1' is an a t o m , b u t McKinsey's algebra is not integral since 0 = a;b (see T h . 307). McKinsey's algebra is not associative since a;(b;b) = a;V = a ^ 0 = 0 ; 1 ' = (a;b);b. McKinsey's algebra is not in SA since a ; l = V + a ^ a ; l ; l = 1. O n t h e other h a n d , McKinsey's algebra is in WA, for if x V = 0 t h e n (V x);l;l = 0 = (V x);l, while if 1' < x t h e n x ; l = l = x ; l ; l . McKinsey's algebra is 1-generated by a a n d also by b, w i t h o u t t h e identity, since 1' = a;a a n d b = V + a.
29.
An algebra in SA~RA
Let 21 be t h e algebra with a t o m s V,a,r,r [ l ' , r , r ] , [r, l ' , r ] , [a,r,r], [r,a,a], a n d [r,r, a].
a n d cycles [ l ' , l ' , l ' ] , [ l ' , a , o ] , T h e n t h e equation x\(x\x) =
( x ; x ) ; x f a i l s w h e n x = r s i n c e r ; ( r ; r ) = r \ V = r b u t ( r ; r ) ; r = (a + l ' ) ; r a;r + r = a + r. This observation is used to prove Th. 545.
30.
=
Lyndon's nonrepresentable algebras in RA ~ RRA
Lyndon constructed several nonrepresentable relation algebras, the smallest with 52 atoms. The one published in Lyndon [133], presented next, has 56 atoms: - an and a'u for i £ {1, 2, 3, 4, 5}, - aij, a'ij, aik, a'ik,
- [alh an, au] where i <E {1, 2}, {k, 1} C {3, 4, 5}, k^l. Then Cm (T) 6 RA, but Cm (T) is not representable because it fails to satisfy Lyndon's condition C2, which states that if 0 / £02;£21 ' ^03;£31 2:04;£41 then 0 7^ X2o;£o3 X2i;xi3 (x2o;^o4 X2i;xi4);(x4o;a;o3 X4i;xi3). Condition C2 is an immediate consequence of equation (L) (see p. 30).
32, Lyndon'S ALGEBRAS FROM PHOJEOTIVE GEOMETRIES
359
31. Jdnsson's algebras from projective geometries A set L 6 V is a projective geometry, its elements are called lines, and elements of (J L are called points, if no point is a line, every line has at least two points, and (i) for every two points a and b there is exactly one line in L, called ab, such that a, b € ab 6 L1 (ii) if a, 6, and c are distinct points, 32 ^ db, x G cb, y € ac, and x ^ y, then Ty fl ofc ^ 0. It follows from (i) that the intersection of distinct lines contains at most one point, and (ii) is illustrated in Figure 2. Let L be a projective geometry in which every line contains at least three points. Let U = (J L U {e} for some e ^ \J L. Let T be the ternary relation on U consisting of all triples of distinct collinear points of L, plus all the triples of the form (e,a,a), {a,e,a}, and {a,a,e} with o f f / . In other words, if S = U1 then T contains the identity S-cycles and the 3-cycles of collinear points of L. Note that Cm (T) is symmetric and V = {e} is an atom of €m (T). In the case of a single line with exactly three points we get a representable relation algebra, for if L = {1} and \l\ = 3 then £m(T) ^ £m(Z 2 x Z 2 ), but otherwise we only have Cm (T) € SA. €m (T) ^ RA whenever some line has four or more points, for in that situation we have a,b,c,d(z I € L1 {a, 6, c, d}\ = 4, and {a, b, c), (c, &, d) £ T, but there is no x G (J L such that {a, as, d), {b, b, x) £ T. J6nsson [112, Th. 4] proved a lemma that gets around this difficulty: If T is a ternary relation with field U such that I = {e}, S is the identity relation on U, that is, S = (x : x £ U), and (6.170) and (6.169) hold, then T C T' for some ternary relation T' that satisfies (6.170), (6.169), and (6.171), i.e., €m(T') 6 RA, and an additional technical property. Then, supposing L is a non-Desarguesian projective plane, that is, it has two triangles that are centrally perspective but not axially perspective, J6nsson uses the lemma to choose an extension T' D T with €m (T') € RA. The three triangles that are centrally perspective but not axially perspective produce, by the additional technical property, a violation of formula (J) (see p. 30), which is valid in every representable relation algebra. A triangle is, by definition, a triple of distinct non-collinear points. The ternary relation T contains all triangles. Suppose a,b,c and n,v,w are triangles that are axially perspective (which means that audbv = bvC\cw = auHcw) but are not centrally perspective, which means that the three points ab D uv, ac n uw, and 6c n vw are not collinear. A violation of (J) arises by taking a;oi = abf) uv, %ca = a, &21 = b, X24 = c, a;o3 = u, xis = v, and £43 = w. To see this, draw the pictures in the style of the illustrations of (6.171). Therefore £tn(T") is a nonrepresentable relation algebra. It is also integral and symmetric and infinite. 32. Lyndon's algebras from projective geometries Lyndon's construction of a ternary relation T from a projective geometry differs from Jonsson's by the inclusion of all triples of the form {a, a, a). If L is (the set of points in) a projective geometry, U = (J L U {e} where e ^ (J L, and T is the ternary relation on U consisting of all triples of distinct collinear points
360
8, RELATION ALGEBRAS
of L, plus all the triples of the form {e,a,a}, {a,e,a}, {a,a,e}, and (a, a, a) with a , that is, T = {(a, b, c) : 3 = |{o, 6, c}|, {a, b,c} C\e L} e a u
U ^ > > °^> ^ e> a J' ^ a ' e J' ^ a ' a ^
then Cm (T) is the Lyndon algebra of L. Conversion in Cm (T) is trivial, so €m (T) is a symmetric algebra. The reason for restricting the next theorem to geometries with at least four points on every line is that if L has a line with exactly three points, say a, b, and c, then T contains the cycles [a, a, a] and [a, 6, c], but there is no point x such that [a, 6, a;] and [a,c, x\ are cycles, so Cm(T) ^ RA. Projective geometries with at least four points on every line create a class of relation algebras whose characterization is given in the next theorem. Theorem 347 (Lyndon [135]). St is the Lyndon algebra of a projective geometry with at least four points in every line iff 21 G RA, SI is complete, atomic, symmetric, V is an atom of SI, and a;a = a + V for every atom a. PROOF. The construction of an algebra from a geometry was described above. Conversely, to construct a geometry from an algebra St, let the set of points consist of the atoms distinct from 1', and let the line containing a, b be ab = {x :
a;b + a + b>x
e At%}.
D
The next theorem is Lyndon's key observation. Theorem 348 (Lyndon [135]). The Lyndon algebra of a projective geometry L is representable iff L is embeddable in a projective geometry with one dimension more than L. The representation of each point is the set of pairs of distinct points which, with the given point, make a collinear trio. For some informative diagrams and more explanations of this material from a cylindric algebraic point of view, see Monk [183], By Th. 348, the Lyndon algebra of a projective line of order n (which contains n + l points on a single line) is not representable whenever there does not exist a projective plane of order n. Since there is no projective plane of order 6, it follows that a particular symmetric integral relation algebra with 8 atoms is not representable. Whether this Lyndon algebra satisfies equations (M) or (L) (see p. 30) is not known. Lyndon's 8-atom nonrepresentable relation algebra was the smallest known algebra in RA ~ RRA when it was published in 1961. McKenzie found a 4-atom nonrepresentable RA for his dissertation in 1966. 33. McKenzie's nonrepresentable algebra McKenzie [166] found a 4-atom nonrepresentable relation algebra that turns out to be algebra 14a7 (algebra number 14 among the 37 algebras listed in Chapter 8 that have atoms I1, a, r, and r). Its atoms are V,a,r,r. This algebra's four identity cycles are [1', 1', 1'], [1',a,a), [r, l',r], and [1',r,r]. Its four diversity cycles are [r, r, r], [a, r, r], [r, a, r], and [r, a, a]. Its three forbidden diversity cycles
33.
McKenzie'S NONREPRESENTABLE ALGEBRA
1437
1' a r r
V V a r r
a a V +r + f a+r a+f
r r a+ r r 1
f f a+ r 1 f
TABLE 3. Multiplication table for McKenzie's nonrepresentable algebra
are [r, r, a], [r,r,r], and [a, o,a]. McKenzie's algebra is certainly not the smallest nonrepresentable relation algebra if size is measured by the number of atoms. Nor does it have the smallest number of cycles. It has four cycles, but so do the nonrepresentable algebras 2437, 2537, and 2737. But it does have the smallest cycle structure, containing only 28 triples, while the cycle structures of 2437, 2537, and 2737 contain 29, 30, and 31 triples, respectively. The relative multiplication table for the atoms is determined by the list of cycles, and is shown in Table 3. Let x = V+r. Then a; is transitive since x;x = ( l ' + r ) ; (V+r) = V+r+r;r = V+r = x and reflexive since x\(V x) = x;x = x and (1' -x)\x = x. Thus x is partial ordering element of I437. Note that x is antisymmetric since x-x = (V + r)-(V +r) = V. The corresponding incomparability element (corresponding to the notion and 2") is x x = (a + r) (a + r) = a. Suppose a representation exists, and that it correlates the nonempty binary relations / , A, R, and R'1 with the atoms 1', a, r, and r, respectively. A pair of distinct incomparable points p and q have an upper bound u and a lower bound I. This is expressed in the algebra by the Since inclusion a < r;f r;r, and in the representation by A C _R|_R-1 (~l R-1\R.
(p, q) £ A, there is some u and I such that (p, u) E R, (u,q) E R 1, (p,l) E R 1, and (l,q) G R, so (q,u) G R and (l,p) G R as well. The lower bound / is strictly below the upper bound u since (I, u) E R;R C R, but, by the inclusion r < a;a, there must be some element i that is incomparable with both u and I, that is, {i, u) £ A and {i, I) £ A. If i were above q it would be above /, while if i were below q, it would be below u, but i is incomparable with both I and u. Therefore i is incomparable with q. Similarly, i is incomparable with p. Since p and q are themselves incomparable, this gives us three mutually incomparable elements, namely p, q, and i. It follows that the relation An J4|A is not empty. On the other hand, a;a-a = 0, so we have a contradiction. There cannot be any representation. This argument is encapsulated by a single equation with only a single variable, due to Givant, McNulty, and Tarski; see Tarski-Givant [240, p. 55]. This equation, which holds in all representable relation algebras but fails in McKenzie's algebra when the lone variable x is assigned to the partial ordering element 1' + r, is 1 = l ; ( x f x + ( x ; x + V + ( x - x ) ; ( x - x ) - x ) - x+ x ' \ x ) ; l .
To show this equation holds in RRA, it suffices to prove that it holds in every 5Ke (U) (with M ^ I , since all equations hold in the trivial algebra £Re (0)), where it is equivalent t o 0 ^ x \ x + (x; x + V + (x x); (x x) -x) -x + x^x. Assume, t o t h e contrary, t h a t 0 = x f x + (x; x + V + (x x); ix x) x) x + x~ \ x. T h e n
362
6. RELATION ALGEBRAS
0 = x \ x = x f x = (x;x + V) x = (x x); (x x) (x x), so, letting a = x x, we get 1 = x;x = x;x, x;x + V < x, and 0 = a;a a. Note that x a s a partial ordering. Indeed, since x;x + V < x we know that x is transitive and reflexive on U. From 1 = x;x we have 0 ^ 1' D x;x, hence 0 ^ x x = a, so a pair of incomparable elements exist in U. From 1 = x;x we also have 1 = £;£, so every pair of elements has an upper and lower bound. Arguing as above, we deduce that there are at least 3 incomparable elements, contradicting the assumption that 0 = a;a a. For another proof of the nonrepresentability of 1437, note that (J) fails when £01 = (i, £02 = r, £21 = r, X03 = r, £31 = r, £24 = a, and £43 = a. This failure is
actually quite closely related to the arguments given so far. For yet another proof that McKenzie's algebra is not representable, it is enough to note that (M) fails when £02 = r, £21 = r, and £01 = £03 = £32 = £24 = £41 = a.
34. Allen's interval algebra An example of a representable relation algebra used in applications is the Interval Algebra, due to J. F. Allen [1, 2]. Let U be the set of "events", where an event is simply a pair of real numbers, the second larger than the first. The first number in an event is its "starting time", the second its "ending time". Seven binary relations on events are defined in the list below, where x,x',y,y' are real numbers (element of R), the relation < is the usual ordering of R, and (x,x'), {y,y') are events. "identity"
1' = {((£, x) , (y, y')) : x = y < x = y'}
"precedes"
p = {{{x, xlsj , (3/, j/')) : x < x' < y < y'}
"during"
d = {((x, x) , (y, y')) : y < x < x < y'}
"overlaps"
o = {((£, a;') , (3/, y')) x < y < x < y'}
"meets"
m = {((x, x) , (y, y')) : x < x = y < y'}
"starts"
s = { ( ( x , x') , (y, y')) :x =
y<x'
"finishes"
/ = {((x, x) , (y, y')) : y < x < x = y'}
The seven relations listed above are studied by van Benthem [246] and are used in some computer programs; see Allen-Koomen [5], Malik-Binford [160], and Simmons [217]. They generate a finite subalgebra of $Re (R), called the interval algebra. The interval algebra has 13 atoms, namely 1', p, p, d, d, o, o, ra, rh, s, s, / , and / . It turns out that p alone generates the interval algebra, as do each of the elements p, m, rh, o, and o; see Ladkin-Maddux [128, 127]. Starting with the rational numbers instead of the reals, or any dense linear ordering without endpoints, results in an algebra that is isomorphic to the interval algebra. But other infinite linear orderings produce relation algebras generated by 1', p, d, o, m, s, and / that are not finite, and the relations listed above are no longer atoms. This happens, for example, with the integers. If we start with a finite linear ordering, say < on a finite set U, then the subalgebra generated by 1', p, d, o, m, s, and / will be all of $Re ([/). Any relation algebra obtained in this way may be called an interval algebra (while Allen's interval algebra is obtained from the reals or
34. Allen'S INTERVAL ALGEBRA
V
P
P
d
d
o
6
1'
V
P
d
d
o
6
p
P
p
pdoms
P d
pdoms pdomf
P
V d
P 1
P 1 P
d
pdomf pdoms
P
P
P 1
pdomf
d
d
pdomf
Vddoossf f
d
dof
dos
o
o
P
pdoms pdoms
dos
pom
Vddoossf f
6
6
pdomf
P
dof
pdomf pdoms
Vddoossf f
pom
m
m
P
pdbms
dos
P
dos
rh
rh
pdomf
P
dof
P
P dof
s
s
pdomf
pom
P dof
8
8
f f
f f
P
P
P
d
pdomf
P
dof
d
dof
6
P
P
d
pdoms
dos
pom
P
pdoms
dos
d
o
dos
TABLE
4. Multiplication table for the interval algebra, first part
rationals). Allen's interval algebra has 75 cycles, written here without commas: [ l ' l T ] , [Vss], [Vmm], [Vpp], [l'oo], [Vff], [Vdd], [si's], [ml'm], [pVp], [ol'o], [/!'/]j [dl'rf], [sss], [smp], [spp], [som], [sop], [soo], [sfd], [sdd], [msm], [mmp], [mpp], [mop], [mfs], [mfo], [mfd], [mds], [mdo], [mdd], \psp], [pmp], [ppp], [pop], [p/s], [pfm], [pfp], [pfo], [pfd], [pds], [pdm], [pdp], [pdo], [pdd], [oso], [omp], [opp], [oom], [oop], [ooo], [ofs], [ofo], [ofd], [ods], [odo], [odd], [fsd], [fmm], [fpp], [fos], [foo], [fod], [ / / / ] , [fdd], [dsd], [dmp], [dpp], [dos], [dom], [dop], [doo], [dod], [dfd], [ddd].
The table of relative products of atoms of the interval algebra is given in two parts (see Tables 4 and 5). The + signs are omitted to save space. For example, pdoms = p + d + o + m + s. The table appeared first in Allen [2]. It not only shows relative products of atoms in the interval algebra, but also shows containments for the Allen-Hayes algebra [3, 4]. By the Allen-Hayes algebra we mean the direct product of "all" interval algebras, i.e., the direct product of an indexed system of algebras containing one algebra from each isomorphism type of interval algebra. The Allen-Hayes algebra contains the elements 1', p, p, d, d, o, 6, m, rh, s, s, f, and / . They form a partition, i.e., are pairwise disjoint and 1 =p+p + d + d + o + d + m + rh + s + s + f + f. Finally, the relative product of any two of them is contained in (and not necessarily equal to) the corresponding entry in the table.
6. RELATION ALGEBRAS
8
f f
/ /
P
pdoms
P
pdomf
P
P dos
d
pdomf
P d
pdoms
dof
d
dos
d
m
fh
s
3
r
m
fh
s
p
P
pdoms
P
P
P pdomf
P
d
P
d
dof
0
P dof
dos
0
dof
dos
pom
P
dof
pom
6
dos
P Vss
17/
m
m
dos
dof
P fh
s
P Vss
fh
d
pom
6 m fh
s
P
P fh
s
dof
m
Vss
s
6
d
f /
m
P dos
d
pom
f
0
d
17/
17/ /
TABLE
m
5. Multiplication table for the interval algebra, second part
35. Cycle structures of complex algebras The operation of forming a complex algebra from a ternary relation produces an algebra from which the original ternary relation may be recovered as a cycle structure. Theorem 349. Every ternary relation is isomorphic to the cycle structure of its complex algebra, that is, i / T e V and T C V3 then T9iCy(€m(T)). PROOF.
Note that {x,y,z) € T
{{x}, {y}, {z}) € Cy{£xn(T)).
U
Although the cycle structure determines the operations ; and " in every atomic 21 £ NA, it does not determine which joins of atoms of 21 exist. However, if every join of atoms exists, i.e., if 21 is complete, then 21 is completely determined by its cycle structure. This observation was first made in a far more general setting. Instead of a single ternary relation, let us consider an arbitrary relational structure, consisting of a set U together with a set of fmitary relations on U, whose complex algebra is the complete atomic Boolean algebra 031 (U) of all subsets of U augmented with the normal and completely additive (universally additive) operators determined by the relations on U. An (n+ l)-ary relation R C , Xn C U, Un+1 determines an n-ary operator / on U, where for any inputs X\, (6.177)
n)
= {u:
,un,u)
lr--
,un
36. REPRESENTATION BY COMPLEX ALGEBRAS
365
Jonsson-Tarski [119, Th. 3.9] observed that the complex algebra of a relational structure is a normal complete atomic Boolean algebra with completely additive operators, and, conversely, every normal complete atomic Boolean algebra 21 with completely additive operators is isomorphic to the complex algebra of a relational structure which is obtained from 21 in a manner that generalizes the way the cycle structure was obtained in case 21 £ NA. For the following theorem one need only note additionally that the operators in an NA are normal and completely additive. Theorem 350 (Jonsson-Tarski [119, 3.9], Maddux [142, 3.13]). 7/21 £ NA and 21 is complete and atomic, then 21 = Cm (C?/(2l)). The next theorem gathers some observations one can make in the somewhat more general setting of an atomic 21 £ NA that may not be complete. Theorem 351 (Maddux [142, 3.13]). Assume 21 £ NA and 21 is atomic. (i) 2l^|CCm(Cy(2l)). (ii) If Cm (C?/(2l)) £ RRA then 21 £ RRA. (iii) Cm (6*2/(21)) € NA. (iv) IfK is RA, SA, or WA, then Cm (6*2/(21)) £ K <s> 21 £ K. PROOF. For part (i), let / be the map that carries each element x of 21 to the set of atoms of 21 that lie below x. Then / is an embedding of 21 into £m(C?/(2l)). Part (ii) follows from part (i) and ISRRA = RRA. It follows from Th. 345 that (6.169) and (6.170) hold when T = C?/(2l), so by Th. 346 we conclude that Cm (C«/(2l)) £ NA. The converse of part (ii) may fail. Indeed, it is possible that 21 £ RRA and yet Cm (Cj/(2l)) f. RRA. Exceptions occur when 21 is both atomic and generated by its atoms, in which case it contains as few joins as possible. The complex algebra of the cycle structure of 21 contains all joins, that is, there is an element for every subset of At$l. The presence of these additional elements can cause nonrepresentability, as in Th. 323. Let us explore the reasons in more detail. Suppose 21 is an atomic RRA. Suppose a embeds 21 in 6 b {E). Define a : Sb (Am) -> 56 {E) by a (X) = U^ex a ( x )- Then a is a homomorphism of Cm (Cy(2l)) into 6 b (E) iff, for all X,Y C At% (6.178) (6.179) (6.180)
a(X\JY)=a(X)\Ja(Y), a(X) =a(X), a(X;Y)=a(X)\a(Y),
(6.181) The first and fourth equations always hold, while the second and third equations
hold iff a (AM) = \JaeAm a (a) = E. 36. Representation by complex algebras Let 21 £ NA. In view of the existence and uniqueness of perfect extensions, we could simply add a superscript "+" to "21" and denote a perfect extension of
366
6. RELATION ALGEBRAS
21 by 2l + , as was done in Th. 326. In contrast, recall that in case 03 € BA, we let 03+ be the Boolean algebra of all sets of ultrafilters of 03, an algebra which is naturally isomorphic to every perfect extension of 03. Here we extend this construction to NA. We obtain an algebra isomorphic to every perfect extension of 21 by constructing the complex algebra of the ternary relation T on the set £//2l of ultrafilters of 21 denned by T := {(F,G,H) : F,G,He
Uf%{f;g
3
= (*7/2l) n {{F, G, H) :F;*GC
: f € F,g € G} C H} H}.
Define a function £ : A —> 56 (t//2t) by e(x) :={F :x€
F £ 17/21}
for every x E A. We say that T is the ultrafilter structure of 21, and £ is the ultrafllter embedding. Let <£m2l:=£m(T). Then Ghn2l is the canonical embedding algebra of 21. This name was applied by Henkin-Monk-Tarski [93, 2.7.4] to the corresponding construction for cylindric algebras, which, by the way, was based on maximal proper ideals instead of ultrafilters. The version presented here appears in McKenzie [165, Th. 2.11]. The Jonsson-Tarski Representation Theorem [119, Th. 3.10] says that if 21 is a Boolean algebra with normal, completely additive operators, then 21 is isomorphic to an algebra that has the complex algebra of a relational structure as one of its perfect extensions. The proof proceeds by noting that 21 has a perfect extension 2l + , which, because it is complete, atomic, and has normal completely additive operators, is isomorphic to the complex algebra of a relational structure obtained by denning the appropriate relations on the atoms of 2l + . The next theorem is the NA version of the Jonsson-Tarski Representation Theorem, combined with a few additional observations. It is a consequence of Th. 326, Th. 350, and Th. 351. Theorem 352 (Jonsson-Tarski [119, 3.10]). Let 21 € NA. Then (i) <£m2le NA, (ii) if 21 is finite then 21 = £tn 21, (iii) ifK is RA, SA, or WA, then 21 e K <s> <£m2l e K, (iv) the ultrafilter embedding is an isomorphism from 21 onto a subalgebra 21' o/(£m2t, 21^21' C <£m2t, such that Ghn2l is a perfect extension o/2t'. 37. Elementary arithmetic in SA Jonsson-Tarski [119, 4.18(ii)] observed that every integral relation algebra is simple. Jonsson-Tarski [119, 4.17] also proved that a relation algebra is integral iff its identity element is an atom. In one direction this holds for NA. The other direction fails for WA but holds for SA. Theorem 353 (Maddux [147, Th.4]). Let 21 £ SA. Then 21 is integral iff V is an atom of 21.
37. ELEMENTARY ARITHMETIC IN SA
367
PROOF. One direction follows from the observation that if 21 is an integral NA then 1' is an atom, by Th. 307. For the converse, assume 21 £ SA and 1' £ At 21. By Th. 307, an NA is integral iff it has at least two elements and x\\ = \ whenever x 0. So we need only assume x 0 and show x ; l = 1. Now it follows from 1' £ At% and the definition of atom that 1' ^ 0, and this implies that 21 has at least two elements. By 1' £ At%, we also have either 1' x ; l = 0 or 1' x;l = V. However, if 1' x; 1 = 0, then 0 = x V ; 1 = x by the cycle law, contradicting our assumption that x ^ 0. Therefore 1' < x;l. But then, by Th. 276, 1 = 1';1 < a ; ; l ; l = x ; l < 1, so 1 = x; 1, as was to be shown. The assumption that 21 £ SA is essential, because McKinsey's algebra is a nonintegral 21 £ WA in which 1' is an atom. In McKinsey's algebra, the atoms are 1', a, b, and the cycles are [1', 1', 1'], [1', a, a], and [1',b,b]. Then 1' is an atom, but a;b = 0, so 21 is not integral. Next we show that many special cases of the associative law holds in every SA. The development culminates in Th. 365 below, which says that associativity may be freely applied to any relative product in which one of the factors is 1. T h e o r e m 354 (Maddux [150, Th. 13]). Assume 21 £ SA. For all x,y,z we have (6.182)
(x-y;z);l
=
(6.183)
l;(x-y;z)
= l;(z-y;x),
(6.184)
x;yl;z = x;(yl;z),
(6.185)
x;y-z;l
(6.186)
(x-l;y);z = x;(z-y;l),
(6.187)
(x;y);l=x;(y;l),
(6.188)
(l;x);y = l;(x;y),
=
(6.189)
(yx;z);l,
(x-z;l);y,
(x;y);(z;l)=x;(y;(z;l)),
(6.190)
((l;x);y);z = (l;x);(y;z),
(6.191)
x;(y;l);z = x;((y;l);z),
(6.192)
(x;(l;y));z = x;((l;y);z).
PROOF. Proof of (6.182): (x-y;z);l<((yx;z);z);l
Th. 265, (6.46)
<((yx;z);l);l
Th. 265
= (yx;z);l
Th. 276(ii)
<((x-y;z);z);l
Th. 265, (6.47)
<((x-y;z);l);l
Th. 265
= (x-y;z);l
Th. 276(ii)
Proof of (6.183): (6.183) follows from (6.182) by converse duality.
£ A,
6. RELATION ALGEBRAS
Proof of (6.184): 1 ;z
x;y
= x ;(y < X
! ; ( !
= x ;(y < X
;*))
(6.44)
;*))
Th. 265
x;(l
1 y\
Th. 276(ii) Th. 265
\y- i ; ( i ; l;z
Th. 276(ii)
= X ;«/
Proof of (6.185): (6.185) follows from (6.184) by converse duality. Proof of (6.186): (x -l;y);z
< (x l;y);(z
(x I;$)";!)
(6.44)
<x;{z-{y\l)\l)
Th. 265, Th. 239, Th. 243, R 7 , Rg
= x;(z-y;l)
Th. 276(ii)
<(x-l;(z-y;iy);(z-y;l)
(6.46)
< (x l\{\;y))\z
Th.265, Th. 239, Th. 243, R 9
= (x-l;y);z
Th. 276(ii)
Proof of (6.187): (x;y);l
= (1
x;y)\\
= (x-l;y);l
(6.182)
= x;(l-y;l)
(6.186)
(6.188) follows from (6.187) by converse duality. Proof of (6.189):
( T'lll
' (7 ' 1 ) — \(T'1I\''7\''\
I fl 1 S V ]
= (x;yl;z);l
(6.182)
= (i;(scl;z));l
(6.184)
= x;((yl;z);l)
(6.187)
= x;((l-y;z);l)
(6.182)
= x\{y\{z\\))
(6.187)
Proof of (6.191): (T- (ir 11V 7— ff T -nViV7
ffi 1 87")
= (x;y);l-l;z
(6.184)
= x\{y\l)-\;z
(6.187)
= x;(y;l-l;z)
(6.184)
37. ELEMENTARY ARITHMETIC IN SA
= a:;((y;l);a)
369
(6.184)
It is only in SA that ideal elements have Peirce's remarkable property (see p. W). Theorem 355. 7/SI e SA and xe A then (i) x;l G Dm% i j T G DmSl, (ii) I ; i 6 flnE, Ija; g TJnSt, (iii) l;a;;l 6 7e2t, I j ^ T e IeSi, (iv) DmSl is closed under x;(-), (v) 72n2t is closed under {-)",x, (vi) l;(a;tO),l;a;tO€7eStJ (vii) 0fa:;l,(0ta:);le/ea, (viii) 7e2t is closed under x;(-) and {-)\x, (ix) meets and joins of subsets o/TJmSl, Rn$l, and Ie% are again in Dm%, Rn%, and 7eSl, respectively. PROOF. Proof of (i): We obtain x;l G DmSl from the fact that the equation (x; 1); 1 = x; 1 is valid in SA (see Th. 276), hence i | T e Dm% by Th. 305. Proof of (ii): We get l;x € -Rn21 from the validity of l;(l;a;) = l;x in SA, so TJi e iJna by Th. 305. Proof of (iii): From (i) we have l;a;;l £ DmSL. By (6.187) or (6.188), 1;«;1 = l ; ( z ; l ) , hence l;a;;l € i?nSt by (ii). We therefore have l;a;;l € DmSln RnSl = Ie% and l;a;;l £ leSL Th.305. Proof of (iv): If y £ UmSl then x;y = E ; ( J / ; 1 ) = (x;y);l by (6.187), so x;y £ DmSl by (i). Proof of (v): If y £ Rn% then. y;x = {l;y);x = l;(y;x) by (6.188), so j/;a; e & I by (ii). Proof of (vi): We have a;fO = a;;l € TJmSt by (i), hence l;(a;fO) 6 -DrraSt by (iv). We also have l;(a;tO) G Rn% by (ii), so l;(a;tO) G JeSl. We have TJi £ Rn$l by (ii), so \\x\\ £ flnSl by (v). Also, \\x\\ G UmSl by (i), hence l;a:;l G Je2l. Finally, 1;x \0 = T ] E ; 1 G / e a by Th. 305. Proof of (vii): By (vi) and Th. 305. Proof of (viii): By (iv), (v), and Ie% = DmSl n RnSi. D The equation 0'; 0'; 0'; 0' = 0'; 0' was first proved for relation algebras by Julia RobinsonJ in 1945; see Chin-Tarski [49, p. 359]. As we prove next, it happens to hold in every SA but fails in some WA. The related equation 0' ;0'; (01 ;0') = 0' ;0' holds in every NA; see Th. 309. Theorem 356 (Chin-Tarski [49, 3.10], Maddux [143, 14(3)]). (i) 7 / a e S A ften((0!;0!);0!);0'=0';0\ (ii) There is a 3t 6 WA in which ((0!; 0 ! );0');0' # 0';0'. PROOF. Notice first that a;;0';0' < a;;l;l = x ; l = x ; ( l ' + 0 ' ) =x;l'+x;0' = a;+a;;0'. Let a; = 0'-0';0'. Then a; < 0';0' and a; < 0', soa;;0';0' < a;+a;;0' < 0';0'.
6. RELATION ALGEBRAS
1'
V V
a a
a b
a b
r +o
;
b b 0 1'
0
T A B L E 6 . A W Ai n w h i c h ( ( 0 ' ; 0 ' ) ; 0 ' ) ; 0 ' # 0 ' ; 0 '
Finally,
< (0' l;0');0'
For such a WA in which ((0'; 0'); 0'); 0' # 0'; 0', use an 8-element algebra with three symmetric atoms 1', a,6 whose cycles are [l',a, a], [V,b, b], and [a, a,a]. The table of relative products of atoms is shown in Table 6. Then 0' = a + 6, 0'; 0' = 1' + a, and (0';0');0 J = V +a + b= ((0';0');0');0\
38. Associativity in groupoids Let {A, ;} be a fixed groupoid. Let P be the function that maps finite sequences of elements of A to subsets of A,
\J An -+Sb(A),
P: such that, for all x\,..., P(xi,...
xn £ A,
,xn) = {y;z : y € P(xi,.. =
. ,xm-i),z
\^j 2<m
= P(xi);*P(x2,...
€ P{xm,.
P(xi,...,Xm-l);*P(xm,...,Xn)
,xn-i)\J
...
U P(X1, . . . ,Xm-l);*P(Xm,. U P(xi, . . .
,Xn-l);*P(xn).
The simplest cases of the definition of P are
= {xi};*{x2} =
. . ,Xn) U . . .
,xn),2
< m < n}
38. ASSOCIATIVITY IN GROUPOIDS
= {xi};*{x2;x3}
371
U {xi ;a;2};*{x3}
= {xi;(x 2 ;x 3 ), (xi;x 2 );x 3 }, P(xi,x 2 ,x 3 ,a;4) = {xi;((x 2 ;x 3 );x 4 ), xi;(x 2 ;(x 3 ;x 4 )), (xi;x 2 );(x 3 ;x 4 ), (xi;(x 2 ;x 3 ));x 4 , ((xi;x 2 );x 3 );x 4 }. If the groupoid (^4, ;} is absolutely freely generated by x £ A, then the cardinalities , are the Catalan numbers: C\ = 1, C2 = 2, C3 = 5, of P(x,x), P(x,x,x), CA = 14, C5 = 42, , respectively, where
for all k > 1. The function P has the following property, which can be used as an alternative definition. (6.193)
P ( x i , . . . , x
n
)
=
( J P ( % i , l<m
= P(xi;x2, U P ( n ,
U
x3,
,%m-i, x
; x
m
+ i , x
m
+2,
, x
n
)
,x n )
x 2 ; x 3 , xA,
U P(xi,
m
,xn)
,xn-2,
xn-i;xn).
The sets that occur in the definition of P are disjoint, while the sets in the alternative definition (6.193) are not disjoint. The latter fact is used in a later proof. We say that an element a £ A is 3-associative if \P(x,y, z)\ = 1 whenever a 6 {x,y,z} C A . S i n c e P(x,y,z) = {(x;y);z,x;(y;z)}, a ne l e m e n t a 6 A is 3-associative iff the two elements in P(x, y, z) coincide whenever a is either x, y, or z. This can be stated in three equations. Theorem 357. An element
a £ A is 3-associative
(6.194)
(a;x);y = a;(x;y),
(6.195)
(x;a);y = x;(a;y),
(6.196)
(x;y);a = x;(y;a).
iff, for all x,y £ A ,
We say that an element a £ A is 4-associative if \P(xi,X2,X3,XA)\ = 1 whenever a £ {X\,X2,X3,XA} C A. For any finite n > 4, the element a is said to be n-associative if |P(xi, , x n )| = 1 whenever a £ {xi, , xn} C A. The next theorem is an immediate consequence of these definitions. T h e o r e m 3 5 8 . F o r all x , y £ A , x ; y i s n - a s s o c i a t i v e if x o r y i s n + 1 a s s o c i a t i v e . I n p a r t i c u l a r , if x £ A i s ^ - a s s o c i a t i v e t h e n x ; y a n d x ; y a r e 3 associative. The next theorem shows that 3-associativity and n-associativity are independent for every n > 4. Theorem 359. Let n > 4. Then (i) 3-associativity does not imply n-associativity,
372
6. RELATION ALGEBRAS
a b c
a a b c
b c b c c b c
TABLE 7. Groupoid with a 3-associative but not 4-associative element
; a aa a(aa) (aa)a
oo
(aa)a oo
a aa
aa
a(aa)
a(aa)
00
00
00
(aa)a
oo
oo
oo
oo
oo oo oo
00
00
00
00
00
00
00
00
oo
oo
oo
oo
TABLE 8. Groupoid with a 4-associative but not 3-associative element
(ii) (n + 1)-associativity does not imply
n-associativity.
PROOF. The binary operation on {a,b,c} given in Table 7 yields a groupoid in which a is 3-associative but not 4-associative, since (a;6); (6;6) = b;c = b but a;((6;6);6) = o;(c;6) = a;c = c. Note that the entry occupied by can be replaced by either a, b, or c, because the product c;c is not used in these last two equations. In fact, any nonassociative groupoid with an identity element can be used for this proof, since the identity element (o in this case) is 3-associative but not 4-associative. For the second part, consider the groupoid with 5-element universe {o, aa, a(aa), (aa)a, oo} and operation ; defined in Table 8. The element a is 4-associative but not 3associative, so the result holds for n = 4. It is routine to extend this example to a sequence of groupoids that show (n + l)-associativity does not imply nassociativity. If a G A is 4-associative, then for all w,x,y =
G A,
(6.197)
((a;w);x);y
(6.198)
(x;(a;w));y = x;((a;w);y),
(6.199)
(x;(w;a));y = x;((w;a);y),
(6.200)
(x;y);(w;a)
=
(a;w);(x;y),
x;(y;(w;a)),
so an element that is both 3-associative and 4-associative satisfies (6.194)-(6.196) and (6.197)-(6.200). The converse is also true: if a satisfies (6.194)-(6.196) and (6.197)-(6.200) then a is both 3- and 4-associative, as shown by the following theorem.
39. INDEPENDENCE OF SEVEN WEAK ASSOCIATIVE LAWS
373
T h e o r e m 360. Assume a is a 3-associative element of the groupoid (A, ; ) . Then the following statements are equivalent: (i) a is ^-associative. (ii) for all w 6 A, a;w and w;a are 3-associative. (iii) (6.197)-(6.200) hold. PROOF. If a is 4-associative, then, by Th. 358, a;w and w;a are 3-associative for all w £ A. Next suppose that for all w, a;w and w;a are 3-associative. Derive (6.197) by applying (6.194) to a;w, derive (6.198) and (6.199) by applying (6.195) to a;w and w;a, respectively, and derive (6.200) by applying (6.196) tot»;a. Thus a satisfies (6.197)-(6.200). Finally, we assume a satisfies (6.197)-(6.200) and prove C A. We derive \P(w,x,y,z)\ = 1 by a is 4-associative. Suppose a E {w,x,y,z} showing that the five elements of P(w, x, y, z) coincide in each of the four cases w = a, x = a, y = a, and z = a. a;{x;(y;z)) = (a;x);(y;z) = ((a;x);y);z
(6.194) (6.197)
= {a;{x;y));z
(6.194)
= a;{{x;y);z)
(6.194)
((w;a);y);z = (w;(a;y));z
(6.195)
= w;((a;y);z)
(6.198)
= w;{a;{y;z))
(6.194)
= (w;a);{y;z)
(6.195)
w;(x;(a;z)) = w;((x;a);z)
(6.195)
= (w;(x;a));z
(6.199)
= ((w;x);a);z
(6.196)
= {w\x)\{a\z)
(6.195)
{{w;x);y);a = (w;x);(y;a)
(6.196)
= w;{x;(y;a))
(6.200)
= w;((x;y);a)
(6.196)
= (w;(x;y));a
(6.196).
39. Independence of seven weak associative laws In this section, let us say that an equation among (6.194)-(6.196), (6.197)(6.200) is independent if it fails in a groupoid in which the remaining six equations are valid. Every one of them is independent, as will be shown. Note that (6.197) and (6.200) are converse duals of each other, as are (6.194) and (6.196). Consequently, a left-right switch on any groupoid showing the independence of (6.194), (6.197), or (6.198), also shows the independence of (6.196), (6.200), or (6.199), respectively. Therefore, to obtain the independence of all seven equations,
6. RELATION ALGEBRAS
a b c TABLE
a a a a
b b b b
c b a a
; a b c
a a a a
b b b b
c a b a
9. The only 3-element groupoids for the independence of (6.197)
a b c 0
a 0 0 0 0
6 c 6 0 0
c 0 0 0 0
0 0 0 0 0
; a b c 0
a 0 0 0 0
6 c 0 0 0
c 0 c 0 0
0 0 0 0 0
TABLE 10. Groupoids for the independence of (6.194) and (6.195)
it suffices to show independence only for (6.194), (6.195), (6.197), and (6.198). The groupoid in the proof of Th. 359 does not show the independence of any one equation, since all three of (6.194)-(6.196) fail, while (6.197)-(6.200) are valid. Thus a is about as non-3-associative as it can get. No 2-element groupoid shows independence for any one of (6.194)-(6.196), (6.197)-(6.200), because, in every 2-element groupoid, either - (6.194)-(6.200) all hold, - (6.194)-(6.200) all fail, - (6.194), (6.196), (6.197) hold, the others fail, - (6.194), (6.196), (6.200) hold, the others fail. The only equations for which independence can be shown with 3-element groupoids are (6.197) and (6.200). There are (up to isomorphism) only two 3-element groupoids that show independence for (6.197). They are shown in Table 9. There are many 4-element groupoids that show the independence of (6.194) and (6.195). For example, to prove the independence of (6.194) and the independence of (6.195) we may use, respectively, these two groupoids: No 4-element groupoid shows the independence of (6.198) (or (6.199)), but the independence of (6.198) can be easily arranged in a larger groupoid using elements that are named after subterms of (6.198). Let G be the following 15-element set: G = {a, x, w, y, aw, xa, xaw, wy, xaw, awy, (xaw)y, awy, x(awy), x(awy), 0}. Define a binary operation ; on G so that a;w = aw, x;a = xa, x;aw = xaw, w;y = wy, xa;w = xaw,
aw;y = awy, xaw;y = ( a;wy = awy, x;awy = x(awy), xa;wy = x(awy),
71. RRA IS NOT FINITELY BASED
<— l o o s e -¥
1' dk Ck
0 0
Cl
0 0 0 0
r
r
CA C3 Cl
ffli
ai
0---0 $---ai
$
$
$
ai---$ $
<- poly ->
<- tight -> a^+i aj
aj+i
av
Oi+l Oj 0---0
ak ' ^ j + i ' ' ' dk ' ap Ck ' aj-^i_ ''' Ck ' ap
loose, poly, tight tight
0---0 0---0 0---0 0---0 0---0
CA ' a j + i ''' CA ' ap
tight tight tight tight
C3 aj + l
C3
Op
C2 ' flj + 1
C2
Op
Cl
Cl
Op
Oj + 1
0---0 +
TABLE 47. Partition P
tight pieces of P, in fact. All the monochromatic pieces of P are tight pieces of P+. All the loose pieces and all the polychromatic pieces must occur among dk Oj+i, , dk ap, although some of these may be tight pieces of P+. Thus we have the following conclusions. If loose(P) = 0, then P is a set of atoms. If loose(P) > 1, then poly(P + ) < poly(P) - loose(P) < poly(P). So either P is a set of atoms, or poly(P+) < poly(P). Repeat the process of passing from P to P + whenever P has loose pieces. With each repetition the number of polychromatic pieces drop. It can drop at most \P\ times, if each repetition produces a new partition with exact one loose piece. The process therefore stops after finitely many steps, producing a finite partition P°° that has no loose pieces and is a set of atoms of a finite subalgebra containing the initial partition P . The cardinality of P°° is bounded by a function of the cardinality of P . Writing P = { ! ' } U { a i , . . . ,a{} U {ai+u
.. .,aj} U {aj+i,...
,ap}
and
P
^ {!'} U {ai> > ai\ U {oj+i,..., aj} U {dfc U \C\,. .., Ck} {aj+i,..., tip},
Op}
helps illustrate why |P| = 1 + loose(P) + tight(P) + poly(P), so, since k
476
6. RELATION ALGEBRAS
= P\+ loose(P) poly(P). The latter cardinality is maximized when tight (P) = 0 and both loose (P) and poly(P) are about half of |P|, in which case | P + | is (except for small numbers) bounded by |P| 2 . Maximizing the number of passages from P to P + requires an opposite trend: loose (P) should be repeatedly equal to 1. In any case, |P°°| is bounded by a polynomial function of |P|. Cubic is clearly enough. The number of atoms in a subalgebra of £ generated by g elements is therefore no more than 23fir, since the number of atoms that arise via Boolean operations only is 29, and the cube of that is enough to exceed the number of atoms generated by relative multiplication as well as the Boolean operations. Suppose the number of colors n exceeds 23g. Then every g-generated subalgebra of C must contain a polychromatic atom. Polychromatic atoms are easily seen by some computation to be flexible atoms. The previous theorem, combined with the observation that all but finitely many of the finite symmetric integral relation algebras obtained from S^+j by splitting are not representable, gives the following results. Theorem 466 (Jonsson [115]). RRA does not have an equational taining only finitely many variables. Theorem 467 (Monk [176]). RRA has no finite 72. The number of finite integral relation algebras In this section we derive an asymptotic formula for the number of isomorphism types of finite integral relation algebras. As a first step we count the number of ternary relations on a given finite set U with fixed involution S and identity element / = {e} whose complex algebras are nonassociative relation algebras. Every finite integral relation algebra with n atoms is isomorphic to the complex algebra of such a ternary relation. Theorem 468. Assume n = \U\ G ui, e G U, I = {e}, S : U -^ U, 5(e) = e, S{S(x)) = x for all x e U, and s = \{x : x e U, S(x) = x}\. Then the number of ternary relations T such that (6.153), (6.154), (6.155), and £m(T) G NA is 2Q{n's) where Q(n, s) = -(n- l)((ra - I) 2 + 3s - 1). 6 PROOF. Cm (T) e NA iff T is the union of all cycles of the form [a;, e, a;], where x G U, together with some diversity cycles, i.e. T =
( U lx'e'xY) xeu
u
fci)S/ij^i]
U
U
[xt,yt,zt]
for some t Go;, x\,... ,xt, yi,..., yt, z i , . . . , zt G £ / ~ { e } . So the number of such ternary relations is 2 raised to the power |{[a;,j/,«] : x,y,z £ C/~{e}}|. Let x,y,z G C ~ { e } . Then | [ K , J / , « ] | = 6 unless there are u, v 6 [ 7 ~ { e } such t h a t either
[x, y, z] = [u, u, u] = {(u, u, u}} and Su = u, or
72. THE NUMBER OP FINITE INTEGRAL RELATION ALGEBRAS
477
[a;, y, z] = [it, u, Su] = {{u, u, Su), {Su, Su, u)} and Su ^ u, or [a;, y, z] = [u, v, v] = {{u, v, v), (v, Sv, u), {Sv, u, Sv}}, Su = u, and u ^ v. Now use these facts to count the number of triples in ([/~{e}) s in two ways. On the one hand, there are (n — I) 3 . Every triple appears in a unique diversity cycle. Every diversity cycle has cardinality 1, 2, 3, or 6. The number of diversity cycles containing just one triple is s — 1, thus accounting for * — 1 triples. There are \{n — a) distinct diversity cycles containing two triples, accounting for n — a additional triples. The number of diversity cycles containing exactly three triples is (* — \){n — 2). Let N be the number of diversity cycles of cardinality 6. Then (n - I) 3 = (a - 1) + (n - a) + 3(« - l)(n - 2) + 6JV, so the total number of diversity cycles contained in (C^~{e})3 is therefore (« - 1) + | ( n - « ) + ( « - l)(n - 2) + N = Q(n, s). D Under the assumptions of Th. 468, let K{n, s) be the set of ternary relations T such that (6.153), (6.154), (6.155), and Cm(T) g NA. For any property
478
8, RELATION ALGEBRAS
Suppose ax = Sx. For all u,v £ U ~{e,x,Sx}, [ax,au,av\ = [Sx,au,av\ = [x,av,au], so [crx,tru,crv] = [x,u,v] iff (ru = v and av = u. There are fewer than n — 3 pairs (u, v) such that an = v, av = u, and M, V are in [/ ~{e, x, Sx}, Consequently the number of diversity cycles that are moved by er is at least (n — 3)(ra — 3) — (n — 3). But this is more than | ( n — 2)(n — 3) since n > 6. This completes the proof in case Sx ^ a:. Assume Sx = T. Then, for all u, v £ [/~{e,as,era:}, [x,u,v] = [ T , « , « ] , and [x,u,v] is moved by a since ax is not in {x,u,v,Su,Sv}. For all u,v,y,z 6 17 ~{e, x, ax}, [x,u,v] = [x,y,z] iff {u, v} = {y, z}. Hence at least {n — 3) + | (n — 3)(n — 4) = | ( « — 2)(n — 3) diversity cycles are moved by a.
D
Suppose G(n, s) and H(n, s) are real-valued functions of n, s £ u>. We say that G(n, s) approaches H{n, s) and write G(n, s) ~ H(n, s) if for every real number r > 0 there is some N € w such that if JV < n g w, 1 < * < n, and n — s is even, then
Let
whenever * < n € w and n — s is even. Then P{n, s) is the number of automorphisms of (U, S, {e}}. Theorem 470. Under the assumptions of Th. 468, (i) Pr[€m(T) is not rigid] < i ( fi";g_3) */« ^ (ii) Pr[€m(T) is rigid] ~ 1.
n
-
PROOF. Suppose er is a nontrivial automorphism of (U, S, {e}}. How many ternary relations T £ K(n, s) are there such that a is also an isomorphism of T? By Th. 469, there are at least (|)(n — 2)(n — 3) diversity cycles moved by er, so the number of orbits of diversity cycles under a can be no more than Q(n, s) — {\){n — 2){n — 3). Now if a as an isomorphism of T, then for every diversity cycle [x,y,z], either T contains [E,J/,Z] and all the cycles in the orbit of [x,y, z) under a, or else T is disjoint from all those cycles. Hence the number of such relations is at most
There are only P(n, s) isomorphisms of (U, S, {e}), so there are no more than Pin fl)2e(™''')"3(™"2)(™"3) relations in K(n, s) that have a nontrivial isomorphism. Thus (i) holds, and (ii) follows from (i). For every integer t > 1, define a property D(t) of relations in K(n, a): D(t)
(yxi,...,xt,yi,...,yt
e U~{e})(3z e U~{e})(Txiyiz,
...,Txtytz).
72. THE NUMBER OP FINITE INTEGRAL RELATION ALGEBRAS
479
It is easy to see that D(t +1) implies D(t) for all t, D(l) implies (6.172), and D(2) implies (6.171), so Cm(T) 6 RA whenever T satisfies D(2). For what follows it is convenient to let D(0) be any property that holds for all relations in K(n, s). Theorem 471 (Maddux [144, Th. 11]). Let t be any nonnegative integer. (i) Pr[D(t) is false] < (n - 1)2*(1 - 2"*)"- 2 *- 1 . (ii) P r [ D ( t ) ] ~ l . PROOF. Note that (i) and (ii) hold in case t = 0, since Pr[ D(0) holds] = 1 and JY[D(0) is false] = 0 . Let xi,...,xt,yi,...,yt e. t/~{e}. Then, for all z G U~{e}, we have Pr[Txiyiz, ..., Txtytz] > 2~*, so
Pr[^(Txiyiz,
. . . , Txtytz) ] < 1 - 2"*.
Furthermore, if w,z G t / ~ { e , x i , . . . , % t , y i , . . . , y t } and w ^ z, then
Pr[Txiyiw, ..., Txtytw, Txiyiz, . . . , Txtytz] = (Pr[Txiyiw, ..., Txtytw])(Pr[Txiyiz, ..., Tmtytz]). It follows that Pr[(Vz G [/~{e,a;i,...,a; t ,2/i,... ,yt})-*{Txiyiz, . . . , Ta;4t/tz)] <(l-2-*)"-2*-1. There are only (w — I)2* ways to choose xi,..., holds, and (ii) follows from (i).
xt, yi, .., j/t from U ~{e}, so (i)
Let D{t, n, s) be the number of isomorphism types of relations in K{n, s) that satisfy D(t). Theorem 472. Let t be any nonnegative integer. Then
PROOF. If T is any relation in K (n, s), then the number of relations in K(n, s) that are isomorphic to T is either equal to P(n, s), just in case T is rigid, or else less than P(n,s). Hence 2
D(t) ] < P(n, s)D(t, n, s) < \{T : D(t) holds and T is rigid}| + P(n, s)\{T : D(t) holds and T is not rigid}|,
so, byTh.470(i), Fr[(D(t)]<
D(t,n,s)P(n,s)
,*?}"''*.
480
6. RELATION ALGEBRAS
n
s Q(n,s) P(n,s)
1 2 3 3 4 4 5 5 5 6 6 6
1 2 1 3 2 4 1 3 5 2 4 6
0 1 2 4 7 10 12 16 20 25 30 35
i»C»,s)
1 1.00 2.00 1 2 2.00 2 8.00 2 64.00 6 170.66 8 512.00 4 16384.00 24 43690.66 4194304.00 8 89478485.33 12 120 286331153.07
F(n,s) 1 2 3 7 37 65 83 1316 3013 47865 988464 3849920
F(n,B)P(n,s) 2«(«.<0
1.000000 1.000000 1.500000 0.875000 0.578125 0.380859 0.162109 0.080322 0.068539 0.011412 0.011047 0.013446
TABLE 48. Expected and actual numbers of finite relation algebras
The desired result follows by Th. 471. Let F(n, s) be the number of isomorphism types of relations in K(n, a) whose complex algebras are relation algebras. Then F(n, s) is the number of isomorphism types of integral relation algebras with n atoms and * symmetric atoms. Theorem 473 (Maddux [144]). An asymptotic formula for the number of finite integral relation algebras with n atoms and s symmetric atoms: F(
" ' S ) ~ P(n,s)
=
(a-l)i(I(n-,))!2i<»->
PROOF. It can easily be verified that D(l) implies (6.172) and D(2) implies (6.171), so £m(T) e RA whenever D(2) holds. Then 25(2, n, s) < F(n, s) < 25(0, n, a), so the desired result follows by Th. 472. Some numerical data is shown in Table 48. According to Th. 473, the number in the rightmost column of the table below should be approaching 1 as n gets large. It is interesting to note that until n = a = 6 the values are actually getting smaller as n and a increase. 73. Many nonrepresentable relation algebras representable In this section will be shown that the number of isomorphism types of nonrepresentable symmetric integral relation algebras is increasing at a rate that is greater than 2 raised to the power of a cubic polynomial in the number of atoms.
73. MANY NONREPRESENTABLE RELATION ALGEBRAS
481
Let U be a finite set such that 4 < \U\ = n € w, let V,a,b,c be distinct elements of U, let " be the identity on U, and let (6.278)
L(n) = {Cm (T) : T C U3, Fd (T) = [/, Cm (T) e NA, [a, a, &], [a, 6,6], [a, a, c], [a, c, c], [6,6, c], [6, c, c] C T, (Va; G U ~{1', a, 6, e})([a, c, a;] C T => [a, b, x] n T = 0 = [6, c, a;] n T)}.
L(4) contains just 4 algebras, but two of them are isomorphic. In fact, LD(4) = I{2165,2265,2365} All the algebras in L(ri) are nonrepresentable relation algebras. Theorem 474 (Maddux [144]). (i) Equation (M) fails in every algebra in L(n). f'i\
] T /mnW
K^ — A^f\G(n,Jt)— 37&-I-4
(u) \L(n)\ = 5 2 v t > (iii) The number of isomorphism types of nonrepresentable relation algebras that fail to satisfy equation (M), and hence are not in RRA is at least
(iv) 7/0 < r < gj then, for sufficiently large n, the number of such isomorphism types is at least 2™ . PROOF, (i): For every €m (T) € L(n), equation (M) fails in €m (T) when the variables xoi = a, XQZ = a, a;c« = c, 132 = c, xz\ = b, XIA = 6, and 141 = c. (ii): The number of diversity cycles is Q(n, n). Not every combination of these diversity cycles can occur in a ternary relation T for which Cm(T) is in L{ri). In any such T, 6 diversity cycles must be included, 2 diversity cycles must be excluded, and 3(n — 4) other diversity cycles fall into n — 4 groups of 3 cycles each, namely {[a,6,a;], [a,c,a;], [6,c,a;]}, for every x € [/~{l ! ,a,6,c}, such that either [a, c,x] C T while [a,6,i]flT = 8 = [b, c, x] D T, or else [a, c,x]DT = 9 and any combination of the other two is included. Thus for each such group there are 5 choices for forming T. The number of remaining diversity cycles is Q(n, n) — 3w + 4. Each of them can either be included or excluded, independently. Therefore the number of possible choices for T is 5»-*2(2^K'™^3™+4. (iii): For every property ip of algebras in L(n), let Pr[ip] be the fraction of algebras in L(n) that have property tp. Let v, w, x1 y € U ~{1'}. If {«, w, x, y} C {a,6,c}, then it is easy to check that Pr[(Bz 6 {a,6,c})(Tvwz, Txyz)] = 1, so Pr[(¥z e U~{V})^(Tvwz, Txyz)] = 0. Suppose {«, w, x, y} is not included in {a, 6, c}. Then one of the pairs {«, w}, {x,y} must be different from each of the pairs {a, b}, {a,c}, {b, c}. Assume that pair is {x,y}. Let z £ [/~{r,a,6,c}. Then Pr[Txyz] = , and Pr[Tvwz] is either \, §, or \, since Pr[Tacz] = § and Pr[Tabz] = Pr[Tbcz] = f. The smallest is f, so Pr[Twto.z, Ta;^] > ^ and P r [ - i ( r u w , Txyz)] < ^ . Consequently
6. RELATION ALGEBRAS
(6.279) Pr[ {Mz € U ~{1' })->{Tvwz, Txyz) ] < Pr[(Vz e U~{V,a,b,c})^(Tvwz, Txyz)] < (J From the two preceding paragraphs, plus the fact that there are (n — I) 4 ways to choose v,w,x,y from £/~{l'}, it follows that
Pr[D(2) is false] < Pr[3v,w,x,y € [/~{e}V^ £ U~{e}, ->{Tvwz, Txyz)] i
(n-4)
.10, Consequently \{€m(T) :£m(T) e L{n), (l-(n-l)4(9/10)n-4)5"-42'' Part (iii) is now a consequence of this inequality and the following facts. Every algebra in L{n) fails to satisfy (M), is a relation algebra if it satisfies D(2), and is isomorphic to at most (n — 4)! algebras in L(n). Part (iii) implies (iv). In is possible to prove Th. 474 using the algebras 5465 and 5865 in place of the algebras 2165, 2265, and 2365. McKenzie's nonrepresentable RA with 4 atoms satisfies (L) but not (M). The RA's in L(4) also satisfy (L) but not (M). The algebras 546S and 5865 satisfy (M) but not (L), so (M) and (L) are independent. In fact, out of 102 integral RA's with 4 atoms, 5465 and 5865 are the only ones that satisfy (M) but not (L).
74. Algebras with few subalgebras With trivial exceptions, every integral relation algebra has at two distinct subalgebras, itself and the subalgebra generated by 0. In 1983 Jonsson speculated that there should be infinitely many integral relations with exactly two subalgebras, but an initial investigation by Comer and myself revealed very few. So far, only 21 have been found. Among those with four or fewer atoms, there are the following 19 algebras: li, 1 2 , I2, 1 3 , 23, 3 3 , 1 7 , 27, 3 7 , 4 7 , 5 7 , 67, 77, 1337, 3365, 3965, 4065, 4165, and 4265. Among the millions of integral relation algebras algebras with five or six atoms, there is only one more, namely algebra 380i3i6The multiplication table for the atoms of 380i3i6 is shown in Table 49. Also, an infinite one found by B. Jonsson. These 21 algebras are the only ones known. Are there any others? See Jipsen-Lukacs [110] for more on this subject.
75. Non-embeddable relation algebras Results in this section come from Frias-Maddux [75]. Let U be an arbitrary set. If U is empty then 9le (U) is a trivial one-element algebra, so 9le (0) is not simple and has no atoms. On the other hand, if U is not empty, then *Re (U)
75. NON-EMBEDDABLE RELATION ALGEBRAS
;
1' a b r f
V V a b r f
a a l'arf r arf abrr
b b r Vrf abrr brf
r r abrr brf abrr Vabrf
f f arf abrr V abrf abrr
TABLE 49. Multiplication table for algebra 380i3i6
is simple and atomic. The atoms of 9le (U) are the binary relations of the form {(a, 6}}, where a,b EU. Every atom of 9k (U) satisfies the condition (6.280)
0^x;l;x
+
x;l;x
If x is an element of a simple relation algebra 21 satisfies (6.280), then x must be an atom of 21 (see Th. 499). Suppose x is an element of a simple relation algebra 21. We say that a; is a persistent atom of 21 if x is an atom of 21 and x is also an atom of every simple relation algebra that contains 21 as a subalgebra. In a simple relation algebra 21, every element x that satisfies (6.280) is a persistent atom of 21, for if 55 is a simple relation algebra that contains 21 as a subalgebra, then x is an element of 55 that still satisfies (6.280), so x is also an atom of 55. For example, all the atoms of *He (£/) are persistent. J6nsson[113, Lemma 7.4] observed that 9le ([/) therefore cannot be properly embedded in any simple relation algebra whenever 9le (U) is finite. Here is a simple criterion by which the persistence of one atom can be deduced from the persistence of another. Theorem 475. Assume 21 £ RA, 21 is simple, and x £ At$l is a persistent atom o/2t. 7/21 has elements y,z such that 0 ^ z < x;y and z;z y;y < V then z is also a persistent atom of 21. Let x be an element of a relation algebra 21. We say that a; is a coherent element in 21 if e;x = x;e whenever V > e E A. All subidentity elements are coherent. The only coherent elements in 9le (U) are the subidentity elements. In an integral relation algebra, where 1' is an atom, every element is coherent by various parts of Th. 476. The converse holds when the algebra is simple by Th. 477. Theorem 476. Suppose x and y are elements o/2l € RA. (i) If x is coherent and y < x then y is coherent. (ii) If x is coherent then x is coherent. (iii) If x and y are both coherent then x + y and x; y are coherent. (iv) If x < V and x is an atom, then x; 1; x is coherent. Theorem 477. 7/21 E RA then the following statements are equivalent: (i) 1 is coherent in 21. (ii) Every element in 21 is coherent. (iii) For every x £ A, (1' x); 1 = 1; (1' x). ( i v ) F o r every y € A , y ; l = l ; y .
6. RELATION ALGEBRAS
V V a b c c'
a a a 0' 0' 0'
c '
b b 0' 1' + a 0' 0' 6
c c 0' c 0'a b + a -H / A ( C ' , C ) O-l
1' a b c c'
O-l
©A
c' c' 0' -c' 0'-6 fo + a + / A (c,c') a
T A B L E 5 0 . P r o d u c t s of a t o m s in
(v) F o r aZZz,y € . 4 , ( 1 ' x);y = y;(V
x).
(vi) 21 is a subdirect product of integral relation algebras. Hence a relation algebra is integral iff it is simple and 1 is coherent. T h e o r e m 478. If 21 £ RA, v,w,x,y,z £ A , w = w;w-0', v;v-v = 0, w < x\y, w;x w;y < w;z, x;z < 0 ' , and y;z < 0 ' , then v is a coherent element of 21. 7/21 is integral, then w is an atom of 21.
The next theorem shows there are finite integral relation algebras in which the identity element 1' is a persistent atom that does not satisfy (6.280). Its proof uses Th. 478. Theorem 479. (i) 1' and b are persistent atoms of 4365, 4765, 5465, and 5865(ii) 1', r, and r are persistent atoms 0/3437. (iii) 5465 and 5865 have arbitrarily large proper integral extensions. (iv) 3437, 4365, and 4765 have no proper simple extensions. Data in §6.64 shows that 3437, 4365, 4765, 5465, and 5865 are not in RA5, hence not representable. The next theorem provides many more examples of non-embeddable algebras. Let C be a set disjoint from { l ' , o , 6 } . Let C' 3 ' be the set of 3-element subsets of C. Choose any A C C' 3 '. Let S £ be the relation algebra whose atoms are {V ,a,b} U C and whose forbidden diversity cycles are [a,a,a],
[b, b, c] and [c, c, o] for all c € C, [c,c',c"] for all {c,c',c"} £ C[3] ~ A. Table 50 gives the products of atoms whenever c and c' are any two distinct elements of C. Two of the entries in that table use a function that is denned for all c,c £ C by U(c,c') = {c,c'}U{c":{c,cl,c"}eA}. If C has only one element, then C' 3 ' = 0 and the table for S)£ reduces to the table for 4765, so Z>1 = 4765. T h e o r e m 480. If C is finite and A C C' 3 ', then S £ is a finite symmetric integral algebra in RA ~ RA5 with no proper simple extensions.
75. NON-BMBEDDABLE RELATION ALGEBRAS PROOF. If (a;o2,a;2i,a;o3,a;3i,a;o4,a;4i) = (b,b,b,c,b,a),
485
t h e n (L) fails in 1)%,
soSg£RA5. If U is finite, then the relation algebra 9k (U) is generated by a single relation; see Tarski-Givant [240, Theorem 8.4(xiv)]. Indeed, any linear ordering of U generates 9te (U). It follows that every simple RRA that has a square representation on a finite set can be embedded in a one-generated simple RRA. A significant extension of this observation is that every simple finitely-generated (and possibly infinite) RRA can be embedded in a one-generated simple RRA; see Tarski-Givant [240, Theorem 8.4(xv)]. Such results cannot extended to nonrepresentable relation algebras, because the construction of 2)£ happens to include algebras that require arbitrarily large numbers of generators. We see next that if, given k, we choose n so that k + 3 < Iog2(n + 3), let \C\ = n, and let A be either 0 or the set of all 3element subsets of C, then £>£ cannot be generated by fewer than —3 + log 2 (n+3) elements. Of course, T)% cannot be properly embedded in any simple relation algebra. It can also be shown that £>£ cannot be embedded in any fc-generated relation algebra, simple or not. Theorem 481. Assume that C is finite, \C\ = n, and 2) is either S^[3] or -00
(i) If {V, a, 6} C G C D and G is closed under the Boolean operations then G is a subuniverse ofT). (ii) 5) cannot be generated by fewer than Iog2(3 + n) — 3 elements. (iii) If m < Iog2(3 + n) — 3 then D cannot be embedded in any m-generated relation algebra. Let TT(W) be the formula 0 ^ w;l;w + w;l;w < V. It was known to Jonsson and Tarski that TT(IU) defines atoms in simple relation algebras. It was natural to wonder whether there are other such formulas, and there are. Let
O');(w;w
0') = w;w + VA
3x,y,z[(w;w
0' < x;y)
A (w;x
w;y
< w;z)
A (x;z
+ y;z
< 0')].
The proof of Th. 479 shows that
A 3 a ; [ ( 0 / w < v;x)
A (w;w
x;x
< 1')]].
With trivial exceptions, atoms that satisfy TT can occur only in nonintegral simple relation algebras, while atoms that satisfy tp or ip can occur only in integral relation algebras. Atoms that satisfy TT,
486
6. RELATION ALGEBRAS
76. Complex algebras of cycle structures Every ternary relation T is isomorphic to the cycle structure of its complex algebra: T = Cy{£m (T)). The next theorem shows that composing the operators in the opposite order produces an interesting characteristic of WA. Under the operator Cm(Cj/(-)), WA is closed but NA is not closed, while the closure of RRA under <£m {Cy(-)) properly contains SA (and may be all of WA). Part (i) of the following theorem was proved in Th. 351 under the additional assumption that 21 is atomic. Portions of that proof appear again in the next proof. It follows from Th. 351 that whatever algebras are used to prove parts (ii) and (iii) cannot be atomic. Every atom is part of a cycle in an atomic NA, but this is not true for all NA. One can arrange an NA with one symmetric diversity atom and an atomless Boolean algebra of elements below 1'; see the proof of part (ii). Theorem 482 (Maddux [142, 3.8, 3.9, 3.10]). (i) 7/21 £ WA then Cm (Cj/(2l)) £ WA. (ii) There is some a £ NA such that £m(Cy(2l)) £ NA. (iii) There is some 21 € RRA such that Cm(Cy(2l)) € WA~SA. PROOF. Proof of (i): Let S and / be denned by (6.154) and (6.155), respectively, with T = Cj/(2l). Let a, b £ At%. We will show that Sab iff a = b and a £ 7 iff a > V. Note that Sab holds iff, for all x, y 6 At%, we have
a;x y ^ 0 <=> b;y x ^ 0,
x;a y ^ 0 <=> j / ; 6 - x ^ 0 ,
and a € I iff for all x, y £ At%L, ( n ; i - | / ^ 0 V i ; « - ! / ^ 0 ) => x = y.
If a = b then Sab holds by the cycle law. For the converse, assume Sab. From a 6 At% and 21 £ WA it follows that a' 6 At% and a;a' a ^ 0. From the latter statement we get b;a a' ^ 0 by the assumption that Sab, so a';a b ^ 0 by the cycle law. However, a = a';&, so a b ^ 0. It follows that a = b since a and b are atoms. Every atom has a converse, so (6.169) holds. If a < V a n d a;x y ^ 0, t h e n 0 ^ a;x y < V ;x y = x y , h e n c e x = y since x and y are atoms. Similarly, if a < V and x;a y ^ 0 then x = y. Thus a £ / whenever a < V. For the converse, assume a E I. We have 0 ^ a = a; a' a, hence a' = a since a 6 / , but a'
76. COMPLEX ALGEBRAS OP CYCLE STRUCTURES
487
follows: 0 x y x-y + 0' x y + 0' 1'
if x = 0 or y = 0, if 0 ^ x < V and 0 ^ y < V, if x > 0 ' a n d 0 ^ y < 1', if 0 ^ a; < 1' and y > 0', if x > 0 ' and y > 0'.
Set 21 = (03, ; , B \ r ) = (B,+,',;,B1 ,V) and verify that 21 e NA. We have AM = {0'} and Cy(2t) = 0 since 0';0' 0' = 0. Hence the identity element of £m (Cj/(2l)) is {0'}, and the identity law fails in Cm (Cj/(2l)) since {0'};{0'} = 0 ^ {0'}. Therefore, Cm(Cy(2t)) ^ NA. Proof of (iii): Let Q be the set of rational numbers. Let U = {eoo,en,e22,dn,d22,doi,dio,do2,d2o}, U' = UU {dr12 : r E Q} U {dr21 : r E Q} i-
r
i
-* — \6OO5 6 l l
622 J
Define " : U' -> U' as follows, for all r E Q. (eoo)" = eoo (en)"
( d n ) " = dn = 611(^22)"
(doi)" = dio =^22(^10)"
(^02)" = ^20 =doi(
(^12)" = ^21 =^02(^21)"
=
^12
Let 03 = Cm (T) and C = Cm (T1), where T = T' n U3 and T' is the union of the following cycles: [eii,en,en]
[e22, e22, 622]
[eoo, eoo, eoo]
[dn, eii,dn]
[^22,622,^22]
[dio,eo
[doi, en,doi]
[do2,622,^02]
[d2o,eo
[doi,dn,doi] Verify that <8 € WA~SA. We will show that C e RRA, and there is some St C C such that Cm (Cj/(2l)) = 03. This completes the proof, for we will have 21 G RRA and £m(Cy(St)) e WA~SA. Let if and L be distinct countable infinite sets, pick an element in neither of them, say m £ K U L, and pick a function P : {K x L) U L(xK) —> Q with these properties: (i) p(fc, 0 = p(/, k) for all fc € K, I € L, (ii) if k,k' E K,k ^ k',r,s E Q then there is some I E L such that p(fc, I) = r a n d p(k',1) = s, (iii) if /, /' G L, / ^ /', r, s G Q then there is some k £ K such that p(fe, I) = r and p(k',1) = s.
488
6. RELATION ALGEBRAS
For an example, let Mo = Q, Mi = Mo x Q x Mo x Q, Mn+2 = Mn U (Mn+i x Q x Mn+i x Q) for every n E LJ. Set K = \Jneuj M2n and L = \JneuJ M2n+i If {x, r, j/, s) 6 M n x Q x M n x Q and x ^ y, then set p(x, (x, r, y, s)) = p({x, r, y, s), x) = r, P(y, (x, r,y, s)) = p({x,r, y, s) ,y) = s, p(k, I) = p(l, k) = 0
otherwise.
Define an embedding F of £ into d\t [K ULU {m}) as follows: F(eoo) = {{m,m)}
F(dol) = {m} x K
F ( e n ) = K1
F(dio) = K x {m} F(dn) = K x K
F(e 22 ) = L1 F(d20) = L x {m}
F(d02) = {m} x L F(d 22 ) = Lx L
F(dr12) = {{k, I) : k G K, I € L, p(k, I) = r} F(dai) = {
F(X) = U F(x) xdX
Thus 2t e RRA. Next we choose 21 C C. Let H be the set of all subsets of Q that are finite unions of intervals Q ("I (a, 6) where a and 6 are irrational. Then (H, U, ) is an atomless Boolean algebra. Let A be the set of subsets of U' of the form X U {dT12 : r 6 R} U {ds21 : s E S} where X C H a,nd R, S C H. Then ,4 is closed under the relevant operations and is therefore a subuniverse of a subalgebra a of C and Cm (Cy(2l)) = 93. 77. Flexible systems of atoms We say that an atomic 21 G WA has a flexible system of atoms if for every pair of identity atoms u and v there is a diversity atom x such that xd = u, x' = v, and x < y;z whenever y and z are diversity atoms satisfying the conditions yd = u, r
d
r
y = z , z = v. Theorem 483 (Maddux [142, 5.13]). For every complete atomic 21 6 WA there is a simple complete atomic 23 E WA such that 23 has a system of flexible atoms and 21 = £Hts9S for some s G 5V23. PROOF. We may assume, without loss of generality, that At% and {At^'Si)2 are disjoint. Set U = A£2tU (At^VL)2. Define / as follows. (6.281)
f = {{x,x) :xeAm}U{{{u,v),{v,u)) - 1
: u,v G At^X).
Note that / is an involution on U, that is, / | / = f\f = U1. Furthermore, At%, and fx = (v,u) if x = (u,v) E (At^^i)2. Another way to fx = xiixE express / is f = (x:x €AM)l)((v,u) : (u,v) E (At^Slj2) . Let T be the union of the following /-cycles: (i) [x,y, (xd,yr)] for all x,y E Ato,% and x' = yd, (ii) [x, {xr, u), (xd, u}] for all x G Am and u G At^%
78. TRAILS OP MATRICES
489
(iii) [{u, v), {v, w), {u, w)] for all u,v,w £ At^ 21. Let T ' = T U «a;,y,z) : z,2/,2 £ At 21, x;y > z}, 23 = Citi(T'), and s = At21. Notice that the field of T' is U, so the universe of 58 is Sb (U) and s is an element of 93. Obviously 58 is complete and atomic. Use Th. 346 to show that 03 € WA. 23 is simple complete and atomic, s £ SV23, 21 = $R[593, and 93 has a system of flexible atoms. The properties of subidentity elements in a WA are required for checking the details of these claims. Basic matrices satisfying the off-diagonal condition give rise to representations. Suppose 21 £ WA and 21 is atomic. We say that m is an n-labelling in 21 if m € Bn% Cj/(2l) = Ra (ra), and ra satisfies the off-diagonal condition. We say that a quadruple (i,j,a,b) is a flaw in the labelling m if i,j < n, a,b £ Cy(%V), mij
23 £ RRA.
78. Trails of matrices This section is devoted to the construction of the canonical relativized cylindric set algebra from any relational basis. This construction is related to the n-square representations of Hirsch-Hodkinson [96]. It can be used to prove the Relative Representation Theorem for WA, Th. 488 above. Let 21 £ NA. Assume 21 is atomic. Let n be an ordinal such that n > 2 and n is infinite only if 21 is complete. Suppose that M C Mn2l, every matrix in M satisfies
480
8, RELATION ALGEBRAS
the diagonal condition and is closed (path-consistent and symmetric), and that x[k/j] 6 M whenever x €W. and k, j < n. We refer to such a set of matrices as a suitable set of matrices. We say that t is a trail of M, or an M-trail, if there is some n £ w such that t: (n + 1) -) (M x n) and t satisfies certain other conditions. To express those conditions, and for brevity, we write a typical M-trail in this fashion: t =
(xo,ko,...,xn,kn),
but the meaning and function of the components of a trail would perhaps be more easily comprehended by the use of a more elaborate notation, such as *>0 Xo
fcl Xl
*>2
*n-2
X2
*n-l Iii-l
%n
kn >
The conditions an M-trail must satisfy are that i < n then Xi ^ T»+I and xi and Xi+x agree up to fa. Let Tr(M) be the set of M-trails. We say that an M-trail t = {TO,ko,... ,xn,kn) begins at XQ and ends at xn, that kn is the pointer of t, and that t has length \t\ = n + 1. The trail t is said to be reduced if the following conditions hold: - if 1 = |t|, t = (xo,ko), and (xo)koj < 1', then k0 < j < n, - if 1 < |t| then kn-i = kn and for all j < n, xn £ Ekn§ iff fcn = j , - if 0 < i < |t| — 2, then either T» =^ 3Sj+2 or fe ^ fcj+i. For every j < n, let tj = (Xo,ko, . . . ,Xn-X,kn-X,Xn,kn} j = {xa,ko,.. ,Xn-X,kn-X,Xn,j) All trails have length 1 or more. A reduced trail of length 3 or more cannot have a subsequence of the form {x,j,y,j,x}. If t is a trail, then so is tj. Next define some binary relations on trails. Let Pi be the set of pairs of M-trails of the form \\%0i &O5
5 2-i; iiV-i 3-! ^ii
! *^7M fan) 3 \*^05 n-0,
5 Xi, fa, . . . , Xn
/
let P2 be the set of pairs of M-trails of the form ((xo,ko,...,xn,j,y,kn),
{xo,ko,
,xn,kn)),
where j ^ kn,
and let P3 be the set of pairs of M-trails of the form ((xo,ko,...,xn,j),
(xo,ko,...,xn,kn))
where {xn)jkn < 1'.
We say that a trail t' is obtained from a trail t by a reduction of type (1), (2), or (3), if {t,t') is in Pi, P2, P3, respectively. Let Q be the smallest equivalence relation on Tr(M) that contains Pi, Pa, and P 3 . For each t e Tr(M), let tM be the Q-class of i, i.e., tH = t/Q = {t' : (*, *') eQ,t' G Tr(H)}. Let t/(M) = {tH : t 6 Tr(M)}. [/(M) is called the canonical base for M, or M-base, and the equivalence classes in f7(M) are called canonical base points. In the next theorem and its proof we use an alternative meaning for exponentiation with integers greater than 1. For every binary relation R, let R2 = R\R,
78. TRAILS OF MATRICES
491
R3 = R\R\R, etc., and denote the transitive closure of R by R". Thus R" = R U R2 U R3 U . Let (6.282)
P4 := P3 n {{ti, tj) : i > j } ,
(6.283)
P6:=Pa\(PiUP2)\Pa,
(6.284)
P6:=P3UP5,
(6.285)
Z:=Tr(M)~Do((P 4 UP B )),
(6.286)
PT.=
P%\ZX.
Theorem 489. (i) (ii) (iii) (iv) (v) (vi) (vii) (viii) Cixi ! ^Ji.^
(xi) (xii) (xiii) (xiv)
P 2 is a function, i.e., P 2 " 1 |P 2 C (Tr(M))1, P 3 is an equivalence relation on Tr(M), Pf 1 |Pi = (Tr(M)) 1 UPi|Pf 1 , P2~1|-pi = ft U P1IP2"1 anrf f f ^ f t = P2~l U PilPf 1 , Pf X|P3 = PsIPf1 ond P3|Pi = Pi|P 3) Pf^ftlPi C f t l P f ^ f t , P 1 - 1 |P 3 |P 2 C PSJPS"1 U Ps"1 and P ^ P ^ P i C P6\P^ U PB, P2"1|P3|P2 CP 3 , P~1IP« C PP. P~l n _ /p y p-i\u _ pwI/p-iw VC^
Q <J J. Q
J
Q I
Q
J
j
/or enery t G Tr(M), i is reduced iff t £ Z, Q = P 6 a '|Z 1 |(P 6 " 1 ) u; = P7IP7"1, Z 1 |P 7 = Z 1 , P7 is a function.
PROOF. Parts (i), (iii)-(v), and (viii) follow just from the relevant definitions. For part (ii), note that P 3 is reflexive on trails since every matrix in M satisfies the diagonal condition, P 3 is symmetric because every matrix in M is symmetric, and P 3 is transitive since every matrix in M is path-consistent. Part (vi) follows from (ii), (iii), and (v). Part (vii) follows from (ii), (iv), and (v). Parts (ii), (vi)-(viii) imply (ix). We have (Tr(M))1 C Pi U P 2 U P 3 C P 6 C Q by part (ii), and Q is the equivalence relation generated by Pi U P 2 U P 3 , so Q = {P& U P^" 1 )". Part (ix) implies (Pe U P^" 1 )" C Ps'KP^" 1 )" by induction, and the opposite inclusion is trivially true. Thus (x) holds. If |t| = 1 then t is reduced iff t 0 Do {Pi). If |t| > 1 then t is reduced iff t £ Do (P5). This follows from the observation that if the pointer can be changed by a type (3) reduction, then a type (2) reduction can be performed. More precisely, if \t\ > 1, (£,£') G P 3 , and t / t', then t' = tj for some j , and hence either t G Do{P2) or t' G Do{P2). Thus (xi) holds. Let R = PA U P5. Then Tr(M) = Z U Do {R), so (Tr(M))1 = Z1 U {Do {R))1 C Z1 U R\R~Y = Z1 U ^ ( ^ ( M ) ) 1 ^ " 1 C
z1 u PKZ 1 u fllfl"1)^-1 = z 1 u Biz1!/?"1 u P^K-R-1)2Continuing in this way, we get (6.287)
(Tr(M))1 = Z 1 U (J 0
R^Z1^-1)11
VJ Rn\{R-1)n.
6. RELATION ALGEBRAS
whenever 2 < n < to. If {t,t') € P 6 then |t| > |t'|, and if (ti,tj) € P 4 then i > j , so there are no infinite iZ-chains. Therefore, given an arbitrary t 6 Tr(M), there is some n such that (t,t) (£ R^^^RT1)71 and 2 < n < ui, which implies, by (6.287),
that (t,t) <E Z1 U\J0
This proves 1
(Tr(M)) C Z
UR^lZ^iR-1)".
Note that Z1 U R C P 6 . Consequently (Tr(M))1 C P ^ ^ p - 1 ) " - 1 and Pg\Pg = PQ . By (x), we have
Q = p6wKTr(M))ii(p6-ir ci^|i^|z i i(p 6 - i ri(p 6 - i r = p 6 w |z i i(p 6 - i r. Note that P f : = Z 1 ! ^ ) " 1 = Z^^P^Y, so Q = Pi^1. Thus (xii) holds. By the relevant definitions, ZX\P% = Z^^Tr^))1 UP 4 U Pf 1 U P6) = Z 1 U Z ^ P ^ 1 . Also, P^^Pe C P 3 |P 6 = P6 by part (ii). Consequently ZX\P% = Z1 U Z^Pf 1 by induction. Also, P f 1 ^ 1 = 0, so Z ^ P T = Z^Pe^lZ1 = (Z1 U Z ^ P f 1 ) ^ 1 = Z 1 . Thus (xiii) holds. By the definition of P7, (x), (xii), and (xiii), P 7 " 1 |P 7 = Z1|(P6a')"1|P6a'|Z1 C Z^QIZ1 = Z^P^P^^Z1
= Z 1,
so (xiv) holds. By Th. 489, P7 is a function contained in Q, Piit) is reduced, and t is reduced just in case Pi{t) = t. Thus P7 maps each trail t to the unique reduced trail in iM. Since P3 is an equivalence relation and P3IP5 = P5 = P5IP3, we have P6" = (P3 U P 6 ) w = P 3 U PBW, so P 7 = Pe^l^1 = (P3 U P%)\ZX = ((Tr(M))1 U P 4 U P ^ 1 U Pg1")!^1 = Z1 U (P4 U PB'OIZ1. In other words, to compute P7(t) in case t is not reduced, follow a Pg-chain until a trail is obtained that is not in DO(PB), and then reduce the pointer as much as possible by using P4 once. Notice that |P 7 (t)| < |t| for every trail t. If |t| = 1, then t $ Do(P5), and either t is already reduced, or else (£, Pi{t)) 6 P4, where Pr(i) = ti for some ordinal i that is smaller than the pointer of t. For every M-trail s = {xo, ko, xi, fci,..., xn-i, kn-i,xn, kn) let S
=
\%n, Kn—1, Xn— 1 , Kn — 2,
X\ , fco, iCO, "^n/
If t = (yo,jo,..., ym,jm) is any other M-trail, then s 0 £ is defined if s ends where t begins, in which case s 0 t = (xo,ko,xi,ki,...
,xn-i,kn-i,yo,jo,.
.. ,ym,jm)
Also,
{
S0 t
if Xn = yo
sQt
if xn ^ yo = xo ,
t
if Xn 7^ 2^0 7^ ^ 0
Let Pm(M) = {Is : s e Tr(M)}. and, for any X C Tr(M), L(X) = \Jtex(Ls(t)f. If s and t are M-trails, then s is an M-trail of the same length, and if s 0 t is defined, then s Qt is also an M-trail with |s ©t| = |s| + \t\ — 1. The associative law for 0 holds whenever both sides are defined. If |s| = 1, then s = s and Ls(t) = t for every M-trail t. Note that (s 0 t)i = s 0 £i and Ls(t)i = Ls(ti). Theorem 490. Suppose s, t G Tr(M). T/sen
78. TRAILS OF MATRICES
493
(i) ls(f) = (Ls(t))H, lslB(f)=lslg(tH), (ii) tH = (iii) ls is a permutation ofU(W) and (h)^1 = lgPROOF. Suppose s begins at xo and ends at xn. If t begins at j/o then Ls(t) begins at [xo, xn](yo), where [so,a;n] is the permutation of M that interchanges xo and xn and fixes all other elements of M. Hence, if Ls(t) and Ls(t') have the same beginning, then so do t and t', and the definitions of Ls(t) and LB(t') fall into the same three cases, i.e., Ls(t) = t iff LB(t') = t', LB(t) = sQt iff LB(t') = s 01', and Ls(t) = sQt iff Ls(t') = sQt'. It follows easily that Ls is injective. Furthermore, t, LgLs(t), and LBLg(t) have the same beginning. According to the definitions of 0 and LB, t is always a final segment of Ls(t). Consequently Ls preserves Pi, P>, and P 3 , i.e., L'^P^L., C Pi, L~1\P2\LS C P 2 , 1 1 and L7 |-Ps|-^s f= ft- So L s also preserves Q, i.e., LJ \Q\LB C Q. Proof of (i): Suppose t' 6 Ls(iM). Then there is some t" e iM such that t' 6 L s (t") M . Therefore (t",t) £ Q and (t',Ls(t")) G Q. Since L s preserves Q, we have (LB(t"),LB(t)) E Q, so (t',LB(t)) e Q, i.e., t' E LB(tf. Thus ls(f) C Ls(i)M. The opposite inclusion holds trivially. Proof of (ii): Check that LgLs(t) is either t, s Q s Q t, or s Q s Q t. We will show LgLB(t) e tK by considering three cases. Obviously LgLs(t) 6 tK if LgLB(t) = t. Suppose LsiLs(t) = s 0 s 0 t ^ f. Then |s| > 1 and s 0 s 0 t £ Do (Pi). In fact, (s © sQt,t) E P j 3 ' " 1 , so LgLs(t) E f. Similarly, if LgLB(t) = sQsQt ^ t, t h e n (sQ'sQt,t) € P j " 1 " 1 , so LuLs{t) € f. From L3Ls(t) € f a n d part (i) we get iM = (L;r.Ls(£))M = ?s-(Ls(i)M) = lglB(tK), which shows one equality of (ii). The other equality holds similarly. Finally, part (iii) follows from parts (i) and (ii). By Th. 490, Pm(M) is a group of permutations of the canonical base points, so the functions in Pm(M) are called canonical permutations of U(M). For every x en, let (6.288)
R" = {((tkf
:k
Tr(M), t ends a t x}.
Note that every element of R" is a function mapping n into £/(M), so R" is a set of n-sequences of canonical base points. We let V(K) be the union of these sets: (6.289)
V(M) = ( J R*.
Next we define some special subsets of V(Vl) and some unary operators on subsets of V(K). For i,j
D%m = {((tkf
:k
Tr(M), (ti)H =
(tjf}.
For every X C V(M) and every k < n, let (6.291)
4 V(M)1 X = { / : / £ V(n), gGX,
f(k) = g(k) for all k < n}.
Let C be the smallest family of subsets of V(M) such that R" 6 C for every i £ H , D [J(M)] e
c for all i , j < n ,
6. RELATION ALGEBRAS
C is closed under complementation with respect to V(Vl), C is closed under arbitrary unions (and intersections), for every k < n. C is closed under Ck We may use C as the universe of an algebra
£(M) is an example of a cylindric-relativized set algebra of dimension n (see HenkinMonk-Tarski [94, 3.1.1(iv)]), called the canonical relativized cylindric set algebra of M. Theorem 491. Let x 6 M. Then (i) Pm(M) preserves R", and Pm(M) acts transitively on R", (ii) R™ is an atom o/C(M),
(iii) R" is the orbit of a single n-sequence under the group Prn(W). PROOF. The first part implies the other two parts. For every set X of functions mapping n into U(M) and every permutation p of £/(M), let pX = {a : a\p £ X, a:n^> U(n)}. We first show that fsR" C RKX for every s E Tr(K).
/~R* = {a\ls : a £ {{(tif : i < n) : t G Tr(M), t ends at x}} = {((ti)K : i < n) \ls : t 6 Tr(M), t ends at x} = {(Is((**)*) -i
:i
:i
Tr(K),
t ends a t x}
Tr(M), t e n d s a t x}
Since ls and h are inverses, so are ls and Is. Hence R" = /sZsR" C /SR" C R", so R* is preserved by ls. To show that Pm(B) acts transitively on R", let us assume that t and t' are trails that end at x. We wish to find a canonical permutation ls that maps ((ti)H :i
:i
= (Ls(tiH)
:i
= ((Ls(ti))H
: i < n) = ((t'i)H
: i < n) . U
Theorem 492. For every i £ B and i,j < n, Hj < V iff R" C D^ ( M ) ] . PROOF. If i = j then the result holds since xu < V for all x £ M and all i < n, so assume i ^ j and Xij < V. Let ((tk)K : k < n) £ R". Then t ends at x and (ti,tj) £ P3, so (ti)w = (tjf, which implies ((tkf : k < n) £ D[V(M)]. NOW so (t,tj) £ Q. assume R* C D^ (M)1 and let t = (x,i). Then ((tk)n :k
78. TRAILS OF MATRICES
495
But t and tj are not in the domain of P5 since \t\ = \tj\ = 1, so (t,tj) G P3, hence
a^-
D
Theorem 493. Ifx, y € M, i < n, and x, y agree up to i, then R" C C[y(M)IR" . PROOF. If x = y, then R" = R" C C[y(M)IR", so we may assume x # y. Suppose ((tkf : k < n) G R". Let t' = tQ{x,i,y,i). Note that ((t'kf : k < n) £ RKy. If k / i then (tk,t'k) = (t 0 (x, k), t 0 {x,i,y, k)) e Q. So (tfc)M = {t'kf whenever k =/= i, and therefore
((tkf
:k
Cp ) ] {((t'fc) M : fc < „ ) } C C[V(M)1RM,.
Thus RM, C C[V(M)1R^.
D
Our next goal is to prove the converse, namely T h e o r e m 494. If x,y € M, i < n, and R" C C[ y(M)I R", then x and y agree up to i. To this end, first note t h a t x[i/j] € M whenever x € M, x[i/j] = x whenever Xij < 1' and x €.W, x [^lJ] = y[i/j] whenever x, y agree up to i and x,y £M. Let Q = {a : 3n{n G LU, a : [n + 1) —> n 2 ) } . For every a = (ko,jo, , kn,jn) 6 fi, \[kn/jn\- Note that for all a,T G fi, (
M = {(aA(i), [t](aA(i))} : aA(i) / i < n} U {(rA(i), [t](rA(i))) : rA(i)
^i
Since M is finite, there is some S G fi that is the result of concatenating all the pairs of M in some order. From [t]\[t] = [t] and the assumption crA|[£] = T A |[£] it is easy to show that 0~<5)A = ( T ~ 5 ) A , SO (xo5A)aA = xo(a~5)A = X O ( T " 5 ) A = (XO5A)TA. S i n c e \t\ = 1 , if ( i , j ) S M , t h e n ( t i , t j ) G P 3 a n d (xo)ij
6. RELATION ALGEBRAS
For the inductive case, let n > 1, and assume that Th. 495 holds for all trails of length no more than n. Let t = {xo,fco, , xn-i,kn-i,Xn, kn), and set t' = {xo, fco,..., xn-i, fcn-i). Therefore |t| = \t'\ + 1 = n + 1. Assume a, r E Q, t collapses on RgrA, and <7A|[(:co,fco)] = TA|[<]- We wish to prove XQO-A = xnrA. Suppose that t E Do Pi. Choose t" E Tr(M) so that (£,£") £ Pi- Obviously |i"| = \t\ — 2 = n — 1 < n, so we may apply Th. 495 to t". (This case cannot occur when n < 3.) Notice that t" begins at xo and ends at xn. By the definition of Pi, we clearly have {ti,t"i} E Pi for every i < n. Consequently P7(ti) = P7(t"i) for all i < n. It follows that t" collapses on RgrA since t is assumed to do so. It also follows that [t] = [t"\, and hence <7A|[(:co,fco>] = rA\[t] = rA\[t"\. We may therefore apply the inductive hypothesis to t", a and r, obtaining xo«rA = xnrA. This completes the proof of Th. 495 in case t 6 Do Pi. Therefore assume t tfi Do Pi. We consider two cases. Suppose there is some j < n such that j ^ fcn-i and (xn)krl_1j < 1'- Set v = r~ {kn-i,j). Notice that vA = (r~ (fc n -i,i)) A = rA\ (fc n -i,i) A = rA\[kn-i/j], so RgvA C RgrA ~{kn-i}. Next we show t' collapses on Rgv. Let i £ RgvA. Then j £ RgrA, so |J-V(f*))| = 1 since t collapses on RgrA. Also, i ^ fcn-i, so {ti,t'i} E P2, hence PT(ti) = P7(t'i), which implies 1 = \P7(ti)\ = \Pr(t'i)\. Thus t' collapses on Rgv. Next we show [t] = [kn-i/j]\[t']- Since j kn-i, we have (tkn-i,tj) € PA U P ^ 1 and (ij, i'j) € P 2 , so P7(tkn-i) = P7(tj) = P7{t'j), hence [i](fcn_i) = [t](j) = [t'](j) = ([kn-i/j]\[t'])(kn-i). On the other hand, if fc ^ fcn_1; then (tk,t'k) E P 2 , so P7(tk) = P7(t'k), hence [t](k) = [t'](k) = ([kn-i/j]\[t'])(k). Thus [t] = [kn-ilj}\[t'\. By assumption, aA|[(:ro,fco>] = rA\[t], but rA\[t] = rA\[kn-i/j]\[t'] = vA\[t'], so crA|[(xo, fco)] = i) A |[t']. We may apply our inductive hypothesis to t',
a, and v, obtaining xoo~A = xn-ivA. However, xn-ivA = X I I - I ( T ' ^ (kn-i,j))A = {xn-i[kn-i/j])rA by the relevant definitions. Furthermore, we have xn-i,xn agree up to fcn_i and {xn)kn_lj < V, so £n_i[fcn_i/j] = xn[fcn_i/j] = x n by (2) and (3). Therefore, xoaA = xnrA. This completes the proof of Th. 495 in the first case. Suppose there is no j < n such that j ^ fcn-i and {xn)kn_1j < 1'. We are assuming t ^ Do Pi, and the assumptions for this case imply that tkn-i £ Do(Pi U P 4 - 1 U P 2 ), so tfcn_i is reduced. Therefore P7(tfcn_i) = tkn-iNow |P7(tfcn_i)| = n+ 1 > 1 and t collapses on RgrA, so fcn-i ^ RgrA. Choose any j < n such that j ^ fcn-i. This is possible since n > 2. Set v = T " (fcn_i,j). As above, we have vA = r A |[fc n -i/i], but this time kn-i fi RgTA, so vA = TA. If fc ^ kn-i (in particular, if fc E RgvA = RgrA) then (tk,t'k) E P 2 , so P7(tk) = P?(t'k) and [t](k) = [t'](k) = {[kn-i/j]\[t'])(k). Now t collapses on RgrA, so t' collapses on RgvA. It is possible that [t] and [fc«-i/i]|[i'] differ on fcn-i- However, since fcn-i ^ RgrA we have r A = TA|[fcn-i/J], hence TA|[i] = rA\[ku-i/j]\[t'] = vA\[t'}. By assumption, aA\[(x0,k0)} = rA\[t], so aA\[{x0,k0)} = vA\[t'].
We may now apply the inductive hypothesis to t', cr, and r, obtaining XQOA = xn-iv . Since a;n-i,a;n agree up to fcn-i, we have xn-i[kn-i/j] = xn[kn-i/j] by (3). Therefore xoaA = xn-ivA = (xn-i[kn-i/j])rA = (xn[kn-i/'j])rA = xnvA. A
78, SINGLETONS AND TWINS IN A simple SA
497
But we also have TA\[{xn,kn)] = wA|[{in, kn}] since T A = vA, and trails of length 1 collapse on n, so by the inductive hypothesis, applied to [(xn,kn)], T, and v, we get xnrh = xnvA. Hence xocrA = xnrh. This completes the proof of Th. 495. To finish the proof of the Th.494, suppose x,y G H and Rl C C^(M)]R™. We wish to show x, y agree up to k. Since x, x agree up to k, we may assume x =^ y. Let * = (x,k). Then {(si)n : s < n) 6 R", so, by our hypothesis, there is some reduced trail t g Tr(M) such that ((ti)n : i < n } g R j and {si,ti) 6 Q whenever k / t < n. Choose i < n so that k / i. This is possible since n > 2. It follows from (si,ti) G Q that s and t both begin at x. Note that t ends at y, t collapses on Rg[k/i] and [k/i]\[a] = [k/i]\[i\. Therefore, by Th.495, x[k/i] = y[k/i\, which implies x,y agree up to k. Here is an alternate proof of Th. 488. Assume SI E WA. Since SI is a subalgebra of a complete atomic WA (e.g., its perfect extension) we may assume without loss of generality that 21 is itself complete and atomic. Let M = B32I. Verify that M is a suitable set of matrices, so that the construction of Tr(M) may be applied. Let U = ?7(M), the set of canonical base points. Define a function p that maps each element of the algebra 21 to a binary relation on C/(M) as follows. For each element a £ A, let p{a) = {(ti,tj) : i, j < n, t £ Tr(M), t ends at x G M, and Xij < a}. Finally, one may check that p is an embedding of 21 into %ilp(ij?Re(U), Because of Th. 491, we know that the relative representation obtained by this method has much stronger properties that those obtained by the first proof of Th. 488. For much more on nice representations, see Hirsch-Hodkinson [99, Ch. 13]. 79. Singletons and twins in a simple SA The next two theorems are closely related to Th. 402. First, Th. 402 does not hold in every SA, but one of consequences does, namely, Theorem 496 (Maddux [150, 40(i)]). LetSL G SA. Ifx" G At 21 and a; £ FnSt then x 6 At%. Note that xd is an atom by Th. 330. Suppose 0 ^ it < 1. Then w < x and wA ^ 0 since 0 ^ w = wa ;w, so wA = xA since xA is an atom. Then PROOF.
a
A
x=-x \x=-w \x = (I1 w;w);x < (w;l);l = w;l so x = x w;\ < w;(l
w;x) < w;(x;x) < w;V = w, D
Theorem 497 (Maddux [150, 40(iv)]). Let I 6 SA. If x g Pt%. and y 6 Ata, then (i) x;l;y,
y;l;x
£ AMU
{0},
(ii) y;l;x £ F n E . (iii) 7/21 is simple then x;l;y,
y;l;x
g
AtVi.
498
6. RELATION ALGEBRAS
PROOF. Note that x;l;x = x < V because a; is a point. Assume 0 ^ w < x;l;y. T h e n 0 ^ y (x;l)";w = y (l;x);w. T h i s yields y < l;x;w b e c a u s e y is an atom. Then x;l;y < a:; 1; (1; a:; w) = a;; 1;a;;w < V ;w < w. Thus x; 1;y E ,4*21 U {0}, and, similarly, y;l;x £ Af&\J {0}. Finally, (yA;xY;(y;l;x)
= x;(l;y);(y;l;x) = x \ { \ \ y \ y \ \ ) \ x <x \ \ \ x < 1',
s o y ; l ; x £ F n $ l . N o w s u p p o s e 21 i s s i m p l e . S i n c e x ^ 0 ^ y , w e g e t x ; l ; y ^ 0 ^ y;l;x by Th. 379. Hence x;l;y, y;l;x £ At%. The previous theorem still holds if we assume that a; is a singleton instead of a point. The proof is essentially the same. Theorem 498. Let 21 E SA and assume 21 is simple. = {u + v:u,v£Pt% u v = 0}. (i) IfPr&~At1,VL (ii) //Pr2ln^t 1 >2l = Pt2lUT«;2l. (iii) Ifx E Pt% andy E P i 2 t U T « ; 2 l then x;l;y, y;l;x E AM and y;l;x E FnK. holds: (iv) If x £ Pr$l then exactly one of the following statements (a) x E Pt% (b) x £ Tw'A, (c) x = u + v for some distinct u,v £ P£2L PROOF, (i): Let x £ P r 2 l ~ ,4^21. By Th. 310, x <£ At% S O I = M + I;, u v = 0, and u, v ^ 0 for some u, v E A. By Th. 310, we have u, v < V. Hence u;l;v = u;0' ;v + u;V ;v = u;0' ;v + u v = u ; 0 ' ;v a n d , s i m i l a r l y , v;l;u = « ; 0 ' ; u . We also have 1 = l ; i t ; l = l;w;l since 21 is simple, by Th. 379. Then u;l;u
=
u;(l;v;l);u
<
x;0';x;0';x
< !' Thus u ^ 0 and t i ; l ; « < 1', » M £ Pt2l. Similarly, w G Pt2l. For the opposite inclusion, suppose u, v E Pt% and u v = 0. Let x = u + v. Clearly x f. ^44^21 since u, v ^ 0. We must show x;0';a;;0';a; < 1'. By the distributivity of ; over + , x is the join of the elements ((r;0';s);0');£ where r,s,t £ {u,v}. For such an element, if r = s, then ((r;0';s);0');i = (0;0');i = 0, and if s = t, then ((r;0';s);0');i < ( l ; s ) ; 0 ' ; t = l;(s;O';t) = l ; 0 = 0, so ((a;;0';a;);0');a; = ( ( « ; 0 ' ; « ) ; 0 ' ) ; « + ((«;0';«);0');t; < ((«;1;1);1);« + ( ( « ; l ; l ) ; l ) ; t ; = «;1;« + v;l;v < V. (ii): First we show P£2l C At^Ql. Let x E Pt%. Then 1' > x 0 = x;0';a;. For every y E A, (x y); 1; (x y) = (x y); 0'; (x y) < x; 0'; x = 0, hence x y = 0 or x -y = 0, by Th. 379. Therefore x £ At^>21. If x £ Tw^H then a; is a pair disjoint from every point. In particular, x is not the join of two points, so it must be an
78, SINGLETONS AND TWINS IN A simple SA
499
atom by paxt (i). Thus TwWt. C At^%, Combining what has been proved so far with Th. 310 yields P r 21n Afy®. D PtStU TwVL For the opposite inclusion, we assume a; 6 PrStn At^f&^TwSl and show x 6 Pi%. Since x g P r 21 ~Tw 21, there is some 3/ G Ft SI such that x y / 0. Hence y < a: since PtSl C Afy SI. But (iii): We have y 6 At SI by part (ii), so the desired conclusion follows by Th. 497. We show next that Th.496, Th.497, and Th.498(ii)(iii) fail to hold in some simple finite WA. Let a = 9tlS(3)9te (3), where 5(3) = {(i, j) : i, j < 3 and \i-j\ < 1}. Then 21 is a simple finite WA by Th.368(ii). To show Th.496 fails, let x = {{1,2}, (1,0)}. Then xA = {{1,1}} £ AtSL and x;x = {{0,0}, {2, 2}} < 1', so x £ Fn% but x $ At SI. To show Th.497 and Th.498(ii)(iii) fail, let x = {(0,0}, (2,2}} and y = {(1,1)}. Then x g Pt% but a; g AtSt, so Th. 498(ii) fails. Also 1/ G A t a n P t S l but x;l;y = {{0,1}, {2,1}} ^ AtSl U {0}, so Th.497 and Th. 498(iii) fail. Theorem 499 (Maddux [150, Th.41]). Suppose % £ SA and 21 is simple. If x e 5«2l then x g At2l ond a;d,a;r g PtSt. We have xi;l;x'i < E ; E ; 1 ; ( E ; E ) < E;(X;1;S;);X < a;;l;x < 1', and a; ^ 0 since x j= 0, so xA € PtSt. Similarly, a;r € PtSt. By Th.498(iii), a;d;l;a;r 6 D AM. But 0 / x = Ed;a;;a;r < Ed;l;a;r G AtSl, so a; = a;d;l;a;r and x G At2l. PROOF.
d
Th. 499, restricted to relation algebras and without the conclusion a;d,x'' £ Pt% is related to Jonsson-Tarski [119, 4.30]. Th.499 shows that if the relation algebra SI in part (ii) of J6nsson-Tarski [119, 4.30] is simple, then 21 is also atomic, and therefore "atomistic" may be deleted from part (ii) if "simple" is added. Jonsson and Tarski knew that Th. 499 holds for RA's, but did not state it in J6nsson-Tarski [119]. It was first published in J6nsson [113, Lem. 7.3], and is generalized in Maddux [150, Th. 41] to SA's. The next theorem was proved for relation algebras by Schmidt- Strohlein [212, 7(i)] under some additional assumptions (that 21 is complete and atomic) which are included in their definition of relation algebra but are not used in their proof. Theorem 500. Suppose St g SA and 21 is simple. If0^x y;l, and i , y £ FnSl, then x\y G AtSl. PROOF.
= x;l1 0 ^ y =
Let z = x;y. We will see that Th.499 applies to z. First we have z;l;2
=
x;{y;l;y);x
= x;x a n d , similarly, z;l;z < 1'. By T h . 379, 0 ^ x;l;y x = x;l. T h u s z g AM by T h . 4 9 9 .
= x;y = z since x,y
^ 0 and
500
6. RELATION ALGEBRAS
Theorem 501. Assume 21 £ RA and 21 is simple. Ifx,y one of the following statements holds:
£ Tu>2l then exactly
(a) x;l;y 6 At%, (b) t h e r e are d i s t i n c t v , w s u c h t h a t x ; l ; y = v + w , and v , w , v , w £ A t $ l (~l Fn%. P R O O F . W e a s s u m e ( a ) is false a n d p r o v e ( b ) . T h u s w e h a v e x;l;y ^ At%. W e also k n o w t h a t x;l;y ^ 0 since x,y ^ 0 a n d 21 is s i m p l e , b y T h . 3 7 9 . H e n c e t h e r e a r e v,w £ A s u c h t h a t (6.292)
x;l;y
= v + w,
v w = 0,
u ^ O , and w ^ 0.
y;l;x
= v + w,
v w = 0,
#7^0, and w ^ 0.
This implies
Next, we show from (6.292) that v, w £ Fn21. We have 1 = 1;y; 1 since 21 is simple and y ^ 0. So s =
d a;
= 1' -x;\
Th.310
= r - ( « + u));l = 1' v;l + V = v6
(6.292) w;l
+w6,
but wd ^ 0 and u>d ^ 0 since v,w ^ 0, and a; £ ^4t2l, so x = vd = wd. In a similar way we get y = v' = w'. Hence (6.293)
v = y;v,
v = x;v;y,
x<w;w,
and w = w;y.
The statements in (6.293) were chosen just for the following derivation, which contains the only essential use in this proof of the associative law. v;v = y;v;(x;v;y)
(6.293)
< y;v;(w;w;v;y)
(6.293)
= y;v;(w;y;w;v;y)
(6.293)
= y;(v;w);y;(w;v);y
R4
W e h a v e w < v since v-w = 0, so v;w < v;v < 0 ' , a n d h e n c e iu;v < 0'. T h e r e f o r e , v;v
(4)
ye
so v £ Fn'R. By a similar proof, w £ Fn$i. We have v6 = w6 = x £ AtQl, so v, w £ Am by Th. 496. It follows similarly from (2) that v, w £ Fn% f] Am.
80. ALGEBRAS FROM MODULAR LATTICES
501
The previous theorem fails in some simple SA. In fact, for every n > 2 there is a simple pair-dense 2ln £ SA~RA with distinct x, y 6 ^4n such that Tw%n = {x,y}, 1' = x + y, and x;l;y is the join of n atoms, none of which is functional. To see this, let n > 1. Let 2ln be the SA determined by the following conditions. (a) (b) (c) (d) (e)
Af&n = {ao,ooo,ai,on} U {aoi : i < n} U {a\0 : i < n}, 1' = ao +ai, if x £ {ao,aoo,ai,an} then £ = x, if i < n then (o0i)" = alo and (a\0Y = a oi; if i,j<2,i^ j , a n d k,l < n, t h e n o,i',a,i = an ',aa = a j , aj;o« = o«;aj = an, k _ k _ k i jaij — aij jaj — aij j
a
[ a% + an [an
if k = I if k ^ I,
(f) if x,y £ At%n and x;j/ is not determined by (e), then x;y = 0. If n = 1, then the second case in the last part of (e) cannot occur, and 211 is isomorphic t o the subalgebra of 9le (4) generated by {(0,0), (2, 2)}, under the isomorphism h which behaves as follows on the atoms of 2li: ft(aoo) = {<(), 2) , ( 2 , 0 ) } , A(OI) = { < 1 ) 1 > , < 3 , 3 > } ,
h(ail)
= {(1,3), (3,1)},
A(o? 0 ) = { ( 1 , 0 ) , ( 3 , 0 ) , ( 1 , 2 ) , (3, 2 ) } . If a > 2, t h e n 2l a £ RA, since a
o l 01 i a 10 ! a 00 =
2_^
= °o +aoo-
i
L e t x = oo a n d y = a\. T h e n T w 2 l n = { x , y } , 1' = x + y , a n d x;l;y = ^2i
a'Oi,
80. Algebras from modular lattices £ = (L, +, is a modular lattice if £ is an algebra with two binary operations and + that are commutative, associative, idempotent (x + x = x = x x), and satisfy the two absorption laws x (x + y) = x and x + (x y) = x. An element 0 £ L is a minimum element if 0 a; = 0 for every x £ L. A minimum element
502
6. RELATION ALGEBRAS
can be added to any modular lattice. Choose any 0 ^ L and let 0 + x = x and 0 x = 0 for every x E LU {0}. Modular lattices arise from relation algebras. For every 21 = {A, ) 6 RA let i?(2l) be the set of equivalence elements of 21 that contain 1', that is, £(21) := {x : 1' < x;x = x £ A}. Theorem 502 (Chin-Tarski [49, p. 383] Jonsson [112, p. 463]). //21 £ RA, B C i 5 ( 2 l ) , B is closed under ; and and x ; y = y ; x for all x , y £ B , then { B , ;, ) is a modular lattice with minimum element V.
We refer to (B, ;, ) as a lattice of commuting equivalence elements. Every modular lattice arises in this way, as a sublattice of a lattice of commuting equivalence elements of some relation algebra. Theorem 503 (Maddux [141]). Let £ = (L,+, ) be a modular lattice with minimum element 0. Define a ternary relation T by T := {{x, y,z) : x,y,z £ L,x + y = x + z = y + z). Then L is the field of T, Cm (T) is a symmetric relation algebra, and is a lattice of commuting equivalence elements. Let I := {{y : x + y = x,y € L} : x € L). Then I is an embedding of £ into & that sends each element of L to the principal ideal of £ generated by that element.
81. Factor algebras This section considers a method, similar to relativization, for obtaining algebras of relational type from other such algebras. It shows up in the proof of Th. 102 and is explicitly defined (although not named) by McKenzie [165, p. 58]. Factor algebras are limited to equivalence elements of relation algebras. The factor algebra 5ae2l obtained from a relation algebra 21 and an equivalence element e £ Eq%L differs from a certain subalgebra of *H[e;i;e21 only by having a different identity element. Let 21 £ NA and e £ A. Then -FaeSI = {x : x £ A, e;x = x =
x;e}.
Notice that if a; £ Fae% then e ; x = e;(e;x;e)
= ( e ; e ) ; ( z ; e ) = e;x;e = x ,
and, similarly, x;e = x. T h e o r e m 504. Let 21 £ RA and e £ EqW. Then 0, e, e ; l ; e £ Fae% Fa,e& is closed under the operations +, ~ e ; 1 ; e ; ; ; and ".
and
P R O O F . T O establish t h e first claim, it suffices t o check t h a t e ; 0 ; e = 0, e ; e ; e = e, a n d e ; ( e ; l ; e ) ; e = e ; l ; e (this last e q u a t i o n follows from 21 6 SA). For closure, we m u s t a s s u m e e ; x ; e = x a n d e;y;e = y a n d check t h a t
e;(x + y);e = x + y,
81. FACTOR ALGEBRAS e;(x-y);e = x-y, e;(x e;l;e);e = W e;{x;y);e = x;y, e;x;e = x.
e;l;e,
For closure under complementation with respect to e;l;e, x e;l;e < = < < < < <
e;(e;(I?;e));e e;(e;(eT«Te;e));e e;(e;efa;);e e;i;e 1 e;(as e;(l;e));e e;(s; e;l;e);e e;as;e e;(e;l;e);e
rot. a; = e;a;;e Rio, mon. Rio, mon. rot. e = e,SA mon.
<e;e;a;;e;e-e;l;e
as = e;as;e,SA, e;e = e Rio, mon.
For closure under meets,
= e;(a;-e;(y;e));e = e;(x-y);e = and, by associativity, e;(x;y);e
< e;x;e
e;y;e
x-y = (e;x);(y;e)
= x;y.
D
The final computation requires associativity and the theorem fails for SA. Consider the symmetric SA presented earlier, whose cycles axe [a, a, a], [a, b, c], [6,6,6], [c,c,(f], [a,d,d], and [b,d,d]. The multiplication table for the atoms of this algebra is shown in Table 22. Let e = V +a. Then d = e;d;e so d 6 Faef&, However, d;d = 1' + a + b and e;(d;d);e = (V +a);(V
+a + b);(V +a) = V+a
+ b + c,
so d;d f FaJlL. Thus Fa e 2l is not closed under relative multiplication. In view of the previous theorem we define, for every St 6 RA and every e E Eq 21, an algebra
This always produces a relation algebra. Theorem 505. Let % £ RA and e G .Eg21. TAew gc^a G RA. For every iT C RA let (6.294)
Fa K = {3"ae E : a G RA, e G Eq21}.
504
8, RELATION ALGEBRAS
Note that 1' e .Eg21 and Sa^ a = 21, so that Faif C RA. Furthermore, if e G and e' € £g3"aea, then $ae> (3"ae21) = ffoe'2l. It follows that FaFaHf = Faif. Thus Fa is a closure operator on classes of relation algebras. Theorem 506 (Jonsson-Tarski [119, 4.27] McKenzie [165, Lem.2.7]). (i) If EQ and E\ are equivalence relations with Eo C E\, then there is an equivalence relation E2 such that #dg0 &b (Ei) = &b (E2). (ii) Fa RRA = RRA. PROOF.
For part (i), set E% = {(x/E0,y/E0) ft = ({(w/E0,y/E0)
:(x,y)eR}:Re
: {x,y) e Ei and $aBa &b ( B i ) ) .
Then h is the required isomorphism. Part (ii) follows from part (i). Define three classes of algebras as follows. I RRA := [{21: a G RRA, 21 is integral}.
GRA := S{£m(©) : © is a group}. PRA:=FaGRA. Algebras in PRA are called permutational, a name suggested by Lyndon. Note that a semiassociative relation algebra is integral iff 1' is an atom, so [RRA = l{» : a e RRA, 1' € AM}. IRRA, GRA, and PRA are universal classes, but they are not equational classes because all the algebras in them are simple. Note that GRA = SGRA C PRA = SPRA C IRRA = SI RRA. Jonsson-Tarski [119, 4.18(i), 5.10] observed that a relation algebra is integral and representable whenever it is isomorphic to a subalgebra of a complex algebra of a group, i.e., GRA C [RRA. They left open question whether, conversely, every integral representable relation algebra is isomorphic to a subalgebra of a complex algebra of a group, i.e., whether IRRA = GRA. Lyndon [135, §5] showed that the existence of a projective plane whose order was not a power of a prime would solve the problem. McKenzie solved it by another method; see below. Jonsson and Tarski also asked whether there were any integral nonrepresentable relation algebras. J6nsson [112] found such an algebra. Theorem 507 (McKenzie [165, Th.4.4], [166, §2]). GRA C PRA. PROOF. $aH£m(G) € PRA~GRA when G is the group of permutations of the non-negative integers, and H is the subgroup of G consisting of those permutations that leave every even number fixed. Define a permutation <x using group-theoretic cycle notation by
,8,6,4,2,0,l,3,5,7,9,---) and let x = H;{a};H. Then x;x~x D H and a;"1 ;x = H, but if f aHCm (G) were D in GRA, then it would satisfy Va!(a;;a;":L D H <=> a;"1 ;x = H). Thus GRA is not closed under Fa. McKenzie also found infinitely many algebras in PRA ~ GRA with the properly that any nonprincipal ultraproduct of these algebras is in GRA (McKenzie [166, 3.1]), so
81. FACTOR ALGEBRAS
808
T h e o r e m 508 (McKenzie [185], [IBB, 3.2]). GRA is not finitely axiomatizable relative to any elementary class containing PRA. GRA is therefore not finitely axiomatizable relative to IRRA or RRA. "n.f.b." means "not finitely based", and "f.b." means "finitely based: GRA n c b PRA = Fa GRA " c ^ IRRA = Fa IRRA f C RRA = Fa RRA. Denote the alternating and symmetric groups by A» and S». McKenzie also proved
Theorem 509 (McKenzie [165, p.82]). (ii) (iii) (iv) (v)
(i) daksks $ GRA,
GRA, and Stiff As G GRA for all other subgroups H C Ag. If n > 4 and m > 3, then 3 r a in An+2 = 3raSm S r o + 2 = ffa^ ABIf p is a prime not of the form 2k — 1, then S'as _ 1 S2 P -i ^ GRA. If n > 2, and 2n + 1 is not a prime power, then 3'0s 2n _ 1 Ss B -i ^ GRA. ^a Ag As has 8 atoms and a 7-atom sitbalgebra that is not in GRA.
McKenzie asked whether PRA = IRRA. The answer was shown to be "no" by Andreka-Duntsch-Nemeti [8]. Theorem 510 (Andreka-Duntsch-Nemeti [8]). PRA C IRRA. PROOF. Recall that 9 = {0,1,2,3,4,5,6,7,8} and 5 = {0,1,2,3,4}. Define permutations of 9 as follows (using group-theoretic cycle notation);
S:= (0,1,2X3,4,5X6,7,8), G:= (0,3,6)(l, 4,7)(2,5,8), ff:=(0,4,8)(l,5,6)(2,3,7), if:=(0,5,7)(l,3,8)(2,4,6). Note that {S, G, H, K, S~\ G"1, -ff"1, K~\ 91} is a partition of 92 = 9 x 9. Use these permutations to define four binary relations on 5 x 9 as follows: * : = { « U ) . < < . S y ) » : i e 5 , JG9}, ff :={((*, i),
{i +B 1, k)):ie 5, (j, k) G Rm}, (i + s 2, k)) : i G 5, (j, k) £ Bm}.
+B
6. RELATION ALGEBRAS
s 9
h k s 9
s s
9
h k
9
9
V k
h k h k V
h k k h
k
s
9
h
9
h
V k
k V
9 s
9
9
9 9 s
k h
h
s s
s
h
h k
9
V
s s
s
V
k h
h k
9
h
s s
ro
ro
ri
ri
ri
r2 6o
r2
r2 ro
9 ri ri ro r2 r2 r2 ri ro ro ro r2 ri
61
61
62
62 60
62 60
60 61
6i 62
60 61 62
k h
ro
ri
ri
r2
ro
ri
V
s s
ri
s
V
k k h
r2 ro ro
h 9
r2 r2 ro r2
9
k
ri
T2
T2
ro
ro
ri
ri
62
62
61
60 61
60 61
62 60 fi
r2 ro r2 ri ri ro fi ro fi ro r2 r2 ri r2 r2 fi r2 ri ro ro r2 ro ro
60 61
62
6"i
60
62
60 61
62
&i
60
62
TABLE
62
61 62
62 60
60
60 61
60
6l
62
b\
9
r2 ro r2 ro ri ri
ri
r2 ri
6
ro r2 6
6 6
6 6
6 6
60 61
6
6
6
6
6
6
62
6
6
r2 ro
6 ssV ghk
62 60
f f
ro 6
ghk ghk
ghk fi ghk ghk ssV f f b\ f ssV
f f
f f
51. A nonpermutational algebra, first part
Let 6 := 60 U 61 U 62 and r := ro U ri U r2. To keep notation compact, we write, for example, 6 instead of 6" 1 . Then {s, g, h, k, s, g, h, k, r0, n, r2,60,61,62, r 0 , ri, r2,60,61,62} is a subalgebra of *He (5 x 9). Tables 51 and 52 show the relative products of atoms in this subalgebra. This algebra is integral and representable, but not permutational. Once again, a single example can be expanded to infinitely many, resulting in another nonfinite axiomatizability result. The next theorem is proved by the construction of an algebra in PRA that is an ultraproduct of algebras in IRRA ~ PRA. Theorem 511 (Andreka-Diintsch-Nemeti [8]). PRA is not finitely axiomatizable relative to IRRA.
82. A characterization of representability Let 21 = {(^4,...) be a nontrivial algebra of relational type, and suppose that F
if (i, j , a) € L t h e n (i, j , a + b) € L a n d (i, j , b + a) € L,
62. A CHARACTERIZATION OP REPRESENTABILITY
h
61
62
*
61
62
60
fa
g
&2
60
61
h k
60
61
&1
62
62 &o
s g
&2
60
61
&1
60
&2 &1
ri
ro
6 & 6 r r
62 bx bo b b b
60
h k
ri ri ri f0 ri ri
5
n ri
b0
h
&2
ro ri ri
bo b\ b\
T
ra
h
61
62
ri
62
60
61
To To
n
62
bo
ri
b\
&i
62
60
To
n
&2
ri
60 bi
61
T\
60
ri
To
61
T2
TO
b2 &o r
b\ b\ bo
shk
ra shk shk ggV
r
r
T
T
Shk shk shk r r
gW
w
he
«2
r
6 & 6 r r
r\ ri
1
r r r kkV sgh sgh
r
r r ftrjfel' sgh
r r r
b b b b b b
b b b b b b
b b b b b b
6O
r
b\ b2 r
r
r
r
r hhV sgk sgk b b b
r sgk hhV sgk b b b
r sgk sgk
r
T
61
hhV
1 hi hi.
b b b T
r
r
r
r
r
T
TABLE 52. A nonpermutational algebra, second part
(6.296)
{i,j,a)eLiff{i,j,a)$L,
(6.297)
if (i,k,a) e L and (k,j,b) £ L then (i,j,a;b) e L,
(6.298) (6.299)
(i,j,a)eLiS(j,i,a)eL. if * € Fd (Do (L)) then (*, *, 1'} € L.
An F-labelling L is said to be finitary if Do(L) is a finite relation. For each n € w, an .F-labelling L is said to be n-ary if Do (L) C n 2 . An .F-labelling L is complete if, for all a, & G F, - if (i,j,a + b) 6 L then (i,j,a) e L or (i,j,b) e L, - if (i, j,a;b) £ L then for some fe£w, we have {i, k,a) £ L and {k, j , b) G L. Here are some elementary observations. Suppose L is an F-labelling in 21. It is possible that L = 0 because the hypotheses of (6.295)-(6.299) fail when L = 0, so (6.295)-(6.299) hold for L, Suppose L is not empty, that there are i, j 6 w and a €. F such that (i,j, a) € Uo (L). Assume that 1 € .F, 1 = 0, and a + 1 = 1 for every a £ A. By (6.295) we get (i,j, a + 1) £ L, so (i,j, 1) £ L since a + 1 = 1, hence (i, j , 0} ^ £ by (6.296) and T = 0.
SOS
8, RELATION A L G E B R A S
Let OF (31) be the set of F-labellings in SI. $ is an F-labelling system in Si if # C Hi? (21) and # has the following properties: (i) Every L € # is finitary. (ii) If 0 / w E F, then there is some Io £ f such that (0, l,w) € Lo and Do (Lo) = {{0,0}, {0,1}, (1,0), {1,1}}. (iii) If a, h g F and («, j , a + & } g l € $ , then there is some M 6 # such that L C M and either {«, j , a} G M or {«, j , 6} E M. (iv) If a,6 E F, (i,j,a\b) £ L E #, and k £ Fd(Do(L)), then there is some M 6 $ such that L C M, (i, k, a) e M, and {fc, j , b) 6 M. Suppose that # is a {w}-labelling system in 21. By (ii), there is some Lo with (0,1,w) E Lo. By (6.295), (0,1,w + w) E L o . By (6.298), (1,0,w) E L o , so Fd(Do(L0)) 2 {0,1}. Then, by (6.299), we also have (0,0,1'} 6 Lo and (1,1, V) 6 Lo. Nothing more can be deduced, for if w ^ w ^ 1! and 21 € NA, then it is possible that Although {0, l,w) , (1,0, w) E Lo, one cannot conclude that {0,1, w\w) E Lo from (6.297), because w <£ {w}. Every representation gives rise to labelling systems in a natural way. Suppose that p is a representation of SI over E. Let # be the set of relations L C w2 x A having the property that there is a function TT : n —> Fd(E), where 0 < n G w, such that -E takes values in a single equivalence class of E, that is, nxn = TTIEITT^1, and L is determined by w as a snapshot, so to speak, of the representation p, that is, L = {{i,j,a) : a E A, i,j E n, {m,^} £/?(«)} Then $ is an A-labelling system in SI. Let L = {{i,j,R) : i,j eu,RC
w2, (i,j) e R} = En (w2 x Sb (w2)).
Then L is a Sb (w2)-labelling in 9te (w), L is not finitary, and L is complete for Sb (w2). Let # L be the set of subrelations of L that are Sb (w2)-labellings in 9\t(w). Then #£ is a finitary Sb (w2)-labelling system in 9te(w). Theorem 512. If SI E RRA t/sen tfeere is an A-labelling system in St. The next two theorems form a partial converse to Th. 512. Under mild additional assumptions, a nontrivial algebra of relational type that has a system of .F-labellings for each finite subset F is, in fact, a representable relation algebra. In the proof of this fact, labellings get extended and partial representations are combined via ultrafilters. Variations on the method of extending a labelling (until it is, say, complete for a specified countable subset) were derived from similar procedures in Lyndon [133] and Jonsson [112] and applied in Maddux [139]. One such application in Maddux [139, 138], namely, the proof that tabular relation algebras are representable, also combines partial representations via ultrafilters. The definition of .F-labelling has been weakened from Maddux [138] by relativizing all, not just some, of the conditions to the finite subset F. This provides a convenient sufficient condition for representability that is applicable to algebras
82. A CHARACTERIZATION OF REPRESBNTABILITY
B09
constructed by Hirsch-Hodkinson [98]. The notion of labelling system corresponds to the model-theoretic notion of consistency family (Monk [184]), and what corresponds to the following theorem is the Model Existence Theorem (Monk [184, 18.9]). Theorem 513. Suppose 21 is an algebra of relational type in which V = V, V ;a = a = a;V for all a £ A, and for every finite F C A there is an F-labelling system,. If 0 ^ w £ A then there is a homomorphism h from 21 into a proper relation algebra such that h(w) ^ 0. PROOF.
Let T be the set of finite subsets of A that contain w and 1': T :={F : V,w£FCA,\F\
Let F E T. By hypothesis there is some $ F C i\p{ty) such that $ F is an Flabelling system. Next we show the existence of a F-labelling in 21 that contains (0,1, w) and is complete. Let r : w —> LO2 x F2 be an enumeration of UJ2 x F2 in which every pair appears infinitely many times. Define a sequence of F-labellings Lo, , Ln, L n +i, £ $ F as follows. By (ii), there is some LQ £ $ F such that (0,1, w) £ Lo and Do (Lo) = 2 x 2 . Assume L\, ,Ln £ <3>F have been defined, C Ln, and Do(Ln) = m x m for some 2 < m E u. Suppose that Lo C T n = {i,j, (a,b)), where i,j £ u; and a,b £ F. The plan is to first extend Ln to L' in a way that accounts for the possibility that {i,j,a + b) £ Ln and does not change the domain, and then extend again, from L' to Ln+i, this time handling the possibility that (i,j,a;b) £ L'. This latter step may enlarge the domain. If {i,j, a + b) $: Ln, then set L' = L. Assume otherwise, namely, (i,j, a + b) 6 Ln. By (iii) there is some L' E $ F such that L' D Ln and either (i,j,a) E L' or (i,j,b) £ L ' . N e x t , if (i,j,a;b) $. L ' l e t L n + 1 = L ' . If (i,j,a;b) £ L ' ,t h e n b y (iv) there is some M E $ F such that M D L', (i,m,a) E M, and {m,j,b} E M. Set Ln+i = M and note the Do {Ln+i) = ('in + I) 2 . This completes the construction of the sequence Lo, Li, L2, £ $ F - Set
LF := ( J Ln. Thus, for each F E J-, LF is an F-labelling in 21 that contains (0,1, w) and is complete, as is easily checked. Note that the domain of each LF is u;2 because of the infinitely many occurrences of (0,1, (w, 1')) in T. SO, for all a,b £ F and all i,j,k E UJ, (6.300)
{0,l,w)ELF,
(6.301) if (i,j,a) (6.302) if (i,j,a (6.303)
(i,j,a)£LF
(6.305) if (i,j,a;b) (6.307)
F
t h e n (i,j,a
+ b) E L
(6.304) if (i,k,a) (6.306)
£L
iff £L
F
EL
(i,j,a)ELF {i,i,V)£LF.
F
+ b) £ L
t h e n (i,j,a) (i,j,a)
a n d (k,j,b)
EL
F
a n d (i,j,b
+ a) £ L
F
o r (i,j,b)
E L
F
,
£L
F
,
(j,i,a)
,
<£ LF, £L
F
t h e n (i,k,a;b)
F t h e n for s o m e k E UJ, (i,k,a)
iff
F
E L
F
,
EL
F a n d (k,j,b)
E L
F
,
510
8, RELATION ALGEBRAS
For each F £ T let I(F) = {Y : F C Y £ F}. If p,g : T -> w and a G A, let J{p,q,a) = {F : F 6 J7, (pPjqF,a} 6 L F } . Therefore, (6.308)
F G J(p, q,a) <& (pF,qF,a) e LF.
Properties (6.300)-(6.307) above are listed in approximately the order in which they are needed to prove the following properties of J for all p, q : T —> u and a,be A, (6.309)
J{T x {0}, T x {1}, w) = T,
(6.310)
J(p,q,a + b)n I({a,b}) = (J(p,q,a) U J(p,q, b)) n I({a,b}),
(6.311)
J{p,q,a) n I({a}) = ( F ~ J(p,g,a)) n I({a}),
(6.312)
J(p, g, a; 6) n J({a, b}) = J(p, r, a) n J(r, g, 6) fll({o, 6}), for some r : IF —¥ u,
(6.313)
J(p, q, a) n I({a}) = J(g,p, a) n I({a}),
(6.314)
J(p,g, 1!) D {F : F g F , pP = qF}.
Proof of (6.309): If F € J 7 then {0,1, w) e LP by (6.295), so F g J(.F x {0}, J 7 x {l},w) by (6.308). Proof of (6.310): Suppose F g J(p,q,a + b) n /({a,6}). Then F 6 J(p,q,a + b) and F 6 J({o,6}), so (pF,gF,a + 6) € 2/j? and {a,6} C F, so, by (6.302), (pF,gF,a) G L F or {pF,qF,b) G L F , hence F G J(p,q,a) or F G J(p,q,b), so F g J(p,g,a) U J(p,q,b). The inclusion in (6.310) from right to left follows similarly from (6.301). Proof of (6.311): The following statements are equivalent: F€
J(p,q,a)nl({a})
(PF,qF,a) G LF, a £ F {PF,qF,a) $ LF, a £ F
Proof of (6.312): The inclusion from right to left is a consequence of (6.304). For the other direction, first construct r from p, g, a, and b as follows. For every F G J-, if F ^ J(p,q,a;b) D /({a,&}) then TF may be any element of w. In the other case, where F G J(p,q,a;b) n /({a,&}), we have F G J(p,q,a;b) and F 6 /({a,6}), hence (pFigFja^) 6 LF and {a,6} C F , hence, by (6.305), there is some k G w such that (pF,fe,a) G L F and (k,qF,b) G Lj?. Let rF be any such fc. If we write rF in place of k, we get (pF,rF,a,) £ LF and {rF,qF,b) G Zip1, hence F g J(p, r,a) and F g J(r, q, b), so F is in the set on the right hand side of (6.303). Let W be an ultrafilter of T that contains {I{F) : F G J-}. Define a function g-.A^Sb (fuf) by (6.315)
g(a) := {(p, g) : p, q G ^w, J(p, q, a) G W},
82. A CHARACTERIZATION OF REPRESBNTABILITY
511
for every a G A, so (6.316)
(p, q) € g(a)
J(p, q, a) € U.
Note that g may not be a homomorphism from 21 into 56 (fw) 2 ) because it may happen that g(V) # (^w)1. However, for all a, 6 € A we can prove that (6.317)
0/aH,
(6.318)
g(
(6.319)
S(
(6.320)
S(
(6.321)
S (a) =
(6.322)
S (l')
( S (a))-\
D fa;) 1 .
Proof of (6.317): It follows from (6.309) and (6.315) that {T x {0},.F x {1}) <E g{w)Proof of (6.319): From right to left, we proceed as follows.
hyp. (6.316)
J(p,q,a) $U F~J(p,q,a)£U, I({a}) G U
U is an ultrafilter on T def. of W
) eu J(p,q,a)ni({a}) eU J(p,q,a) eU (p,q)£g(a)
U is a filter (6.311) U is a filter (6.316)
Proof of (6.320): For one direction,
(p,q) £g(a;b) J(p,q,a;b) G U I({a,b})£U J(p,q,a;b) n/({a,6}) G U
hyp(6.316) def. of U U is a filter
J(p, r, a) n J(r, q, b) n /({a, 6}) G I for some r G w J(p, r, a) e It, J{r, q,b) eU
W is a filter
(p,r) G g(a), (r,q) G g(b)
(6.316)
(6.312)
Next, let E := g(V) and let h := ({{r/E, s/E) : r, s G ^w, J(r, s, a) G W} : a G Then, by Th. 102, h is a homomorphism from 21 into 6b (^w/E) with the property that ft(w)#0 by (6.317).
512
6. RELATION ALGEBRAS
Theorem 514. Suppose 21 = {A, +,~, ;, ", 1') is an algebra of relational type such that (6.323) (6.324)
f=l', V ;a = a = a;V for all a £ A ,
(6.325)
o + fo + o + 6 = 0 <=> a = b, for all a, 6 £ A,
(6.326)
for every finite F C i there is an F-labelling system.
Then 21 £ RRA. PROOF. For every nonzero w E A there is, by Th. 513, an equivalence relation Ew and a homomorphism hw from 21 into Sb (Em) such that hm(w) ^ 0. Arrange this choice so that the fields of the equivalence relations Ei are disjoint. Let
h:=(
(J hw(a) : a £ A} .
By Th. 104, h is a homomorphism from 21 into 56 (Uo^meA Ew J By hypothesis (6.325), h is injective and h is therefore a representation of 21 over Uo^™eA ^TO> so 21 € RRA.
83. Complete representability A Boolean homomorphism cr : 03 —^ 53' is complete iff it preserves all existing meets and joins, that is, if M C B, ra £ B, and ra is the least upper bound of M in 03, then a (m) is the least upper bound in 53' of the
83. COMPLETE REPRESBNTABILITY
fix) = z h(x). Then z £ Eq*>B, IKl^QS is a complete atomic RA, and f is a complete embedding o/2t into OTZ23. PROOF.
First we have
=£
{(h(y)Y : y £ AtVi} {h{y)
" is completely additive
y £ AfSL}
h is a h o m o m o r p h i s m
so z = I < z , a n d hence z = z. To show z\z < z, a s s u m e z\z > « £ AiQS. B y t h e definition of z a n d t h e c o m p l e t e a d d i t i v i t y of ;, we have Z]z
= ^2{h(x);h(y) x;y)
: x,y G : x,y € At%}.
Hence t h e r e a r e x, y £ At%l such t h a t u < h(x;y). B y t h e a s s u m p t i o n s concerning 21, t h e r e a r e finitely m a n y a t o m s vo, , vn-i such t h a t x;y = vo + vn-\, so
u < h(vo +
+ Vn-i) = h(vo) +
+ h(vn-i).
Hence, for some m < n, u < h(vm) and vm 6 At%, i.e., u < z. Thus z\z < z. From this and z = z we get z 6 Eq%5, and hence £R[ZQ3 e RA. To show / is a homomorphism we must show, for all x, y £ A:
(1) f(x + y) = f(x) + f(y), (2) f{x y) = f{x)
fiy),
(3) f{x) = ifix)Y\ (4) /(0) = 0 and /(I) = z, (5) fix;y) = fix);'fiy), (6) fix) = ifix))"\ (7) fiV) = V*. Now (l)-(4) and (7) follow by Boolean algebra from the fact that ft is a homomorphism. For (6) we have fix) = z h(x) = z z
= z iz
ft(x)
hix)Y
For the proof of (5), first note that = < z;z
iz-hix));iz hix);hiy)
6. RELATION ALGEBRAS
< z- h{x;y) For the opposite inclusion, we begin by assuming f(x;y) u < f(x;y) u < h(w).
> u E At%5. Then
= z h(x;y) < z = ^2h*(At$l), so t h e r e is some w E Af2[ such t h a t Therefore, 0 ^ u < h(w) h(x;y) = h(w x;y), so 0 ^ to x;y a n d
w < x;y. By the complete additivity of ; we have x-,y
=^ 2 {i;
so t h e r e m u s t be q, r E At%
r
x > qe A t %y > r e
such t h a t w < q;r
Am},
< x;y,
q < x, a n d r < y.
Therefore h{q) < z h(x) = f(x) and h(r) < z h(y) = f(y), s o i i < h(w) < h(q;r) = h(q);h(r) < f(x);f(y). Thus any atom of 23 below f(x;y) is also below
f(x);f(y), hence f(x;y) < f(x);f(y). This completes the proof of (l)-(7). If x G AtQl, then h(x) ^ 0 since h is injective, and h(x) < z by the definition of z, so f(x) = z h(x) = h(x) ^ 0. Thus / is injective. To show / is complete, assume X CAandw = Y,mX exists. We must show ^ f(x) = / H - Suppose f(x) is an arbitrary element of f*(X), with x £ X. Then x < w and f(x) < f(w) since / is a homomorphism. Thus ^D*8 f*(X) < f(w). For the opposite inclusion, assume f(w) > u G At^B. Then u < f(w) < z, so there is some y € AtQl such that u < h(y). Then 0 ^ h{y) f(w) < h(y) h(w) = h(y w) = hiYf'iy x : x € X}), so 0 7^ 12 {y x : x E X}. Since y E AtSi,, there must be some x E X such that y < x. Hence u < h(y) < h(x), and we have u < z, so u < f(x) and x E X, i.e., u < E * f*(X). Thus f(w) < E® f*(X), which finishes the proof that / is complete. Not every representable relation algebra is completely representable. The first example of an infinite representable relation algebra which is not completely representable is due to Lyndon [133]. Other examples of such algebras are in Maddux [139]. These examples are presented in the next section. The problem thus arises of finding partial criteria under which representability implies complete representability. The following theorem gives one such criterion. Theorem 516 (Maddux [150, 33]). Assume 21 E RA, 21 is atomic, and {w : x;y > w E At^i} is finite for all x,y completely representable.
E At%.
Then 21 is representable
iff % is
PROOF. Let fcbea representation of 21 over the equivalence relation E. Note that &b (E) is a complete atomic RA and h is an embedding of 21 into &b (E). By Th. 515 there is a complete isomorphism / mapping 21 into d\\z&b (E), where z = J2Sb(E)h*(At%) = \Jh*(At%) € Eq&b (E), but <mzSb (E) = Sb (z), so / is a complete representation of 21 over z.
An obvious corollary: Theorem 517. A finite relation algebra is representable iff it is completely representable.
84. RRAS WITH NO COMPLETE REPRESENTATIONS
518
84. RRAs with no complete representations The first example of a (necessarily infinite) representable relation algebra that is not completely representable appears in Lyndon [133]. Lyndon [133] presents two atomic RA's, M and M', and proves that they have the same (up to isomorphism) finitely generated subalgebras. He proves that M is representable, so it follows that M' is also representable because RRA is an equational class. Lyndon also shows that M' fails to satisfy a condition called C4, which states that if aioi i £02, £21, £03, £31 6 At SI and a;oi < a;oa; £21 xoa', £31, then there is some 3523 £ At 21 such that £23 < (astw^asos £21; (£31)" and for all 124,143 £ At21, if 3:23 < S24;s43, then a;oi < (EO2;S;24 xQ3;(x4sT);((x24y;x2i £43;»S3i). Condition C4 is a consequence of (L), so if St has a 5-dimensional relational basis then SI satisfies condition C4; see Th. 341. Thus Lyndon's M' has no 5-dimensional relational basis, and yet it is in RAg because it is representable. By Th. 339, if St € RA4 and St is atomic, then 21 has a 4-dimensional relational basis, but Lyndon's example shows that this cannot be generalized by replacing "4" with "5". Now we describe Lyndon's M, Let £ be an irrational number in the interval (0,1) and let
For all * € {1,
,5} and all p € Q U {£}, the following are atoms of M: jf
'
'
m[3
m'22 fn'is
'
*f
m'u
ro2f
JTlf
JTI43 "*51
"*52
TO
53
JTI44 TO
54
mfg TO41 JTI42 m
M
m^
m%
TR43 TO44 TO45 m'53 m'54 m'55
The converse of any of these atoms is obtained by reversing the subscripts. The identity element of M is 1' = mil + ??J22 + mss + m.44 + mssThen M := Ctn(T) where T be the ternary relation on the atoms that does not contain any of the following forbidden cycles: [mu,nj,8ij]
[mi2, m%g, mft] [mfJ, mfjj, mf|]
ry ^ 8ij
ft,
& £ {3,4}, p / f, p< / p, = ps, / C, i, i, * £ {1,2,3}
Another way to state the limiting condition in the third line is that exactly two of the superscripts are equal but differ from £. Theorem 518 (Lyndon [133, p. 718]). M £ RRA.
516
6. RELATION ALGEBRAS
Let T' be the ternary relation obtained restricting the range of the superscripts in the description of T to the interval (0,1), i.e., the irrational £ is excluded, and let M' := Cm(T'). Then M' fails to satisfy Lyndon's condition C5 (Lyndon [133, p. 723]), and therefore, although M' is complete and atomic, it has no 5-dimensional relational basis. T h e o r e m 519 (Lyndon [133, p. 726]). Every finitely generated subalgebra of M' is isomorphic to a finitely generated subalgebra of M. It follows from the last theorem that every finitely generated subalgebra of M' is in RRA because it is a subalgebra of the representable relation algebra M. Since RRA is a variety, this implies that M' £ RRA. Many more examples of algebras in RRA that have no complete representations can be constructed. What we show next is that if 5 < q < u then there is an atomic 21 £ RRA which has a (q — l)-dimensional relational basis but no q-dimensional relational basis. Theorem 520 (Maddux [139, p. 154ff]). Let5
I = {e'iti
i < q},
D' = {dkj :i,j,k
=3,r
We assume that if any two atoms of 23 have subscripts which differ in any way. then they are distinct. Thus At93 is partitioned into four disjoint sets / , / ' , D, and D'. Let d{'J £ D. Then i is the initial index of d{ 'J, j is the final index, k is the middle index, and r is the rank of d{ 'J. The same applies to dhj £ D', except that dkj has no rank. The initial and final indices of e^i and e\ti are i, and e*,* and e'iti have no middle index or rank. If i,j < q and i ^ j , then D{j
= {d{'j
: r < to, i,jj^k< k
q}, a n d D\j k
are distinct, then D j = {d j
= {dkj
: i, j ^ k < q}. If i,j, k < q
: r < to}. The conversion of atoms is denned as
follows: u = u for all u E I L) I', (dk'rY \
= dk'r for all dk'r E D, and (dk A" = dk f
J
for all djti E D'. T is of the union of the following cycles: p.
(-f>\
[I
I
I
[" I
[di 'Jyd]1^
(C) (D)
]
s
k r rl '
/7^'5l
f '
rik'r
rf
1
[ '
.
rl
k
rlk
rl^ 1
d™'k], where I ^ k a n d r > s,t,
[di,jid™l, , d'l'l\, [dij,dj^ie,d1''l],
[di:j, d™k, d"j,], where / ^ k,
8B. POINT-DENSITY AND PAIR-DENSITY
B17
Finally, let 21 = Sg (<8) (At*B). Note that 21 is a countable atomic subalgebra of 23, but 25 itself is uncountable. A few remarks may help clarify the definition of T. Every cycle in T has matching indices, that is, the initial index of the first and third atoms are the same, the final index of the first atom is also the initial index of the second atom, and the second and third atoms have the same final index. If any pair of indices coincide then the corresponding atom is in / U /', e.g., if i = j then aij = e,,j or aij = e'iti. If i = j and Oy = e;,j then ajk = Oik, but if ajk ^ aik
then a^ = ej^. If i,j, k are distinct, then we have two cases: all three atoms have ranks (are in D), or one of the atoms has no rank (is in D'). In the first case, the atom with the largest rank must have a middle index which is distinct from the 'opposing index', for example, if ajk = dj'Tk has rank larger than a^ and ajk, then I ^ i. In the second case, one of the atoms with no rank must have a middle index distinct from the opposing index. For example, if (d'lj, d™^, d™'f.\ E T then either i ^ k, m ^ i, of n ^ j . These algebras are described and many of their properties are proved in detail in Hirsch-Hodkinson [99, §14.4] 85. Point-density and pair-density Let 21 6 NA. We say that 21 is point-dense if ^ P £ 2 t = 1' and that 21 is pair-dense if J^ Pr 21 = 1 ' . It is easy to show (as in the proof of Th. 525 below) that 21 £ NA is point-dense (or pair-dense) just in case every nonzero identity element contains a point (or pair), i.e., the points (or pairs) are dense below 1'. That is why 'dense' is used in this definition. Theorem 521 (Maddux [150, 45]). Every point-dense NA is also pair-dense. PROOF. This follows immediately from Th. 310. Theorem 522 (Maddux [150, 46]). Every point-dense SA is an RA. PROOF. Assume 21 £ SA and 21 is point-dense. We prove only one inclusion in the associative law. Given x, y,z E A, let w = x;(y;z) (x\y)\z. Then
b u t , for every v E Pt%,
v;l;v
w;v = (x;(y;z)
= v < V, so (x;y);z);v
= x;(y;z);v
(x;y);z;v
v < V
= x; (y; z); v
(x; y); z; (v; 1; v)
v = v; 1; v
x;{y;z);v
v;l;v
= x;{y;z);v = x;(y;z);v = (x;(y;z) =
0;v
= 0,
so w = 0, hence ( x ; y ) ; z < x ; ( y ; z ) .
= v v < V
518
6. RELATION ALGEBRAS
If n > 2, then the algebra 2ln constructed after Th. 501 is a pair-dense SA that is not a relation algebra. Next we give a two examples of properties that imply point-density. Theorem 523 (Maddux [145, Th. 5]). 7/21 € SA and (6.327) then 21 is
Vx3y(y;0';y
= 0 Al ; x ; l=
l;x;y;l,
point-dense.
Theorem 524 (Maddux [145, Th. 10], [152, Th. C]). Let St € SA and assume there is some w £ A such that w + w = 0' and
Then w;w < w, w w = 0, and 21 is point-dense. If 21 C 9te(L0 and w C U2, then the hypotheses of Th. 524 say that w is a relation such that any two distinct things in U are related by either w or its converse, and for every relation R
86. Simple pair-dense algebras Theorem 525 (Maddux [150, 47]). Suppose 21 € SA and 21 is simple. (i) 7/21 is point-dense, then At^Q = Pt%. (ii) 7/21 is pair-dense, then At1i%. = Pt% U Tw2l. PROOF. Proof of (i): By Th.498(ii), Pt2l C AfySl. To prove the opposite inclusion, suppose x E At^WL. Then 0 ^ x = x-V = x - ^ P £ 2 l = ^2vept<%x'v, s o there is some v £ P£2l such that 0 ^ v x. But x £ At^H and v £ At$l, so x = v £ P£2l. Proof of (ii): By Th. 498(ii), we need only show At^VL C Pr2l. Let x £ ,4^21. By pair-density, 0 ^ x = ^2vepr
;v;ff
;v < V, so x £ P r 21.
Theorem 526 (Maddux [150, 48]). (i) Every simple pair-dense relation algebra is atomic. (ii) Every simple point-dense semiassociative relation algebra is atomic. PROOF. Assume 21 is a simple pair-dense RA. We will show that every nonzero element of 21 contains an atom. Accordingly, assume 0 ^ x € A. Then x d ^ 0 since x = xd;x. By pair-density, there is some y £ Pr% such that y < x d . Then y = y xA = y;xA < y;x;l, so y;x ^ 0, which implies (y;x)' ^ 0. By a similar argument, there is some z E Pr21 such that z < (y;x)' and y;x;z ^ 0. By Th. 498(i)(ii), y is either a point, a twin, or the join of two points, and the same is true of z. For each of the resulting nine cases we will show that y; 1; z is either an atom, the join of two atoms, or the join of four atoms.
88, SIMPLE PAIR-DENSE ALGEBRAS
519
If y,z £ Tw% then y;l;z is an atom or the join of two functional atoms by Th.501(i). Suppose y 6 PtX. U Tw5i. If z 6 Pt% then y;l;z 6 At% n Fn% by Th. 498(iii). If z is the join of two points u andi), then y;l;z = y;l;u-\-y\l;v, and y;l;M, y;l;w 6 AtSl n -FnSt by Th. 498(iii), so y;l;z is the join of two functional atoms. Similarly, y;l;z is an atom (whose converse is functional) or the join of two atoms (whose converses are functional) if z £ PtSl U Tw% and y € PtSL or y is the join of two points. Finally, if both y and z are joins of two points, then y; 1; z is the join of four functional atoms by Th. 498(iii). We have 0 ^ y,x;z < y;l;z, and y;l;z is join of finitely many atoms, so y;x;z must contain one of those atoms. But y;x;z < x, so a; also contains an atom. Now we turn to a key result which says, in effect, that every partial representation of a simple pair-dense RA can be extended wherever necessary. Theorem 527 (Maddux [150, 50]). Let 21 be a simple pair-dense relation algebra. Then BwSl is an w-dimensional relational basis for 21. PROOF. We only show the extension condition (6.97) holds. Assume m £ Bw2l, K, A, n < w, fj, ^ K, A, x, y € i4i2t, and m^x < a?;tf- We begin by defining m' for almost all arguments; the exceptions are ro^M and mtM with v £u~{K,A,/*}. (6.328)
m'^ = a;r = / ,
(6.329)
m'K/1 = T,
(6.330)
m'wj = mwj
m^re = x, if
m^A = j / ,
m^ = y
i/,^6u ~{^}.
By Th. 330, the second equation in (6.328) holds, and all the elements of A appearing in (6.328)-(6.330) are atoms. Two of the desired properties of mf are guaranteed by (6.329), namely m'Kll = x and m'^ = y, and, by (6.330), ro and mf will agree up to n, no matter how the definition of m' is completed. What remains is to define m'^ and m'uti for all v £ w ~ { K , A, fj,}, and show that mf £ Bw2l. Let AQ = {K, A, fj,}. For every n < w, let A B +i = A» U {y}, where v is the least element of w ~ A B , and let £„ = ({p} x An) U (A n x {p}) U (w Clearly £» is symmetric and reflexive, i.e., if (i/, f) € S» then (y, y ) , (f, i/}, (^, £} 6 E», and w x w = Ungw S » - Conditions (6.328)-(6.330) define m'vi whenever (v, f) G So- It is easy to show that the following three conditions hold for n = 0: (6.331)
mvv < 1'
whenever
jc^JES,,
(6.332)
(m'tf€)" = ??4,
whenever
(i/,()£SB,
(6.333)
mv% < m'vp; m'pi
whenever
(v, f ) , (v, p), {/?, f) £ S B .
Suppose, given some fixed n < u, that m ^ and m'vli have been defined for every v £ An in such a way that (6.331)-(6.333) hold. We will choose m'^p and m'p^, where {{3} = A^+i ~ An, and prove that (6.331)-(6.333) still hold if n is replaced
520
6. RELATION ALGEBRAS
by n + 1 . There are four cases, in three of which the definitions of m ^ and mp^ are forced, while in the fourth case m'^p may be either one of two functional atoms. For the first case, assume there is some v G A n ~{/i} such that m'vp G Fn%. Then, by (6.333), 0 # m'vv < mvp\mpv
m^-.m'^
< m'vp ; 1 m'vlib; 1.
Using the cycle law and (6.332), we get 0 / " V ; {m'vl3; 1) = ( m ^ \m'vp)\ 1. Consequently 0 / m'^,,; m'^. O / m ' ^ m ' ^ s o , by Th.402,
Thus we have m'^
(6.334)
m'^;m'^ € Am.
€ At$l, m!vp € Fn2l, and
In this case we define m'^p and mp^ as follows: (6.335)
m^p = mliv\mvp
and m ^ = (m'^) w .
For the case under consideration we now establish (6.333) for n + 1. Let £ G A n +i. Then (6.336)
0 # m^
(6.337)
= m'rt m'^;m'vi
(6.333) if ^ # /3, (6.335) if ^ = /3,
(6.338)
<m;4-m^;(m'v/3;m^)
(6.333)
(6.339)
=m!lit}-m'tll/;m'vp-)m!pi
R4
(6.340)
= m^
(6.335)
m^p'jTnp^
By the cycle law and (6.332), 0 # m'M/3 m'^;m^p, since m ^ G At%. Thus we have shown (6.341)
fn'^/3 < Ti^jwi^
and hence m'M/3 <
whenever £ € A n +i.
In proving that (6.331)-(6.333) hold for n + 1, we need only consider cases not covered by the assumption that (6.331)-(6.333) hold for n. There are no such additional cases for (6.331), the additional cases for (6.332) follow immediately from (6.335), and all the additional cases for (6.333) can be easily derived from (6.341) using (6.332) and (6.335). In the second case, we assume m'v/J £ Fn^i for some v G A n ~{p}. As in the first case, we have vn!pv\m!vpi G At2t. Hence we let m 'l3ii = m'pv;m'vli, m'M/3 = ( m ^ ) " , and show that (6.331)-(6.333) hold for n + 1. For the last two cases we assume (6.342)
m'vij. £ Fn$l and m'vp £ Fn%
for every
v G A n ~{p}.
Let v €. A n ~{/u}. We have m'vv,mpp € At^Sl, so, by Th. 525(ii), m!vv)m!pp € Pi21 U TwQL. According to Th. 498(iii) and Th. 501(i), the only way m'vv ; l;m'pp can fail to be an atom is for it to be the join of two functional atoms, which can occur only if m'vv,m'pp € Tin 21. But m'vp <m'vv;m'vp
;m'pp
<m'vv;l;m'pp
and m'vp £ At% so if m'vl,;l;mpp were the join of two functional atoms, then m'vp would have to be one of those two functional atoms, contradicting (6.342).
87. COMPLETE REPRESENTABILITY RESULTS
521
Therefore m'vp = m'vv;\;m'pp G Ai2l. Furthermore, if m'pp G Pt2l, then m'vp = niyy-^Xyrrijjjj E Fn% by Th. 498(iii), again contradicting (6.342). Hence m'pp E Tu> 21. The same observations apply with p, in place of /3. Thus we have (6.343)
m'vp = rnvv\\\m'fSfs and m'vpb = mvv ;l;m' MM .
Since 0 7^ m ^ = m'vv;m'vv and 21 is simple, it follows that 1 = From (6.331), (6.332), and (6.343) we get m'^ ; 1;m'pp = m'^ \\\m'vv\rnvv;
l]m'vv]m'vv;l.
1;m'pp = mliv ;m'vp.
Thus we have shown m'^^^m'pp G Tw21 and (6.344)
m ' ^ ; l ; m ^ = mlivymv(i
for every 1/ e A n ~{/f}.
By Th. 501 (i), m'MM ; 1 ;?7i^/3 is either an atom or the join of two functional atoms. If m'pp ; 1;m'pp is an atom, we must let m'^p = rM^M;l;rM^, but if m^ ; 1;m'pp is not an atom, then we may let m'M/3 be either one of the two functional atoms that m^;l;mjg£ contains. Both cases can be handled simultaneously by assuming only (6.345)
m'lxl3 = z E Am,
z < m'^ ;l;m'00,
and m'0li = (m'M/3)".
From (6.345) we get (m]^)6 = m'^ by Th. 330, so
and, similarly, m'M/3 = m'^p ;m'pp. These two cases, together with those following from (6.344) and m'^p < m ^ ; l ; r M ^ , give us (6.346)
m'pp < vaIJtv\vavji
for every
v E An+i.
It follows from (6.345) and (6.346) that (6.331)-(6.333) hold for n + 1. This completes a proof by induction that m' can be constructed so that (6.331)-(6.333) D hold for every n < w. Since a;2 = Un<w ^«> ^ follows that m' G £^,21.
87. Complete representability results Every simple pair-dense RA is completely representable. Theorem 528 (Maddux [150, 51]). Let 21 be a simple pair-dense relation algebra. For every set U the following statements are equivalent: (a) 21 has a complete representation over U, (b) \U\ = \Pt%\ +2|Tw2t|. PROOF. First we show that (a) implies (b). Suppose that R is a complete representation of 21 over U. For every x E P£2l, R(x) is a point of JHe(f7), and so there is some a E U such that R(x) = {{a,a}}. Distinct points of 21 must correspond to distinct elements of U, since R is injective. This establishes a oneto-one correspondence between Pt% and a subset of U. Now let y E Tw%. R(y) is not a twin of 9U (U) (in fact, TwVie (U) = 0), but R(y) is a pair of 9U (*7) which is not a point. Hence there are distinct b,c G U such that i?(y) = {(b,b), (c, c)}. Thus every pair of 21 corresponds to a two-element subset of U. Distinct identity atoms are disjoint, so distinct pairs in 21 correspond to disjoint two-element subsets
522
6. RELATION ALGEBRAS
of U, and an element of U corresponding to a point of 21 cannot also correspond to a pair. Thus there is a one-to-one correspondence between Tw% and a collection of two-element subsets of U, each disjoint from the subset corresponding to Pt%. It follows that \U\ > |Pi2l| + 2|Tw2l|. To get the inequality in the other direction, it suffices to show every element of U corresponds to some point or pair of 21. Let a e U. 21 is atomic, so 1' = ^.Ai^Sl. R i s complete, so U1 = -R(l') = i?(E^
£ Am.
T h e n x;y
< xd;l;y'
a n d xd,y'
£ At^%
by T h . 330, so
d
x ,y' £ Pt&UTwVL by Th.525(ii). By Th.498(iii) and Th.501(i), either xd;l;y' is an atom or xd;l;y' is the join of two atoms. Thus \{z : x;y > z E ^4t2l}| < 2 for all x, y € At$l. By Th. 516, 21 is completely representable. Since 21 is also simple, there is a set V and a complete representation R of 21 over V. Since (a) implies (b), we conclude that \V\ = \PM\ + 2|Tw2l| = \U\. Choose / : V -> U so that / is a one-to-one correspondence. Define R' : A —^ Sb (U2) by R'(x) = f~1\R(x)\f for every x £ A, and confirm that R' is a complete representation of 21 over U. Every simple point-dense SA is completely representable. We also can characterize square relation algebras in terms of point-density. Theorem 529 (Maddux [150, 52]). (i) Let 'Abe a simple point-dense semiassociative relation algebra. For every set U the following statements are equivalent: (a) 21 has a complete representation over U; (b) \U\ = \Pt&\. (ii) 21 = 9k ([/) iff 21 is a simple complete point-dense semiassociative relation algebra and \U\ = |P£2l|. (iii) 21 = $Re (P£2l) iff 21 is a simple complete point-dense semiassociative relation algebra. PROOF. Proof of (i): By Th. 521, Th. 522, Th. 525, and Th. 310, every simple point-dense SA is a simple pair-dense RA in which Tw2l = 0. The equivalence of (a) and (b) therefore follows from Th. 528. Proof of (ii): For one direction it suffices to observe that 9le (U) is a simple complete point-dense SA and Ptd\t(U) = {{(a, a)} : a £ U}. Assume 21 is a simple complete point-dense SA and \U\ = |P£2l|. By part (i) there is a complete representation R of 21 over U. Let x £ At21. Then xd,x' £ At^VL = PVOk by Th.330 and Th.525(i), s o i = xd;l;x', since x = xd;x;x' < xd;l;x' £ Am by Th.498(iii). Also, R{xd), R(x') £ Pme(U), so there are
87. COMPLETE REPRESENTABILITY RESULTS
523
a,b €U such that R(xA) = {(a,a)}, R(x') = {(b,b)}, and hence R(x) = R(xd;l;x')
= {(a,a)}\ (U2)\{(b,b)} = {<«,&>}
Thus R maps AM into At9\e ([/). Note that 21 is atomic by Th. 526, so 1 = J^ At%i. R is complete, so U2 = R(l) = R(Y,At%) = \J{R(x) : x £ Ati&}. Hence every atom {(a,b)} of Die (U) is the image of some atom of 21. Thus the embedding R establishes a one-to-one correspondence between the atoms of 21 and *Re ([/). Since R is complete, i i must be an isomorphism. Proof of (iii): This part follows from part (ii). The original unpublished proof of Th. 529(iii) from 1973 was more direct and used the following method. Define a function R : A —> Sb (P£2l x P£2l) by R(x)
= {(a,b)
: a,b e PM a n d l;a;x;b;l
= 1}
for every x £ A, and then show that R is a complete representation of 21 over Pi2l. Next we consider algebras that may not be simple. Here we encounter the difficulty that pair-density and point-density are not preserved by homomorphisms. In fact, we can construct an example which shows that a point-dense RA may have a simple homomorphic image which is not even pair-dense. Let SOI3 be the subalgebra of 9le (3) that has universe M 3 = {0, 3 1 , Di n 3 x 3,3 2 }. Then OT3 is neither pair-dense nor point-dense. The subalgebra SDT2 of *Re (2) with universe M2 = {0, 2 1 , Di PI 2 x 2, 22} is also not point-dense, but it is pair-dense. Let h be the function whose domain consists of all those 'eventually constant' sequences whose 'limits' are in M3, and let h map each such sequence to its limit. Thus
h = {{R,S) .Re^Sb
(32) , S eM3,
(3K < W)(VA)(K
< A < to -> i?A = S)}
Let A = Do (h) and check that A is the universe of a subalgebra 21 of Y\i^w ^ e (3)The points of 21 are those sequences which have either {(0, 0)}, {(1,1)}, or {(2, 2)} in only finitely many places, and 0 everywhere else. Any identity element of 21 contains a point, so 21 is point-dense. Finally, h is a homomorphism mapping 21 onto SDT3. Note that 21 is incomplete. For complete algebras the situation is different, as the next theorem shows. Theorem 530 (Maddux [150, 53]). Suppose 21 is a complete pair-dense SA. (i) / / 0 ^ 1 < F , then there is some y E Pr% such that y < x and l;j/;l = l ; x ; l . (ii) Every homomorphic image of% is pair-dense. PROOF. Proof of (i): Let <1> be the family of sets Y having these properties: (1) Y
524
6. RELATION ALGEBRAS
Note that $ is closed under unions of chains. Let Y be a maximal set in $. Set y = ^Y, which exists since 21 is complete. We have y < x by (2), and so l;y;l < 1 ; K ; 1 . TO prove the opposite inequality, assume 1;j/;l x # 0. By pairdensity, there is some u £ P r 21 such that u < l;y;l-x. Let Y' = YU{u}. We claim Y' € $. Since u €. Pr%l and u < x, we need only check property (3) for Y'. For every v €Y we have 1;v; 1 < 1;j/; 1, and therefore l;v;l-l;u;l < 1; j / ; 1 1; j / ; 1 = 0. This not only confirms (3), but also shows that u 0 Y, thus contradicting the maximality of Y. We may conclude that l;y;l x = 0, i.e., x < l;j/;l, which implies 1 ; K ; 1 < 1; j / ; 1. Thus 1 ; K ; 1 = 1; j / ; 1. Since x / 0, this also gives j / / 0. What remains is to show that y £ Pr2l. First note that
Suppose u, u, to € Y. If M # v then u;0';i;;0';w < l ; u ; l - l ; u ; l = 0, and, similarly, if v / w or « / w then M;0' ;u;0' ;u> = 0. Therefore y,0';y,0';y=
^
M ; 0 ' ; M ; 0 ' ; M < 1'.
The last inclusion holds by (1). Since y / 0, we have y £ Pr2t. Proof of (ii): Suppose ft is a homomorphism from 21 onto 58. Let z £ B and 0 / z < 1'. Choose w € ^4 such that /i(ui) = 2 and set a; = w V. Therefore h(x) = z and 0 / x < V. By part (i) there is some y G Pr21 such that y < x and l;a;;l = l;y;l. We will show that /i(y) < « and h{y) G Pr«8. F i r s t , h(y) < h ( x ) = z . N e x t , l ; z ; l = l ; h ( x ) ; l = h ( l ; x ; l ) = h ( l ; y ; l ) = l;h(y);l, but z / 0, so h(y) / 0 as well. Finally, ft(tf);0';A(l/);0';A(l/)
= Hy;0';y;0';y)
< ft(l') = 1',
so /i(t/) € PrQ3.
Theorem 531 (Maddux [150, 54]). (i) Every pair-dense RA is representable. (ii) Every point-dense SA is representable. PROOF. Suppose 21 £ RA and 21 is pair-dense. Let 58 be a completion of 21. We have Pr2l C Pr*8 since 21 C 58, so ^ ® Pr2l < Y.* Pr^- B u t 1' = Yf Pr^ since 2t is pair-dense, and ^ a Pr2t = ^ ® Pr2l since 58 is a completion of 21, so 1' = Yf" Pr58, i.e., 58 is pair-dense. Every relation algebra is a subdirect product of simple relation algebras, so for some index set 7, there is an /-indexed system (<£; : i e I) of relation algebras and an embedding h such that
(i) h : » - > n i 6 i C i . (ii) for every i £ /, (£i is a simple homomorphic image of 58. Choose an /-indexed system of sets {Ui : i 6 /} so that (iii) f/j fl = 0 whenever i,j £ I and i / j , (iv) |C/i| = iPtCIil + 2\Tw€i\ for every i £ /.
87. COMPLETE REPRESBNTABILITY RESULTS
525
Suppose j £ I. 25 is pair-dense and complete, so
Note that 75 is an equivalence relation by (3). Define a function R : A —> Sb (E) by
R(x) = \J Ri(pi(h(x)))
for all x e A.
Now show that R is a representation of 21 over _B. The representation R obtained in the last step can be incomplete. For example, consider (SHe (2))" or even (SHe (1))"\ Since every point-dense SA is representable, we get the following results from Th. 523 and Th. 524. Theorem 532 (Maddux [145, Th. 5]). 7/21 G SA and (6.347)
Vx3y(y;0';y
= 0 A l ; i ; l = l;x;j/;l,
then 21 is representable. Theorem 533 (Maddux [145, Th. 10], [152, Th. C]). Let 21 6 SA and assume there is some w £ A such that w + w = 0' and Then 21 is representable.
This Page is Intentionally Left Blank
CHAPTER 7
Algebraic logic 1. Equipollence of £ and £ + Now we return to a discussion of the formalisms of Tarski-Givant [240], defined in Tables 1 and 2, p. 190. By Th. 139, £ is a subformalism £+. this means that Sent(£) C Sent+(£) and $ h ip implies $ h + ip whenever $ C Sent(£) and ip £ Sent(£). Provability in £ + extends that of £ because £ + has more axioms, namely, additional instances of (AI)-(AIX) plus all instances of axiom schemata (DI)-(DV), which express the intended meanings of the predicate operators and predicate equality symbol. On their basis the operators and equality symbol can be eliminated from any formula in Fm + (£) to produce a semantically equivalent one in Fm(£). This process of elimination carries sentences to sentences. Consequently, £ + is equipollent with £ in means of expression. In fact, for any given nice language £ = £(C, J-, 7?., rank), we define a recursive function G : Fm + (£) —> Fm(£) which eliminates occurrences of predicate operators and predicate equality and produces as output a formula that is semantically equivalent to its input. The function G is called the elimination mapping. It is defined by Tarski-Givant [240, 2.3(iii)] for the case £ = £(0, 0, {E}, rank) with rank(E) = 2. The existence of such a function shows that the addition of predicate operators and predicate equations does not increase the means of expression. The elimination mapping G is determined by the following rules, in which ip,ip£ Fm+(£), x£V,A,B£ll, and to,*i £ Tm(£). (7.1)
G(
AtFm(£),
(7.2) (7.3) (7.4) (7.5)
G(A = B)= VVOVV1 (G(voAvi) & G ( v 0 B v i ) ) ,
(7.6)
G{t0A + Bh) = GitoAh) V G(t0B*i),
(7.7) (7.8)
G{to~At1) = - G ( t o ^ i ) , GiUA-Bti) = 3Vh {G{t0Avk) A G(vfcBti)), where k is the smallest element of to such that v^ ^ var(to) U var(ti),
(7.9)
G(toiti) = G(tiAto).
528
7. ALGEBRAIC LOGIC
It is easily seen from the rules just stated that the elimination mapping has no effect on formulas which contain no predicate operators and no occurrences of the predicate equality symbol. Consequently it maps Fm + (£) onto Fm(£). Although the elimination mapping may introduced new variables, according to the rules (7.5) and (7.8), it does not add or delete free variables, so its output has the same set of free variables as its input. The elimination mapping therefore maps Sent + (£) onto Sent(£). A straightforward comparison of the rules (7.5)-(7.9) with the definition of satisfaction, especially rules (4.53) and (4.48)-(4.51), shows that the elimination mapping transforms each formula into a semantically equivalent formula which has no predicate operators and no predicate equality symbols. Thus the additional predicate operators and equality provide no additional means of expression. The next theorem, due to Tarski-Givant [240, 2.3(iv)], states these basic properties for an arbitrary nice language (rather than a language with only a single binary relation symbol). Theorem 534. Let G be the elimination mapping for a nice language £, and let Lp £ Fm + (£). (7.10)
If(pe Fm(£) then G((p) = (p.
(7.11) (7.12)
G*(Fm+(£)) = Fm(£). free(Gte)) = freefa).
(7.13)
G*(Sent+(£)) = Sent(£).
(7.14)
G(
(7.15)
If
The semantic equivalence of G(ip) and ip is stated in (7.14). But (7.15) states that the equivalence between G(ip) and (p can also be proved using the rules and axioms of the formalism £ + when (p is a sentence (as required by the definition of the formalism £ + ) . Thus G(tp) and tp are equivalent both semantically and provably. Of course, it is possible to deduce (7.13) from (7.14) by appealing to Godel's Completeness Theorem, but Tarski-Givant [240, 3.8(ix)] have extended this theorem to the formalisms £3 and £3 which are obtained, in case the underlying language has only binary relation symbols, by appropriately restricting notions of £ and £ + to three variables and by supplementing the set of axioms in ways that are necessitated by the failure of Godel's Completeness Theorem to extend to formalisms with only finitely many variables. The direct proof of (7.15) in the 3-variable version is consequently considerably more complicated; see Th. 547. The elimination mapping may introduce additional variables. This occurs in rules (7.5) and (7.8); for all the other rules the sets of variables of the input and output formulas are the same. However, in many circumstances the elimination mapping will not introduce any variables other than the first three. Rule (7.5) only introduces the variables vo and vi. Recall from (4.22) that V3 := {vo, vi, V2}. Rule (7.8) will introduce a variable that is not in V3 only if the terms to and t\ jointly contain all three variables vo, vi, and V2. This cannot happen if |var(£o)| = |var(ti)| < 1, because in that case there is a variable in V3 that differs from the (at most two) variables that appear in to and t\. Notice that the output of
1, EQUIPOLLBNCE OP C AND £+
529
(7.5) involves atomic formulas that always satisfy this criterion, and if the input to rule (7.8) satisfies this criterion, then so do the atomic formulas involved in its output. Consequently one can prove by induction that if every term that occurs in a formula
iff
G*(^)h
(ii) // * C Sent(£) and
530
7. ALGEBRAIC LOGIC
2. Inequipollence of £,x and C+ The axiom schemata (BI)-(BX) of £ x are just a transcription of the axioms Ri-Rio for relation algebras. The rules of inference for £ x are familiar from common algebraic practice and are formally described in systems of equational logic; see Tarski [236] or McKenzie-McNulty-Taylor [167]. Since the set of predicates II in Cx has a single generator E, we may say that £ x is the equational logic of 1generated relation algebras, while M.^* is the equational logic of n+1-generated relation algebras. Theorem 537 (Tarski-Givant [240, 3.4(i)(ii)]). £ x is a subformalism of C+, i.e., Sent x (£) C Sent+(£), and * / * C Sent x (£) and A = B £ Sent x (£), then * Hx A = B implies * H+ A = B. PROOF. Assume * C Sent x (£), A = B £ Sent x (£), and * Hx A = B. We must show by induction that every predicate equation derivable from ^ in Cx is also derivable from ^ in £ + . Applying this result to our hypothesis ^ h x A = B, we obtained the desired conclusion, that ^ h + A = B. The induction requires several lemmas to the effect that the axiom schemata of £ x are all derivable in C+ and that the effect of the rules of inference of £ x can be reproduced in £ + . For example, consider an instance {C = D, C;E = D;E) of the rule Rp. We wish to show that C = D\-+ C;E = D;E. After some preliminary work involving propositional calculus, various lemmas such as (4.111), and axiom schemata (Dili) and (DV), we see that we need to establish VvoVv1(3v2(voCv2 A vaSvi)) » 3v2(v013v2 A v 2 Svi)). Certainly this can be done. One can invoke Godel's Completeness Th. 170, Th. 160, and the equipollence of C+ with £ to give a semantic proof. However, for the purpose of establishing the equipollence of £ x with the 3-variable formalisms C% and £3, it is important to know that the proof can be carried without the use of any variables other than vo, vi, and V2. The same consideration applies to the axiom schemata of £ x , and it is here that the difficulty connected with the associative law for relative multiplication arises. Each instance of axiom schemata (BI)(BIII) and (BV)-(BX) can indeed be derived in C+ using only three variables, but instances of (BIV) require four variables. If the number of variables used in derivations in £ + were not a consideration, then the entire proof could be carried out semantically. We could, for example, conclude that h + C;(D;E) = (C;D);E as a fairly obvious consequence of Godel's Completeness Th. 170, Th. 160, together with axiom schema (Dili). We are now well-situated to compare the formalisms £ x and £. Both of these formalisms are subformalisms of £ + , and one of them, namely £, is equipollent with this common extension. To compare the formalisms Cx and C it now suffices
2. INEQUIPOLLENCE OF £ x AND £ +
531
to compare Cx with its extension C+. It happens that Cx is strictly weaker than C+ in means of expression and proof. 2.1. Means of expression. A sentence is said to be Cx-expressible if it is semantically equivalent to a predicate equation A = B with A, B £ II. Already in 1915 Lowenheim [131] presented a proof (taken from a letter by Korselt) that a sentence saying there are at least four elements, such as 3 vo 3v 1 3v 2 3v 3 (-'Vo=vi A -ivo=v 2 A - i v i = v 2 A -.vo=v 3 A - . v i = v 3 A -.v 2 =v 3 )
is not equivalent to any predicate equation. Tarski-Givant [240] formulated Korselt's result in this way. Theorem 538 (Tarski-Givant [240, 3.4(iv)]). The sentence Vv0VvlVv23V3(-ivo=V3 A - i v i = v 3 A - i v 2 = v 3 ) x
is not C -expressible. Tarski observed that the sentence in this last theorem is equivalent to the predicate equation 1 = 1 in all infinite interpretations, but this is not the case for the sentence in the next result. Theorem 539 (Tarski-Givant [240, 3.4(v)]). The sentence VvoVvlVv23V3(voEv3 A viEv 3 A v 2 Ev 3 ) x
is not C -expressible. Kwatinetz [126, Th. 1.1.12] found a general method for proving such results. Several other such sentences are given by Wostner [257], who showed that a sentence is not £ x -expressible if it asserts that (the interpretation of) E is the ordering of a semilattice, lattice, modular lattice, distributive lattice, complemented lattice, complemented modular lattice, Boolean algebra, or atomless Boolean algebra. Theorem 540 (Kwatinetz [126, Th. 1.2.11]). The restricted (or weak) pairing axiom (7.16)
VvoVvl(3v2(voEv2 A viEv 2 ) => 3V2Vv3(v3Ev2 <=> v 3 = v 0 V v 3 =vi))
is not Cx -expressible. In contrast, Tarski proved that both the Axiom of Unordered Pairs, (7.17)
VvoVV1 (3V2 (v 0 Ev 2 ) A 3 V2 (viEv 2 ) => 3 V2 (3 V0 (v 2 Ev 0 ) AVv3(v3Ev2 <=> v 3 = v 0 V v 3 =vi))),
and the (unrestricted or universal) pairing axiom, (7.18)
Vv0Vvl3V2Vv3(v3Ev2 <S> v 3 = v o V v 3 = v i ) , x
are both C -expressible.
532
7. ALGEBRAIC LOGIC
Theorem 541 (Kwatinetz [126, Th. 1.2.15]). None of these three sentences is Cx -expressible. The greatest lower bound axiom, (7.19)
V vo V V1 3v 2 ( v 2 E v 0 A v 2 E v i A VV3 (v 3 Ev 0 A v 3 E v i => v 3 E v 2 ) ) ,
the least upper bound axiom, (7.20)
V vo V V1 3v 2 ( v 2 E v 0 A v 2 E v i A VV3 (v 3 Ev 0 A v 3 E v i => v 3 E v 2 ) ) ,
the union axiom, (7.21)
Vv0Vvl3v2VV3(v3Ev2 « - v 3 E v 0 V v 3 E v i ) .
A general observation of Tarski is that if an Cx -expressible sentence is altered by replacing each atomic subformula by its negation, then the altered sentence is also Cx-expressible. The union axiom can be obtained this way from the greatest lower bound axiom. Theorem 542 (Kwatinetz [126, Th. 1.2.16]). The union-individual axiom (7.22)
Vv0Vvl3v2Vv3(v3Ev2 <^ v 3 =v 0 V v 3 Evi),
is not Cx -expressible. In set-theoretical language the sentence (7.22) expresses the existence of X U {Y} for all classes X and Y. Tarski-Givant [240, 3.6(ii)] mentioned that (7.19), (7.21), and (7.16) are not Cx-expressible, but stated that the problem was still open for (7.22) [240, p. 63]. Formisano-Omodeo-Policriti [72, Prop. 1.6] gave a detailed proof of Th. 542, and also showed that the conjunction of the unionindividual axiom with the Axioms of Extensionality and Difference is also not Cx -expressible. Kwatinetz [126, Th. 2.2.1] (see also Tarski-Givant [240, 3.10(v)]) showed that there is no algorithm for determining whether a sentence is Cx-expressible, and, more generally, for each n > 3, there is no algorithm for determining whether a sentence in Sent(£) is equivalent to one in Sentn(C). It is not yet known whether, for fixed n > 3, there is an algorithm for determining whether a sentence in Sent n +i(£) is equivalent to one in Sent n (£) (see Tarski-Givant [240, 3.10(v)]). 2.2. Means of proof. Clearly Cox and Cwx are also subformalisms of £ + along with Cx. In fact, Cox is a subformalism of Cwx, and Cwx is a subformalism of Cx. The proofs of these facts are quite trivial and require little beyond the observation that every instance of (BIV') is an instance of (BIV). By the results above, these formalisms are also not equipollent with C+ in means of expression. It turns out that all three differ in means of proof. To see why this is so, it helps to first state some basic connections between these formalisms and the varieties RRA, RA, SA, and NA. The first two parts of the following theorem were established by Tarski-Givant [240, 8.2(ix)(x), 8.3(vii)(viii)] for the formalism M(n)x (in which n may be any cardinal) as a means for deriving results about RRA and RA from results about M(n)x.
2. INEQUIPOLLENCE OF £ x
AND £ +
Theorem 543. Suppose that C = C(C, T, 1Z, rank) is a nice ^ C Sentx (£). Define four binary relations on predicates A, B £ II by (7.23)
A~+B
iff V\-+ A = B,
(7.24)
^ ~*B
igf * h x A = B,
(7.25)
^ ~ *B
j# * h x A = B,
(7.26)
A ~°9 B
iff ^\-x A = B.
Then (i) ~ J , ~ £ , ~JjJ, and ~ J ore congruence relations on the predicate algebra
VofC, (ii)
(a) the quotient algebra ^P/—^ is a representable relation algebra, (b) ^5/~0~ is a /ree representable relation algebra that is RRA-freely generated by {-R/-} : R £ Tl, rank(ii) = 2}, (iii) (a) the quotient algebra ^P/—£ is a relation algebra, (b) ^P/—£ is a /ree relation algebra which is RA-freely generated by { f l / ~ * : fl € ft, rank(B) = 2}, (iv) (a) the quotient algebra ^P/—$ is a semiassociative relation algebra, (b) ^P/—gf is a /ree semiassociative relation algebra that is SA-freely generated by {R/~$ : R € ft, rank(B) = 2}, (v) (a) ifee quotient algebra ^P/—$ is o nonassoeiative relation algebra, (b) ^P/—0 is a free nonassoeiative relation algebra that is NA-freely generated by {.R/~0 : ReTZ, rank(i?) = 2}. PROOF, (i): It follows directly from the use of the rules Rp and Tr in the definition of provability for the formalisms Cx, Cwx, and Cox that ~ J , ~5JI, and ~ ^ are congruence relations on the predicate algebra Vji. For ~^J the same conclusion is reached by proving, in effect, that Rp and Tr are "derived rules of inference" for the formalism C+. Proof of (iii)(a), (iv)(a), (v)(a): That the quotient algebras 9V~£, W - * i a n d ?P/~J are in RA, SA, and NA, respectively, is due to the fact that the axiom sets for the formalisms Cx, Cwx, and Cox are transcriptions of the equational axiomatizations of RA, SA, and NA, respectively. Proof of (ii)(a): To show that ^P/—<jj is a representable relation algebra, we use the Assembly Lemma, Th. 88. Suppose A ^ B, i.e., I/J A = B. By the Completeness Th. 170 and Th. 160, there is an interpretation M such that M \= \l/ and M. \/= A = B. Then (-)M is a homomorphism from ^5 into $Re (M) such that g £ ^ i m p l i e s RM = gM for a l l AM _£ BM Q n t h e Qther h a n d ; gince R R, S € II, it follows that the homomorphism (-)M may be factored through the quotient homomorphism (-)/~^, yielding a homomorphism h, from the quotient algebra ^P/~^ into the square relation algebra 9le (M) e RRA, that separates A/~+ from B / ~ + : i i ^ = h(R/~$)
for all
flen,
534
7. ALGEBRAIC LOGIC
By the Assembly Lemma, Th. 88, the quotient algebra ^J/~^ may be embedded in a direct product of square relation algebras and is therefore representable. Proof of (ii)(b): We must show that
ReTZU{=}, if rank(iZ) = 2 and anything else, say 0. otherwise. Take care of function symbols and constants in any way. By the definition of interpretation, (-)j is denned on all of 1Z U II and the restriction of {-)Mj to II is a homomorphism from ?p into IHe (Uj). Define a homomorphism h from %5 into Yliei ^ e (^) ^y setting, for every
A en, Suppose A, B £ II and A ~j~ _B. Then h + A = _B by definition, so by soundness A and B are assigned to the same relation by every interpretation. In particular, AMi = BMi for every i £ I, so h(A) = h(B). It follows from this reasoning that ~j~ is in the kernel of h, hence there is a homomorphism k from ^5/—^ into n , e / ^ e (^) s u c n t h at /i(A) = k(A/~^) for every A G n . Since g is an embedding with inverse g~ , we get a homomorphism / ' from *p/~g to 21 if we define / ' by f'(A/~+) = g~1(k(A/~+)) for every A 6 II. To show that / ' extends /, first note that HA/-+)
= h(A) = (AMi
:i£l)
apply p" 1 , and get
f'(A/~+) = g-'iHA)/^) = f(A/~+). Now we consider the application of this theorem in case C = £(0, 0, {E}, rank) where rank(E) = 2. It follows from Th. 543 that if we wish to find a predicate equation that is provable in one of the formalisms in the sequence £ + , £ x , Cwx, Cox, but not in the next one, we need only transcribe an equation which contains a single variable and is valid in the corresponding variety in the sequence RRA, RA, SA, NA, but not in the next one. This procedure was carried out by Givant for McKenzie's nonrepresentable relation algebra. The resulting 1-variable equation, simplified later by McNulty and Tarski, appears in the next theorem.
3. FINITE-VARIABLE FORMALISMS
535
Theorem 544 (Tarski-Givant [240, 3.4(vi)]). £ x is strictly weaker than £+ in means of proof, for if A := 1; (E f E + (E;E + 1' + (E E); (E E) E) E + E f E); 1 then\-+ A = \ and\fx A = \. In §6.29 there is a semiassociative relation algebra which is not a relation algebra because the equation x;(x;x) = (x;x);x fails in it. This is a 1-variable instance of the associative law for relative multiplication, so by Th. 543, it yields a sentence provable in £ x but not in Cwx. Theorem 545. Cwx is strictly weaker than £ x in means of proof. In fact, h E;(E;E) = (E;E);E, but \fx E;(E;E) = (E;E);E. x
The equation (x;l);l = x;l holds in every SA. The very nonassociative algebra from §6.27 and McKinsey's algebra from §6.28 are both in NA and they both fail to satisfy this equation. We therefore get the following result. Theorem 546. £o x is strictly weaker than Cwx in means of proof because \- (E;l);l = E;l, but \/x (E;l);l = E;l. x
3. Finite-variable formalisms In this section we consider the formalisms £3, £jj~, £53, £sjj~, Cn, C^ for n > 4. We have seen that £ is a subformalism of £ + that is equipollent with £ + in means of both expression and proof. In contrast, £ x is a subformalism of £ + that is not equipollent with £ + in means of expression nor in means of proof. The observation in Th. 535, that every predicate equation is equivalent to a sentence in Sent3(£), led Tarski to consider weakening £ and £ + in such a way that the weakened formalisms would still equipollent with each other, and yet they would both also be equipollent with £ x . The first step is natural in light of the observation that every predicate equation is equivalent to a 3-sentence: choose Sent3(£) and Sentj|"(£) as the sets of sentences of the weakened formalisms. With regard to means of expression, all is well, for Tarski was able to show that every 3sentence (in binary relational language) is semantically equivalent to a predicate equation. With regard to means of proof, it is natural to simply restrict some particular standard axiom set for first-order logic with countably many variables to those instances that contain only three variables. However, difficulties arise that led to the consideration of the axiom schemata (AVI'), (AIX'), (AIX"), (AX), and (AX'). Instances of axiom schemata (AVI'), (AIX'), (AIX"), (AX), and (AX') can be derived from (AI)-(AVIII) when there are countably many variables. However, proofs of instances of these and related schemata involve the introduction of variables that do not occur in (p. This may not be possible when the number of variables is is finite, since every variable in the language may occur in a single formula. Consequently, Tarski-Givant [240, p. 91] explicitly include (AIX') in place of schema (AIX) for their finite-variable formalisms. Indeed, axiom schemata (AVI'), (AIX'), and (AIX") ought to be included, either as axiom schemata or
536
7. ALGEBRAIC LOGIC
as theorems, in any system of first-order logic with finitely many variables. It is desirable to include all equivalences between pairs of formulas that differ only by the process of renaming bound variables. Such formulas are called alphabetic variants of each other; see Quine [204, 205]. Logic with a fixed finite number of variables should be characterized only by the inability to refer to more than that number of objects of the domain at one time. Our ability to name these objects should not be unduly restricted. For example, there should be no inherent distinction between the following two sentences, which both say, assuming "Rxyz" means "x loves y at time z", that Everybody Loves Somebody Sometime (words & music by Irving Taylor & Ken Lane): Vv o 3 vl 3v 2 -RvoVlV2,
Schemata (AX) and (AX') express the associative law (BIV) for relative multiplication. In general, proofs of instances of (AX) and (AX') require the simultaneous examination of four objects. Tarski's goal, formulated in [227] and reached by Tarski-Givant [240], was to create a system of logic with only three variables that is equipollent in means of expression and proof to the equational logic of relation algebras. Equipollence in means of expression is possible, but equipollence in means of proof is not really possible, since some instances of (AX) and (AX') require four variables to prove. Tarski [227] and Tarski-Givant [240, §3.7] get around this problem by simply including (AX) in the axiom schemata of £3 and Cf in order to gain the equipollence of £3 and Cf with £ x . Givant [240, p, 70] showed that equipollence can also be attained by using the somewhat conceptually simpler schemata (AIX") and (AX'), which utilize the interchange of two variables instead of substitution, in place of (AIX') and (AX). This strategy is superfluous for £„ and Cn when n > 4, since (AX) and (AX') are derivable on the basis of the remaining axioms once there are at least four variables, and if the strategy is simply not followed and neither (AX) nor (AX') is included among the axiom schemata in case n = 3, the resulting formalisms are £53 and Csf (the "s" signifies "standard"). The reasoning by which £ is seen to be a subformalism of £ + applies equally well to all these finite-variable formalisms, and leads to the following conclusions, in which n > 4 and "C" abbreviates "is a subformalism of": (7.27)
£s3 C Csf,
£3 C £ + ,
Cn C £+,
(7.28)
£s3 C £3 C Cn C £ n + i C
(7.29)
& J ^ £+ C £+ C £+ + 1 C
, .
Furthermore, the properties of the elimination mapping that are stated in Th. 534, Th. 535, and Th. 536 can be extended to these finite-variable formalisms, resulting in the following extension of Th. 534, due to Tarski-Givant [240, §3.8, p. 89,91-92]. T h e o r e m 547. £53 and £sjj~ are equipollent, £3 and £jj~ are equipollent, and Cn and £ j are equipollent for all n > 4.
3. FINITE-VARIABLE FORMALISMS
B37
The proof of this theorem, if written out in complete detail, would be elementary but rather long. This is due to the choice of Tarski-Givant [240] to start with axiom schemata (AI)-(AIX) and the rule MP in their axiomatization of £. As pointed out by Tarski-Givant [240, §3.8], a complete proof would require not only the details given there but also proofs of several lemmas from Tarski [235] and Quine [202, 204]. Many of those details are presented here in (4.111), (4.122), (4.123), (4.124), (4.133), (4.135), and (4.136)-(4.146). Tarski-Givant [240, §3.9] went on to prove that £3 and £ j are not only equipollent with each other but also equipollent with £ x in means of expression and proof. However, the inclusion of (AX) among the axiom schemata of £3 and £c!~ led Tarski-Givant [240, p. 89] to say, "the (standardized) formalisms £53 and £sj . . . are undoubtedly more natural and interesting in their own right than £3 and £3"." Indeed, the pair of formalisms £s3,£sj, followed by the pairs £ n , £ ^ , with n > 4, form a natural sequence with similar axiomatizations. The pair £3, £3" stands apart from this sequence by the inclusion of (AX). Since £53 and £sj may be obtained from £3 and £^ by deleting (AX), and (AX) expresses axiom schema (BIV) of £ x , it is natural to ask whether the formalism £o x , which is obtained from £ x by simply omitting (AX), is equipollent with Cs~l. As we saw in the previous section, the answer turns out to be "no" because the weakened associative law (BIV') can be derived in £sj but cannot be derived in £o x . A natural response to this inability to derive (BIV') in £o x is to include it as an axiom schema, thereby obtaining the formalism Cwx. This time the situation is quite satisfactory. Every predicate equation derivable in £sj is derivable in £to x , and, furthermore, every predicate equation derivable in C\ is derivable in £ x . Theorem 548 (Maddux [139, 146]). For all A,B 6 II, (7.30)
hj A = B
iff
h x A = B,
(7.31)
h+ A = B
iff
h x A = B.
Over the next few sections we develop the means to prove this theorem. A proof is given on p. 577. We close this section instead with some remarks about the significance of this result and its consequences. Th. 548 implies that L\ is equipollent with £ x in means of proof, and that list, is equipollent with £tox in means of proof. The relations of subformalism and equipollence in means of proof stated in (7.27)-(7.31) are shown again in Figure 1. The (transitive) relation of subformalism is indicated by ascending lines. A line marked with a bullet or circle also indicates that the two formalisms so connected are equipollent in means of proof. The equipollences indicated by bullets were established by Tarski-Givant [240]; see Th. 547 and Th. 556. The equipollences indicated by circles are the ones that result from Th. 548. The question whether £o x is equipollent with £sj is marked in Figure 1 with a "?". Its answer ("no") is indicated by the fact that the line from £o x to £uix is not marked by a circle. As a final remark we combine Th. 548 with a summary of parts (ii)(b)-(v)(b) of Th. 543. We use some ad-hoc notation as a reminder of the more precisely
538
7. ALGEBRAIC LOGIC
FIGURE
1. Equipollence in means of proof
formulated but rather long statements in Th. 543: (7.32) (7.33)
RRA \=A = B iff RA |= A = B iff
K^ A = B, h x A = B iff
[-+A = B
(7.34)
SA\=A = B iff
\-lA = B iff
\-t A = B
(7.35)
NA\=A = B iff
x
K A = B.
Although we cannot change T + " to Tg~" because the meaning of the latter symbol is reserved (see the remark after Th. 556 below), (7.32)-(7.34) may be paraphrased as follows. - the equational theory of semiassociative relation algebras is the firstorder logic of binary relations restricted to what can be expressed and proved using three variables, - the equational theory of relation algebras is the first-order logic of binary relations restricted to what can be expressed using three variables and proved using four variables, - the equational theory of representable relation algebras is the first-order logic of binary relations restricted to what can be expressed using three variables and proved using any finite number of variables. 4. Algebras of formulas We will construct algebras of relational type using formulas in Fm + (£) for an arbitrary nice language C = €(0,^,11, rank), following Maddux [139, 156]. For a given interpretation M for C with domain M, there is a function ^ : Fm+(£) -> 56 (M 2 ) ,
4. ALGEBRAS OF FORMULAS
539
which associates a binary relation on M with every formula in Fm + (£). The function DenM is called the denotation function of M, and is defined on each formula ip G Fm + (£) by (7.36)
D e n M 0 ) : = { < s o , s i ) :s€"M,M\=
We say that DerT^^) is the (binary) relation defined by the formula ip in M.. Den^1 has the following existential closure property: Den^O?) = DenM(3x
(7.37)
= RM,
since DenM(vOjRvi) = {{s0, si) : s € "M, M \= voi?vi[s]} = {{so, « i ) : « e aM, (s M (v 0 ), s M (vi)) G flM} = {{so,Sl):s<E"M,
(so,si)ei?M}
= JJ M .
Now (-)"M is a homomorphism on the predicate algebra ^}3, whose universe is II, but {vo-Rvi : R e II} is a copy of II as a subset of Fm + (£). It is therefore natural to consider operations on this copy of II that produce a copy of the algebra ^3. Define a binary operation | and a unary operation ° on Fm+(£) by setting, for all v?,V e Fm+(£), (7.38)
ip\ip :=3v 2 (Si2VASo2t/'),
(7.39)
Although they are defined on all formulas, the operations | and ° are designed for application to formulas whose free variables belong to V2. Consider two such formulas
M
^
^
(7.41)
Of course, DenM has some other obvious properties. (7.42)
Den^O? V ip) = DenM(
(7.43)
Den^(-,y>) = M 2 ~ Den^(ip),
(7.44)
Den A1 (v o =v 1 ) = M 1 .
(7.40) and (7.41) also happen to hold for all formulas in which V2 does not occur free, but may fail otherwise. For example, consider a language with a binary relation symbol < and an interpretation M. in which <M is a linear ordering
540
7. ALGEBRAIC LOGIC
without endpoints, such as the usual ordering of the rationals or real numbers. Consider the formula vo < vi Avi < v 2 , which we will abbreviate to vo < vi < V2. Then Den M (v 0 < vi < v 2 ) = {(so, si> : s € "M, M \= v 0 < vi < v2[s]} = <M, however, (7.40) fails in this case since DenM((vo < vi < v 2 ) | (vo < vi < v 2 )) = Den M (3 V2 (Si 2 (v 0 < vi < v 2 ) A S 02 (v 0 < vi < v 2 ))) = Den M (3 V2 (vo < v 2 < vi A v 2 < vi < v 0 )) = Den M (3 V2 (v 0 < v 2 < vi < v 0 ))
=0 Next, define an algebra of formulas by setting (7.45)
5m+(£) := (Fm+(£),V,-,|, ° , v o = v i ) .
We will usually omit the reference to £ and simply denote this algebra by $m+. Other algebras defined below will be subject to the same notational convention. Note that $m+ is an algebra of relational type that satisfies some nontrivial identities. Indeed, for any ip,ip £ Fm + (£), we have (7.46)
V°°
=
(7.47)
(^VVO°=^V^0,
(7.48)
(^)° = ^ ° ) .
In view of (7.48) we may write simply -ap° instead of either (-«p)° or ->(
4. ALGEBRAS OF FORMULAS C
There are many simple observations that could be made, and many more difficult questions that could be asked, about these algebras and their interrelationships. Instead we focus our attention on the algebras #1113(2) and #TnJ-2)- The next theorem should be compared to Th. 567 and Th. 559 below. Theorem 549 (Maddux [139, 11(1)], [156, 4.1]). Let C = C(C, T, U, rank) be a nice language and let 3 < n < ui. (i) // M is an interpretation for C with domain M, then (a) Den^, restricted to Fmn(2)(£), is a homomorphism from #mn(2) into 9\e(M), (b) ifip,ipeFmn(2) (C) and(p = ip then DenM (ip) = Den^ (ip). (ii) The semantic equivalence relation =, restricted to Fmn(2)(£), is a congruence relation on 5rmn(2). (iii) #m n ( 2 )/= is a representable relation algebra. PROOF. Part (i)(a) follows from (7.40)-(7.44). For part (iii), note first that if ip, ip £ Fmn(2)(£) and ip is not semantically equivalent to ip, then there must be an interpretation M.^^ and a sequence s £ u(MVllp) such that, say, M.^^ \= ip[s] and Mip,$ y= tp[s], or the other way around. Hence (so,si) G DenMf^(ip) Q DenMlf^ (tp). Thus, for each pair of semantically inequivalent formulas ip, tp E Fmn(2)(£), there is, by parts (i) and (ii), an interpretation Mv^ and a homomorphism h,p^ from #m n ( 2 )/= into 9le(M^^) such that hv^(np) 7^ hv^(ip). By Th. 88 (the Assembly Lemma), there is an isomorphism from #m n ( 2 )/= into
hence g r m n(2 )/= is a representable relation algebra. Th. 549 remains true if Fmn(2)(-C) and 3ttV(2) Jmi 2 >, respectively. Hence we have
are
replaced by Fm^ 2 j(£) and
Theorem 550. Let C = C{C,T,1Z, rank) be a nice language and let 3 < n < ui.
(i) // M is an interpretation for C with domain M, then (a) Den^, restricted to Fm^,2,(£), is a homomorphism from Svn^j into 9\e(M), (b) if
542
7. ALGEBRAIC LOGIC
is an isomorphism from 3"tri^,2,/= onto 3mn(2)/=In the proof of Th. 550, one uses properties of the elimination mapping. In particular, the function described in the theorem is onto because every formula tp in Fmi 2 >(£) is semantically equivalent to one in FmB(2)0C); namely, G(ip). The structure of 3mB(2)/= ( or 5wi^ 2 ,/=) depends on the symbols of C and the rank function of £. Do these ingredients entirely determine the structure of $m B ( 2 )/=? In particular, do different choices for C, IF, 1Z, and rank lead to nonisomorphic algebras? It seems likely that this is the case. We show in Th. 553 that if C = 0 = J- and every symbol in Tt is binary, then $mB(2)/= ' s ^ n e ^ e e representable relation algebra on \7t\ generators. Consequently, it is a special case of the question just raised to determine whether free representable relation algebras on different numbers of generators are nonisomorphic. Again, this seems likely. CONJECTURE
551. For cardinals n and m, i/$tKRRA = $tTORRA then n = m. 5. Eree RRAs of formulas
We show in this section that if £ is a binary relational language, then 3m3(2)/= is a free representable relation algebra. In fact, $1113(2)/= ' s RRA-freely generated by the semantic equivalence classes voiZvi/= of the atomic formulas v©JEvi with R £ H. To show that these equivalence classes generate the entire algebra ^^3(2)/= we will show that every formula in (p € Fm3(2)(£) is semantically equivalent to another formula, called T(ip) in the proof of Th. 552 below, that is an element of the subalgebra of ^1113(2) generated by {voiivi : R £ 72.}. Although every element of the algebra iJtrigp) is a formula that has only two free variables vo and vi, its subformulas may have three free variables. Such subformulas may not be elements of the algebra 5m3(2), but do belong to the strictly larger algebra ^m 3 , which contains 3*1113(2) as a subalgebra. For this reason we will actually work within the algebra ^vx^- The following theorem corresponds to parts of Tarski-Givant [240, 3.9(iii)], Maddux [139, 11(3)], Maddux [156, 4.2], and Hirsch-Hodkinson [99, 3.32]. Theorem 552. Assume C is a binary relational language. If'ip £ Fm3(a)(£), then there is some tp e &8iSmW>') ({v0Rvi : R £ 11}) such that
(7.49)
Z := 6 f l « m sm) ({v o ijvi : R e %}).
The mapping T has the property that for every formula tp £ Frr^jC) there are three finite sequences tp, Xi ff °f formulas in Z, all of the same length, say k < u, such that (7.50)
T(ip) = f\ (Si#* V Scaxi V
5. FREE RRAS OF FORMULAS
1
v || voiivi Vliivo viRv2 V2RV1
V> F F F F
vo-Rvi (v o i?vi)
vo-Rv 2 V2.RV0 Vo-Rvo Vliivi
F F
V2.RV2
T | (vo-Rvi A vo=vi) TABLE
a
X F F (vo.Rvi) vo-Rvi
F F F F F
|
voiivi (vo-Rvi)
F F F F (v o itVi A v o = v i ) |T T | (vo-Rvi A vo=vi)
F
1. Choices for the atomic case
Let us consider one of the conjuncts in T(ip), say Si2ipi V S02X1 V Oi for some i < k. Since T/J;,X;,<7J £ Z C Fm3(2)(£), the only variables that may occur in these formulas are vo, vi, and v 2 , and the only variables that may occur free are vo and vi. It follows that the sets of free variables of Si2tl>i, So2Xi> a n d (Ti are contained in {vo,V2}, {v2,vi}, and {vo,vi}, respectively, and therefore free(Si2V>i V S02X; V ai) C V3. The fact that T((p) has the particular form in (7.50) is expressed by saying T(ip) is in "T-normal form", a special kind of conjunctive normal form that was used by Tarski-Givant [240] and Maddux [139, 156]. Since A and V are operations on formulas denned in (4.9) and (4.10) in terms of -1 and =>, the form of T(ip) given in (7.50) is rather complicated and even ambiguous because it contains a finite conjunction of formulas indexed by k £ ui. In the definitions that appear below we use even more complicated index sets, such asfc3. To insure that T is a well-determined computable function all such potential ambiguity would have to be eliminated by strictures on the placement of parentheses and the order of the formulas that appear in the finite disjunctions and conjunctions. Such precision is not needed for our purposes, and will not be given. Suppose R£TZU {=} and ip is the atomic formula ViRvj, where i,j £ 3. In this case, we let T(
where ip, x, and a are determined according to the nine possible cases listed in Table 1. We wish to show that every 3-variable formula is semantically to one that can be obtained from formulas of the form vo-Rvi using operations of the formula algebra $m3, so the choices that appear in Table 1 have been designed to satisfy that criterion. They are clearly elements of Z. Noting that /J, V F = /j,forevery formula /J,, and also F = S12F = S02F, we can see that T(
T(vo T(vi
= S12F V S02F V vo-Rvi = v o i?vi, = Si2F V S02F V (v 0 iivi) 0 = vitfv
544
7, ALGEBRAIC LOGIC
(7.53) (7.54) (7.55) (7.56) (7.57) (7.58) (7.59)
T(viflv 2 ) T(v 2 iivi) T(v o i?v 2 ) T(v2Rvo) T(voflvo) T(viRvi) T(v 2 iiv 2 )
= S12F V S02((v0.Rvi)0) V F = vii?v 2 , = S12F V Soavoflvi V F = v 2 i2vi, = Siavoflvi V S02F V F = vO-Rv2, = Sia((voi?vi)°) V S02F V F = v 2 i?v 0 , = S12F V S02F V (vo.Rvi A v o =vi) |T = v o flv o , = S12F V S02F V T | (voi?vi A v o =vi) = Viflvi, = Si 2 (T| (vofivi A v o =vi)) V S02F V F = v 2 i?v a .
To define T(-np), T(tp => tp'), T(\?voip), T(\/V1ip), and T(VV2y), we start with the formulas T(
T{ip) = A (Si2^i V i
T(
(7.61) We then let
T(-^) := A [ S12 f V A A
=^ V )
"Q9)
-i^i) V S02 f V (* ( I S121
\, W
-iXi) V V
-'Oi 1,
A -iWj V to, ) V
A ( S l 2 p V Soa(-'(-'^iD l-'O-i) V Xi) V
T(VV2¥?) == A (Si2FVSo2FV(-.(-.^i|-.Xi)V(Ti)). i
In (7.51)-(7.59) we saw that T{tp) = tp whenever tp £ AtFm(£). For the nonatomic cases, we may assume (7.60) and (7.61). By applying negation to both sides of (7.60) and utilizing various familiar laws from prepositional calculus, we have = -i A (Sl2^>i V SoiXi V
5. FREE RRAS OF FORMULAS
= \ / ^(Sl2ipi
V So2Xi V <Ti)
i
= \J (-iSl2^0i A ->S02Xi A -«Ji i
= \J {Si2^ipi A S 0 2-'XJ A -icr,
= A ( V S12^iV Y f£h3
/(«)=0
/(i) = l
/(i)=2
= A ( Si2 ( V ^)vs O 2 ( v -™)v V =
T(^).
Utilizing this computation in the second step below, we have T(
'
= A ( Si2 ( V ^ ) V S o 2 ( V ^ < ) v V ^ /€ fe 3 V
/(i)=0
/(«) = 1
/(i)=2
( Si2 ( V V S i 2 ^ V S 0 2Xj V <J'J
( Si2 ( V -^vVj)vso 2 ( v - ^ v x ; ) v v k
fe 3,j
\
f(i)=0
f(i) = l
f(i)=2
Finally, we deal with just one of the three universal quantifications.
= VV2 A ( S 1 2 ^ V S o 2 X i V<7.) i
= A Vv2(Sl2V'iVSo2Xi VfTi) i
= A -'3V2-.(Sl2V'i V So2Xi V (Ti)
nffiv
7. ALGEBRAIC LOGIC
i A -i(3V2(Si2-iipi
A Sce^Yi) A -wr»)
V2 ^ freef-iCTj) for all
«*>
/ \ (S12F V S02F V (-.(-.^ I ->X<) V at
If ip g Fm 3 ( 2 )(£), then there are ip,Xi® G ^ ^ f° r some fe < w such that A(
* V (Tj), SO tp = VVaG(
v2
= T(VV2G(rf) = / \ (S12F V S02F V (-.(-.^i I -.x<) A ffi) = /\(-(^»hxi)A(ri). But this last formula is in Z.
D
Although the computations in the proof of Th. 552 use the notion of semantic equivalence, each instance could be justified on the basis of simple rules of probability in first-order logic. This produces a stronger theorem, obtained by replacing = with a smaller relation based on provability; see Th. 568 below. The next theorem and its proof are quite similar to Th. 543 (ii) and its proof. Theorem 553 (Maddux [139, 11(4)], [156, 4.3]). Assume £ is a binary relational language. (i) 5mg(2)/= *s a free representable relation algebra on \1Z\ generators. (ii) 3fni3(2)/= is RRA-freely generated by {VQRVI/= : R € 1Z}. PROOF. From Th. 552 and Th. 549 we know that 3tos(2)/= is a representable relation algebra and that {voi?vi/= : ii 6 Tt} generates §1113(2)/=. To complete the proof we need only show that every mapping of {voiZvi/= : R € Tt} into a representable relation algebra can be extended to a homomorphism. Let / be a function mapping {voi?vi/= : ii g 71} into a representable relation algebra St. We wish to find a homomorphism / ' from $m 3 ( 2 )/= into SI that extends / . Since SI is representable, it is isomorphic to a subalgebra of a direct product of square relation algebras. Hence there is an index set I and disjoint sets Ui for i £ / such that SI is isomorphic to a subalgebra of Yliei ^ e (^*5- Let g be an
5. FREE RRAS OF FORMULAS
isomorphic embedding of 21 into Yitei ^ e (^*) anc^ ^e^ P' ^ e ^ n e projection function from Y\,ieI^^{Ui) onto 9le(t/;). For each i £ /, create a interpretation Ali by setting for every R E 1Z. By Th. 549, the restriction of DenMi to Fm3(2)(£) is a homomorphism from 5^3(2) into 9le {Ui). Define a homomorphism /i from 5m3(2) into fTie/*He (f/i) as follows. For every (p E Fm3(2)(£) let
By Th. 549, if
:ie
I)
Applying g'1 yields /'(v o flvi/=) = p-^fcCvoiJvi)/^) = /(v o flvi/=). D The next theorem is an immediate consequence of Tarski [227, Th. 5.24] or Tarski-Givant [240, 3.9(iii)(73)(e)], which are, however, strictly stronger results because they deal with provability in Cf, rather than semantic equivalence. Theorem 554 (Tarski). Suppose £ is a binary relational language. If
548
7. ALGEBRAIC LOGIC
a homomorphism from the predicate algebra ^5 into *Re (M). These two homomorphisms must be the same because they agree on the generators of ?p. Indeed, if R £ 11 then, by (7.37), RM = Den M (v 0 Bvi) = DenM (f(R)) = DenM(h(R)). In particular, Den M (v 0 Avi) = AM = DenM(h(A)) = DenM(iP) = DenM(
that VvoVvl(vo^vi) = Of^tO = l, sovs = Ot^tO = l. A more direct proof of Th. 554 can be obtained given by suitably modifying the mapping T denned in the proof of Th. 552 so that it more closely resembles the original translation mapping H of Tarski-Givant [240, §3.9]. This new map, which we call H because of its resemblance to H, has the property that for every formula
H(vo-Rvi) := v o 0v 2 V v 2 0vi V v o i?vi = v 0 i?vi,
(7.63)
H(VIRVQ)
:= voOv2 V v 2 0vi V vo-Rvi = viiZvo,
(7.64)
i7(vi_Rv2) := voOv2 V v2-Rvi V voOvi = vi_Rv2,
(7.65)
i7(v 2 iZvi) := voOv2 V v 2 i?vi V VoOvi = v 2 iZvi,
(7.66)
H(v0Rv2)
:= vo-Rv2 V v2Ovi V v o 0vi = v o Ev 2 ,
(7.67)
i7(v2iZvo) := voBv 2 V v2Ovi V VoOvi = v2iZvo,
(7.68)
H(v o iivo) : = v o 0 v 2 V v 2 0 v i V v o ( i i - r ) ; l v i =
(7.69)
H(viRvi)
(7.70)
H(v2Rv2) :=vo(l;(R-
:= v o 0v 2 Vv 2 0vi V v o l ; ( i i - l')vi V))v2 V v20vi V v o 0vi = v 2 i?v 2 .
The other possibility is that the atomic formula
B + ~A B) f Ovi
5. FREE RRAS OF FORMULAS
549
Next suppose tp,tp' G Fm3~(£) and that there are k,k' G LU, A, B,C G *II, and A',B',C e * ' n such that H(V) = /\ (vo
(7.71)
i
(7.72)
ff
(^') = /\ j
We then let
:= f\ f\ ((v( o( ^ ^
(7.73)
/€fc3 V f(i)=0 V f(i)
vo(( (7.74)
H(
v2(
^
(vo( ^ 1 7
BT+B;)VIVVO(
/(«) = !
(7.75)
/\
^
CT+
/(«)=2
^"(Vvo^) := / \ (v o 0v 2 V v 2 ( i i f Ci) + i
(7.76)
H(Vvlip):=
f\ ( v o ( C i t £ i ) + ^V2 V v 2 0vi Vv c 0vi) =Vvl i
(7.77)
H(VV2
(v 0 0v 2 Vv 2 0vi
ik
The first two semantic equivalences involve only propositional calculus and the meanings assigned to the predicate operators, while the last three also involve some elementary facts about quantifiers. To prove Th. 554, we start with some tp € Sent^"(£). Since
= /\ (voOv2 V v20vi V vo(Ai f B{) + i
-A
7. ALGEBRAIC LOGIC
and then tp = VV0Vvlip
= Vv0Vvl (v0 f j ((Ai f Bi) + d) vi) i
The original mapping H of Tarski-Givant [240, §3.9] has nice properties not shared by the mapping H defined above. For example, from Tarski-Givant [240, 3.9(iii)($)] we have free(
iff * h* A = B.
It follows from Th. 556 and (7.30) that h£ A = B iff \~t A = B. This notationally curious result (which suggests that the passage from 3 variables to 4 variables has no effect in the power of proof) is due to the fact that the associativity axiom schema (AX) is included in the axiom set for £3"; see TarskiGivant [240, pp. 92^93]. 6. SAs and RAs of formulas Assume £ is a nice language and 3 < n < u. In Th. 550 we saw that the semantic equivalence relation = is a congruence relation on Sin^ 2 j and the quotient algebra §m^/2x/= is in RRA. Here we prove similar theorems with provable equivalence in place of semantic equivalence.
6. SAS AND RAS OF FORMULAS
551
Recall from p. 215 and p. 217 that, for an arbitrary nice language £, \-hn is provability in Fm+(£) using axioms (HI), (HII), (HIII'), (HIV), (HV), (HVI'), (CVII), (CVIII), (AIX*), (DI)-(DV), and the rules MP and Gen. In case C is binary relational language, we can refer to schemata (HV) and (HVI) instead of (HV) and (HVI'). Define a binary relation ~hn on Fm+(£): (7.78)
V-ni>
iff
\~n V <=> V>
for all formulas cp, tp 6 Fm^(£). Next we have a sequence of theorems leading to a proof that if 3 < ra < n then (7.79)
5m+ ( 2 ) /~^ <E SA,
(7.80)
Sm+ ( 2 ) /~^ e RA if 4 < n.
First we have a consequence of the Propositional Completeness Th. 147. Theorem 557. Assume 3 < m < n. Then (i) ~ ^ is a congruence relation on the algebra (Fm m (£), V, -i), and the restriction of ~ ^ to Fm^, 2 ,(£) is a congruence relation on the algebra (ii) The quotient algebras (Fm+ (£), V, -,) /~hn and ( F m + ( 2 ) ( £ ) , V, -,) /~hn are Boolean algebras. PROOF. TO show that the congruence conditions and the Huntington axioms hold it is enough, by the definition of ~ ^ and the propositional completeness theorem, to check that the following formulas are tautologies whenever
(
iy) v v>)) <^ ¥>
Theorem 558. Let ip, ip £ Fm^ (£) and x, y 6 Vn. Then (7.81)
w u
- ~'h
(7.82)
!
(7.83)
if tp —n ip then V^^? —n Va;^,
(7.84)
if ip ~n ip then 3X<^> ~n
3xip,
:
(7.85)
\?'xisp h 0) — n ^x^P A V^^,
(7.86)
3x((p V ip) ~hn 3x(p V 3xip,
552
7, ALGEBRAIC LOGIC
(7.87)
if x £ free(p) then Vx(ip V ^ } ^ p V V ^ ,
(7.88)
ifx $ free(ip) then Ux(
(7.89)
if x £ free(p) tften
(7.90)
t/a; £ free(p) tften
(7.91)
v i = v i A v? ~ i v»= V i A S , ^ ,
(7.92)
tf
(7.93)
ip A 3*$,
V^,
v<,v,- ^ free(9?), iften H^
PROOF. (7.81) and (7.82): By Th.157, Th.140, and Th.147. Proof of (7.83): i. v =» ^
Hyp-
2. h ^ =4- ^ ,
l-» ^ =* V
Th. 147, Th. 140
3. V-l Vx(
h^ V^^ ^ V ^
Gen Th. 158, Th. 140
5. V ^ =» V,,^
Th. 147, Th. 140
Proof of (7.84): From
h^ V,^ =* ^
(CV)
h-hn%tp A\!mtl> ^> tp Aip h
3. h n%(%VA%rP
Th. 147, Th. 140
^
Gen
4. h£ V ^ A VsV => Va (v? A V) 5. h^ %(tpAtl> =4- p),
(HIV), Th. 140
h ^ V ^ ^ A ^ =S- ?/<),
6. h^ Va (v? A V) => V^^,
h i Va (v? A V) => VK^
Th.147, Gen Th. 158, Th. 140
7. h i %(
Th. 147, Th. 140
8. Vs. (tp A V) =£ Va y» A V,,^
4, 7, Th. 147, Th. 140
Proof of (7.86): This follows from (7.85) by Th. 147 and Th. 140. Proof of (7.87) and (7.88): Both paxts follow from (HIV), Th. 147, and Th. 140. Proof of (7.89): 1. h i V,. (99 => ip) 2. h i
Th.147, Gen (HIV), Th. 140
3. h\vm
(CV)
4. 9? ~ i yxip
2, 3, Th. 147, Th. 140
6. SAS AND RAS OF FORMULAS
553
Proof of (7.90): This follows from (7.89) by Th. 147 and Th. 140. Proof of (7.91): For step 2, note that tp = SijSijtp. 1. h-hn Vi= Vj - => (tp => Sijtp) h
(AIX*)
2. \- n v i = v j => (Sijtp => tp)
(AIX*) applied to Sijtp
3. Vi=Vj A ¥3 ~Jl Vi=Vj A Sij v?
1, 2, Th. 147, Th. 140
Proof of (7.92): If i = j the desired conclusion follows from Th. 147. Therefore assume i ^ j . We have 1. Y-^ Vj=Vj => (tp => Sy^>) h
2. \3.
n
-n(tp => Sijtp) => ->Vi=Vj
\-n V V i (-'(y => Sy-y) => - I V J = V J )
4. h^ -.(p => Sijtp) => Vv.^Vi=Vj h
5. Y- n -.V V ;-iVi=Vj => (95 => Sijtp) 6.
\-
h n
tp => Sijtp
h
(AIX*)
Th. 147, Th. 140 Gen
(HIV), Th. 140 T h . 147, T h . 140 (CVII), Th.140
7. \- n Sijtp ^ tp
Th. 156
8. tp ~hn Sijtp
6, 7, Th. 147, Th. 140
By Th. 550, the semantic equivalence relation is a congruence relation with respect to which the quotient algebra 3rn+ ( 2 ) /= is in RRA. The following Th. 559 says that if we replace semantic equivalence with provable equivalence using 3 or 4 variables, we again get congruence relations with respect to which the quotient algebras are in SA or RA, respectively. T h e o r e m 559 (Maddux [139, Th. 11(15)(21)]). Let C = €(0,^,11, a nice language and 3 < m < n. Then (i) ~ ^ is a congruence relation on 3rci^(2)
rank) be
(iii) If 4
7, ALGEBRAIC LOGIC
Axiom Rg holds in 3in^(2)/—» because (
2¥> A S02C V Snip A S02C)
Th. 557, (7.83) (7.85)
Axiom Rg holds in | m i 2 > / ^ because
(7.91), Th. 557, (7.83)
~^A3V2(v2=vi)
(7.87)
h
~ ntp
(CVII), Th.147
Axioms Rr and Re hold by (7.46) and (7.47), respectively. Axiom Rg holds in | i t i L 2 ) / - i j because
(SiaSoi^ A S02S01V?)
Th. 557, (7.83)
Proof that axiom Rio holds in 3'm+^2^/~^,: We wish to show that
= - i 3 V 2 (S12S01V A - i 3 V 0 (S02S12V = - i 3 v a (SO2S1293 A - i 3 V 0 (So2Sl2(£ A if)))
=» VV2 (C ^ 3v0 (C A
tf))
Th. 557, (7.83)
so is suffices to prove (7.94)
K^^VV2(£^3V0(£A^)),
and we do so as follows: l-»VvO--tfAtf) =>-.(£AV)
(CV)
^
Th.147
=> (€=> 3vo(CA^)
l-»Vva(tf => (£=>3vo(£Atf)) h ^
=> VV2(C => 3V0(C A
Gen tf))
(HIV), Th. 140
6. SAS AND RAS OP FORMULAS
Proof that the semiassociative law holds in 3rn+ ( 2 ) /~^: First note that m(2)/—™ ^Sa n o n a s s o ciative relation algebra because axioms R5-R10 hold, so T ~ n T|T. It therefore suffices to prove v?|T|T ~ ^ <^|T. First note that T ~ ^ S02T by Th. 147 and Th. 140, since T and S02T are tautologies. Then
Th. 557, (7.83)
=i3»i9
(7.89)
~^Si 2 3 v l y>
(7.92)
~hn 3 V 2 (Si 2 y A S 02 T)
Th. 557, (7.83)
Proof of (iii): "We have (p ~ ^ S23V and ip ~ ^ 823^ by (7-92), so ip\ %j> ~ ^ S23VI S23V1 by (i). Applying (7.92) once more, we get tp \ ip ~hn S23(S23y | S231P) = S233V2 (Sl2S23V? A 502523^) = 3v3 (Sl3¥? A SosV1)Proof of (iv): By (i) we need only check that the associative law holds. £
(7-92), (i)
~ ^ 3 V 2 ( S i 2 3 V 3 (Si 3 S23^ A S03ip) A S02S23C)
(iii); ( 0
= 3 V 2 ( 3 V 3 (Si3
~hn 3V23V3(S13
AS03S02C)
(7.87), Th. 557
~Ji 3 V 3 (Si3^ A 3V2(So3Si2V' A S03S02C)) (7.81), Th.7.87, (7.83) A So33v2(Si2V' A S02C)) (m) D Theorem 560. If C = C(C, J-, 1Z, rank) is a nice language, 3 < n, and the function h : II —> Vm~^,2AC) is defined by h(A) = voAvi/~^ for every A £ II, then h € + ^ PROOF. It suffices to show
h(A + B)~hnh(A)Vh(B), h(A) ~hn -nA(A), h(A;B)~hnh(A)\h(B), h(A) ~hn h(A)°.
7. ALGEBRAIC LOGIC
5
By the definitions of h, ~5», |, and °, these statements axe respectively equivalent to ~n V0A + B v i «
(V O AV
Y-hn V O A V I
Each of these last four statements can be easily proved by appealing to instances of (DI)-(DIV), respectively, along with some instances of (GV). Let * C Sent x (£) and tp e Sent x (£). By Tarski-Givant [240, 3.9(11)], if * h x tp then * I-3" tp. As part of a detailed proof of this result one would show that Kj~ £ whenever £ is an instance of (BI)-(BIII) or (BV)-(BX). However, in carrying out this task it is not necessary to ever use any instance of (AX), because such instances are only required for the case in which x is an instance of (BIV). Therefore, if * H* tp then 4 and
\-hn C = D
(7.96)
Y\ Vv 0 V vl (v 0 Cvi « voDvi)
(DV), prop. cal.
(7.97)
Y\ VOCVI
Gen, (CV), prop. cal.
(7.98)
v 0 Cvi ~n vo-Dvi
(7.78)
(7.99)
h(C) = h(D)
def. of h
> voUvi
If C = D is an instance of one of the axiom schemata (BI)-(BIII) or (BV)-(BX), then h(C) = h(D) because, by Th. 559(ii), h is homomorphism into a quotient algebra that satisfies the corresponding axiom for SA, namely, R1-R3 or R5-R10, respectively. If C = D is an instance of (BIV'), then h(C) = h{D) by Th. 559(ii) and (6.187). If C = D is an instance of (BIV) and 4 < n, then h{C) = h{D) by Th.559(iv). D
7. ALGEBRAIC SEMANTICS
557
7. Algebraic semantics Suppose that £ is a binary relational language. For such languages, we will generalize ordinary semantics into what we call "algebraic semantics", perhaps more properly described as "relation algebraic semantics". As motivation for the upcoming definitions, consider an interpretation M for C. How could we describe the interpretation M. in algebraic terminology? Notice that M / 0 and RM C M2 for every R £ 71, so RM is an element of the square relation algebra 9te (M). This assignment of relations to relation symbols extends to the homomorphism (-)M from the predicate algebra ?P into the square relation algebra %\t{M). Every square relation algebra is atomic and in RRA. We will generalize these notions by considering maps from 1Z, (and the homomorphisms on ty$ they determine) to atomic algebras in NA, SA, and RA. In terms of the given fixed interpretation M. for £, the satisfaction relation M. \= -[-] is defined as a binary relation between formulas tp € Fm+(jC) and sequences s £ "M, We therefore need an algebraic replacement for WM, and, since we wish to consider languages with finitely many variables, we also need to generalize from w to 1 < n < w and find an algebraic replacement for nM. A sequence is a function from w into M, but we can also describe each sequence as a function from aj2 into the universe of 9le (M). Indeed, each sequence a 6 " M determines, and is in turn completely determined by, a function a : u)2 —> M defined, for all i,j < w, by (7.100)
o«
Notice that {(SJ, SJ)} is not only an element of 9le (M), but an atom of !He (M), Furthermore, the atoms of Dte (M) in the range of a are linked together, for if i,j, k < n then an Q l'su(M) = M ,
These are the essential properties of a, for if a were an arbitrary function from w2 to atoms of -We (M) having these properties, then a would have to arise from some sequence * € UM according to (7.100). In this way, every s 6 UM corresponds to a basic matrix a G Bu9ie(M). In showing that various formulas are logically valid, we use certain properties of UM (and BulQie(M)) that have been used in he definition of semantical basis. It is the notion of semantical basis that serves as our algebraic analogue of WM. For 3 < n < w, an n-dimensional algebraic
interpretation .4= (21,
,
for a binary relational language £ consists of an atomic semiassociative relation algebra SI € SA, a map (-}A that assigns each relation symbol R € TZLS {=} to an element RA of 21 such that =A = l'a, together with an n-dimensional semantical basis N C B B a for a.
S5S
7. ALGEBRAIC LOGIC
It is essential for some of the later results that the algebra SI of an algebraic interpretation be in SA. However, if in this definition we assume only SI € WA instead of a 6 SA, then we may conclude by Th. 334(ii) and Th. 335(vii) that the algebra of an algebraic interpretation is nevertheless in SA. If the algebra 21 in an algebraic interpretation A is an atomic RA, we may refer to A as an algebraic RA-interpretation. For example, if n > 4 then every n-dimensional algebraic interpretation is, in fact, an algebraic RA-interpretation by Th. 334(ii) andTh.335(viii). The definition of algebraic interpretation adopted here is modelled after that of algebraic realization, defined in [139, p. 200] as a complete atomic 21 G SA, a map from TZ into A, and an n-dimensional cylindric basis N (where cylindric basis is defined, however, with Th. 333 (ii) in place of (6.99)). The conditions (6.98) and (6.96) are not needed for some semantical purposes so, for example, in [143, p. 78] an n-model is defined as a complete atomic St € SA, a homomorphism h from the predicate algebra $p into SI, and a set N C BnSi such that (6.95) and (6.97), but not necessarily (6.96) or (6.98). Every n-dimensional algebraic interpretation A supplies a denotation for every binary relation symbol in TZ and for the equality symbol = . We extend this to all predicates. For every A G II, let AA be the image of the A under the unique extension of the map (RA : R e U, rank(.R) = 2) to a homomorphism from the predicate algebra *$ = (II, +, ~, ;,w, 1'} into St. Thus A determines a unique homomorphism (-)A from $P into SI:
For every n-dimensional algebraic interpretation A for C and all A, B 6 I I , we therefore have (7.101)
(A + B)A := AA + BA,
(7.102)
(A)A := I *
(7.103)
(7.104)
(A;B)A:=AA;BA,
(I)* 4 := (AAy.
The operations on the left sides of these equations are part of the predicate algebra, while the ones on the right sides are the operations of 21. Notice also that "R, C II since there are no non-binary relation symbols in a binary relational language. The algebraic satisfaction relation associated with an n-dimensional algebraic interpretation A is the unique binary relation determined by the following rules. If A, B G I I , i,j,k < n,
(7.105)
A^A = B[a] iff aOi < Of^"4 8-B-4) f0,
(7.106)
A ^ ViAvj [a] iff ay < AA,
8. ALGEBRAIC SATISFACTION AND SUBSTITUTION
(7.107)
A\^-«p[a]
(7.108)
A ^
(7.109)
.A ^ VVfc 9? [a] iff A ^ 9? [6] whenever 6 £ iV and (a, 6) £ I*1 (21).
559
iff A¥=
J£A\=
(^)[a]
iff AP
PROOF. The proof is by induction on formulas in Fm^(yC). The theorem holds for ViAvj, where i,j
A ^ viAvj [07] Next we prove the theorem for the other atomic case, where
Then (7.110) and (7.111) are equivalent, respectively, to
(7.112)
aOi<0fa;t0,
(7.113)
(07)01 < 0 fa; f0.
7, ALGEBRAIC LOGIC
Assume (7.112) holds. Then (7.113) also holds since {0.7)01 = aT(o)7(i)
< o7(o)o ;«oi; 017(1)
(6.94), Th. 265 Th.265, y <\ (7.112), Th.265 Note (a) below
Note (a): The set leSl of ideal elements of SI is defined in (6.14). Since St E SA we may applj Th. 355 and conclude that 1 ;x; 1 € Je2t. By Th. 305 (for which we need only know 21 E NA), leSl is closed under complementation, hence 1;«;1 € JeSt. But 0 f a; f 0 = 1 ;¥; 1, so 0 f as f 0 is an ideal element. Consequently, 1; (0 f x f 0) = (Ofa:tO);l = Ota:tO. By similar reasoning, (7.113) implies (7.112). In this part of the proof we used the assumption SI E SA. Up to now we have only needed to know that 21 E NA. If the theorem holds for ip then it holds for ->ip since the following statements are equivalent:
A^^ip [a-y] Similarly, if the theorem holds for ip and f then it also holds for ip => f. To complete the proof we assume the theorem holds for iji and prove it for Vv^, where i
h{vt) $ (J{var(fefe)) : y G Vn, h{y) / y / v<},
(7.116)
Sub M (V v ^) =V h ( v i ) Sub w (^).
£ has no constants and no function symbols, so Tm n (£) = V» and (7.115) reduces to ft(vj) ^ {h(y) ". y € V, ft(y) ^ V ^ v i}- The function ft therefore arises from a corresponding function /> : n —> n. In fact, h — p where p = vlfelv"1. The properties of h, restated in terms of p, are (7.117) (7.118) (7.119)
p(j) = f(J) whenever i ^ j € n,
8. ALGEBRAIC SATISFACTION AND SUBSTITUTION
5
Let Ni := T/*(2l) n N2 for every i < n. Consequently, the statements A SubK1 (ip) [a] and A \^= ip [07] are equivalent, respectively, to (7.120)
if 6 Npii) a then A ^ Sub[/5](V>) [b]
(7.121)
if b Ni a-y then
We need only prove that (7.120) and (7.121) are equivalent. Suppose (7.121) holds. Assume 6 Np(i) a.
(7.122) If j , k ^ i, then = ap{j)p{k) = bpU)p{k) =
(7.118) (7.117), (7.122)
(bP)jk,
so 07 Ni bp. Also, bpe N since 6 € N, by (6.100) and (6.101). Hence A\^ip [bp] by (7.121). The theorem is assumed to hold for ip, so A \^ Sub^\ip) [b], which shows that (7.120) holds. Now suppose (7.120) holds. Assume b Ni 07. Since property (7.118) implies that ap Ni wy, this assumption implies (7.123)
6 Ni ap.
Pick some I 6 {p{j) : i ^ j £ «} Choose a : n —> n so that for all k < n, p(a(k)) = k whenever k £ Ra(p), and p{a(k)) = I whenever k £ Ra{p). Let n~Ra (p) = {mo, rnp-i}. Then (7.124)
/9o
= [mo/Z]o...o[m /3 -i/Z],
(7.125)
poao
(7.126)
/, mo,... ,mp-i
p =p , are distinct.
In particular, p o a is the identity on n if /3 = 0, i.e., n = Ra (p). It follows from (7.117) and the definition of a that (7.127) (7.128)
t = ap(i), p{i)^l,mo,...,mp-i.
An easy consequence of (7.123) and (7.127) is (7.129)
ba Np(i) apa.
From 6, a 6 N we also deduce, by induction using (6.100) and (6.101), that (7.130)
ba,apaeN.
It follows by Th.333(vi) from (7.124), (7.126), (7.128), (7.129), and (7.130) that there is some c £ N such that (7.131)
c Np(z) a,
(7.132)
ba = cpa.
7. ALGEBRAIC LOGIC
Next we prove b = cp.
(7.133) Assume (7.134)
j , k j= i.
By (7.117) and (7.134) p(j), p{k) ^ p( i), which is equivalent, by (7.125) and (7.127), to (7.135)
Then (7.123) , (7.134)
Cp(j)p(k)
(7.131) , (7.135)
1
II 1
bjk = (ap)jk
We have &jCTp(j) = bij since
(6. 94)
bj
= bij;
(7- 123), (7.134), (7.135)
< bij; 1'
(7- 125) (6. 92)
<&«,,
Re (6. 94) (7- 123), (7.134), (7.135)
=
biat>(i) 'i pU)p"pU) a
= bl
bilTf>(i) i-*-'
= h,t
(7- 125) (6.92) Re
so {cp). H = {c.pop)ij = (^p)ii
(7.125) (7.132)
v
=
biap<j)
(7.127)
and, similarly, using Th. 270, we get {cp)ji = bjt. Finally, (cp)u = (cpap)ii
(7.125)
8. ALGEBRAIC SATISFACTION AND SUBSTITUTION
= (bap)u
563
(7.132)
Otrp(i)trp(i)
= ba
(7.127)
This completes the proof of (7.133). By (7.120) and (7.131), A ^ Sub[/i](V>) [c]. But the theorem holds for ip, so A ^ ip [cp\. Thus A ^ ip [b] by (7.133), which completes the proof of (7.121) from (7.120). The next theorem should compared to Th. 132. Theorem 563 (Maddux [146, Lem. 20]). Let 3 < n < u), and let A be an ndimensional algebraic interpretation for a binary relational language C with atomic algebra 21 E SA and semantical basis N C Bn%. For all ip E FmJ(yC), k < n, and a,b E N, i/v/c ^ free(^j) and a agrees with b up to k, then -4F^H
*# -4 ^if [b].
PROOF. The proof is by induction on formulas in FmJ(£). Suppose that if = ViAvj for some A E II. Assume v^ ^ free(^j) = {vi,Vj} and a agrees with 6 up to k. Then k ^ i,j and a^ = bij, so the following statements are equivalent: A ^ VJ AVJ [a] atJJ < AA btJ < AA
j [b]
Assume ip = A = B and a agrees with 6 up to k. Let y := AA Q BA. following statements are equivalent:
601 < 0 f y 10
Then the
Note (b) below
A ^ A = B [b] Note (b): If k 0,1 then aoi = fooi so the equivalence is trivial. Suppose k = 0 and a No b. As was shown above in Note (a), p. 560, OfyfO is a n ideal element of 21 since 21 € SA. Hence boi
(6.94)
= &02; «2i
a
Nob
< 6o2;(a2o;aOi)
(6.94), Th. 265
<&02;(a 2 o;(0t2/t0))
aoi < 0 f 2/10, Th. 265
7. ALGEBRAIC LOGIC
Th.265 One can similarly deduce 001 < 0 f y f 0 from 6Oi < 0 f y f 0. Next let ip = -
[a]
Similarly, if the theorem is true for ip and £, then it is also true for ip => £. Finally, suppose (p = VVi'tp f° r some ip £ Fm^(£) and i < n. Assume the theorem is true for ip, Vk fi free(tp), a agrees with b up to k, and (7.136)
A\?=VViip[a]. 1
To prove A \= Vv;*/ [6], we assume c e N, c agrees with 6 up to i, and show that A \= ip [c]. If k = i, then c, 6, and a all agree up to i, and it follows immediately from (7.136) that A \S= MViip [c]. We may therefore assume k ^ i. Since c agrees with a up to k, i, we conclude by (6.99) that there is some b' which agrees with c up to k and agrees with a up to i. From (7.136) we get A\= ip [&']. Since the theorem holds for ip and Vk £ free(ip), we get A \= ip [c]. Similarly, if A \= Vvtip [b], then A \= yviip [a], so the theorem is true for VViip. 9. Algebraic soundness Next is the Soundness Theorem for algebraic semantics, corresponding to the Soundness Th. 141. It shows that every instance of every axiom schema in §6.4 except (AX), (AX'), and (BIV) is algebraically 3-valid. T h e o r e m 564 (Maddux [146, Th. 22]). Suppose that C be a binary relational language, 3 < n < u, ip £ FmJ(£), and (p is an instance of one of these schemata:
(AI)-(AIX), (AVI'), (AIX'), (AIX"), (AIX*), (DI)-(DV), (BI)-(BIII), (BIV), (BV)-(BX), (LI)-(LIII), (HI)-(HVII), (HIII'), (AVI*), (CIV)-(CVIII). Then ip is algebraically n-valid. PROOF. Assume 3 < n < LJ. Let A be an arbitrary n-dimensional algebraic interpretation with atomic algebra 21 6 SA and semantical basis N C Bn2t. Let Ni := T;n(2t) fl N2 for every i < n. We wish to show A \= ip for every instance (p of the listed schemata. Validity for tautologies and closures. Every tautology is algebraically n-valid. The proof of this fact is the same as the proof of Th. 130(i), but uses (7.107) and (7.108) in place of (4.56) and (4.55). Every instance of schemata (HI)-(HIII), (HIII'), and (LI)-(LIII) is a tautology and is therefore algebraically n-valid.
9. ALGEBRAIC SOUNDNESS
565
Next we prove that A \= Vv;¥> ifi A \=
A F V V i ( ^ => ip) => (tp => VV;V) H
whenever v, ^ free(y>), and, in all cases, (7.138)
A\^VVi(tp
=> V) ^ (Vv ; ^ => V Vi V)W-
For both of these statements we may make the same hypothesis, namely, (7.139)
A£VVi(
=> i/>)[a].
To prove (7.137) we may also assume v; ^ Uee(ip) and (7.140)
A\S:
while to prove (7.138) our additional assumption is (7.141)
A\^VVi
In both cases our desired conclusion is (7.142)
A£\/Viip[a].
To get this conclusion we assume b Ni a and prove A \= ip [b]. Under the assumption that VJ 0 free(tp) and (7.140) we may apply Th. 563 to conclude that (7.143)
A \*
while if we assume instead (7.141), then we get (7.143) directly from (7.141). From 6 N a and (7.139) we get
566
7. ALGEBRAIC LOGIC
so, combining this with (7.143), we obtain A \= ip [b], as desired. Every instance of schema (AV) is the closure of an instance of (CIV), and hence is algebraically n-valid by what has been shown so far. Some instances of schema (AVII) are closures of instances of (GVI), but, because of the restriction in (CVI) that the variable not occur in the formula at all, there are some instances of (AVII) that are not closures of instances of (CVI). However, all instances of both schemata can be seen to be algebraically n-valid if we show validity for every formula ip => yViip whenever v» ^ free(^). To do so, our desired conclusion is once again (7.142), this time under the assumption that A \^ ip [a] and vj ^ free(^>). For this goal it suffices to notice that if b Ni a then A\^ip[b] by Th. 563. Validity for (AVI), (HV), (AVI*), (CV), and (AVI'). Every instance of (AVI*) is an instance of (AVI). Instances of (AVI) are closures of instances of (CV). Every instance of (CV) is an instance of (HV). In general, every instance of (HV) is an instance of (HV'), but not conversely. However, for a binary relation language there are no terms other than variables, so the two schemata (HV) and (HV') actually coincide. Schemata (AVI') and (HV) are clearly related. They both attempt to catch the idea of instantiation, that if a statement is true for everything (it begins with a universal quantification) then it is true for each particular thing. However, the two schemata express this idea by means of different substitutions. Schema (AVI') use a good substitution defined by Tarski-Givant [240], while (HV) uses the classical form of substitution, which is not a good substitution. Because of these considerations, we will only show algebraic n-validity for schema (HV) and for formulas whose closures are instances of (AVI'). Consider the formulas tfvi/vj],
(7.144)
Vv^ =
(7.145)
VVi(p => Sub^.p,
where if € Fm£(£), i,j < n, and v,- is free for v* in tp. We will show that both are algebraically »-valid. In both cases we assume a € N and (7.146)
t[a]-
We wish to show A |= ¥?[vj/vj] [a] and A \= SubvJ tp [a]. For the first of these two desired conclusions we are dealing with a particular good substitution Sub'-'-'(-) such that p[vi/vj] = S u b ^ ^ ) where 7 = [i/j]. It happens that this good substitution does not needlessly respell bound variables, that is, in (4.44), the function h is chosen so that h(x) = x whenever x ff. \J{var(g(y)) : y € Vn, g(y) =£ y ^ %}. In general, good substitutions and ordinary substitution produce different results. However, as can be seen by a straightforward induction, any good substitution that does not needlessly respell bound variables will produce the same result as the ordinary substitution of a term t for a variable a; in a formula ip whenever t is free for x in. ip. Consequently we also have Subjtip = Sub^-'(^). What we therefore wish to prove is, in both cases, simply A |= Sub^-'(y>) [a]. By Th. 562 we have »4 \= Sub^(ip) [a] iff A |= tp [o/f], so we need only show A\=tp [aj], which will
8. ALGEBRAIC SOUNDNESS
567
follow from (7.146) if a Ni 07. But 07 = a[«/j], so it is an immediate consequence of the relevant definitions that a JV» 07. Validity for (AVIII), (CVII), and (HVI). Consider an instance of (CVII), say 3 Vj (VJ=VJ) where i ^ j . For a given a € N, we wish to show A |= 3 Vj (VJ=VJ) [a]. By unwinding the meaning of this statement according to the definition of |=, we see that we need to find some b such that b Ni a and by < l'a- Such a b can be obtained simply by letting b = a[i/j], for then we have 6 € iV by (6.100), 6y = a[*/j]y = OJJ < 1' by (6.92), and b,a agree up to * by the relevant definitions. Thus 3 Vi (vi=Vj) is algebraically n-valid. Every instance of (AVIII) also algebraically n-valid because it is the closure of an instance of (CVII). Every instance VJ=VJ of (HVI) is also algebraically n-valid because, for every a 6 N, A f= VJ=VJ [a] iff an < V, but the latter statement holds by (6.92). Validity for (AIX), (CVIII), and (HVII). We consider a single nontrivial case of (CVIII), namely Vi—Vj => (viAvk => VJAVJ.). To show that ^4 is an ^-dimensional algebraic model of this formula, we assume a € N, A |= v»=Vj [a], and A \= VJAVJJ [a]. We wish to show that A \= VjAv^ [a]. From our assumptions we get (7.147) Then
aHJ < r , <
aji;aik
= < V;AA = A
A
«« < AA. (6.94) (6.93) (7.147), Th. 240, Th. 265 Th. 269, Th. 270
so A f= v/Avfc [a]. Similar computations show the algebraic n-validity of every instance of (CVIII) and also of (AIX), since every instance of (AIX) is the closure of an instance of (CVIII). Schema (HVII) expresses the same idea as (AIX), that one may legitimately substitute equals for equals, but there are instances of (HVII) that are not instances of (AIX), and instances of (AIX) that are not instances of (HVII). An instance of (HVII) has the form Vi=Vj => (
(6.94)
7. ALGEBRAIC LOGIC
< f; aih
an < 1', Th. 240, Th. 265
= aik
Th. 269, Th. 270
(6.94)
ay
= aih
Th. 270
and (7.149)
a[i/j)M = < o>ki; a y
(6.94)
ay < 1 ' , Th. 265 R6
<««;%»
(6.94)
= ahj;(anY
(6.93)
ay < 1 ' , Th. 240, Th. 265 Th. 269, Re
= Oki
Validity for (AIX'), (ADC"), and (ADC*). We will prove algebraic n-validity for the two formulas VJ=VJ => {ip => ^[VJ/VJ]) and VJ=V.,- => (y> => Sij-y>),
where y? 6 Fmit(£) and i, j < n. The closure of the first one is an instance of schema (AIX'), the second is an instance of (AIX*), and its closure is an instance of (AIX"). We may as well assume these instances are nontrivial in the sense that i ^ j , because trivial instances can easily be shown to be algebraically n-valid on the basis of earlier observations (they are tautologies). For both instances we have the same assumptions, namely, a € N, A f= Vj=v.,- [a], and ,4 |= tp[a]. We wish to show A \^ ¥>[VJ/V,-] [a] and A \^ Sijip[a]. The substitutions used in (AIX') and (AIX") are good substitutions, so, by Th. 562, A ^ ^[VJ/VJ] [a] iff A f= y[a[«/j]], and A |= Syy>[o] iff A \= tp[a[i,j]]. Hence it is enough to show a = a[i/j] = a[i, j]. From A |= VJ=VJ [a] we know atj < 1'. We already proved a = a[i/j) in computations (7.148) and (7.149) above. Notice that part of what was demonstrated by (7.148) and (7.149) is that from ay < 1! we get aik = ajh and au = auj for every k
A ^ v 0 A + Bvi & (vo^vi V vo-Bvi) [a],
(7.151)
» 4 ^ v 0 A v i <=} -ivoAvi [a],
(7.152)
A ^ v 0 A;Bv!
(7.153)
^t^=voivi
3v 2 (v 0 Av 2 A vaBvi) [a],
ALGEBRAIC SOUNDNESS
When we unwind the meaning of these statements according to the relevant definitions, we find that what we need to prove are these four equivalent versions of the previous four statements:
(7. 154) (7- 155) (7- 156) (7- 157)
or aoi
A
iff
aoi <
aoi <\M
iff
aoi
iff
3fc(l
h a,
iff
aio <
AA
aoi S A -f -B aOi < AA aoi f^ (-A
A
A
Y
AA AA
A
602 < A ,
621 < BA
(7.154) and (7.155) hold just because aoi is an atom of 21. An atom in 21 (or in any Boolean algebra) is (by definition, see p. 237 or p. 296) either included in, or entirely disjoint from, every nonzero element of 21. An atom is included in the join of two elements iff it is included in one or the other of the two elements, and it fails to be included in some element iff is included in the complement of that element. In one direction, the proof of (7.156) is quite simple. If b N2 a, 602 < AA, and 621 < BA then aoi = 601
b N2 a
<&02;&2i A
(6.94) bO2
A
For the converse, assume aoi < AA;BA. Since 21 is atomic, every element of 21 is the join of the atoms below it by Th. 182, and ; is completely additive Th. 296, so (7.158)
aOi
: BA > v £ Am} A
= J2U;v
>u£
-AA >u, BA >v, u,v € Am}
Am}
Th. 182 Th. 296 Th.296
If an atom is included in a join of some set of elements of a Boolean algebra, then it must be included in one of those elements (a consequence of (5.35)). Hence, since aoi is an atom, it follows from (7.158) that there are atoms u, v such that aoi < u;v, u < AA, and v < BA. By (6.98) there is some c € N such that coi = aoi, C02 = u, and C21 = v. Since n < w, we get a JV21 |iV n -i c from Th. 333(iii), so there is some 6 € N such that a N2 b N3 \ \ Nn-i c. Combining these facts, we get 602 = C02 = u < AA and 621 = C21 = v < BA. We have thus found a 6 € N such that a ./V2 b, 602 < AA and 621 < BA, which completes the proof of (7.156). Finally, (7.157) holds by (6.93) and R 7 . Validity for (DV). Now suppose tp is an instance of (DV), say A = B VVOVV1 (vo^4vi <^> voBvi). To prove that tp is algebraically n-valid we must assume a € N and show that A ^ A = B & VvoV
570
7. ALGEBRAIC LOGIC
But this statement holds iff the following two statements are equivalent:
o
V o Bvi)[a],
and these two statements are respectively equivalent to these two: aoi <0}AAeBA}0, VcV6(c iVi & No a => A ^ (v 0 Avi « v 0 Bvi) [c]),
(7.159) (7.160)
so need only show (7.159) and (7.160) are equivalent. following statements axe equivalent: (7.161)
A ^ (vo^vi «- v 0 Bvi) [c],
(7.162)
A^voAinlc]
iff > t ^ v 0 S v i [ c ] , 4
(7.163)
coi < ^ ^ iff coi < B" A
(7.164)
cox
First, notice that the
def. of ^ def. of ^
A
cox is an atom
For one direction, assume (7.159) and c Nx b No a. We get (7.164) from our hypotheses as follows. cox < co2;c2i
(6.94)
= 602; C21
c Nx b
<6oi;6ia;cai
(6.94), Th.265
=
& iVjj CE
box 5 CE12 j C21
Th. 179(i), Th. 265
< l;(aio;(aoi;aia));l
(6.94), Th.265
< l;(l;(o 0 i;l));l
Th.l79(i), Th.265
= (l;l);aoi;(l;l)
Th. 365, a £ SA
= l;aoi;l
Th. 275 (7.159), Th.265
A
A
= 0fA e B f0 A
A
Note (a) above, p. 560 Th. 278
This completes the proof of (7.160) from (7.159). For the converse, we assume (7.159) fails and show that (7.160) fails. Let r := AA QBA. Then, since aoi is an atom and (7.159) fails, we have aoi < l ; r ; l , so aia < l;(r;l) = 1; (Y^{u:r;l
> u E AM})
= ^ { 1 ; « : r ; l > M G AM}
Th. 182 Th. 296
Since 012 is an atom, there is an atom u € AtSl such that u < r ; l and 012 < 1;M. Similarly, 012 < 1 ; M = f ^ A t a l ;«
Th. 182
9. ALGEBRAIC SOUNDNESS
: v£ At%}
Th. 296
so there is some atom v £ At% such that ai2 < I>;M. By Th. 334 we know that (6.97) holds. We apply (6.97) to an < v;u and obtain b E N such that 6 No a, bio = v, and 602 = u. Once more, w :r > w £ A* 21}) ;1
Th. 182
;l : r > w £ At%}
Th. 296
so there is some atom w £ At%l such that w
Th. 296
so there is some atom x £ At% such that u < w;x. Then we apply (6.97) to b02 = u < w;x and obtain c £ N such that c Ni b, coi = w < r, and C12 = x. Since coi ^ 0 we have coi £ f = A-4 Q B- 4 , so (7.164) fails. Thus we have found b,c £ N such that c Ni b No a and (7.164) fails, which shows that (7.161) fails, as desired. Validity for (BI)-(BIII), (BlV), (BV)-(BX). Consider an instance of (BI), say A + B = B + A where A, B £ II. Let a £ N. We have 4
+ B)A = (B + A)(A + B)Ae (B + ^)^ = 1 Of (A + ByL e (s + Ay to = 1 aoi < 0 f((yl + jsye(B into (A
(7.101), Ri 3
Th. 271 Th. 179(i)
Similarly, if ip is an instance of (BII), (Bill), (BV)-(BX) then A is an algebraic model of ip because 21 satisfies the identities by R2, R3, R5-R10, respectively. If (p is an instance of (BIV'), then ip = (A;(B;1) = (A;B);1) for some A,B 6 II. Since 21 6 SA, it follows from (6.187) and the reasoning above that A is an algebraic model of ip. T h e o r e m 565. Assume 3 < n < cu and ip, ip £ (i) If ip and ip => ip are algebraically n-valid, then so is ip. (ii) If ip is algebraically n-valid then so is Vv;
572
7. ALGEBRAIC LOGIC
A ^= VV;
h(cp) = Y,{aoi :aeN,
A^V[a]}.
Then (i) h is a homomorphism, from, 3m^ into 21, (ii) if ip —^ tp then h(tp) = /J(«/>).
PROOF. TO prove ft is a homomorphism we must show that the following formulas hold for all ip,ip £ Fm+ (2) (£): (7.166) (7.167)
h{
(7.168)
h(cp\^) =
(7.169)
h(
(7.170)
/i(v o =vi) =
9. ALGEBRAIC SOUNDNESS
To verify (7.166) we use the fact that if X and Y are sets of atoms of 21, then
h{ip V V) = ^{aoi :aeN,A^ip\/i/j
[a]}
i : a eN,A\^ip[a] or A\^ip [a]} i : a € N, A ^ ip [a]} + ^ { a O i : a € iV, .4 ^ ip [a]} Next we show that {aoi : a £ ^ j is the set of atoms of 21. One inclusion holds because every a £ AT is a matrix of atoms. Let x £ Am. Then a; = a;; 1'
R,6 :
1' > « € At 21}
Th. 182 Th.296
so there is an atom u £ At$l such that x < x;u. By (6.98) there is some a £ N such that aoi = x, ao2 = x, and 021 = u. Thus x £ {aoi : a £ N}. Since 21 is atomic, it follows that 1 = J2{aoi a £ N } . Then (7.167) holds since h(-np) = ^ { a o i : a € N, A\=-np [a]} = S2 ({aoi : a £ N} ~{a O i : a £ AT, A p=
To prove (7.168) it suffices, since 21 is atomic, to show that h(ip\ip) and h(ip);h(ip) include the same atoms. Suppose x £ At$i and x < h(ip\ip). Then by (7.165) there is some a £ N such that aoi = x and A \= 3V2(Si2V5 A 802^) H- Let AT^ : = T"(2t) n N2 for every i < n. It follows that there is some b £ N such that b T2 a, A\^ Si2ip[b], and .A ^ 802^ [&] Note that 6[1, 2],6[0, 2] £ A^ by (6.101). By Th. 562, yt ip [6[1, 2]] and yt ^ ^ [6[0, 2]]. Hence 6[1, 2]Oi < h(ip) and 6[0,2]oi < h(ip). But aOi = 601 since b T2 a, so, by (6.94), x = aOi =601 < 6025621 =6[l,2]oi;6[0,2] O i
This shows /i(vlV') <
K^'M^)-
Now suppose that x £ .At21 and a; < h(ip);h(ip). completely additive by Th. 296, we have
Since 21 is atomic and ; is
h{tp) > y £ A m } ; ^ { 2 : h{ip) > z £ A m } : h
(v>) > ! / £ Am, h{ip) >z<E
Am}
so there are atoms y,z £ .At21 such that t/ < ft(y), a < /i(V'), and x < y;z. By (6.98) there is a some matrix a £ N such that aoi = x, 002 = y, and 021 = a. Note that a[l, 2], a[0, 2] £ AT by (6.101). We have o[l,2] 0 i = a02 = y < h(ip) and a[0, 2]oi = a 2 i = « < /i(V'), so i ^ y>[a [1, 2]] and A p= V[° [0, 2]]. It follows from Th. 562 that A \= Si2tp [a] and A \= So2ip [a]. Consequently A \= 3 V 2 (Si2
574
7. ALGEBRAIC LOGIC
Soa^O [a], but 3V2(Si%tp AS021P) =
This shows h((p);h(ip) < ^(^|^) and completes the proof that h((p);h(ip) = h(tp\ip). Suppose a € N and *4 f= 93° [o]. Then A f= 80193 [a] since ^?° = Soiy>. We have a[0,1] G iV by (6.101) and A ^ p[a[0,l]] by Th. 562, so a[0, l]oi < ft(p). But a[0, l]oi = aio = (aoi)", so (aoi)" < fe(¥>), hence aoi < {h{(p)Y by Th. 241. This shows ft (^?°) < (ft(^?))" for every tp. Applying this to tp°, we also get h((p) = h(<poa) < {h(
=r This completes the proof that ft is a homomorphism. Assume tp ~^ ip. Then H^ tp O , so .4. f= 93 > ^>[a] for every a £ N by Th. (iii). But *4 ^ v> «* ip [a] iff A \^
(7.171)
h n
v o =vi => (v o =vi =4- vi=v 0 )
2. h* v o = v i ^ v i = v 0 3. r-n Vo^vi => (voJZvi => viiJvi) 4. \-n vi=vo => (viJZvi => voiJvi) 5. vo-Rvi A v o =vi = i viiJvi A v o =v x
(ADC*) Th. 147, Th. 140 (CVIII) (CVIII) 2, 3, 4, Th. 147, Th. 140
10. FREE SAS AND RAS OF FORMULAS
6. T(viflvi) = S12F V S02F V T I (vo-Rvi A v o = v i ) ~^T|(voflvi Avo=vi)
Th. 557
~hn TI (viflvi A v o = v i )
5, Th. 559(i)
= 3V2(Si2T AS 0 2(viflvi A v o = v i ) ) ~hn 3V2 (viflvi A v 2 = v i ) A3v 2 (v 2 =vi)
Th. 557, (7.84) (7.88) (CVII), Th.557
7. viiZvi ~"n T|(voi?vi Avo=vi)
6.
8. V2.RV2 = Sl2Vli?Vl
-nSi 2 (T|(v 0 j Rvi Av o =vi))
7, Th.156
-n Si2(T | (voflvi A v o =vi)) V S02F V F = T(v2-Rv2)
Th. 557
We have shown above that T(vii?vi) ~^ \\Rvi and T(v2.Rv2) ~^ V2.RV2. Similarly one can also show T(voflvo) —^ voflvo. This completes the inductive proof for the atomic case. Next suppose that tp is either -up or ip => (,, and assume V ^n T(V)) and ^ - ^ T(£). We have -,T(^) - ^ T(-.V) and T(^) =* T(^) ~"n T{ip ^ 0 from Th. 140 and Th. 147 alone, since -iT(V>)
n Vv0T(V>)
(7.83)
VV0 /\(Sl2&VS 0 2<TiV(Si)
n /\(S02<Ti VVvo(Si2^V5i))
= /\S02(<Ti VVV2(So2Sl2&VSo2&))
Th.7.87, Th.557
7. ALGEBRAIC LOGIC
~hn f\ S02(ai V -.3v2(Si2-.(^i°) A SO2-<5i))
- n
A(SFvS
) => O-OVF)
Th. 557, (7.83)
Th.557
The other two cases are handled similarly. This completes the proof of (7.171). Let ip £ Fm+(£). Then
The desired V1 is therefore Ai
O
Theorem 569 (Maddux [139, Th. ll(30)(31)], [156, Th. 6.3, 6.4]). Suppose C = £(0, 0,1Z, rank) is a binary relational language. Then (i) (ii) (iii) (iv)
51^3(2)/—3 51^3(2)/—3 ^m3(2)/—4 3Tn3(2)/~4
is is is is
a free semiassociative relation algebra on \1Z\ generators, SA-freely generated by {vo-Rvi/~ 3 : R £ It], a free relation algebra on \1Z\ generators, RA-freely generated by {v 0 itVi/~4 : -R £ 72.}-
PROOF, (i) follows from (ii), since we know that $m3(2)l—3 is a semiassociative relation algebra by Th. 559(ii). To prove (ii) we need to show that {v 0 itVi/~3 : R 6 } generates $m3(2)l—3 and that every map from {v 0 itVi/~3 : R £ 72.} to a semiassociative relation algebra extends to a homomorphism. Th. 568 guarantees that {vo-Rvi/~3 : R E TZ} generates ^m3(2)/—3. Let 21 £ SA and let / be a function mapping {voi£vi/~3 : R £ It] into 21. We wish to show that / extends to a homomorphism g of 5m3(2)/—3 into 21. Let 2l + be a perfect extension of 21, which exists by Th. 326. Then 2l + £ SA, 2t+ is atomic, and i?32l+ is a 3-dimensional semantical basis for 2l + by Th. 339(i). We obtain a 3-dimensional algebraic interpretation for C,
by setting RA = / ( v o - R v i / ^ ) for every R 6 TZ. For every <£ £ FmJ,2j(£) let 1: a €
B 3 a +
'
A
Then /i is a homomorphism from $mf into 2l + by Th. 567. It also follows from Th. 567 that h can be factored through the natural homomorphism (-)/~3 from g m j onto 3Tn3(2)/~3, that is, there is a homomorphism g from 3rn3(2)/—3 to 2l +
10. FREE SAS AND RAS OF FORMULAS
577
such that h(ip) = g(ip/~^) for every (p G Fm^,2,(£). To see that g extends / we note that p(vO-Rvi/~3) = : a 6 B32l+ A ^ v o flvi [a]} : a G B 3 2l + o0i < RA] = RA
Since / maps the generators of 5^13(2)/—3 into the subalgebra 21 of 2t+, and g is a homomorphism extending /, it follows that g also maps 5m3(2)/—3 into 21. Proof of (iii) and (iv): In the proof of (i) and (ii), change every occurrence of "3" to "4" (except in theorem numbers), change SA to RA, and appeal to Th. 339(ii) instead of Th. 339 (i). We can now prove Th. 548. We will only show (7.30). With only minor changes the same proof establishes (7.31). Assume C is a binary relational language. Recall that the predicate algebra %5 is an algebra of relational type with universe II that is absolutely freely generated by the set 1Z of relation symbols of C. Define the binary relation ~ x on II by A ~ x B iff h x A = B. By Th. 543(i)(iii), ~ x is a congruence relation on «p and ?P/~ X is a relation algebra which is RA-freely generated by {R/~x : R £ 1Z}. Let 21 = ^ 3 / ~ x and let 2l+ be a perfect extension of 21. Then _B42t+ is a 4-dimensional semantical basis for 2l+ by Th. 339(ii). Let
where RA := iZ/~ x for every R E 1Z. Then A is a 4-dimensional algebraic interpretation for £. Since (-)A and (-)/~ x are homomorphisms from the predicate algebra ?ft into the relation algebra ?p/~ x that agree on the generators of %5, they must be the same homomorphism. Therefore AA = ^4/~ x for every A £ II. Now assume h^ A = B. By Th. 565 (iii) we have A \^= A = B [a] for every a € B42t+. By the definition of ^, this gives us aOi < 0 f(AA e B - A ) t 0 for every 0 G B^H+. But {aoi : 0 G Ba$i+} is the set of atoms of 2l+, so 1 = 0 \{AA e BA) f 0. From this we get 0 = 1; (AA 0 BA); 1, then 0 = AA 0 B"4, hence AA = BA. By the observation made above, we get A/~x = B / ~ x . But then A ~ x B since ~ x is a congruence relation. By the definition of ~ x , we conclude that h x A = B, as desired. Conversely, if h x A = B then h^ A = B by Th. 561. The following theorem, which generalizes Th. 548, can be proved by similar methods. Theorem 570 (Maddux [146, Th. 24]). Let C be a binary relational language. (i) For every
578
7. ALGEBRAIC LOGIC
(ii) For every ip G Sentg"(£), hg~ ip iff \~t
11. Formalizing set theory in £ x Despite the inequipollence of £ x with £ and £ + , it is possible to formalize many first-order theories within £ x . In fact, Tarski-Givant [240, §4.7, Ch. 7] proved that practically all systems of set theory, as well as the elementary arithmetic of natural numbers, the elementary arithmetic of real numbers, and very many other mathematical theories formalized in £, can be equipollently formalized within the equational formalism £ x (or one of its variants M^* with more than one binary relation symbol). This is easiest to prove for those theories that contain (or prove) the sentence TT, where 7T : = VvoV v l 3v2Vv3(v3Ev2 «=> V 3 = V o V V 3 = V i ) .
This sentence may be called the "unrestricted axiom of unordered pairs". (The Axiom of Ordered Pairs in (2.86) is restricted to sets.) This sentence is present as an axiom in many systems of set theory that stem from the axiomatization of Zermelo [260]. In this section we consider a binary relation language £ = £(0,0, {E}, rank) where rank(E) = 2. For any predicates A,B £ II, define QAB £ Sent x (£) as follows. QAB := (A;A + B;B + V) A;B = 1. The meaning of QAB is expressed by the following theorem. Theorem 571. Suppose A, B 6 II and M is an interpretation for £. The following statements are equivalent: (i) M \= QAB, (ii) M \={A;A + V = V,B;B + V =V,A;B = 1}, (iii) AM and BM are functions and (AM)~1\BM = M2. Next is the connection between QAB and TT. Theorem 572 (Tarski-Givant [240, 4.6(ii)(iii)]). For any D,F G II, if we define predicates A, B £ II by A:=D-(D\V),
B:=F-((F
+
A)n'),
then QAB = A; B = 1. //, in addition, £>:=E;(E-(E"tl'))>
F := E;E,
then TT = QABWith the help of the QRA theorem (Th. 427) we may easily prove the equipollence of £ x with £ + relative to any sentence QABTheorem 573 (Tarski-Givant [240, 4.4(xxxvii)]). Let * C Sent x (£) and let C,D€T1. Then QAB, * h x C = D iff QAB,^> h+ C = D.
11. FORMALIZING SET THEORY IN £ x
579
PROOF. Let * = {QAB} U * . One direction is easy: if $ h x C = D then <> j \-+ C = D because £ x is a subformalism of C+. For the other direction, we will assume (7.172)
$ h+ C = D
and show * h x C = D. Define a binary relation ~ x on II: for R, S € II, R ~ x 5 iff $ h x R = S. By Th. 543, ~ ^ is a congruence relation on the predicate algebra ^5, and the quotient algebra ^P/~^ is a relation algebra. The presence of QAB in $ implies that A/~£ and B/—* are a pair of conjugated quasi-projections in W - * - Hence
If 0 = E then 6 b (i5) is a 1-element algebra and p maps all predicates to the same element. In particular, p(C/~$) = p(Z>/—*) But then C/~£ = -D/~£ since p is injective, so C ~£ Z3, i.e., $ h x C = D, as desired. Now assume E is not empty. By Th. 105, 6b (E) is isomorphic to the direct product of all algebras of the form $Re (U), where U ranges over the (nonempty) equivalence classes of E:
UeFd(E)/E
and, for each equivalence class U e Fd (E)/E, the function (X n U2 : X € 56 (£)) is a homomorphism from 6b (E) onto 9te (?7). Consequently, p(-/~^) D t/ 2 is a homomorphism from ^5 into 9te(U), obtained by composing the quotient homomorphism -/—* with the homomorphism p, and then composing the result with the homomorphism (-) PI U2 from 6b (E) to $Re ([/). Each equivalence class U £ Fd(E)/E also determines an interpretation Mu for Cx, where (7.174)
EMu := p ( E / ~ x ) n U2.
Since {-)Mu also is a homomorphism from *p into 9\e (U) which agrees with the homomorphism p(-/~^) n U2 on the absolutely free generator E of *p, these two homomorphisms must be the same. Thus we have shown that (7.175)
RMu
:=p(R/~*)nU2
for every R 6 11. Note that Mu \= $, for if R = S € $ then $ h x R = 5, hence R ~ x 5, hence i i / ~ x = 5 / ~ x , so RMu = SMu by (7.175), i.e., Mu \=R = S. It follows from (7.172) by the Soundness Th. 141 that C = D is a semantic consequence of <1>, so C = D is also satisfied in Mu, i.e., CMu = DMu. By (7.175), p(C/~£) n U2 = p(Z3/~J) n U2. Since this last equation holds for every equivalence class U of E, it follows that p(C/~^) = p(Z)/~^). Consequently C / ~ ^ = Z?/~£ because p is injective. But this is equivalent to C ~£ D, hence, by definition of ~ £ , we get $ h x C = Z) as desired.
580
7. ALGEBRAIC LOGIC
For the moment, let us consider two predicates A, B £ I I and two formalisms, £.QAg and £ Q A B ! which are obtained from C+ and £* by adding the sentence QAB to the axioms sets of C+ and £ * , even though this violates the principle that, for formalisms with sentences in Sent + (£), sets of axioms should contain only logically valid sentences. Let the notions of provability for the two extended formalisms CQ and CQ be hg and \-Q , respectively. Then Th. 573 expresses the equipollence of CQ and CQ in means of proof, and could be written as for all * C Sent* (C) and
AQAB,
or, equivalently, QAB \= ip > ij). Such equipollence can indeed be proved. We turn next to that task. Recall that we are considering two fixed predicates A, B e II. Define two additional predicates AC,BC E II, and a sequence of predicates Pn € II for n E w by (7.176)
Ac:
(7.177)
Bc ;=B + V -(BjO),
(7.178)
Pb := B\
(7.179)
Pn+1:=Ac;Pn
forngu.
As we saw earlier, if M. is an interpretation for £ such that M |= QAB, then AM and BM are functions for which we also know (AM)~1\BM = M 2 . The M M domains of A and B need not be all of M. However, the relations (AC)M and (BC)M are "completions" of AM and BM in the sense that they are functions defined everywhere in M that AM and BM fail to be defined. Thus both of them have domain M. Since they extend AM and BM, they also have the property that ((A°) M )~ 1 |(.B C ) M = M 2 . Define a function U : Fm+(£) -> I I as follows. For every
C T f a ) : =P i Q ; ( P i Q
Pin;(PinT +
Define the auxiliary mapping MAB : Fm (£) —} II by the following rules, in which i,j 6 w, C, D g II, and yj 6 Sent + (£): (7.181)
AfABCvil'v,-) := (Pi
(7.182)
MAafviCv,-) := (Pi;C7 P,);!,
Pj);l,
11. FORMALIZING SET THEORY IN £ x
(7.183)
MAB(C
= D)
581
: = O t ( C - D + C-D) fO,
(7.184) (7.185) (7.186) Define the translation mapping KAB KAB(¥>)
:=
Sent + (£) —> Sentx (£) as follows.
MAB (
We now get the equipollence of CQ and £ Q the Main Mapping Theorem for £ x and £ + .
in means of expression and
Theorem 574 (Tarski-Givant [240, 4.4(xxxiii)(xxxiv)]). Lei A,B G II and
(iii) KAB{
(v) QAB A ifAfl(ip) = QAS A 93(vi) For ewerj/ * C Sent + (£) ond ewen/
(7.187)
PROOF.
This Page is Intentionally Left Blank
CHAPTER
4329 finite integral relation algebras 1. Cycles of algebras I1316—1316i3i6
I1316 2l316 3l316 4l316 5l316
61316 7l316 813I6 9l316 101316 Hl316 12l316 13l316 14i316 15l316 16l316 17l3l6 18l316 191316 20l316 21l316 22i3i6 23l3l6 24-1316 25l3l6 26l3l6 27l3l6 28l3l6 29l316 301316 311316 32l3l6
aaa bbb rrr rrr abb baa arr rar brrrbr rrr abb arr rar brr rbr rrr aaa abb arr rar brr rbr bbb rrr abb arr rar brr rbr aaa bbb rrr abb arr rar brr rbr rrr abb arr rar brr rbr rrr abb aaa arr rar brr rbr bbb rrr abb arr rar brr rbr aaa bbb rrr abb arr rar brr rbr rrr rrr abb arr rar brr rbr arr rar brr rbr aaa rrr rrr abb arr rar brr rbr bbb rrr rrr abb arr rar brr rbr aaa bbb rrr rrr abb rrr abb baa arrrar brr rbr aaa rrr abb baa arrrar brr rbr aaa bbb rrr abb baa arrrar brr rbr rrr abb baa arrrar brr rbr rrr abb baa arrrar brr rbr aaa aaa bbb rrr abb baa arrrar brr rbr rrr rrr abb baa arrrar brr rbr aaa rrr rrr abb baa arrrar brr rbr aaa bbb rrr rrr abb baa arrrar brr rbr brr rbr rrr baa brr rbr aaa baa rrr brr rbr baa bbb rrr brr rbr aaa bbb rrr baa brr rbr rrr baa brr rbr aaa rrr baa brr rbr • •• b b b ••• r r r baa brr rbr aaa bbb • • • rrr baa brr rbr rrr rrr baa brr rbr aaa • • • rrr rrr baa brr rbr • • • bbb rrr rrr baa
raa rbb rra rrb abr bar
raa raa raa raa raa raa raa raa raa raa raa
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
33l316 34i3i 6 35l3l6 36l316 37l3l6 38l3l6 39l316 40l316 41l316 42l316 43l316 44i3i 6 45l316 46l316 47l316 481316 49l316 50l316 51l316 52i3i6 53l3l6 54l316 55l3l6 56l3l6 57l3l6 58l3l6 59l316 60l316 611316 62i3i 6 63l316 64i3i 6 65l3l6 661316 67l3l6 DO1316
69l316 701316 711316 72l3l6 73l3l6 74i3i 6 75l3l6 76l316 77l3l6
aaa bbb rrr rrr abb baa arr aaa bbb rrr rrr baa aaa baa arr rrr aaa bbb rrr baa arr baa arr rrr aaa baa arr rrr baa arr bbb rrr aaa bbb rrr baa arr baa arr rrr rrr aaa baa arr rrr rrr baa arr bbb rrr rrr aaa bbb rrr rrr baa arr b rrr abb aaa rrr nbh bbb rrr nbh aaa bbb rrr aaa bbb aaa bbb rrr rrr bbb rrr aaa bbb rrr rrr aaa rrr aaa bbb rrr aaa
rar brr rbr raa rbb rra rrb abr bar brr
rar rar rar rar rar rar rar rar
rrr abb rrr abb rrr abb rrr abb rrr abb rrr abb rrr abb rrr abb
rrr abb rrr abb rrr abb rrr rrr abb aaa rrr rrr abb aaa bbb rrr rrr abb
baa baa baa baa baa baa baa baa baa
aaa rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr aaa bbb rrr rrr aaa rrr
arr arr arr rar arr rar arr rar arr arr rar arr rar arr rar arr rar baa arr baa arr rar baa arr rar
abb abb abb
aaa aaa bbb
abb abb b abb abb abb
rrr abb rrr abb rrr abb rrr abb b abb abb
rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr
raa raa brr raa brr raa brr raa brr raa raa brr raa brr raa brr brr raa brr raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa brr raa brr rbr raa brr rbr raa brr
roo rbb 1 7
TOO 1 7
TOO
rbb I T
TOO
rbb rbb TOO
rbb rbb 1 1
TOO
rbb rbb 1 1
TOO
rbb rbb 1 1
TOO
rbb rbb 1 1
TOO
rbb rbb 1 1
TOO
rbb rbb 1 1
TOO
rbb rbb 1 1
TOO
rbb rbb r-lth / UU TOO
1. CYCLES OF ALGEBRAS Ii3i 6 -1316i 3 i 6
aaa bbb rrr rrr abb baa arr rar brr rbr raa rbb rra rrb abr bar abb baa arr rar brr rbr raa rbb
78l316 aaa bbb rrr 7QT
OT
r-
1 y 1316
rrr rrr
nbh (JiUU
oaa arr
rar brr rbr
raa
rbb
abb rbb rar brr rbr 8O1316 aaa baa arr raa rrr rrr 811316 aaa bbb rrr rrr abb baa arr rar brr rbr raa rbb 82i3i6 83l3l6 84l316 85l3l6 861316 87l3l6 001316 89l316 90l316 911316 92i3i6 931316 94i316 95l316 96l316 97l3l6 yoi3l6 991316 1001316 1011316 102l316 1031316 104i316 1051316 1061316 1071316 1081316 1091316 HO13I6 1111316 1121316 1131316 1141316 115l3l6 H61316 1171316 H813I6 1191316 1201316 1211316 1221316
oaa baa baa baa baa baa baa baa baa
bbb rrr rrr bbb rrr rrr aaa aaa bbb rrr aaa aaa bbb rrr aaa rrr rrr aaa
bbb
uuu
aaa
rrr rrr rrr rrr
bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr aaa aaa bbb rrr aaa rrr bbb rrr aaa bbb rrr aaa bbb aaa bbb rrr rrr bbb rrr aaa bbb rrr aaa
rrr rrr rrr rrr
rrr rrr rrr rrr
rrr rrr rrr rrr rrr rrr rrr rrr nbh (JiUU
(Of rbr
brr
rbr
rra rra rra
rbr
rra
brr
arr arr arr arr arr
oaa arr baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
Oil brr
arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr
rar rar rar rar rar rar
brr brr brr brr brr brr brr
rbr
brr
rbr
brr
rbr
brr
rbr
brr
rbr
brr
rbr
brr
rbr
brr
rbr
brr
rbr
brr
rbr
brr
rbr
brr
rbr
brr
rbr
brr
rbr
brr
rbr
brr
rar rar rar rar rar rar rar rar rar rar rar rar rar rar
rbr rbr rbr rbr rbr rbr
brr brr brr brr brr brr brr brr brr brr brr brr brr brr
rbr
rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr
rra rra rra rra rra rra rra rra
raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa
rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rbb
rra
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
1231316 1241316 125l3l6 126l316 1271316 1281316 1291316 1301316 1311316 1321316 1331316 1341316 1351316 136l3l6 137l3l6 138l316 1391316 140l316 1411316 1421316 1431316 1441316 1451316 146l316 1471316 1481316 1491316 1501316 1511316 152i316 1531316 154i3i6 1551316 156l316 1571316 1581316 1591316 1601316 1611316 1621316 1631316 164i3i6 165l3l6 1661316 167i3i6
aaa bbb rrr bbb rrr bbb rrr aaa aaa bbb aaa rrr aaa bbb rrr aaa rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr aaa aaa bbb rrr aaa rrr bbb rrr aaa bbb rrr aaa bbb aaa bbb aaa aaa aaa aaa aaa
rrr abb baa arr rar brr rbr raa rbb rra rrb abr bar abb rbb rra rbb rrr abb rrr abb rbb arr arr arr arr arr arr
abb b b abb
rrr abb rrr abb
rar rar rar
abb b
nhh abb
rrr abb rrr abb rrr abb rrr abb arr arr arr arr arr
abb abb abb abb
rrr abb rrr abb rrr abb rrr abb abb abb abb b abb abb
rrr abb rrr abb rrr abb rrr abb rrr abb rrr abb rrr abb rrr abb
rrr rrr bbb rrr bbb rrr abb rrr b rrr abb bbb rrr b bbb rrr rrr rrr abb rrr rrr abb
baa baa baa baa baa baa
arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr
rar rar rar
rar rar rar
rar rar rar rar rar rar
brr brr brr brr brr brr
rbr rbr rbr rbr rbr rbr
raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa
rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb
rra rra rra
rra
rra rra
rra rra
rra rra
rra rra
rra
1. CYCLES OF ALGEBRAS Ii3i 6 -1316i 3 i 6
I681316 1691316 170i3i6 1711316 172i316 1731316 1741316 175l3l6 176l3l6 1771316 178l3l6 1791316
aaa bbb rrr rrr abb baa bbb rrr rrr abb baa aaa bbb rrr rrr abb baa baa aaa baa rrr rrr rrr rrr
aaa aaa
aaa bbb
arr arr arr arr arr
baa arr baa arr abb arr
066
arr
aaa
rrr
abb
arr
aaa
bbb rrr
abb
arr
aaa
rrr
rrr
abb
aaa bbb rrr rrr abb abb baa 1801316 066 60a 1811316 aaa 066 60a 182i3i6 aaa bbb . . . . rrr . . . abb i,aa 1831316 rrr abb baa 184i316 aaa abb baa 185l3l6 aaa bbb rrr . . . . rrr rrf- afri) fraa 1861316 aaa rrr rrr abb baa 187l3l6 1881316 aaa bbb rrr rrr abb baa baa 1891316 60a 1901316 aaa . . . . rrr rrf- . . . fraa 1911316 rrr rrr baa 1921316 aaa bbb 60a 1931316 baa 194i316 aaa bbb bbb rrr baa 1951316 60a 1961316 aaa bbb rrr bbb rrr rrr baa 1971316 baa 1981316 aaa bbb rrr rrr . . . . r r r . . . a\)}) 5 a a 1991316 aaa rrr abb baa 2001316 bbb rrr abb baa 2011316 aaa bbb rrr abb baa 202i3ie . . . . rrr rrf- afri) fraa 203i3ie rrr rrr abb baa 204i3ie aaa bbb rrr rrr abb baa 205i3ie 2061316 aaa bbb rrr rrr abb baa . . . . rrr . . . abb i,aa 207i3ie rrr abb baa 2081316 aaa bbb rrr abb baa 209i3ie abb baa 2101316 aaa bbb rrr . . . . rrr rrf- afri) fraa 2111316 rrr rrr abb baa 2121316 aaa
arr
arr arr
arr arr arr
arr arr arr
arr
rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar
arr arr rar arr rar arr rar arr rar arr rar arr rar arr rar arr rar arr rar arr rar
brr rbr raa rbb rra brr rbr raa rbb rra brr rbr raa rbb rra rra rra rra rra brr rbr rra brr rbr rra brr rbr rra brr rbr rra brr rbr rra brr rbr rra brr rbr rra brr rbr rra brr rbr rra brr rbr rra brr rbr rra brr rbr rra brr rbr rra brr rbr rra brr rbr rra
rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb
raa raa raa raa raa raa raa raa raa raa
rra rra rra rra rra rra rra rra rra rra
rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb
brr brr brr brr brr brr
arr rar arr rar
raa raa raa raa raa raa raa raa
rbb rbb rbb rbb rbb rbb rbb rbb
rra rra rra rra rra rra rra rra
rrb rrb rrb rrb rrb rrb rrb rrb
arr rar brr arr rar brr arr rar brr arr rar brr arr rar brr arr rar brr
raa raa raa raa raa raa
rbb rbb rbb rbb rbb rbb
rra rra rra rra rra rra
rrb rrb rrb rrb rrb rrb
arr
rar
rbr rbr rbr rbr rbr rbr
rrb abr bar
arr rar arr rar arr rar arr
rar
arr rar
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
2131316 2141316 215l3l6 216l316 2171316 2181316 2191316 220i3i6 2211316 222i3i6 223i3i6 224i3ie 225i3i6 226i3i6
aaa bbb rrr rrr abbbaa bbb rrr rrr abbbaa aaa bbb rrr rrr abbbaa nhh baa nhh baa aaa U/UU nhh baa aaa bbb aou rrr abb baa rrr abb baa aaa abb baa aaa bbb rrr baa aaa I I I U/UU baa rrr abb baa aaa bbb rrr rrr abbbaa aaa rrr rrr abbbaa aaa bbb rrr rrr abbbaa
arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr
rar brr rbr raa rbb rra rrb abr bar rar
brr
rar
brr
rar rar rar rar rar rar rar rar rar rar rar rar
brr brr brr brr brr brr brr brr brr brr brr brr
rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr
227i3ie 228i3i6 229i3ie 230i3ie 2311316 232i3i6 233i3i6 234i3ie 235i3ie 236i3ie 237i3ie 238i3i6 239i3i6 240i3ie 241i316 242i3ie 243i3ie 244i3ie 245i3ie 246i3ie 247i3ie 248i3ie 249i3ie 250i3ie 251l316 252i3ie 253i3ie 254i3ie 255i3i6 256i3i6 257i3i6
bbb rrr bbb Trr rrr bbb rrr bbb bbb rrr bbb rrr aaa bbb rrr bbb rrr aaa bbb rrr aaa aaa aaa aaa aaa aaa
rrr
abbbaa brr baa arr brr abbbaa arr brr abbbaa arr arr ror abb baa arr rbr abb rbr arr rar abb rbr arr rar abb baa arr rar rbr abb baa arr rar rbr abb baa arr rar brr rbr abb baa arr rar brr rbr abb baa arr rar brr rbr
rrr aaa aaa bbb rrr rrr rrr abb aaa aaa bbb rrr rrr abb rrr rrr abbbaa rrr rrr abbbaa aaa bbb rrr rrr abbbaa aaa bbb rrr rrr abbbaa rrr rrr abb aaa aaa bbb rrr rrr abb rrr rrr abbbaa rrr rrr abbbaa aaa bbb rrr rrr abbbaa aaa bbb rrr rrr abbbaa rrr rrr abbbaa aaa rrr rrr abbbaa bbb rrr rrr abbbaa aaa bbb rrr rrr abbbaa rrr rrr abbbaa
arr arr arr arr arr arr
rar
brr
rar
brr
rar
brr
rar
brr
rar
brr
rar
brr
rar
brr
rar
brr
rar
brr
rar
brr
rar
brr
rar
brr vi I I vi brr rbr
arr
brr rbr
raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa
rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb
rra rra rra rra rra rra rra rra rra rra rra rra rra rra
rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb abr abr abr abr abr abr abr abr abr abr abr abr abr abr
rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra
abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr
1. CYCLES OF ALGEBRAS I l 3 i6-1316i 3 i 6
258i3i6 259i3ie 26O1316 261l316 262i3i6 263i3i6 264i3i6 265i3ie 2661316 267i3i6 268i3ie 269i3i6 270i3ie 2711316 272i3i6 273i3ie 274i3i6 275i3i6 276i3i6 277i3i6 278i3i6 279i3ie 280i3i6 281l316 282i3i6 283i3i6 284i3i6 285i3i6 286i3i6 287i3i6 288i3i6 289i3i6 290i3i6 2911316 292i3i6 293i3i6 294i3ie 295i3i6 296i3i6 297i3i6 298i3i6 299i3i6 300l316 3011316 302i3ie
aaa bbbrrr rrr abb baa arr rar brr rbr raa rbbrra rrb abr bar aaa rrr rrr abb baa arr abr •• • brr rbr raa rbbrra bbbrrr rrr abb baa arr abr •• • brr rbr raa rbbrra aaa bbbrrr rrr abb baa arr abr •• • brr rbr raa rbbrra rrr rrr abb rar brr rbr raa rbbrra abr •• • aaa rrr rrr abb rar brr rbr raa rbbrra abr •• • bbbrrr rrr abb rar brr rbr raa rbbrra abr •• • aaa bbbrrr rrr abb rar brr rbr raa rbbrra abr •• • rrr rrr abb baa rar brr rbr raa rbbrra abr •• • rrr rrr abb baa aaa rar brr rbr raa rbbrra abr •• • bbbrrr rrr abb baa rar brr rbr raa rbbrra abr •• • aaa bbbrrr rrr abb baa rar brr rbr raa rbbrra abr •• • arr rar brr rbr raa rbbrra rrr rrr abb abr •• • arr rar brr rbr raa rbbrra aaa rrr rrr abb abr •• • bbbrrr rrr abb arr rar brr rbr raa rbbrra abr •• • arr rar brr rbr raa rbbrra aaa bbbrrr rrr abb abr •• • rrr rrr abb baa arr rar brr rbr raa rbbrra abr •• • aaa rrr rrr abb baa arr rar brr rbr raa rbbrra abr •• • bbbrrr rrr abb baa arr rar brr rbr raa rbbrra abr •• • aaa bbbrrr rrr abb baa arr rar brr rbr raa rbbrra abr •• • rrr •• • abb rar raa rbbrra rrb abr • • • aaa rrr ••• abb rar raa rbbrra rrb abr • • • bbbrrr •• • abb rar raa rbbrra rrb abr • • • aaa bbbrrr • • • abb rar raa rbbrra rrb abr • • • rrr rrr abb rar raa rbbrra rrb abr • • • aaa rrr rrr abb rar raa rbbrra rrb abr • • • bbbrrr rrr abb rar raa rbbrra rrb abr • • • aaa bbbrrr rrr abb rar raa rbbrra rrb abr • • • rrr •• • abb baa rar raa rbbrra rrb abr • • • aaa rrr • • • abb baa rar raa rbbrra rrb abr • • • bbbrrr •• • abb baa rar raa rbbrra rrb abr • • • aaa bbbrrr •• • abb baa rar raa rbbrra rrb abr • • • rrr rrr abb baa rar raa rbbrra rrb abr • • • aaa rrr rrr abb baa rar raa rbbrra rrb abr • • • bbbrrr rrr abb baa rar raa rbbrra rrb abr • • • aaa bbbrrr rrr abb baa rar raa rbbrra rrb abr • • • arr rar rrr • • • abb raa rbbrra rrb abr • • • arr rar aaa rrr •• • abb raa rbbrra rrb abr • • • bbbrrr ••• abb arr rar raa rbbrra rrb abr • • • arr rar aaa bbbrrr •• • abb raa rbbrra rrb abr • • • arr rar rrr rrr abb raa rbbrra rrb abr • • • arr rar aaa rrr rrr abb raa rbbrra rrb abr • • • bbbrrr rrr abb arr rar raa rbbrra rrb abr • • • arr rar aaa bbbrrrrrr abb raa rbbrra rrbabr • • • rrr •• • abb baa arr rar raa rbbrra rrb abr • • • rrr • • • abb baa arr rar aaa raa rbbrra rrb abr • • •
4329 FINITE INTEGRAL RELATION ALGEBRAS
303i3ie 304i3ie 305i3ie 306i3i6 307i3ie 308i3i6 309i3ie 3101316 3111316 3121316 3131316 314i3i6 3151316 3161316 3171316 318l316 3191316 320i3i6 3211316 322i3ie 323i3ie 324i3ie 325i3i6 326i3i6 327i3ie 328i3ie 329i3ie 330i3ie 3311316 332i3i6 333i3i6 334i3ie 335i3ie 336i3i6 337i3i6 338i3i6 339i3i6 340i3i6 341i3i6 342i3ie 343i3ie 344i3ie 345i3ie 346i3ie 347i3ie
aaa bbbrrr rrr abb baa arr rar brr rbrraa rbbrra rrb abr raa rbbrra rrb abr abb baa arr bbbrrr raa rbbrra rrb abr abb baa arr aaa bbbrrr raa rbbrra rrb abr rrr rrr abb baa arr raa rbbrra rrb abr aaa abb baa rar rrr rrr arr raa rbbrra rrb abr bbbrrr rrr abbbaa arr rar raa rbbrra rrb abr aaa bbbrrr rrr abb baa arr rar baa arr • • • brr • • • raa rbbrra rrb abr rrr aaa baa arr • • • brr • • • raa rbbrra rrb abr rrr bbbrrr baa arr • • • brr • • • raa rbbrra rrb abr aaa bbbrrr baa arr • • • brr • • • raa rbbrra rrb abr rrr rrr baa arr • • • brr • • • raa rbbrra rrb abr rrr rrr aaa baa arr • • • brr • • • raa rbbrra rrb abr bbbrrr rrr baa arr • • • brr • • • raa rbbrra rrb abr aaa bbbrrr rrr baa arr • • • brr • • • raa rbbrra rrb abr abb baa arr • • • brr • • • raa rbbrra rrb abr rrr abb baa arr • • • brr • • • raa rbbrra rrb abr aaa rrr bbbrrr abb baa arr • • • brr • • • raa rbbrra rrb abr abb baa arr • • • brr • • • raa rbbrra rrb abr aaa bbbrrr rrr rrr abb baa arr • • • brr • • • raa rbbrra rrb abr rrr rrr abb baa arr • • • brr • • • raa rbbrra rrb abr aaa bbbrrr rrr abb baa arr • • • brr • • • raa rbbrra rrb abr aaa bbbrrr rrr abb baa arr • • • brr • • • raa rbbrra rrb abr rar brr • •• raa rbbrra rrb abr abb rrr rar brr • •• raa rbbrra rrb abr abb aaa rrr rar brr • •• raa rbbrra rrb abr abb bbbrrr rar brr • •• raa rbbrra rrb abr abb aaa bbbrrr rar brr • • • raa rbbrra rrb abr rrr rrr abb rar brr • •• raa rbbrra rrb abr aaa rrr rrr abb rar brr • •• raa rbbrra rrb abr bbbrrr rrr abb rar brr • •• raa rbbrra rrb abr aaa bbbrrr rrr abb rar brr • •• raa rbbrra rrb abr abb baa rrr rar brr • •• raa rbbrra rrb abr abb baa rrr aaa rar brr • •• raa rbbrra rrb abr abb baa aaa bbbrrr rar brr • • • raa rbbrra rrb abr baa abb rrr rrr rar brr • •• raa rbbrra rrb abr rrr rrr abb baa aaa rar brr • •• raa rbbrra rrb abr aaa bbbrrr rrr abb baa abb arr rar brr • • • raa rbbrra rrb abr rrr abb arr rar brr • •• raa rbbrra rrb abr aaa rrr bbbrrr abb arr rar brr • • • raa rbbrra rrb abr abb aaa bbbrrr arr rar brr • •• raa rbbrra rrb abr arr rar brr • •• raa rbbrra rrb abr rrr rrr abb arr rar brr • •• raa rbbrra rrb abr aaa rrr rrr abb bbbrrrrrrabb arr rar brr • • • raa rbbrra rrbabr arr rar brr • •• raa rbbrra rrb abr aaa bbbrrr rrr abb rrr baa arr rar brr • • • raa rbbrra rrb abr
bar • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • •• • ••
1. CYCLES OF ALGEBRAS Ii3i 6 -1316i 3 i 6
348i3ie 349 13 ie 350i3i6 3511316 352i3ie 353i3ie 354i3ie 355i3i6 356i3ie 357i3ie 358i3i6 359i3ie 360i3ie 361l3l6 362i3i6 363i3i6 364i3ie 365i3i6 366i3i6 367i3i6 368i3i6 369i3ie 370i3i6 371i316 372i3i6 373i3i6 374i3ie 375i3i6 376i3ie 377i3ie 378i3i6 379i3ie 380i3i6 3811316 382i3ie 383i3ie 384i3ie 385i3i6 386i3i6 387i3ie 388i3i6 389i3ie 390i3ie 3911316 392i3ie
aaa bbbrrr rrr abbbaa arr rar baa arr rar aaa rrr baa arr rar bbbrrr baa arr rar aaa bbbrrr baa arr rar rrr rrr baa arr rar aaa rrr rrr bbbrrr rrr baa arr rar aaa bbbrrr rrr baa arr rar abbbaa arr rar rrr abbbaa arr rar rrr aaa bbbrrr abbbaa arr rar abbbaa arr rar aaa bbbrrr rrr rrr abbbaa arr rar aaa rrr rrr abbbaa arr rar bbbrrr rrr abbbaa arr rar aaa bbbrrr rrr abbbaa arr rar abb rrr arr rar abb aaa rrr arr rar arr rar bbbrrr abb aaa bbbrrr arr rar abb rrr rrr abb arr rar aaa rrr rrr abb arr rar bbbrrr rrr abb arr rar aaa bbbrrr rrr abb arr rar abbbaa arr rar rrr abbbaa arr rar aaa rrr bbbrrr abbbaa arr rar abbbaa arr rar aaa bbbrrr rrr rrr abbbaa arr rar aaa rrr rrr abbbaa arr rar bbbrrr rrr abbbaa arr rar aaa bbbrrr rrr abbbaa arr rar rrr rrr arr rar aaa rrr rrr arr rar aaa bbbrrr rrr arr rar abb aaa arr rar abb aaa bbb arr rar abb rrr arr rar abb aaa rrr arr rar bbbrrr abb arr rar abb aaa bbbrrr arr rar rrr abb arr rar aaa rrr abb arr rar
bbb
rrrabb
rrr abb aaa bbb rrr rrr abb
rbr raa rbbrra rrbabr bar raa rbbrra rrbabr • •• brr raa rbbrra rrbabr • •• brr raa rbbrra rrbabr • •• brr raa rbbrra rrbabr • •• brr raa rbbrra rrbabr • •• brr raa rbbrra rrbabr • •• brr raa rbbrra rrbabr • •• brr raa rbbrra rrbabr • •• brr raa rbbrra rrbabr • •• brr raa rbbrra rrbabr • •• brr raa rbbrra rrbabr • •• brr raa rbbrra rrbabr • •• brr raa rbbrra rrbabr • •• brr raa rbbrra rrbabr • •• brr raa rbbrra rrbabr • •• • • •rbr raa rbbrra rrbabr •• • • • •rbr raa rbbrra rrbabr •• • • • •rbr raa rbbrra rrbabr •• • • • •rbr raa rbbrra rrbabr •• • • • •rbr raa rbbrra rrbabr •• • • • •rbr raa rbbrra rrbabr •• • • • •rbr raa rbbrra rrbabr •• • • • •rbr raa rbbrra rrbabr •• • • • •rbr raa rbbrra rrbabr •• • • • •rbr raa rbbrra rrbabr •• • • • •rbr raa rbbrra rrbabr •• • • • •rbr raa rbbrra rrbabr •• • • • •rbr raa rbbrra rrbabr •• • • • •rbr raa rbbrra rrbabr •• • • • •rbr raa rbbrra rrbabr •• • • • •rbr raa rbbrra rrbabr •• • brr rbr raa rbbrra rrbabr • • • brr rbr raa rbbrra rrbabr • • • brr rbr raa rbbrra rrbabr • • • brr rbr raa rbbrra rrbabr • • • brr rbr raa rbbrra rrbabr • • • brr rbr raa rbbrra rrbabr • • • brr rbr raa rbbrra rrbabr • • • brr rbr raa rbbrra rrbabr • • • brr rbr raa rbbrra rrbabr • • • brr rbr raa rbbrra rrbabr • • • brr rbr raa rbbrra rrbabr • • • brr
brr
arrrar brr rbrraarbbrrarrbabr arr rar brr rbrraa rbbrra rrbabr arr rar brr rbrraa rbbrra rrbabr
•• • •• • •• •
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
393i3ie 394i3ie 395i3ie 396i3ie 397i3ie 398i3ie 399i3ie 4001316 4011316 402i3ie 403i3ie 404i3ie 405i3ie 406i3ie 407i3ie 408i3ie 409i3ie 410l316 4111316 4121316 4131316 414l316 415i316 416i316 4171316 4181316 4191316 420i3ie 421i316 422i3ie 423i3ie 424i3ie 425i3ie 426i3ie 427i3ie 428i3ie 429i3ie 430i3i6 4311316 432i3ie 433i3ie 434i3i6 435i3ie 436i3ie 437i3ie
aaa bbbrrr aaa rrr
raa rbbrra rrb abr bar raa rbbrra rrb abr • •• brr rbr raa rbbrra rrb abr bbbrrr rrr • •• brr rbr raa rbbrra rrb abr aaa bbbrrr rrr • •• brr rbr raa rbbrra rrb abr • •• brr rbr raa rbbrra rrb abr aaa • •• brr rbr raa rbbrra rrb abr • •• aaa bbb brr rbr raa rbbrra rrb abr rrr ••• • •• brr rbr raa rbbrra rrb abr rrr ••• • •• aaa brr rbr raa rbbrra rrb abr • •• aaa bbbrrr ••• brr rbr raa rbbrra rrb abr • •• ' ' ' III brr rbr raa rbbrra rrb abr • •• aaa tit brr rbr raa rbbrra rrb abr • •• aaa bbb• • • rrr brr rbr raa rbbrra rrb abr rrr rrr • •• brr rbr raa rbbrra rrb abr rrr rrr • •• aaa brr rbr raa rbbrra rrb abr • •• aaa bbbrrr rrr rrr abr bar raa rbb abr bar raa rbb ////// abr bar rrr ••• abb aaa raa rbb abr bar aaa bbbrrr ••• abb raa rbb abr bar rrr rrr abb aaa raa rbb abr bar aaa bbbrrr rrr abb raa rbb abr bar rrr ••• abb baa raa rbb abr bar rrr ••• abb baa aaa raa rbb abr bar aaa bbbrrr ••• abb baa raa rbb abr bar rrr rrr abb baa raa rbb abr bar rrr rrr abb baa aaa raa rbb abr bar aaa bbbrrr rrr abb baa raa rbb abr bar rrr ••• abb aaa arr • • • brr • • • raa rbb abr bar aaa bbbrrr ••• abb arr • • • brr • • • raa rbb abr bar rrr ••• abb baa arr • • • brr • • • raa rbb abr bar rrr ••• abb baa arr • • • brr • • • raa rbb aaa abr bar aaa bbbrrr ••• abb baa arr • • • brr • • • raa rbb abr bar arr rar brr rbr raa rbb rrr abr bar aaa arr rar brr rbr raa rbb rrr abr bar aaa bbbrrr arr rar brr rbr raa rbb abr bar rrr rrr •• • arr rar brr rbr raa rbb abr bar rrr rrr •• • aaa arr rar brr rbr raa rbb abr bar aaa bbb arr rar brr rbr raa rbb abr bar rrr ••• abb arr rar brr rbr raa rbb abr bar rrr ••• abb aaa arr rar brr rbr raa rbb bbbrrr ••• abb abr bar arr rar brr rbr raa rbb abr bar aaa bbbrrr ••• abb arr rar brr rbr raa rbb rrr rrr abb abr bar arr rar brr rbr raa rbb rrr rrr abb abr bar aaa arr rar brr rbr raa rbb abr bar bbbrrr rrr abb arr rar brr rbr raa rbb baa arr rar arr rar abb arr rar abb arr rar nhh baa arr rar auu nhh baa arr rar auu nhh baa arr rar auu abb baa arr rar abb baa arr rar abb baa arr rar CluU baa arr rar auu baa arr rar abb baa arr rar abb baa arr rar abb baa arr rar abb baa arr rar
rrr abb
brr rbr
rrr abb
brr rbr
1. CYCLES OF ALGEBRAS I l 3 i6-1316i 3 i 6
438i3ie
aaa bbb rrr rrr abb baa arr rar brr rbr raa rbb rra rrb abr bar bar aaa bbb rrr rrr abb arr rar brr rbr raa rbb aor bar baa arr rar brr rbr raa rbb rrr 7
7
439i3ie AAC\
nhh
UiUU aaa bbb rrr oaa arr abb 441i316 aaa baa arr rrr rrr rrr abb baa arr 442 13 ie rrr rrr abb baa arr 443i3ie aaa 444i3ie aaa bbb rrr rrr abb baa arr
445i3ie 446i3ie 447i3ie 448i3ie 449i3i6 450i3i6 451i3ie 452i3i 6 453i3ie 454i3i 6 455i3ie 456i3ie 457i3ie 458i3i6 459i3ie 460i3i6 461i316 462i3ie 463i3i6 464i3i 6 465i3ie 466i3ie 467i3i 6
aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa
468i3i6 469i3i6
aaa
470i3i6 4711316 472i3i 6
aaa
473i3i6
aaa
474i3ie 475i3ie
aaa
476i3ie
477 13 ie aaa 478i3i6 479i3i6
aaa
480i3i6 4811316
482 13 ie
aaa
bbb rrr bbb bbb rrr bbb rrr bbb bbb rrr
rrr abb rrr abb abb
nhh
bbb
nhh
rrr bbb rrr
abb
abb
rrr rrr rrr rrr bbb rrr rrr bbb
abb abb abb abb nhh
auu
bbb
nhh
rrr bbb rrr
abb abb
rrr rrr rrr rrr bbb rrr rrr bbb
rrr rrr bbb rrr bbb rrr rrr rrr bbb rrr bbb rrr rrr rrr bbb rrr bbb rrr rrr rrr bbb rrr
baa
rrr abb baa rrr abb baa
abb abb abb abb
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
abb abb abb abb
rrr rrr rrr rrr
abb abb abb abb
baa baa abb baa abb baa rrr abb baa rrr abb baa rrr abb baa abb
abb
arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr
aor bar aor bar 7
brr rbr rbb rar brr rbr raa rbb rar raa rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar
brr rbr raa rbb brr rbr raa rbb brr rbr raa rbb
bar bar bar aor bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar 7 7
7
brr brr brr brr brr brr
brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr
rbr rbr rbr rbr rbr rbr
rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr
raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa
rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra
4329 FINITE INTEGRAL RELATION ALGEBRAS
524i3ie
aaa bbbrrr rrr abbbaa arr rar brr rbr raa rbb rra rrb abr bar rra • • • abr bar aaa bbbrrr rrr abbbaa Ul 1 1 Ul 1 UUi • • • rrr arr • • • brr rbr raa • • • rra • • • abr bar abb abb arr • • • brr rbr raa • • • rra • • • abr bar rrr aaa bbbrrr abb arr • • • brr rbr raa • • • rra • • • abr bar abb aaa bbbrrr arr • • • brr rbr raa • • • rra • • • abr bar arr • • • brr rbr raa • • • rra • • • abr bar rrr rrr abb aaa arr • • • brr rbr raa • • • rra • • • abr bar rrr rrr abb bbbrrr rrr abb arr • • • brr rbr raa • • • rra • • • abr bar arr • • • brr rbr raa • • • rra • • • abr bar aaa bbbrrr rrr abb abbbaa arr • • • brr rbr raa • • • rra • • • abr bar rrr abbbaa arr • • • brr rbr raa • • • rra • • • abr bar rrr aaa bbbrrr abbbaa arr • • • brr rbr raa • • • rra • • • abr bar abbbaa arr • • • brr rbr raa • • • rra • • • abr bar aaa bbbrrr rrr rrr abbbaa arr • •• brr rbr raa • • • rra • • • abr bar aaa rrr rrr abbbaa arr • • • brr rbr raa • • • rra • • • abr bar bbbrrr rrr abbbaa arr • •• brr rbr raa • • • rra • • • abr bar aaa bbbrrr rrr abbbaa arr • •• brr rbr raa • • • rra • • • abr bar abb rrr arr rar brr rbr raa • • • rra • • • abr bar abb aaa rrr arr rar brr rbr raa • • • rra • • • abr bar bbbrrr abb arr rar brr rbr raa • • • rra • • • abr bar abb aaa bbbrrr arr rar brr rbr raa • • • rra • • • abr bar rrr abb arr rar brr rbr raa • • • rra • • • abr bar rrr abb aaa arr rar brr rbr raa • • • rra • • • abr bar bbb rrr abb arr rar brr rbr raa • • • rra • • • abr bar rrr abb aaa bbb arr rar brr rbr raa • • • rra • • • abr bar rrr rrr abb arr rar brr rbr raa • • • rra • • • abr bar aaa rrr rrr abb arr rar brr rbr raa • • • rra • • • abr bar bbbrrr rrr abb arr rar brr rbr raa • • • rra • • • abr bar aaa bbbrrr rrr abb arr rar brr rbr raa • • • rra • • • abr bar abbbaa arr rar brr rbr raa • • • rra • • • abr bar aaa abbbaa arr rar brr rbr raa • • • rra • • • abr bar aaa bbb abbbaa arr rar brr rbr raa • • • rra • • • abr bar rrr abbbaa arr rar brr rbr raa • • • rra • • • abr bar aaa rrr bbbrrr abbbaa arr rar brr rbr raa • • • rra • • • abr bar abbbaa arr rar brr rbr raa • • • rra • • • abr bar aaa bbbrrr rrr abbbaa arr rar brr rbr raa • • • rra • • • abr bar rrr abbbaa arr rar brr rbr raa • • • rra • • • abr bar aaa bbb rrr abbbaa arr rar brr rbr raa • • • rra • • • abr bar rrr abbbaa arr rar brr rbr raa • • • rra • • • abr bar aaa bbb rrr rrr abbbaa arr rar brr rbr raa • • • rra • • • abr bar aaa rrr rrr abbbaa arr rar brr rbr raa • • • rra • • • abr bar bbbrrr rrr abbbaa arr rar brr rbr raa • • • rra • • • abr bar
525i3i6
aaa bbbrrrrrrabbbaaarrrar
526i3i6
aaa rrr aaa bbbrrr
483i3i6 484 13 ie 485i3i6 486i3i6 487i3i6 488i3ie 489i3ie 490i3i6 491i3i6 492i3ie 493i3ie 494i3ie 495i3ie 496i3i6 497i3ie 498i3ie 499i3ie 500i3i6 501i3i6 502i3ie 503i3ie 504i3ie 505i3i6 506i3i6 507i3ie 508i3i6 509i3ie 510i3i6 511i3i6 512i3i6 5131316 514i3i6 515l3l6 5161316 517l3l6 5181316 5191316 5201316 5211316 522i3i6 523i3i6
527i3ie
abb abb
arr arr
brr rbr raa
• ••
rra
• • • abr bar
rbb rra • • • abr bar rbb rra • • • abr bar
1. CYCLES OF ALGEBRAS li 3 i 6 -1316i 3 i 6
528i3i6 529i3ie 530i3i6 5311316 532i3ie 533i3ie 534i3ie 535i3i6 536i3ie 537i3ie 538i3i6 539i3ie 540i3ie 541i3i6 542i3ie 543i3ie 544i3i6 545i3ie 546i3ie 547i3ie 548i3ie 549i3ie 550i3i6 551i3i6 552i3i6 553i3i6 554i3i6 555i3i6 556i3i6 557i3i6 558i3i6 559i3ie 560i3i6 561l316 562i3i6 563i3i6 564i3ie 565i3i6 566i3i6 567i3i6 568i3i6 569i3ie 570i3ie 5711316 572i3i6
aaa bbbrrr rrr abbbaa arr rar brr rbr raa rbb rra rrb abr bar rhh aaa rrr rrr abb arr rar 1 UU rra • • • abr bar aaa bbbrrr rrr abb ••• rbb rra • • • abr bar arr rar aaa rrr baa arr rar ••• rbb rra • • • abr bar rhh rra • • • abr bar aaa bbbrrr baa arr rar hh rra • • • abr bar aaa rrr rrr ••• baa arr rar hh rra •• • abr bar aaa bbbrrr rrr ••• baa arr rar 77 nhh baa arr rar aaa rra •• • abr bar auu ••• roo nhh baa arr rar rhh aaa bbb I UU rra •• • abr bar auu rhh aaa rrr •••abb baa arr rar I UU rra •• • abr bar rhh rra • • • abr bar aaa bbbrrr • • • abb baa arr rar hh rra • • • abr bar aaa rrr rrr abbbaa arr rar hh rra • • • abr bar aaa bbbrrr rrr abbbaa arr rar 77 aaa rrr rrr abb rra • • • abr bar rar brr ••• roo rhh aaa bbbrrr rrr abb rar brr I UU rra • • • abr bar rhh aaa bbbrrr rrr ••• baa rar brr I UU rra • • • abr bar rhh rra • • • abr bar aaa rar brr rrr rrr abbbaa aaa bbbrrr rrr abbbaa ••• rbb rra • • • abr bar rar brr 77 aaa rrr • • • abb rra • • • abr bar arr rar brr ••• roo 77 aaa bbbrrr • • • abb rra • • • abr bar arr rar brr ••• roo rhh aaa rrr rrr abb arr rar brr I UU rra • • • abr bar rhh rra • • • abr bar aaa bbbrrr rrr abb arr rar brr rhh rra • • • abr bar aaa bbbrrr baa arr rar brr hh rra • • • abr bar aaa bbbrrr rrr ••• baa arr rar brr 77 aaa rrr • • • abb baa arr rar brr rra •• • abr bar ••• roo 77 aaa bbbrrr • • • abb baa arr rar brr rra •• • abr bar ••• roo aaa ••• rbb rra •• • abr bar rrr rrr abbbaa arr rar brr aaa bbbrrr rrr abbbaa arr rar brr ••• rbb rra •• • abr bar aaa brr rbr ••• rbb rra • • • abr bar rrr rrr ••• aaa bbbrrr brr rbr ••• rbb rra • • • abr bar aaa rrr abb brr rbr ••• rbb rra • • • abr bar aaa bbb rrr abb brr rbr ••• rbb rra • • • abr bar aaa rrr rrr abb brr rbr ••• rbb rra • • • abr bar aaa bbbrrr rrr abb brr rbr ••• rbb rra • • • abr bar aaa brr rbr ••• rbb rra • • • abr bar rrr rrr ••• baa aaa bbbrrr rrr ••• baa brr rbr ••• rbb rra • • • abr bar aaa rrr abbbaa brr rbr ••• rbb rra • • • abr bar aaa bbb rrr abbbaa brr rbr ••• rbb rra • • • abr bar aaa rrr rrr abbbaa brr rbr ••• rbb rra • • • abr bar aaa bbbrrr rrr abbbaa brr rbr ••• rbb rra • • • abr bar aaa arr brr rbr ••• rbb rra • • • abr bar rrr rrr ••• aaa bbbrrr arr brr rbr ••• rbb rra •• • abr bar aaa rrr rrr abb arr brr rbr ••• rbb rra •• • abr bar aaa bbbrrrrrr abb brrrbr• • • rbb rra • • • abr bar arr aaa rrr rrr ••• baa arr brr rbr ••• rbb rra •• • abr bar aaa bbbrrr rrr ••• baa arr brr rbr ••• rbb rra •• • abr bar
4329 FINITE INTEGRAL RELATION ALGEBRAS
573i3i6 574i3i6 575i3i6 576i3i6 577i3ie 578i3ie 579i3ie 580i3ie 581l3l6 582i3ie 583i3ie 584i3i6 585i3i6 5861316 587i3ie 588i3i6 589i3ie 590i3ie 5911316 592i3ie 593i3ie 594i3ie 595i3ie 596i3ie 597i3ie 598i3ie 599i3ie 6001316 6OI1316 602i3i6 603i3ie f\C\A 605i3ie 6O61316 607i3ie 6O81316 609i3ie 6IO1316 6II1316 612l3l6 6131316 614i3i6
aaa bbbrrr rrr abbbaa arr rar brr rbrraa rbbrra rrb abr bar aaa rrr rrr abbbaa arr • • • brr rbr rbbrra •• • abr bar aaa bbbrrr rrr abbbaa arr • • • brr rbr rbbrra • • • abr bar arr rar brr rbr aaa rrr rbbrra • • • abr bar arr rar brr rbr aaa bbbrrr rbbrra • • • abr bar arr rar brr rbr rrr rrr aaa rbbrra • • • abr bar arr rar brr rbr aaa bbbrrr rrr rbbrra • • • abr bar arr rar brr rbr aaa abb rbbrra • • • abr bar rrr abb arr rar brr rbr aaa bbbrrr rbbrra • • • abr bar rrr abb arr rar brr rbr aaa rbbrra • • • abr bar rrr abb arr rar brr rbr aaa bbb rbbrra • • • abr bar rrr rrr abb arr rar brr rbr aaa rbbrra • • • abr bar arr rar brr rbr aaa bbbrrr rrr abb rbbrra •• • abr bar baa arr rar brr rbr aaa rbbrra •• • abr bar rrr baa arr rar brr rbr aaa bbbrrr rbbrra •• • abr bar baa arr rar brr rbr rrr aaa rbbrra •• • abr bar baa arr rar brr rbr rrr aaa bbb rbbrra •• • abr bar baa arr rar brr rbr rrr rrr aaa rbbrra •• • abr bar baa arr rar brr rbr aaa bbbrrr rrr rbbrra • • • abr bar abbbaa arr rar brr rbr aaa rbbrra • • • abr bar rrr abbbaa arr rar brr rbr aaa bbbrrr rbbrra • • • abr bar rrr abbbaa arr rar brr rbr aaa rbbrra • • • abr bar rrr abbbaa arr rar brr rbr aaa bbb rbbrra • • • abr bar aaa rrr rrr abbbaa arr rar brr rbr rbbrra • • • abr bar aaa bbbrrr rrr abbbaa arr rar brr rbr rbbrra • • • abr bar abb arr rar aaa raa rbbrra • • • abr bar rrr abb arr rar aaa bbbrrr raa rbbrra • • • abr bar arr rar aaa rrr rrr abb raa rbbrra • • • abr bar arr rar aaa bbbrrr rrr abb raa rbbrra •• • abr bar baa arr rrr raa rbbrra •• • abr bar baa arr rar aaa raa rbbrra •• • abr bar rrr bbbrrr baa arr rar raa rbbrra •• • abr bar 1 bbb rbb rra •• • abr bar rar oaa arr raa aaa uuu rrr rbb rra • • • abr bar rar baa arr raa rrr baa arr rar rrr aaa raa rbbrra • • • abr bar bbb rrr baa arr raa rbbrra • • • abr bar baa arr rar aaa bbb raa rbbrra • • • abr bar rrr baa arr far raa rbbrra • • • abr bar rrr rrr baa arr i at rrr rrr aaa raa rbbrra • • • abr bar bbbrrr rrr baa arr rar raa rbbrra • • • abr bar baa arr rar aaa bbbrrr rrr raa rbbrra • • • abr bar abbbaa arr aaa raa rbbrra • • • abr bar abbbaa arr rar aaa bbb raa rbbrra • • • abr bar
rrr
615l3l6 6161316 617l3l6
aaa
rrr bbbrrr
abbbaaarr
abb baa arr rar abb baa arr rar
raarbbrra • • • abr raa rbbrra • • • abr raa rbbrra • • • abr
bar bar bar
1. CYCLES OF ALGEBRAS li 3 i 6 -1316i 3 i 6
aaa bbb rrr rrr abb baa abb baa 6181316 aaa bbb rrr rrr abb baa 6191316 rrr abb baa 6201316 aaa bbb rrr abb baa 6211316 rrr abb baa 622 1 3 i6 aaa bbb rrr rrr abb baa 623i3ie rrr rrr abb baa 624i3ie aaa bbb rrr rrr abb baa 625i3ie 6261316 aaa bbb rrr rrr abb baa rrr abb 627i3ie aaa abb 628i3ie aaa bbb rrr rrr rrr abb 629i3ie aaa 630i3ie aaa bbb rrr rrr abb bbb rrr baa 631l3l6 632i3i6 aaa bbb rrr baa bbb rrr rrr baa 633i3i6 baa 634i3ie aaa bbb rrr rrr rrr abb baa 635i3i6 rrr abb baa 636i3i6 aaa bbb rrr abb baa 637i3i6 abb baa 638i3i6 aaa bbb rrr rrr rrr abb baa 639i3ie rrr rrr abb baa 640i3ie aaa 641i3i 6 bbb rrr rrr abb baa 642i3ie aaa bbb rrr rrr abb baa rrr abb 643i3ie aaa abb 644i3ie aaa bbb rrr rrr rrr abb 645i3ie aaa 646i3ie aaa bbb rrr rrr abb 647i3i 6 bbb rrr baa baa 648i3ie aaa bbb rrr bbb rrr baa 649i3ie rrr baa 650i3ie aaa bbb bbb rrr rrr baa 651l316 652i3i6 aaa bbb rrr rrr baa abb baa 653i3i6 aaa abb baa 654i3ie aaa bbb rrr abb baa 655i3i6 rrr abb baa 656i3i6 aaa bbb rrr abb baa 657i3i6 abb baa 658i3ie aaa bbb rrr rrr abb baa 659i3ie rrr abb baa 66O1316 aaa bbb rrr abb baa 66I1316 662i3i6 aaa bbb rrr abb baa
arr arr arr arr arr arr arr arr arr arr
arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr
rar brr rbr raa rbb rra rrb abr bar
''
rar rar rar
rar rar rar
rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar
* *
brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr
rbb rra
raarbb rra raarbb rra raarbb rra rbb rbb rbb raarbb raarbb raa raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb raa rbb
rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra
abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar
4329 FINITE INTEGRAL RELATION ALGEBRAS
663i3i6 6641316 665i3i6 6661316 667i3i6 6681316 669i3i6 670i3i6 6711316
aaa bbb rrr rrr rrr rrr • • • rrr rrr bbb rrr rrr bbb rrr rrr • • •
abb abb abb abb abb
rrr
rrr
bbb rrr bbb rrr rrr
rrr rrr bbb rrr rrr bbb rrr rrr rrr
675i3i6 6761316 677i3ie 678i3i6 679i3i6 68O1316 68I1316
684i3ie 685i3i6 6861316 687i3ie 6881316 689i3ie 690i3ie 6911316
692 13 i 6 693i3ie 694i3ie 695i3ie 696i3ie 697i3ie 698i3ie 699i3ie 700i3i6 701i3i6 702i3ie 703i3ie 704i3ie 705i3ie 706i3i6 707i3ie
rrr
abb
rrr
abb
bbb rrr bbb rrr rrr rrr bbb rrr bbb rrr r r r rrr r r r rrr bbb rrr rrr bbb rrr rrr
abb abb
abb abb abb abb abb abb
rrr rrr
bbb rrr bbb rrr rrr
rrr rrr bbb rrr rrr aaa bbb rrr rrr abb aaa abb aaa bbb abb rrr abb rrr abb bbb rrr abb bbb rrr rrr abb rrr abb bbb rrr abb bbb rrr abb rrr abb rrr rrr abb bbb rrr rrr abb rrr
baa arr rar brr rbr baa arr rarbrr • • • baa arr rarbrr • • • baa arr rarbrr • • • baa arr rarbrr • • • brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr •• • brr rbr ••• brr rbr ••• brr rbr •• • brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr baa brr rbr baa brr rbr baa brr rbr baa brr rbr baa brr rbr baa brr rbr baa brr rbr baa brr rbr baa brr rbr baa brr rbr baa brr rbr baa brr rbr baa brr rbr baa brr rbr baa brr rbr baa brr rbr baa brr rbr baa brr rbr baa brr rbr baa brr rbr baa
raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa
rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb
rra rrb abr bar abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra abr bar rra
1. CYCLES OF ALGEBRAS li 3 i 6 -1316i 3 i 6
708i3i6 709i3ie 710i3i6 711i3i6 712 13 i6 7131316 714l316 715l3l6 7161316 717 13 ie 718 13 ie 7191316 720i3i6 721i3i6 722i3i6 723i3ie 724i3i6 725i3i6 726i3i6 727i3i6 728i3i6 729i3ie 730i3i6 731i3i6 732i3i6 733i3i6 734i3i6 735i3i6 736i3i6 737i3i6 738i3i6 739i3i6 740i3i6 7411316 742i3i6 743i3i6 744i3ie 745i3ie 746i3ie 747i3i6 748i3i6 749i3i6 750i3i6 751i3i6 752i3i6
aaa bbbrrr rrr abb baa arr rar brr rbr raa rbbrra rrb abr aaa bbbrrr rrr abb baa brr rbr raa rbbrra • • • abr arr brr rbr raa rbbrra • • • abr aaa rrr arr brr rbr raa rbbrra • • • abr bbbrrr arr brr rbr raa rbbrra • • • abr aaa bbbrrr arr brr rbr raa rbbrra • • • abr rrr rrr arr brr rbr raa rbbrra • • • abr aaa rrr rrr arr brr rbr raa rbbrra • • • abr bbbrrr rrr arr brr rbr raa rbbrra • • • abr aaa bbbrrr rrr arr brr rbr raa rbbrra • • • abr rrr abb arr brr rbr raa rbbrra • • • abr abb aaa rrr arr brr rbr raa rbbrra • • • abr bbbrrr abb arr brr rbr raa rbbrra • • • abr aaa bbbrrr abb arr brr rbr raa rbbrra • • • abr rrr rrr abb arr brr rbr raa rbbrra • • • abr aaa rrr rrr abb arr brr rbr raa rbbrra • • • abr bbbrrr rrr abb arr brr rbr raa rbbrra • • • abr aaa bbbrrr rrr abb arr brr rbr raa rbbrra • • • abr baa arr rrr brr rbr raa rbbrra • • • abr baa arr aaa rrr brr rbr raa rbbrra • • • abr bbbrrr baa arr brr rbr raa rbbrra • • • abr baa arr aaa bbbrrr brr rbr raa rbbrra • • • abr baa arr rrr rrr brr rbr raa rbbrra • • • abr baa arr aaa rrr rrr brr rbr raa rbbrra • • • abr baa arr bbbrrr rrr brr rbr raa rbbrra • • • abr baa arr aaa bbbrrr rrr brr rbr raa rbbrra • • • abr abb baa arr rrr brr rbr raa rbbrra • • • abr abb baa arr aaa rrr brr rbr raa rbbrra • • • abr abb baa arr bbbrrr brr rbr raa rbbrra • • • abr abb baa arr aaa bbbrrr brr rbr raa rbbrra • • • abr rrr rrr abb baa arr brr rbr raa rbbrra • • • abr aaa rrr rrr abb baa arr brr rbr raa rbbrra • • • abr bbbrrr rrr abbbaa arr brr rbr raa rbbrra • • • abr aaa bbbrrr rrr abb baa arr brr rbr raa rbbrra • • • abr arr rar brr rbr raa rbbrra • • • abr rrr rrr aaa arr rar brr rbr raa rbbrra • • • abr bbbrrr arr rar brr rbr raa rbbrra • • • abr aaa bbbrrr arr rar brr rbr raa rbbrra • • • abr rrr rrr arr rar brr rbr raa rbbrra • • • abr rrr rrr aaa arr rar brr rbr raa rbbrra • • • abr bbbrrr rrr arr rar brr rbr raa rbbrra • • • abr aaa bbbrrr rrr arr rar brr rbr raa rbbrra • • • abr abb rrr arr rar brr rbr raa rbbrra • • • abr rrr abb arr rar brrrbrraa rbbrra • • • abr aaa bbbrrr abb arr rar brr rbr raa rbbrra • • • abr abb arr rar brr rbr raa rbbrra • • • abr aaa bbbrrr
bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar
bar bar bar
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
753i3i6 754i3ie 755i3i6 756i3i6 757i3i6 758i3ie 759i3ie 760i3ie 761l3l6 762i3ie 763i3i6 764i3i6 765i3i6 766i3ie 767i3ie 768i3ie 769i3ie 770i3ie 7711316 772i3i 6 773i3i 6 774i3i6 775i3i6 776i3ie 777i3i6 778i3ie 779i3ie 780i3ie 7811316 782i3ie 783i3i6 784i3ie 785i3ie 786i3ie 787i3i6 7881316 789i3ie 790i3i6 791l316 792i3ie 793i3ie 7QA
aaa bbb rrr rrr rrr aaa rrr bbb rrr aaa bbb rrr rrr rrr aaa rrr rrr bbb rrr rrr aaa bbb rrr rrr rrr aaa rrr bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr rrr rrr aaa rrr rrr bbb rrr rrr aaa bbb rrr rrr aaa aaa bbb rrr aaa rrr bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr rrr rrr aaa rrr rrr bbb rrr rrr aaa bbb rrr rrr aaa bbb rrr aaa bbb rrr rrr aaa bbb rrr aaa bbb rrr rrr aaa bbb rrr aaa bbb rrr rrr aaa bbb rrr hhh
aaa uuu rrr rrr bbb rrr aaa aaa bbb rrr rrr
795i3ie 796i3ie 797i3i6 aaa bbb rrr
abb baa arr rar brr rbr raa rbb rra arr rar brr rbr raa rbb rra abb arr rar brr rbr raa rbb rra abb arr rar brr rbr raa rbb rra abb arr rar brr rbr raa rbb rra abb arr rar brr rbr raa rbb rra abb arr rar brr rbr raa rbb rra abb arr rar brr rbr raa rbb rra abb arr rar brr rbr raa rbb rra abb baa arr rar brr rbr raa rbb rra baa arr rar brr rbr raa rbb rra baa arr rar brr rbr raa rbb rra baa arr rar brr rbr raa rbb rra baa arr rar brr rbr raa rbb rra baa arr rar brr rbr raa rbb rra baa arr rar brr rbr raa rbb rra baa arr rar brr rbr raa rbb rra baa arr rar brr rbr raa rbb rra baa arr rar brr rbr raa rbb rra baa arr rar brr rbr raa rbb rra baa arr rar brr rbr raa rbb rra abb baa arr rar brr rbr raa rbb rra abb baa arr rar brr rbr raa rbb rra abb baa arr rar brr rbr raa rbb rra abb baa arr rar brr rbr raa rbb rra abb baa arr rar brr rbr raa rbb rra abb baa arr rar brr rbr raa rbb rra abb baa arr rar brr rbr raa rbb rra abb baa arr rar brr rbr raa rbb rra abb baa arr rar brr rbr raa rbb rra abb baa arr rar brr rbr raa rbb rra abb baa arr rar brr rbr raa rbb rra abb baa arr rar brr rbr raa rbb rra abb baa arr rar brr rbr raa rbb rra abb baa arr rar brr rbr raa rbb rra arr rar rra arr rar rra arr rar abb rra arr rar abb rra baa arr rar rra baa arr rar rra abb baa arr rar rra nhh
CiUU
7
oaa arr rar
arr rar arr rar abb
7
orr '' arr rar orr '' 7
rrb abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr rrb abr rrb abr rrb abr rrb abr rrb abr rrb abr rrb abr
bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar
rrb abr bar rra rrb abr bar rra rra rrb abr bar rra rrb abr bar
1. CYCLES OF ALGEBRAS Ii3i 6 -1316i 3 i 6
aaa bbb rrr rrr abb baa arr rar brr rbr raa rbb rra rrb abr bar 798i3ie 799i3ie 8OO1316 8OI1316 80213ie 803i3ie 804i3ie 8O61316 807i3ie QAQ
OUO1316 809l316 8101316 8II13I6 812i3i6 8131316 814i316 815l3l6 8161316 817l3l6 8181316 8191316 8201316 821i316
bbb rrr bbb rrr bbb rrr rrr bbb rrr rrr • • • rrr
• • • abb
• • • rrr
• • • abb
bbb rrr • • • abb bbb rrr • • • abb
• • • rrr rrr abb • • • rrr rrr abb
bbb rrr rrr abb bbb rrr rrr abb 825i3i6
bbb rrr
baa
826i3ie
bbb rrr
60a
827i3ie
bbb rrr rrr • • • baa
8281316
bbb rrr rrr • • • baa • • • rrr
• • • abb
baa
• • • rrr
• • • abb
baa
8311316
bbb rrr • • • abb baa
832i3ie
bbb rrr • • • abb baa
833i3ie
• • • rrr rrr abb baa
834i3ie
rra rrb
aaa bbb rrr rrr abb • • • arr rar brr baa arr rar brr aaa bbb rrr aaa bbb rrr rrr • • • baa arr rar brr aaa bbb rrr • • • abb baa arr rar brr aaa bbb rrr rrr abb baa arr rar brr arr rar brr rbr aaa bbb rrr bbb rrr rrr arr rar brr rbr aaa 066 • • • arr rar brr rbr aaa bbb aaa bbb rrr • • • abb • • • arr rar brr rbr aaa bbb • • • rrr abb • • • arr rar brr rbr aaa bbb rrr rrr abb • • • arr rar brr rbr 066 60a arr rar brr rbr aaa bbb aaa bbb rrr • • • abb baa arr rar brr rbr aaa bbb • • • rrr abb baa arr rar brr rbr aaa bbb rrr rrr abb baa arr rar brr rbr
• • • rrr rrr abb baa
bbb rrr rrr abb baa bbb rrr rrr abb baa 837i3ie
bbb rrr
arr
838i3i6
bbb rrr
arr
839i3ie
bbb rrr rrr
arr
840i3ie
aaabbb rrr rrr
841l316
• • • rrr
• • • abb
• • • arr
• • • rrr
• • • abb
• • • arr
arr
rrb rrarrb rrarrb rra rrb rra rrb rra rrb rrb rra rrb rra rrb rra rrb rra rra rrb rrb rra rrb rra rrb rra raa • • • rrarrb raa • • • rrarrb raa • • • rrarrb raa • • • rrarrb rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa • • • rra rrb raa
rra
•••
rra
abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr
bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
843i3i6 844 13 ie 845i3ie 846i3ie 847i3ie 848i3ie 849i3ie 850i3i6 851l3l6 852i3i6 853i3i6 854i3ie 855i3i6 856i3i6 857i3i6 858i3i6 859i3ie 86O1316 86I1316 862i3i6 863i3i6 864i3i6 865i3ie 8661316 867i3i6 8681316 869i3ie 870i3ie 8711316 872i3ie 873i3i6 874i3ie 875i3i6 876i3ie 877i3i6 878i3i6 879i3ie 88O1316 88I1316 882i3i6 883i3i6 884i3ie
aaa bbbrrr rrr abbbaa arr rar brr rbr raa rbb rra rrbabrbar arr raa • • • rra rrbabrbar bbbrrr abb arr abb aaa bbbrrr raa • • • rra rrbabrbar arr rrr rrr abb raa • • • rra rrbabrbar raa • • • rra rrbabrbar arr aaa rrr rrr abb raa • • • rra rrbabrbar bbbrrr rrr abb arr raa • • • rra rrbabrbar arr aaa bbbrrr rrr abb bbbrrr baa arr raa • • • rra rrbabrbar baa arr aaa bbbrrr raa • • • rra rrbabrbar bbbrrr rrr baa arr raa • • • rra rrbabrbar raa • • • rra rrbabrbar baa arr aaa bbbrrr rrr raa • • • rra rrbabrbar abbbaa arr rrr raa • • • rra rrbabrbar abbbaa arr rrr aaa bbbrrr abbbaa arr raa • • • rra rrbabrbar abbbaa arr aaa bbbrrr raa • • • rra rrbabrbar rrr rrr abbbaa arr raa • • • rra rrbabrbar raa • • • rra rrbabrbar rrr rrr abbbaa arr aaa raa • • • rra rrbabrbar bbbrrr rrr abbbaa arr aaa bbbrrr rrr abbbaa arr raa • • • rra rrbabrbar bbbrrr arr rar raa • • • rra rrbabrbar arr rar aaa bbbrrr raa • • • rra rrbabrbar raa • • • rra rrbabrbar bbbrrr rrr arr rar raa • • • rra rrbabrbar arr rar aaa bbbrrr rrr raa • • • rra rrbabrbar abb arr rar rrr abb arr rar rrr aaa raa • • • rra rrbabrbar bbbrrr abb arr rar raa • • • rra rrbabrbar abb arr rar aaa bbbrrr raa • • • rra rrbabrbar raa • • • rra rrbabrbar arr rar rrr rrr abb raa • • • rra rrbabrbar arr rar rrr rrr abb aaa raa • • • rra rrbabrbar bbbrrr rrr abb arr rar arr rar aaa bbbrrr rrr abb raa • • • rra rrbabrbar bbb baa arr rar raa • • • rra rrbabrbar baa arr rar aaa bbb raa • • • rra rrbabrbar raa • • • rra rrbabrbar bbbrrr baa arr rar raa • • • rra rrbabrbar baa arr rar aaa bbbrrr raa • • • rra rrbabrbar bbb rrr baa arr rar rrr baa arr rar aaa bbb raa • • • rra rrbabrbar bbbrrr rrr baa arr rar raa • • • rra rrbabrbar baa arr rar aaa bbbrrr rrr raa • • • rra rrbabrbar raa • • • rra rrbabrbar abbbaa arr rar raa • • • rra rrbabrbar abbbaa arr rar aaa raa • • • rra rrbabrbar bbb abbbaa arr rar abbbaa arr rar aaa bbb raa • • • rra rrbabrbar
885i3i6 8861316 887i3i6
aaa
rrr
abbbaaarrrar
rrr bbbrrr
abb baa arr rar abb baa arr rar
raa raa raa
rrbabrbar rrbabrbar rra rrbabrbar
• ••
rra
• ••
rra
• ••
1. CYCLES OF ALGEBRAS li 3 i 6 -1316i 3 i 6
8881316 889i3i6 890i3i6 8911316 892i3ie 893i3i6 894i3ie 895i3ie 896i3i6 897i3i6 898i3ie 899i3i6 900i3i6 901i3i6 902i3i6 903i3ie 904i3i6 905i3i6 906i3i6 907i3i6 908i3i6 909i3ie 910i3i6 911i3i6 912l316 9131316 914i316 9151316 9161316 9171316 9181316 9191316 9201316 9211316 922i3i6 923i3i6 924i3ie 925i3i6 926i3i6 927i3i6 928i3i6 929i3i6 930i3i6 931i3i6 932i3ie
aaa bbbrrr rrr abb baa arr rar brr rbr raa rbb rra rrb abr bar aaa bbbrrr •• • abb baa arr rar • • • raa • • • rra rrb abr bar rrr abb baa arr rar • • • raa • • • rra rrb abr bar aaa rrr abb baa arr rar • • • raa • • • rra rrb abr bar rrr abb baa arr rar • • • raa • • • rra rrb abr bar bbb aaa bbb rrr abb baa arr rar • • • raa • • • rra rrb abr bar rrr rrr abb baa arr rar • • • raa • • • rra rrb abr bar rrr rrr abb baa arr rar aaa • • • raa • • • rra rrb abr bar bbbrrr rrr abb baa arr rar • • • raa • • • rra rrb abr bar • • • raa • • • rra rrb abr bar aaa bbbrrr rrr abb baa arr rar bbbrrr brr • • • raa • • • rra rrb abr bar aaa bbbrrr brr • • • raa • • • rra rrb abr bar bbbrrr rrr • • • brr • • • raa • • • rra rrb abr bar aaa bbbrrr rrr • • • brr • • • raa • • • rra rrb abr bar rrr •• • abb brr • • • raa • • • rra rrb abr bar rrr ••• abb aaa brr • • • raa • • • rra rrb abr bar bbbrrr •• • abb brr • • • raa • • • rra rrb abr bar aaa bbbrrr • • • abb brr • • • raa • • • rra rrb abr bar rrr rrr abb brr • • • raa • • • rra rrb abr bar rrr rrr abb aaa brr • • • raa • • • rra rrb abr bar bbbrrr rrr abb brr • • • raa • • • rra rrb abr bar aaa bbbrrr rrr abb brr • • • raa • • • rra rrb abr bar baa bbbrrr brr • • • raa • • • rra rrb abr bar baa aaa bbbrrr brr • • • raa • • • rra rrb abr bar bbbrrr rrr • •• baa brr • • • raa • • • rra rrb abr bar aaa bbbrrr rrr ••• baa brr • • • raa • • • rra rrb abr bar rrr ••• abb baa brr • • • raa • • • rra rrb abr bar rrr •• • abb baa aaa brr • • • raa • • • rra rrb abr bar bbbrrr ••• abb baa brr • • • raa • • • rra rrb abr bar aaa bbbrrr •• • abb baa brr • • • raa • • • rra rrb abr bar rrr rrr abb baa brr • • • raa • • • rra rrb abr bar rrr rrr abb baa aaa brr • • • raa • • • rra rrb abr bar bbbrrr rrr abb baa brr • • • raa • • • rra rrb abr bar aaa bbbrrr rrr abb baa brr • • • raa • • • rra rrb abr bar bbbrrr arr brr • • • raa • • • rra rrb abr bar arr aaa bbbrrr brr • • • raa • • • rra rrb abr bar bbbrrr rrr ••• arr brr • • • raa • • • rra rrb abr bar arr aaa bbbrrr rrr • •• brr • • • raa • • • rra rrb abr bar rrr •• • abb arr brr • • • raa • • • rra rrb abr bar rrr ••• abb arr aaa brr • • • raa • • • rra rrb abr bar bbbrrr •• • abb arr brr • • • raa • • • rra rrb abr bar arr aaa bbbrrr • • • abb brr • • • raa • • • rra rrb abr bar rrr rrr abb arr brr • • • raa • • • rra rrb abr bar rrrrrr abb brr• • • raa • • • rra rrbabrbar arr aaa bbbrrr rrr abb brr • • • raa • • • rra rrb abr bar arr brr • • • raa • • • rra rrb abr bar arr aaa bbbrrr rrr abb
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
933i3i6 934 13 ie 935i3ie 936i3ie 937i3ie 938i3ie 939i3ie 940i3ie 941i316 942i3ie 943i3ie 944i3ie 945i3ie 946i3ie 947i3i6 948i3ie 949i3ie 950i3ie 9511316 952i3ie 953i3ie 954i3i6 955i3ie 956i3ie 957i3ie 958i3i6 959i3ie
960i3ie 9611316 962i3ie 963i3ie 964i3ie 965i3ie 966i3i6 967i3ie 968i3ie 969i3ie 970i3i6 9711316 972i3ie 973i3ie 974i3ie 975i3ie
976i3ie 977i3i6
aaa bbb rrr bbb rrr aaa bbb rrr bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr bbb rrr aaa bbb rrr bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr bbb rrr aaa bbb rrr bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr bbb rrr aaa bbb rrr bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr rrr
rrr abb baa baa baa rrr baa rrr baa abb baa abb baa abb baa abb baa rrr abb baa rrr abb baa rrr abb baa rrr abb baa
rrr rrr
rrr rrr rrr rrr
abb abb abb abb abb abb abb abb
rrr rrr
rrr rrr rrr rrr
abb abb abb abb abb abb abb abb
rrr rrr abb abb abb abb rrr abb
baa baa baa baa baa baa baa baa baa baa baa baa
arr rar brr rbr raa rbb rra rrb abr bar raa rra rrb abr bar arr brr raa rra rrb abr bar arr brr raa rra rrb abr bar arr brr raa rra rrb abr bar arr brr raa rra rrb abr bar arr brr raa rra rrb abr bar arr brr raa rra rrb abr bar arr brr raa rra rrb abr bar arr brr raa rra rrb abr bar arr brr raa rra rrb abr bar arr brr raa rra rrb abr bar arr brr raa rra rrb abr bar arr brr raa rra rrb abr bar rar brr raa rra rrb abr bar rar brr raa rra rrb abr bar rar brr rra rrb abr bar raa rar brr rra rrb abr bar raa rar brr raa rra rrb abr bar rar brr rra rrb abr bar raa rar brr rra rrb abr bar raa rar brr rra rrb abr bar raa rar brr rra rrb abr bar raa rar brr rra rrb abr bar raa rar brr rra rrb abr bar raa rar brr rra rrb abr bar raa rar brr rra rrb abr bar raa rar brr rra rrb abr bar raa rar brr rra rrb abr bar raa rar brr rra rrb abr bar raa rar brr rra rrb abr bar raa rar brr rra rrb abr bar raa rar brr rra rrb abr bar raa rar brr rra rrb abr bar raa rar brr rra rrb abr bar raa rar brr rra rrb abr bar raa rar brr rra rrb abr bar raa rar brr rra rrb abr bar raa arr rar brr rra rrb abr bar raa arr rar brr raa rra rrb abr bar arr rar brr raa rra rrb abr bar arr rar brr raa rra rrb abr bar arr rar brr raa rra rrb abr bar arr rar brr raa rra rrb abr bar arr rar brr raa rra rrb abr bar arr rar brr raa rra rrb abr bar arr rar brr
1. CYCLES OF ALGEBRAS li 3 i 6 -1316i
10191316
aaa bbbrrr rrr abbbaa arr rar brr rbrraa rbb rra rrbabr arr rar brr aaa rrr rrr abb raa • • •rra rrbabr arr rar brr bbbrrr rrr abb raa • • •rra rrbabr arr rar brr aaa bbbrrr rrr abb raa • • •rra rrbabr bbb baa arr rar brr raa • • •rra rrbabr aaa bbb baa arr rar brr raa • • •rra rrbabr bbbrrr raa • • •rra rrbabr baa arr rar brr aaa bbbrrr raa • • •rra rrbabr baa arr rar brr bbb rrr raa • • •rra rrbabr baa arr rar brr raa • • •rra rrbabr rrr aaa bbb baa arr rar brr bbbrrr rrr raa • • •rra rrbabr baa arr rar brr raa • • •rra rrbabr aaa bbbrrr rrr baa arr rar brr abbbaa arr rar brr raa • • •rra rrbabr abbbaa arr rar brr raa • • •rra rrbabr aaa bbb abbbaa arr rar brr raa • • •rra rrbabr abbbaa arr rar brr raa • • •rra rrbabr aaa bbb abbbaa arr rar brr raa • • •rra rrbabr rrr abbbaa arr rar brr raa • • •rra rrbabr aaa rrr raa • • •rra rrbabr bbbrrr abbbaa arr rar brr abbbaa arr rar brr raa • • •rra rrbabr aaa bbbrrr raa • • •rra rrbabr rrr abbbaa arr rar brr rrr abbbaa arr rar brr raa • • •rra rrbabr aaa bbb rrr abbbaa arr rar brr raa • • •rra rrbabr raa • • •rra rrbabr rrr abbbaa arr rar brr aaa bbb raa • • •rra rrbabr rrr rrr abbbaa arr rar brr raa • • •rra rrbabr aaa rrr rrr abbbaa arr rar brr bbbrrr rrr abbbaa arr rar brr raa • • •rra rrbabr raa • • •rra rrbabr aaa bbbrrr rrr abbbaa arr rar brr bbbrrr • •• brr rbrraa • • •rra rrbabr rbrraa • • •rra rrbabr aaa bbbrrr • • • orr bbbrrr rrr rbrraa • • •rra rrbabr rbrraa • • •rra rrbabr aaa bbbrrr rrr nbh rbrraa • • •rra rrbabr (JiUU rrr • • • orr abb • • • brr rbrraa • • •rra rrbabr aaa rrr bbbrrr • • • brr rbrraa • • •rra rrbabr abb rbrraa • • •rra rrbabr • • • brr abb aaa bbbrrr rbrraa • • •rra rrbabr rrr rrr abb ' ' ' orr rbrraa • • •rra rrbabr rrr rrr abb aaa ' ' ' orr bbbrrr rrr abb rbrraa • • •rra rrbabr ' ' ' orr rbrraa • • •rra rrbabr aaa bbbrrr rrr abb • • • orr bbbrrr • • • brr rbrraa • • •rra rrbabr baa rbrraa • • •rra rrbabr • • • brr baa aaa bbbrrr bbbrrr rrr • • • brr rbrraa • • •rra rrbabr baa
10201316
aaa bbbrrrrrr
978i3ie 979i3ie 980i3ie 9811316 982 13 ie 983i3ie 984i3ie 985i3ie 986i3ie 987i3ie 988i3ie 989i3ie 990i3ie 9911316 992 1 3 i 6 993i3ie 994i3ie 995i3ie 996i3ie 997i3ie 998i3ie 999i3ie lOOOisie lOOliaie 1002l316 10031316 1004i316 10051316 10061316 10071316 10081316 1009l316 10101316 10111316 1012i316 10131316 10141316 10151316 10161316 10171316 10181316
10211316 1022i3i6
aaa
rrr rrr
baa
abb baa abb baa
rbrraa • • • brr rbrraa rbrraa
•• ••
1
••
bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar •rrarrbabr bar •rra rrbabr bar •rra rrbabr bar
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
1023i3i6 1 f\OA
1025i3i6 1026i3ie 1027i3i6 1028i3ie 1029i3ie 10301316 10311316 1032i3i6 1033i3i6 1034i3ie 1035i3i6 1036i3ie 1037i3i6 1038i3i6 1039i3ie 1040l316 10411316 1042i3ie 1043i3ie 1044i3i6 1045i3i6 1046i3ie 1047i3i6 1048i3ie 1049i3ie 10501316 10511316 1052i3ie 1053i3i6 1054i3ie 1055i3ie 1056i3i6 1057i3i6 1058i3ie 1059i3i6 10601316 10611316 1062i3i6 1063i3ie 1064i3ie 1065i3ie 10661316 1067i3i6
aaa bbb rrr bbb rrr bbb aaa rrr rrr aaa rrr bbb rrr aaa bbb rrr bbb rrr aaa bbb rrr bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr bbb rrr aaa bbb rrr bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr bbb rrr aaa bbb rrr bbb rrr aaa bbb rrr aaa aaa bbb rrr aaa rrr bbb rrr aaa bbb rrr
rrr abb abb abb rrr abb rrr abb rrr abb rrr abb
rrr rrr
rrr rrr rrr rrr
rrr rrr
rrr rrr rrr rrr
abb abb abb abb abb abb abb abb
rrr rrr
rrr rrr bbb rrr aaa bbb rrr rrr rrr aaa
abb abb abb abb abb abb abb abb
abb abb abb abb abb abb abb abb abb abb abb
baa arr baa baa baa baa baa baa arr arr arr arr arr arr arr arr arr arr arr arr baa arr baa arr baa arr baa arr baa arr baa arr baa arr baa arr baa arr baa arr baa arr baa arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr arr
rar brr rbr raa rbb rra rrb abr bar rra rrb abr bar brr rbr raa
rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar
orr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr
ror rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr
raa ' ' ' rrarro raa rra rrb rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa rra rrb raa
n ti'v* r\n '¥* UiUI ULbl
abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar
1. CYCLES OF ALGEBRAS Ii3i 6 -1316i 3 i 6
aaa bbb rrr rrr abb baa arr arr arr arr arr aaa bbb baa arr bbb rrr baa arr aaa bbb rrr baa arr bbb baa arr rrr aaa bbb baa arr rrr bbb rrr rrr baa arr aaa bbb rrr rrr baa arr abb baa arr aaa abb baa arr bbb abb baa arr aaa bbb abb baa arr rrr abb baa arr aaa rrr abb baa arr bbb rrr abb baa arr aaa bbb rrr abb baa arr rrr abb baa arr aaa rrr abb baa arr bbb rrr abb baa arr aaa bbb rrr abb baa arr rrr rrr abb baa arr aaa rrr rrr abb baa arr bbb rrr rrr abb baa arr aaa bbb rrr rrr abb baa arr
rrr rrr abb 10681316 aaa bbb rrr rrr abb 1069i3ie 1070i3i6 aaa bbb rrr rrr abb bbb baa 10711316 107213ie 1073i3ie
107413ie 1075i3ie 1076i3ie 1077i3ie 1078i3ie 1079i3ie IO8O1316 IO8I1316 1082i3ie 1083i3ie 1084i3ie 1085i3ie IO861316 1087i3ie IO881316 1089i3ie 1090i3i6 1091i3i6 1092i3ie 1093i3ie 1094i3ie 1095i3ie 1096i3ie 1097i3ie 1098i3ie 1099i3ie HOO1316 HOI1316 1102i316 11031316 11041316 11051316 11061316 11071316 11081316 11091316 11101316 11111316 11121316
rrr aaa rrr aaa bbb rrr rrr aaa rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr rrr aaa rrr aaa bbb rrr rrr
rrr rrr rrr abb abb nhh auu nhh auu
abb abb abb abb abb abb abb rrr abb rrr rrr rrr rrr
baa baa baa baa
rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar
brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr brr rbr
raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa
rbb rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra
rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb
abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
aaa bbb rrr rrr abb baa arr rar brr rbr raa rbb rra rrb abr bar rrr rrr abb baa 11131316 aaa 11141316 aaa bbb rrr rrr abb baa rrr arr ••• 11151316 rrr arr ••• 11161316 bbb rrr arr ••• 11171316 bbb rrr arr ••• 11181316 arr ••• rrr rrr 11191316 arr ••• H20l316 rrr rrr arr ••• 11211316 bbb rrr rrr arr ••• 11221316 bbb rrr rrr ••• H23l316 rrr ••• a b b ••• arr ••• 11241316 rrr ••• a b b ••• arr 11251316 bbb rrr • • • a b b • • • arr ••• 1126l3l6 bbb rrr ••• a b b ••• arr ••• ••• 11271316 rrr rrr abb • • • arr ••• 11281316 rrr rrr abb • • • arr 11291316 bbb rrr rrr abb • • • arr ••• 11301316 bbb rrr rrr abb • • • arr ••• 11311316 rrr baa arr ••• 11321316 rrr baa arr ••• 11331316 bbb rrr baa arr ••• 11341316 bbb rrr baa arr ••• 11351316 rrr rrr baa arr ••• 11361316 rrr rrr baa arr ••• 11371316 baa arr ••• bbb rrr rrr 1138l3l6 baa arr ••• bbb rrr rrr arr ••• 11391316 rrr • • • abb baa arr ••• 11401316 rrr • • • abb baa arr ••• 11411316 bbb rrr • • • abb baa 1142i316 bbb rrr • • • abb baa arr ••• arr ••• 11431316 rrr rrr abb baa arr ••• 11441316 rrr rrr abb baa arr ••• 11451316 bbb rrr rrr abb baa arr ••• 11461316 bbb rrr rrr abb baa arr rar 11471316 rrr arr rar 11481316 rrr arr rar 11491316 bbb rrr arr rar 11501316 bbb rrr arr rar 11511316 rrr rrr arr rar 11521316 rrr rrr arr rar 11531316 bbb rrr rrr arr rar 11541316 bbb rrr rrr arr rar 11551316 .. . rrr arr rar 11561316 •• • rrr • • • abb arr rar 11571316 bbb rrr •••abb
raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa
rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra rbb rra
rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar rrb abr bar
1. CYCLES OF ALGEBRAS li 3 i 6 -1316i 3 i 6
aaa bbbrrr rrr abbbaa arr rar brr rbr raa rbbrra rrbabr bar aaa bbbrrr rbbrra rrbabr bar abb arr rar • • • 1aa rrr rrr abb rbbrra rrbabr bar arr rar 11591316 ' ' ' raa rbbrra rrbabr bar rrr rrr abb arr rar 11601316 aaa ' ' ' raa bbbrrr rrr abb rbbrra rrbabr bar arr rar 11611316 aaa bbb rbbrra rrbabr bar rrr rrr abb arr rar 11621316 bbb rbbrra rrbabr bar baa arr rar 11631316 aaa bbb rbbrra rrbabr bar baa arr rar 11641316 ' ' ' raa rbbrra rrbabr bar rrr baa arr rar 1165i316 ' ' ' raa rbbrra rrbabr bar rrr baa arr rar H661316 aaa ' ' ' raa bbbrrr rbbrra rrbabr bar baa arr rar 11671316 rbbrra rrbabr bar baa arr rar 11681316 aaa bbbrrr rbbrra rrbabr bar rrr baa arr rar 11691316 rbbrra rrbabr bar rrr baa arr rar 11701316 aaa ' ' ' raa bbb rrr rbbrra rrbabr bar baa arr rar 11711316 ' ' ' raa rbbrra rrbabr bar rrr baa arr rar 11721316 aaa bbb ' ' ' raa rbbrra rrbabr bar rrr rrr baa arr rar 11731316 rbbrra rrbabr bar rrr rrr baa arr rar 11741316 aaa bbbrrr rrr rbbrra rrbabr bar baa arr rar 11751316 ' ' ' raa bbb rbbrra rrbabr bar aaa rrr rrr baa arr rar 1176l316 ' ' ' raa rbbrra rrbabr bar baa abb arr rar 11771316 ' ' ' raa rbbrra rrbabr bar abbbaa arr rar 1178l3l6 aaa bbb rbbrra rrbabr bar baa abb arr rar 11791316 rbbrra rrbabr bar abbbaa arr rar 11801316 aaa bbb rbbrra rrbabr bar rrr abbbaa arr rar 11811316 ' ' ' raa rbbrra rrbabr bar rrr abbbaa arr rar 1182l3l6 aaa ' ' ' raa bbbrrr rbbrra rrbabr bar abbbaa arr rar 1183l3l6 ' ' ' raa rbbrra rrbabr bar abbbaa arr rar 1184i316 aaa bbbrrr rbbrra rrbabr bar rrr abbbaa arr rar 11851316 rbbrra rrbabr bar rrr abbbaa arr rar 11861316 aaa bbb rbbrra rrbabr bar rrr abbbaa arr rar 11871316 ' ' ' raa rbbrra rrbabr bar rrr abbbaa arr rar H881316 aaa bbb ' ' ' raa rbbrra rrbabr bar rrr rrr abbbaa arr rar 11891316 ' ' ' raa rbbrra rrbabr bar rrr rrr abbbaa arr rar 11901316 aaa bbbrrr rrr abbbaa arr rar rbbrra rrbabr bar 11911316 bbb rbbrra rrbabr bar aaa rrr rrr baa abb arr rar 1192i316 • • • raa rbbrra rrbabr bar rrr arr brr 11931316 • • • raa rbbrra rrbabr bar aaa rrr arr brr 11941316 arr brr • • • raa rbbrra rrbabr bar 11951316 aaa bbbrrr rrr rrr arr brr • • • raa rbbrra rrbabr bar 1196l316 rrr rrr arr brr • • • raa rbbrra rrbabr bar 11971316 aaa arr brr • • • raa rbbrra rrbabr bar 11981316 aaa bbbrrr rrr rrr abb arr brr • • • raa rbbrra rrbabr bar 11991316 rrr abb brr• • • raa rbbrra rrbabrbar arr 12001316 aaa bbbrrr abb brr • • • raa rbbrra rrbabr bar arr 12011316 abb brr • • • raa rbbrra rrbabr bar arr 120213ie aaa bbbrrr 1158l316
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
1203i3i6 120413i6 1205i3ie 1206i3i6 120713i6 1208i3i6 1209i3ie 1210i3i6 1211i3i6 12121316 12131316 12141316 12151316 12161316 12171316 12181316 12191316 12201316 12211316 1222i3ie 1223i3ie 1224i3i6 1225i3i6 1226i3i6
aaa bbb rrr rrr rrr aaa bbb rrr aaa bbb rrr rrr rrr aaa aaa bbb rrr rrr rrr aaa aaa bbb rrr rrr aaa aaa bbb rrr rrr rrr aaa aaa bbb rrr rrr rrr aaa bbb rrr aaa bbb rrr rrr rrr aaa bbb rrr aaa bbb rrr
rrr rrr rrr rrr rrr
abb abb abb abb abb abb abb abb rrr abb rrr abb rrr abb
rrr rrr rrr
rrr rrr rrr rrr
1227i3i6 1228i3i6 1229i3ie 1230i3i6 1231i3i6 1232i3ie 1233i3i6 1234i3i6 1235i3i6 1236i3i6 1237i3i6 1238i3ie
aaa aaa bbb rrr aaa rrr aaa bbb rrr rrr rrr rrr rrr rrr aaa rrr rrr aaa bbb rrr rrr aaa aaa bbb
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
1239i3i6 1240i3i6 1241i316 1242i3ie 1243i3ie 1244i3ie 1245i3i6 1246i3i6 1247i3i6
aaa
rrr bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr rrr
rrr rrr rrr rrr abb
baa arr rar brr rbr raarbb raa rbb arr brr raa rbb arr brr raa rbb arr brr raa rbb arr brr raa rbb baa arr brr raa rbb baa arr brr raa rbb baa arr brr raa rbb baa arr brr raa rbb baa arr brr raa rbb baa arr brr raa rbb rar brr raa rbb rar brr raa rbb rar brr raa rbb rar brr raa rbb rar brr raa rbb rar brr raa rbb rar brr raa rbb rar brr raa rbb rar brr raa rbb rar brr raa rbb rar brr raa rbb rar brr raa rbb rar brr raa rbb rar brr raa rbb baa rar brr raa rbb baa rar brr raa rbb baa rar brr raa rbb baa rar brr raa rbb baa rar brr raa rbb baa rar brr raa rbb baa rar brr raa rbb baa rar brr raa rbb baa rar brr raa rbb baa rar brr raa rbb baa rar brr raa rbb baa rar brr raa rbb arr rar brr raa rbb arr rar brr raa rbb arr rar brr raa rbb arr rar brr raa rbb arr rar brr raa rbb arr rar brr raa rbb arr rar brr raa rbb arr rar brr raa rbb arr rar brr
rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra
rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb
abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr
bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar
1. CYCLES OF ALGEBRAS Ii3i 6 -1316i 3 i 6
1248i3i6 1249i3ie 1250i3ie 12511316 1252i3ie 1253i3ie 1254i3ie 1255i3i6 1256i3ie 1257i3ie
aaa bbb rrr aaa rrr bbb rrr aaa bbb rrr rrr aaa rrr bbb rrr aaa bbb rrr bbb aaa bbb
1260i3ie
rrr rrr bbb rrr aaa bbb rrr
12611316 1262i3i6
aaa
1258i3ie 1259i3ie
1263i3ie 1264i3ie 1265i3ie 1266i3i6 1267i3i6 1268i3ie
aaa
bbb aaa bbb rrr rrr bbb rrr aaa bbb rrr aaa
1269i3ie 1270i3ie
aaa
1271i316
bbb aaa bbb
1272i3ie 1273i3ie 1274i3ie 1275i3i6 1276i3ie
rrr rrr bbb rrr aaa bbb rrr aaa
1277i3ie 1278i3ie
aaa
1279i3ie
bbb aaa bbb
1280i3ie 12811316 1282i3ie 1283i3ie 1284i3ie 1285i3i6 1286i3ie 1287i3ie 1288i3ie 1289i3ie 1290i3ie 12911316 1292i3ie
rrr rrr bbb rrr aaa bbb rrr aaa
rrr aaa rrr aaa bbb rrr rrr aaa rrr aaa bbb rrr aaa aaa bbb
rrr abb baa arr rar brr abb arr rar brr abb arr rar brr abb arr rar brr rrr abb arr rar brr rrr abb arr rar brr rrr abb arr rar brr arr rar brr rrr abb baa arr rar brr baa arr rar brr baa arr rar brr baa arr rar brr baa arr rar brr baa arr rar brr rrr baa arr rar brr rrr baa arr rar brr rrr baa arr rar brr rrr baa arr rar brr baa arr rar brr rrr baa arr rar brr rrr rrr baa arr rar brr rrr baa arr rar brr abb baa arr rar brr abb baa arr rar brr abb baa arr rar brr abb baa arr rar brr abb baa arr rar brr abb baa arr rar brr abb baa arr rar brr abb baa arr rar brr rrr abb baa arr rar brr rrr abb baa arr rar brr rrr abb baa arr rar brr rrr abb baa arr rar brr rrr abb baa arr rar brr rrr abb baa arr rar brr rrr abb baa arr rar brr rrr abb baa arr rar brr arr rar brr arr rar brr arr rar brr rrr arr rar brr arr rar brr rrr rrr arr rar brr abb arr rar brr abb arr rar brr
rbr raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa rbr raa rbr raa rbr raa rbr raa rbr raa rbr raa rbr raa rbr raa
rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb
rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra
rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb
abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar abr bar
612
8. 4328 FINITE INTEGRAL RELATION ALGEBRAS
1293i3i6 1294isi6 1295isi8 1296isi6 1297isi6 1298isi8 1299i3i6 13001316 13011316 1302isi6 1303isi6 1304isi8 1305i3i6 1306isi8 1307isi8 1308isi6 1309ISIB
13101316 13111316 13121316 13131818 13141316 1315l3l6 1316l3l6
aaa bbb rrr rrr abb rrr abb abb aaa rrr abb bbb rrr aaa bbb rrr abb rrr abb aaa rrr abb bbb rrr abb aaa bbb rrr abb rrr rrr abb aaa rrr rrr abb bbb rrr rrr abb aaa bbb rrr rrr abb abb abb aaa abb aaa bbb rrr abb abb aaa rrr aaa bbb rrr abb rrr abb aaa rrr abb aaa bbb rrr abb rrr rrr abb aaa rrr rrr abb aaa bbb rrr rrr abb
baa arr arr arr arr arr arr arr arr arr arr arr arr arr baa arr baa arr baa arr baa arr baa arr baa arr baa arr baa arr baa arr baa arr baa arr baa arr
rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar rar
brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr brr
rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr rbr
raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa raa
rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb rbb
rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra rra
rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb rrb
abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr abr
bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar bar
2. Cycles of algebras I3013—30133013 bbb 2 3
3013 a a a 3013
4 3013 5
aaa
6
aaa
S018 8Q18 3013 8 3013 9 8Q18 IO3OI8 1:L 3013 1 28013 13 3013 14 3013 l^SOlS 16 3013 17 3013 18 3013 19 3013 20 3013 2 1 3013 223013 2 3 3013 2*3013 253013 26 3013 27 3013 28 3013 2S 3013 30 3013 313013 7
aaa
bbb bbb
bbb bbb
bbb bbb
aaa
aaa aaa aaa aaa aaa aaa aaa
bbb bbb
ccc ccc ccc ccc
ddd AAA ddd
ddd ddd ddd ddd ddd
bbb
bbb
ccc ccc ccc
bbb
ddd H i ddd
bbb
ccc ddd ccc ddd ccc ddd
aaa aaa
ccc eee eee eee ,,,
aaa aaa
eee ddd
aaa bbb
abb baa
ac
c caa
add
abb abb abb
ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac
c c
add
bcc
bdd
add
bcc
bdd
c
add
c
add
c c c c
add add add add
c c
add add
bdd bdd bdd bdd bdd bdd bdd bdd bdd
abb abb abb abb abb nhh abb
abb abb abb abb abb abb baa abb baa abb baa baa baa baa baa baa baa abb baa abb baa abb baa baa baa baa abb abb abb abb abb abb
daa bcc ebb bdd dbb cdd
add
bcc bcc bee bcc bee bcc bcc bcc bcc
add
bcc
bdd
c
add
c
add
c c e e e
add add add add add
bdd bdd bdd bdd bdd bdd bdd
c c c c c
add
e e
add add
c
add
c caa c caa c caa
add add add
bcc bcc bee bcc bee bcc bee be s be s be s be s be s be be be s be s be s be s
c c
add add add add
cdd cdd cdd cdd
cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd
cdd cdd cdd cdd cdd
bdd
cdd cdd
bdd
cdd
bdd bdd
cdd cdd edd
bdd
bdd bdd bdd bdd bdd bdd
cdd edd cdd cdd cdd
dee abe abd acd
bed
2. CYCLES OF ALGEBRAS l 3 oi3-3013 3 oi3
32
3013 33 3013 34 3013 35 3013 36 3013 37 3013 38 3013 39 3013 40 3013 41 3013 42 3013 43 3013 44 3013 45 3013 46 3013 47 3013 48 3013 49 3013 5 ^3013 51 3013 52 3013 53 3013 54 3013 55 3013 56 3013 57 3013 58 3013 59 3013 60 3013 6*3013 62 3013 63 3013 64 3013 65 3013 66 3013 67 3013 68 3013 69 3013 70 3013 71 3013 72 3013 73 3013 74 3013 75 3013 76 3013 77 3013 78 3013 79 3013 80 3013 81 3013 82 3013 83 3013 84 3013 85 3013 86 3013 87 3013 88 3013 89 3013 90 3013 91 3013 92 3013 93 3013 94 3013 95 3013 96 3013 97 3013 98 3013 "3013 100 3013 101 3013 102 3013 103 3013 104 3013 105 3013 106 3013 107 3013 108 3013 109 3013 110 3013 m 3013 112 3O i3 H 3 3013
aaa aaa aaa aaa
bbb bbb bbb
ccc
ddd
abb
ccc ccc ddd
bbb
aaa
bbb
aaa
aaa
ddd
bbb
ddd
cce ccc
ddd ddd
aaa bbb
aaa
bbb
aaa
aaa
bbb
aaa aaa aaa aaa
bbb bbb
ddd
ccc ccc
ddd ddd
ccc ddd ddd
ccc
ddd
abb abb abb abb abb abb abb abb
aaa
aaa aaa
bbb bbb bbb bbb
ccc ccc
aaa
aaa aaa
ddd
bbb bbb
ddd
ccc
ddd
aaa
aaa
bbb
aaa aaa aaa aaa
bbb bbb bbb
ccc ccc ccc
ccc
ddd ddd
aaa
aaa aaa aaa
bbb bbb bbb
ace ace ace ace
caa caa caa caa caa caa caa caa caa caa
add add add add add add add add add add
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa
add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add
baa baa baa baa baa
aaa
bbb bbb
baa baa baa baa baa baa baa
ccc
ddd
aaa aaa
add add add add add
baa baa
ddd
bbb
caa caa caa caa caa
ccc ccc
bbb
aaa
ace ace ace ace ace
baa
aaa
aaa
baa baa baa baa baa
ccc
ccc
ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb
baa baa baa baa baa baa baa baa
ace ace ace ace ace ace ace ace
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
baa baa baa baa baa
ace ace ace ace ace
aaa aaa
ddd
abb abb abb abb
ddd
abb
ddd
aaa
bbb bbb
aaa
aaa aaa
bbb bbb
ccc
ccc
ddd
aaa
bbb
ccc ccc ccc
ddd ddd
aaa
aaa
bbb
aaa
aaa aaa
bbb bbb
ccc
aaa
aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa
bbb bbb bbb bbb bbb bbb bbb bbb bbb bbb
ddd ddd
ccc
ddd
ccc
ddd ddd
abb abb abb abb abb abb abb abb abb abb
ccc
abb abb abb
aaa aaa
abb
bbb
cdd cdd cdd cdd
bdd
cdd
bec
bdd bdd bdd
cdd
bdd bdd bdd bdd bdd bdd
cdd
bdd
cdd
bdd bdd bdd
cdd cdd cdd cdd
bec bec daa
bec
daa
bec
daa
bec
daa
bec
daa daa
bec bee
daa
bec
daa
bec
daa
bec
daa
bec
daa
bec bec bec
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
bec bee bec bec bec bec bec bec bec bec bec bec bee bec bec
bec bec bec bec bec
abb
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd
dbb
cdd
cdd cdd
cdd cdd
cdd
bdd bdd bdd bdd bdd
cdd cdd
cdd cdd cdd
bdd bdd bdd bdd bdd bdd
cdd cdd cdd cdd cdd
bdd bdd bdd bdd bdd
cdd
cdd cdd
cdd
bdd bdd bdd bdd bdd bdd
dbb dbb dbb
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb
bdd
dbb dbb dbb dbb dbb
bdd bdd bdd bdd
dec abc
cdd
cdd cdd cdd cdd cdd cdd cdd cdd
cdd cdd
cdd cdd cdd cdd cdd cdd cdd cdd
add
bdd bdd bdd bdd bdd bdd
add
bdd
cdd
add
ace
ebb
bec
add
baa baa
dec dec dec dec dec abc
cdd
abc.
cdd
abc
cdd
abc.
cdd
abc.
cdd
abc. abc abc abc
baa baa
caa caa
add add
bdd
cdd
bdd
cdd
baa baa baa
caa caa caa caa caa caa caa caa caa
add add add add add add add add add
bdd bdd bdd bdd bdd
cdd cdd cdd
abc.
cdd
abc.
cdd
abc.
bdd bdd bdd bdd bdd
cdd cdd cdd cdd cdd
abc abc abc abc abc
bdd bdd bdd bdd bdd bdd bdd bdd bdd
cdd cdd cdd
abc.
cdd
abc.
cdd
abc.
cdd
abc.
cdd
abc. abc. abc.
baa baa baa baa baa baa
abb abb
ddd ddd
bdd bdd bdd
add
abb abb
ccc
bec bec bec bee
bee
add add
ddd
aaa
daa
ace ace ace ace ace ace ace
add
bec
ace
add add
bec
add
bec
add
bec
add
bec
add
bec
add add add
bec
ace
baa baa baa baa
ace ace ace ace caa caa caa
bec
bec bec
cdd
cdd
abc.
abc.
abc.
abc.
abd
acd
bed
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
114
3013 3013 116 3013 117 3013 118 3013 119 3013 120 3O13 121 3013 122 3013 123 3013 124 3013 125 3013 126 3013 127 3013 128 3013 129 3013 130 3O13 131 3013 132 3013 133 3013 134 3013 135 3013 136 3013 137 3013 138 3013 139 3013 140 3O13 141 3013 142 3013 143 3013 144 3013 145 3013 146 3013 147 3013 148 3013 149 3013 150 3O13 151 3013 152 3013 153 3013 154 3013 155 3013 156 3013 157 3013 158 3013 159 3013 160 3O13 161 3013 162 3013 163 3013 164 3013 165 3013 166 3013 167 3013 168 3013 169 3013 170 3013 171 3013 172 3013 173 3013 174 3013 175 3013 176 3013 177 3013 178 3013 179 3013 180 3013 181 3013 182 3013 183 3013 184 3013 185 3013 186 3013 187 3013 188 3013 189 3013 190 3013 191 3013 192 3013 1933O13 194 3013 195 3 oi3
aaa aaa
115
aaa
aaa aaa
bbb ccc ddd bbb ccc
abb baa a c caa caa ddd abb caa ddd abb caa ddd abb bbb caa bbb ccc ddd abb caa abb baa caa abb baa a66 baa
bbb
aaa
bbb ccc ccc 6 6 6 ccc bbb ccc
bbb
ddd ddd ddd ddd
a66 a66 a66 a66 abb abb abb abb
aaa
ccc ccc ccc bbb ccc
ddd ddd ddd ddd
abb abb abb abb
aaa aaa
bbb bbb ccc
aaa aaa
bbb bbb
aaa
aaa aaa
bbb
aaa aaa
bbb
bbb
bbb ccc
ddd ddd ddd
abb abb abb a66
aaa bbb
aaa aaa
bbb ccc ccc ccc bbb ccc 666
aaa
bbb
ddd ddd ddd ddd
ccc ccc ccc bbb ccc
ddd ddd ddd ddd
aaa bbb
aaa aaa
bbb
aaa aaa
aaa aaa
bbb bbb ccc ddd ddd ddd
aaa
aaa aaa
bbb bbb ccc ddd
a66 a66 a66 a66 abb abb abb abb
abb abb abb abb a66 a66 a66 abb abb abb abb
abb
baa baa baa baa baa baa baa baa baa baa baa baa
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a
c c c c c c c c c c c c c c c c c c c c c c c c c c c c c c
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa
add daa add add add add add add
bcc bcc bcc bcc bcc bcc bcc
add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add
bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc
ddd
bbb bbb
aaa
aaa
dec dec dec
dbb
dec
ddd
abb
daa
dbb
ccc ddd bbb ccc ddd
aaa
dbb dbb dbb
aaa
aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa
edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
abb
aaa
aaa
dec
abb
bbb ccc
aaa aaa
edd edd edd edd edd edd edd
ddd
bbb bbb ccc
aaa
dbb
ddd
aaa aaa
aaa
ebb ebb ebb ebb ebb ebb ebb ebb
bdd bdd bdd bdd bdd bdd bdd
abc abd acd bed abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
a66
aaa aaa
aaa aaa
ebb
ddd
dec
abc
baa
caa
daa
dbb
dec
abc
abb baa
caa
daa
c c c c c c
caa caa caa caa caa
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec
abc
caa caa
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
c
a
abb abb baa a66 baa bbb a66 baa abb baa bbb ccc ddd abb baa ddd abb baa bbb bbb ccc ddd abb baa a bbb abb a abb bbb ccc ddd abb bbb bbb ccc ddd abb bbb a66 baa a 6 6 baa bbb ccc ddd abb baa bbb bbb ccc ddd abb baa a66 a66 bbb a66
a a a a a a a a
a a a a
c c c c c c c c caa caa caa
bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc
abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
2. CYCLES OP ALGEBRAS l3013-3013 30 i 3
"63013 1983013 1993013 200 3O13 2 °l3013 202 3O13 203 3O13 204 3013 205 3013 206 3013 207 3013 2 »8 3 0 13 2 »9 3 0 13 2 l°3013 2 H3013 2i2 3013 2 3 l 3013 2 l"3013 2 5 l 3013 2 6 l 3013 2 ? l 3013 2 183013 220 3O13 22i 3013 222 3013 223 3013 224 3013 226 3013 226 3013 227 3013 228 3013 229 3013 230 3013 23 l3013 232 3013 233 3013 234 3013 235 3013 236 3013 237 3013 238
3013
240 3013 241 3013 242 3013 243 3013 244 3013 246 3013 246
3013
bbb bbb
3013 3013 ™3013 25 l3013 252 3013 253 3013 264 3013 255 3013 266 3013 257 3013 258 3013 0
3013 3013 3013 263 3013 264 3013 266 3013 266 3013 267 3013 268 3013 269'3013
bbb bbb bbb bbb bbb bbb bbb bbb bbb bbb
ddd ddd ddd ddd ddd ddd ddd ddd
166 ba 166 ba
ddd ddd ddd
bbb bbb
abb ba
bbb bbb bbb bbb bbb bbb
ddd ddd ddd ddd ddd ddd ddd ddd
bbb bbb bbb bbb
ddd ddd ddd ddd
bbb bbb bbb bbb
ddd ddd ddd ddd
abb ba
zbb %bb 166 166 166 166 166 ibb %bb %bb %bb %bb 166 166 166 166 166 166 ibb
ba ba ba ba ba ba ba ba ba ba ba ba ba ba ba ba ba ba ba
ebb ebb ebb ebb abb abb abb abb
• • • • •
• • • • •
dbb dbb dbb dbb dbb
ebb ebb ebb ebb ebb ebb abb abb
bdd bdd bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb dbb dbb
ddd abb abb
• • • •
666 666
262
3013
dbb add dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
bbb bbb
261
270 3013 2? l3013 272 3013 273 3013 274 3013 275 3013 276 3013 277
bdd
bbb bbb
248
249
abb
ddd ddd ddd ddd
247'3013
2
bo.
bbb bbb
ddd ddd
bbb bbb
abb abb ddd abb ddd abb
• • • •
• • • •
ebb ebb ebb ebb ebb ebb ebb ebb ebb
• • • • •
dbb dbb dbb d66 d66 d66 d66 d66 dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
dec
abe
abe abe abe
abe abe
zdd zdd zdd zdd zdd zdd
be be be be be ba
abd abd abd abd abd abd
zdd zdd zdd zdd zdd zdd zdd zdd zdd
be be be be be be be be be
abd abd abd abd abd abd abd abd abd
4329 FINITE INTEGRAL RELATION ALGEBRAS aaa 278
3013 279 3013 280 3013 281 3013 282 3013 283 3013 284 3013 285 3013 286 3013 287 3013 288 3013 289 3013 290 3013 291 3013 292 3013 293 3013 294 3013 295 3013 296 3013 297 3013 298 3013 299 3013
3
°°3013
aaa aaa
bbb
cc c cc c cc c 666 cc e
3013 3O13 303 3O13 304 3O13 305 3O13 306 3O13 307 3O13 308 3013 309 3013 310 3013 311 3013 312 3013 313 3013 314 3013 316 3013 316 3013 317 3013 318 3013 319 3013 320 3013 321 3013 322 3013 323 3013 324 3013 325 3013 326 3013 327 3013 328 3013 329 3013 330 3013 331 3013 332 3013 333 3013 334 3013 335 3013 336 3013 337 3013 338 3013 339 3013 340 3013 341 3013 342 3013 343 3013 344 3013 345 3013 346 3013 347 3013 348 3013 349 3013 360 3O13 351 3013 352 3013 353 3013 354 3013 355 3013 356 3013 357 3013 358 3013 359 3013
abb
baa
abb abb abb
baa
ace
caa
add
caa
baa
caa
baa
caa
add aaa aaa aaa aaa
aaa aaa aaa aaa
ddd
bbb 666
666 666 bbb
aaa
aaa
aaa aaa aaa aaa
bbb
666 666
aaa
aaa aaa aaa
ddd
cc c cc cc e cc cc cc c cc e
bbb -- bbb
abb abb abb abb
c
ddd
c
cc e cc cc cc e cc c cc cc c cc cc e cc e cc c
ddd ddd
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa
abb abb abb abb
baa baa baa baa baa baa
ddd abb abb
ddd ddd . . .
c
cc
baa baa
ddd
c
301 302
ddd ddd ddd ddd
ddd ddd ddd
abb abb abb abb abb abb abb abb
baa baa baa baa baa baa
c
add add add add add add add add add add add add add add add add add add add add add add add add
i
bee
ebb
daa dac dac
ebb
666 bbb bbb
bdd
bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb
bdd
dac
bdd
dac
bdd
dac daa dac daa dac dac
bdd
dbb
dac
bdd
dbb
dac
bdd
dbb
bdd
dbb
bdd
dbb
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb
dac
ebb ebb ebb ebb ebb ebb ebb ebb ebb
dac dac dac dac dac dac dac dac dac
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
dac dac daa
cc e
cc c
aaa aaa
bbb
aaa
666
aaa aaa
666
aaa
666
aaa aaa aaa aaa aaa
bbb bbb bbb bbb bbb
aaa
666
aaa
666
aaa
666
aaa
666
aaa aaa - - -
666 666 bbb
aaa
bbb bbb bbb
- - -
bbb
aaa
666
aaa
caa caa
baa
caa
abb
baa
caa
abb
baa
caa
abb abb
baa baa
caa caa
ddd
abb
baa
caa
ddd
abb
ddd ddd
abb
baa baa
caa caa
abb
baa
ddd ddd
. . .
cc
cc e cc c
daa
cc c cc c cc c cc e cc
. . . ddd ddd . . . ddd ddd
c
cc e
cc c
ddd ddd
. . . ddd ddd
666
c ce
666
cc c
ddd ddd
bbb
bbb cc cc c
aaa bbb
ec
aaa
bbb
cc c
aaa ...
666
aaa
666
. . . ddd ddd ddd
ec
e
cc c 666
aaa ...
. . .
ddd
aaa
666 666
baa baa baa baa
cc
aaa aaa
abb abb abb abb abb abb abb abb
c ce cc c
ddd ddd ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
ac ac ac ac
...
ac a c a c a c
baa
daa dac dac dac dac dac dac daa dac daa dac
caa
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
ace
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa zaa zaa zaa zaa zaa zaa zaa zaa caa
add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add
cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd
daa
dac
dac
baa baa
c
bbb
aaa
aaa
cc
cdd
dbb dbb dbb
dac
bdd
dac
aaa aaa aaa aaa aaa
dbb
dbb dbb dbb dbb dbb
caa caa
bdd
ebb
dac
ddd
ebb
dac
caa ddd
cc c
dac
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
dac dac dac dac dac dac
bec bee bee bee bee bee bec bec bec bec bec bec bee bee bee bee bee bec
daa
bec
ebb
dac
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bec
ebb
daa
bec
ebb
dac dac dac dac dac dac dac dac
bec bee bee bee bee bee bee bec
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
daa
bec
dac
bec
daa
bec
dac
bec
daa
bec
dac
bec
daa
bec
dac
bec
bdd bdd bdd bdd bdd bdd
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
bdd bdd bdd bdd bdd bdd bdd bdd bdd
dec
abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec
abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
ctbcL ac.3, bed abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
2. CYCLES OP ALGEBRAS l 3 oi3-3013 3 oi3
360
3013 3013 362 3013 363 3013 364 3013 365 3013 366 3013
aaa
bbb
aaa
bbb bbb
ccc
aaa
bbb bbb bbb bbb bbb
ccc
361
368
3013 369 3013 370 3013 371 3013 372 3013 373 3013 374 3013 375 3013 376 3013 377 3013 378 3013 379 3013 380 3013 381 3013 382 3013 383 3013 384 3013 385 3013 386 3013 387 3013 388 3013 389 3013 390 3013 391 3013 392 3013 393 3013 394 3013 395 3013 396 3013 397 3013 398 3013 399 3013 4
°°3013
aaa aaa
ccc
ddd
ccc ccc
ccc
aaa
ccc 666 bbb
ccc ccc
aaa bbb aaa
bbb
aaa aaa
666 bbb
a cc
caa
add
dac i
be 2
ebb
bdd
a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc
caa caa caa caa caa caa caa
add add add add add add add
dac i daa
caa caa caa caa
add add add add
caa caa caa caa caa caa caa
add add add add add add add
caa caa
add add
caa caa
add add
caa
add
be z be z be z be 2 be 2 be 2 be 2 be 2 be z be z be z be z be z be z be 2 be 2 be 2 be 2 be 2 be z be z be z be z
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd bdd bdd
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
ddd ddd ddd
666 bbb
aaa
baa
ddd
aaa aaa
abb
ccc ccc ccc ccc
ddd ddd ddd ddd ddd ddd ddd ddd
ccc aaa aaa
bbb
aaa aaa aaa aaa aaa aaa
bbb
ccc ccc
bbb
ccc ccc
bbb
ccc ccc ccc
bbb
ccc ccc ccc
aaa aaa
ddd ddd
bbb
aaa aaa
ddd
ddd ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
3013 402 3013 403 3013 404 3013 405 3013 406 407
3O13
aaa
bbb
aaa aaa
bbb
3O13 aaa
4093O13 410
411
aaa
bbb
ccc ccc ccc ccc
ddd
ccc
ddd
3O13
3013 3013 413 3013
aaa
415
aaa
412
3013
416 3013 417
3013 418 3013 419 3013 420 3O13 421 3013 422 3013 423 3013 424 3013 425 3013 426 3013 427 3013 428 3013 429 3013 430 3O13 431 3013 432 3013 433 3013 434 3013 435 3013 436 3013 437 3013 438 3013 439 3013 4403013 441 3013
bbb aaa
aaa
bbb
aaa aaa
bbb bbb
ccc ccc ccc
ddd
ccc
ddd
ccc
ddd
ccc
ddd
aaa aaa
bbb ccc
aaa aaa
bbb
aaa aaa aaa
bbb
ccc ccc ccc ccc ccc
ddd ddd ddd
aaa aaa
bbb
aaa la
bbb bbb
la
bbb
la
bbb
la
bbb
ccc ccc
a
abb
ccc 666 bbb
a
ddd
ccc ccc ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
a a
daa dac i
dac dac
c a a
dac daa
c a a
dac daa dac
c a a
dac
c a a
dac
c a a
dac dac
caa
add
dac daa
a cc
caa caa
add add
daa dac i
cc cc cc
caa caa caa caa
add add add add
daa dac i dac i
cc cc a cc a cc
caa caa caa caa
add add add add
a cc
caa
add
a cc
caa caa caa caa caa
add add add add add
cc cc cc
dac i dac i daa dac i dac i daa dac i dac i dac i dac i dac i dac i
baa baa baa baa baa baa
a cc a cc a cc a cc a cc a cc
caa caa caa caa
add add add add
caa caa caa caa
add add add add
baa
a cc a cc a cc
caa caa caa
add add add
daa dac i dac i dac i dac i dac i
a cc a cc a cc
caa caa caa
add add add add
dac dac daa
a cc a cc a cc a cc
caa caa caa caa
add add add add
a cc a cc a cc
caa caa caa
add add add
a a
baa baa a
baa baa baa baa baa baa baa baa baa baa
cc cc
dac i dac i
cc
daa dac i
dac dac dac dac dac dac dac
i i i i i i
bdd bdd bdd bdd bdd
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
bdd bdd bdd bdd dbb
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
dac daa
a cc
a cc a
daa dac i
c a a
c a a
a
abb abb abb abb
dac i
c a a
c a a
a
dac i
dac
c a a
a cc
ddd
dac i
c a a
c a a
a cc
ccc
dac i
dac
c a a
a
dac i dac i
daa dac i
c a a
401
daa dac i daa dac i daa
c a a
c a a
baa baa baa baa baa baa baa baa baa
i i i i i i
c a a
c a a
ccc
dac dac dac dac dac dac
be z
ebb
be z be z be z be 2 be 2 be 2 be 2 be 2 be z be z be z z be z be z be 2 be 2 be 2 be 2 be 2 be z be z be z be z be z be 2
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
be 2 be 2 be 2
ebb ebb ebb
be be be be be be
dbb
dbb dbb dbb dbb dbb dbb
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb
bdd bdd
dbb dbb
bdd dbb bdd dbb bdd dbb bdd
dbb
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb
bdd bdd bdd bdd
dbb dbb dbb dbb
edd
dec
abc
abd
edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd
dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec
abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
edd edd edd
dec dec dec
abc abc
abd abd abd
edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd
dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec
abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
abc abc abc abc abc abc abc abc abc
acd
acd acd acd acd acd acd acd acd acd acd acd
bed
4329 FINITE INTEGRAL RELATION ALGEBRAS aaa
bbb ccc ddd ccc ddd bbb ccc ddd
442
3013 3013 444 3013 445 3013 446 3013 447 3013 44 83013 44 93013 450 3013 451 3013 452 3013 453 3013 4 4 5 3013 455 3013 456 3013
aaa
443
aaa
aaa
bbb
458 3 O i3 4 593013 4 60 3 O l3 461 3013 1623013 463 3013 464 3013 465 3013 4 663013
aaa
ccc bbb ccc
aaa
aaa aaa aaa aaa
3013 1693013 470 3O13 471 3013 472 3013 473 3013 474 3013 475 3013 476 3013 477 3013 478 3013 47 9 3 013 4 80 3 O l3 481 3013 482 3013 483 3013 484 3013 485 3013 486 3 O i3 487 3013 4 88 3 0 13 1893013 4 90 3O 13 4 9l3013
ddd ddd bbb bbb ccc ddd
aaa
aaa
bbb
aaa
ccc bbb ccc
aaa aaa
aaa
aaa
ccc ddd bbb ccc ddd
aaa
bbb
aaa
ccc ddd bbb ccc ddd
aaa aaa
aaa
bbb ccc
aaa
bbb ccc
aaa
bbb
aaa
ccc ddd bbb ccc ddd
aaa aaa
aaa
bbb
aaa
ccc bbb ccc
aaa
ddd ddd
aaa
aaa
bbb
aaa
ccc ddd bbb ccc ddd
aaa aaa
aaa
bbb
aaa
ccc bbb ccc
aaa
ddd ddd
aaa
aaa
bbb
aaa
ccc ddd bbb ccc ddd
aaa aaa
aaa
bbb
aaa
aaa
bbb ccc
aaa
3013 aaa 494 3013 aaa aaa 496 3013 aaa 497 3013 aaa 498 3013 aaa 4 99 3 0 13 aaa 500 3O13 aaa aaa 502 3O13 aaa 503 3O13 aaa aaa
3013 aaa aaa
507
aaa
508
aaa
3013 3013 509 3 O i3 510 3O13 511 3013 512 3013 513 3013 514 3013 515 3013 516 3013 517 3013 518 3013 519 3013 520 3013 521 3013 522 3013 523 3013
ddd ddd
aaa
493
505
ddd ddd
aaa
aaa aaa
aaa aaa
aaa aaa
aaa aaa
aaa
bbb ccc ccc ddd bbb ccc ddd bbb ccc bbb ccc
bbb
ddd ddd
abb abb abb abb abb abb abb abb
abb abb abb abb abb abb abb abb
abb abb abb abb abb abb abb abb
abb abb abb abb abb abb abb abb
abb abb abb abb abb abb abb abb
abb abb abb abb abb abb abb abb
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
baa baa baa baa baa baa
abb baa abb baa abb baa abb baa bbb ccc abb baa abb baa bbb ccc ddd abb baa ddd abb baa bbb ccc ddd abb baa bbb ccc ddd abb baa abb baa abb baa bbb ccc bbb ccc
abb abb
ccc ddd bbb ccc ddd
aaa
bbb
aaa
ccc bbb ccc
aaa
aaa
abb abb abb
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
ccc ddd bbb ccc ddd
aaa
aaa
abb abb abb
abb abb
aaa
aaa
468
bbb bbb ccc
aaa
abb abb abb abb abb
bbb
ddd ddd
ace ace ace ace ace ace ace ace
caa caa caa caa caa caa caa
caa caa caa caa caa caa caa caa
add add add add add add add add
caa caa caa caa caa caa caa caa
caa caa caa caa caa caa caa caa
add add add add add add add add
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa
add add add add add add add add add add add add add add add add add add add add add add
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
bee bec bec bec bee bec bec bec bec bec bec bec bec bec bec
bec bec bec bec bec bee bec bec bec bec bec bec bec bec bec bec
add add
caa caa caa caa caa
ace ace ace ace ace ace
add add add add add add add add add add add add add add add
caa
caa
baa baa baa baa
abb abb abb baa abb baa abb baa abb baa abb baa abb baa
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa
caa caa caa caa caa caa
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
bec bec bec bee bec bec bec bec bec bec bec bec bec bee bec bec bec bec bec bec bec bec bec bec bec bec bec bec
ebb
bdd
dbb edd
ebb ebb ebb ebb ebb ebb
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
dec abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd bed acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
2. C Y C L E S O F A L G E B R A S 13013-30133013
aaa 524 3O l3 3013 5263013 527 3013 5 28 3013 529 3013 5503013 531 3013 532 3013 5333013 5343013 5353013 5363013 5373013 538 3013 539 3013 5403013 541 3013 542 3013 5433013 5443013 5453013 5463013 5473013 548 3O i3 549 3 oi3 5503013 551 3013 552 3013 553 3013 5543013 5553013 5563013 5573013 5533013 559 3 oi3 560 3013 5613013 562 3013 5^33013 564 3013 5653013 5663013 5673013 563 3O l3 5693013 57 03013 571 3013 5 72 3013 573 3013 574 3013 5753013 5763013 5773013 5783013 579 30 13 5303013 5813013 582 3013 5 83 3013 584 3013 5 85 3Qi3 5363013 5373013 5333013 5393013 5903013 5913013 592 3 oi3 5933013 5943Q13 595 3 oi3 59&3013 597 30 13 5933013 599 30 13 6003013 601 3013 602 3013 603 3013 604 3013 605 3013
525
aaa
aaa
bbb ccc ccc bbb ccc
ddd abb ddd abb ddd abb
aaa
aaa
bbb
aaa
aaa
bbb
aaa
aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa aaa
bbb bbb bbb bbb bbb bbb bbb bbb bbb bbb bbb bbb bbb bbb bbb bbb bbb bbb bbb bbb bbb bbb bbb bbb bbb
ccc ccc
ccc ccc
ddd ddd
ccc ddd
ccc
ddd
ccc ddd
ccc
ddd
ccc ddd
ccc
ddd
ccc ddd
ccc
ddd
ccc ddd
ccc
ddd
ccc ddd
ccc
ddd
aaa
aaa
bbb bbb ccc ccc
aaa
aaa
bbb
ccc
bbb
ccc ddd ddd
aaa bbb
aaa aaa
ddd ddd
bbb ccc ccc ccc bbb ccc bbb
aaa
ddd ddd ddd ddd
aaa bbb
aaa
bbb ccc
aaa
aaa
ccc
bbb bbb
ccc ccc ddd ddd ddd ddd
aaa bbb
aaa aaa
aaa aaa aaa aaa aaa aaa aaa aaa aaa
bbb ccc ccc bbb ccc bbb ccc bbb bbb ccc bbb bbb ccc bbb bbb ccc bbb bbb ccc
ddd ddd ddd ddd ddd
ddd ddd
ddd
aaa
aaa
bbb bbb
aaa
aaa aaa
bbb bbb
ccc ccc ccc ccc ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
baa ace caa
add daa
baa baa
ace ace
caa caa
baa baa baa baa baa baa
ace ace ace ace ace ace
caa caa caa caa caa caa
add add add add add add
ace ace ace ace ace ace ace ace ace ace ace
caa caa caa
add add add add add add add add add add add
ace ace ace ace ace
caa caa caa caa caa
add add add add add
baa baa baa baa
baa baa baa baa
ace
. . . ace ace
... baa baa baa baa
ace ace ace ace ace ace ace ace ace ace
caa caa caa caa caa
ace ace ace
caa caa caa
ace
caa
a a
-.aa
-.c
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
baa baa baa baa
-.aa -.aa
a
a -.c a ace ace
-.aa caa caa
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa
-.aa
ace
add
ace
add
ace ace
add add
ace ace ace ace ace caa -.c -.aa
add add add add add
add -.aa add add a -.aa add -.c -.aa add a -.aa add -.c -.aa add a -.aa add a -.c -.aa add a
a a
a
a
-.c -.aa
daa daa daa daa daa daa daa daa
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
be _ be. be. be. be _ be _ be _ be _ be _ be. be. be. be. be. be. be be be be be be. be. be. be. be. be be be be be be be. be. be. be. be. be be be be be be be. be. be. be. be. be be be be be be. be. be. be. be. be. be be be be be be. be. be. be. be. be be be be be be be. be. be. be. be. be. be. be. be.
ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb dbb dbb dbb
cdd
dec abc abc. abc. abc. abc abc abc abc abc
cdd cdd cdd
cdd cdd
cdd cdd cdd cdd cdd cdd cdd
cdd cdd
cdd cdd cdd cdd cdd cdd cdd cdd cdd
cdd cdd
cdd cdd cdd cdd cdd cdd cdd cdd cdd
cdd cdd
cdd cdd cdd cdd cdd cdd cdd
cdd cdd
cdd cdd
cdd cdd cdd cdd cdd cdd cdd
cdd
abc. abc. abc. abc. abc. abc. abc abc abc abc abc
abc. abc. abc. abc. abc. abc abc abc abc abc abc
abc. abc. abc. abc. abc. abc abc abc abc abc abc
abc. abc. abc. abc. abc. abc abc abc abc abc
abc. abc. abc. abc. abc. abc. abc abc abc abc abc
cdd
abc. abc. abc. abc. abc.
cdd cdd cdd cdd cdd cdd
abc abc abc abc abc abc
cdd
abc. abc. abc. abc. abc. abc. abc. abc. abc.
cdd
cdd cdd
cdd
cdd cdd
cdd cdd
cdd cdd
cdd
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd bed acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS aaa 606
3013 3013 608 3013 609 3 O 1 3 610 3O13 611 3013 612 3013 61 3 3013 614 3013 615 3013 616 3013 617 3013 618 3013 619 3013 620 3O13 621 3013 622 3013 623 3013 ^ 2 4 3013 625 3013 626 3013 627 3013 628 3013 629 3013 630 3O13 631 3013 632 3013 633 3013 634 3013 6 35 3013 636 3013 637 3013 638 3013 639 3013 640 3013 641 3013 642 3013 643 3013 644 3013 645 3013 4 ^ ^3013 647 3013 648 3013 649 3013 650 3013 651 3013 652 3013 653 3013 654 3013 655 3013 656 3013 657 3013 658 3013 659 3013 660 3013 661 3013 662 3013 663 3013 664 3013 665 3013 666 3013 667 3013 668 3013 669 3013 670 3013 671 3013 672 3013 673 3013 674 3013 675 3013 676 3013 677 3013 678 3013 679 3013 680 3013 681 3013 682 3013 683 3013 684 3013 685 3013 686 3013 687 3013 607
bbb ccc ddd
aaa aaa
bbb
abb abb
ccc ccc ccc bbb ccc
ddd ddd ddd ddd
abb abb abb abb abb abb a66 a66
bbb
aaa aaa
bbb
aaa aaa
bbb ccc ccc ccc bbb ccc bbb
aaa
bbb
ddd ddd ddd ddd
ccc ccc 6 6 6 ccc bbb ccc
ddd ddd ddd ddd
aaa bbb
aaa aaa
aaa aaa
aaa aaa
bbb bbb ccc ddd ddd
aaa
aaa aaa
bbb bbb ccc ddd
aaa
aaa
bbb
aaa
ccc bbb ccc
aaa
ddd ddd
aaa
aaa
bbb
aaa
ccc ddd bbb ccc ddd
aaa
abb baa ace caa
ddd ddd
666
a66 a66 a66 a66 abb abb abb abb
abb abb abb abb a66 a66
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
abb abb abb
caa caa caa caa caa caa
add add add add add add
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa
add add add add add add add add add add add add add add add add
ace
add
ace ace
add add
ace ace ace
add add add
ace ace ace ace ace ace
add add add add add add add add
abb abb baa ace abb bac i ace bac i bac i bac i bac i abb bac i abb baa a66 a66 abb abb
aaa
abb baa ace bbb abb baa ace abb baa ace bbb ccc ddd abb baa ace ddd abb baa ace bbb bbb ccc ddd abb baa ace ace a66 bbb a66 . . . ace a66 ace bbb ccc ddd abb . . . ace ace ddd abb bbb ace bbb ccc ddd abb abb baa ace abb baa ace bbb abb baa ace bbb a66 baa ace ccc a 6 6 baa ace ccc a 6 6 baa ace bbb ccc a 6 6 baa ace a 6 6 baa ace bbb ccc ddd abb baa ace ddd abb baa ace bbb ddd abb baa ace ddd abb baa ace bbb ccc ddd abb baa ace ccc ddd abb baa ace 6 6 6 ccc ddd abb baa ace bbb ccc ddd abb baa ace a66 baa ace a66 baa ace 666 a66 baa ace bbb abb baa ace
aaa
bbb ccc
aaa
aaa aaa aaa
aaa aaa aaa
aaa aaa aaa
aaa aaa aaa
aaa aaa
aaa aaa
aaa aaa
aaa aaa
bbb
ccc
aaa bbb
ddd ddd ddd ddd
aaa
bbb
aaa
bbb ccc ddd bbb ccc ddd
aaa
aaa aaa aaa
aaa aaa
bbb bbb ccc ddd ddd bbb bbb ccc ddd
baa baa baa baa baa baa abb baa abb baa abb abb abb abb abb abb
add daa
ace ace ace ace ace ace
ace ace ace ace ace ace ace ace
caa caa caa caa caa caa
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
add add add add add add
caa caa caa caa caa caa caa caa caa caa caa caa
a66 a66
ac c
add
ac c
add
a66 abb abb
ac c ac c
add add
ac c
add
abb
ac c
add
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec
ebb
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd dbb edd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd
dec abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd bed acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
2. CYCLES OP ALGEBRAS l 3 oi3-3013 3 oi3 aaa 6883013 689 3013 690 3013 691 3013 692 3013 693 3013 694 3013 6 9 5 3 0 13 696 3013 697 3013 698 3013 699 3013 700 3013 701 3013 702 3O13 703 3O13 704 3O13 705 3O13 706 3O13 707 3013 708 3013 709 3013 710 3013 7 ll3013 712 3013 713 3013 714 3013 715 3013 716 3013 717 3013 718 3013 719 3013 720 3013 721 3013 7 22 3 013 723 3013 724 3013 725 3013 726 3013 727 3013 728 3013 7 9 2 3013 730 3013 7 31 3 013 732 3013 733 3013 734 3013 735 3013 736 3013 737 3013 738 3013 739 3013 740 3013 741 3013 74 2 3 013 743 3013 744 3013 745 3013 746 3013 747 3013 748 3013 749 3013 750 3013 7 51 3 013 752 3013 753 3013 754 3013 755 3013 756 3013 757 3013 758 3013 759 3013 760 3O13 761 3013 762 3013 763 3013 764 3013 765 3013 766 3013 767 3013 768 3013 769 3013
bbb ccc
ddd abb
aaa 666
aaa
bbb
aaa bbb
aaa
bbb
ccc ccc ccc ccc ddd ddd ddd ddd
aaa bbb
aaa aaa
aaa
bbb ccc ccc bbb ccc bbb ccc
ddd ddd ddd ddd
aaa bbb
aaa
bbb 666
aaa
bbb
ccc ccc
bbb
ddd ddd ddd
aaa
bbb
ddd
aaa
ccc bbb ccc
aaa aaa aaa aaa aaa aaa
bbb bbb bbb bbb bbb bbb
aaa
bbb
ccc ccc
bbb bbb ccc bbb ccc
abb abb abb abb abb ddd abb
bbb
aaa
aaa
ccc
bbb
ccc ddd ddd
aaa
aaa
bbb
aaa
ccc bbb ccc
aaa aaa
aaa
bbb
aaa
aaa
ccc
bbb
ccc
aaa
aaa
bbb
aaa
ccc bbb ccc
aaa aaa
bbb
aaa
ccc bbb ccc
aaa
bbb ccc
aaa
aaa
bbb
ccc
aaa
aaa
bbb
aaa
ccc bbb ccc
aaa
abb abb abb abb ddd abb ddd abb ddd abb ddd abb
ccc
aaa
aaa
ddd ddd
ccc
aaa
ddd ddd abb abb abb abb ddd abb ddd abb ddd abb ddd abb
aaa
aaa
bbb ccc
aaa
aaa
bbb
ccc ddd
aaa
aaa
bbb
aaa
ccc bbb ccc
aaa
ddd
aaa
aaa
bbb
aaa
aaa
ccc
bbb
ccc
aaa
aaa aaa
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
caa
add
dac
add
dac
add add add add add add add add add add add add add add add
caa caa caa caa caa caa caa caa caa caa caa caa
add add add add add add add add add add add add
baa
aaa
aaa
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
bbb ccc
ddd ddd abb abb abb abb ddd abb ddd abb ddd abb
caa caa
baa baa baa
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
caa caa ace ace ace ace
add
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
add
baa baa baa baa baa baa baa baa baa baa baa baa
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
i bec ebb i bec ebb daa bec ebb dac i bec ebb dac i bec ebb dac i bec ebb dac i bec ebb dac i bec ebb dac i bec ebb daa bec ebb dac i bee ebb daa bec ebb dac i bee ebb daa bec ebb dac i bee ebb dac i bec ebb dac i bec ebb dac i bec ebb dac i bec ebb dac i bec ebb dac i bee ebb dac i bee ebb dac i bee ebb dac i bee ebb dac i bee ebb dac i bec ebb dac i bec ebb dac i bec ebb dac i bec ebb bec
abb abb
ccc
aaa
aaa aaa aaa
ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
add add add add add add add add add add add add add add add add add add
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa
add add add add add add add add add add add add add add add add add add add add add add add add add add add
bee bee bee bee bee bec bec bec bec bec bec bee bee bee bee bee bec bec bec bec bec bee bee bee bee bee bee bec bec bec bec bec bee bee bee bee bee bec bec bec bec bec bec bee bee bee bee bee bee bee bee bee
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
dbb
edd
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd bed
abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd
abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd
edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
dec abc
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
770
3013 3013 772 3013 773 3013 774 3013 775 3013 776 3013 777 3013 778 3013 779 3013 780 3013 781 3013 782 3013 783 3013 784 3013 785 3013 786 3013 787 3013 788 3013 789 3013 790 3013 791 3013 792 3013 793 3013 794 3013 795 3013 796 3013 797 3013 798 3013 799 3013 800 3013 801 3013 802 3013 803 3013 804 3013 8053O13 806 3O13 807 3O13 808 3O13 S093O13 810 3O13 811 3013 812 3013 813 3013 814 3013 815 3013 816 3013 817 3013 818 3013 819 3013 820 3O13 821 3013 822 3013 823 3013 824 3013 825 3013 826 3013 827 3013 828 3013 829 3013 830 3O13 831 3013 832 3013 833 3013 834 3013 835 3013 836 3013 837 3013 838 3013 839 3013 84 03O13 841 3013 842 3013 843 3013 844 3013 845 3013 846 3013 847 3013 848 3013 849 3013 850 3013 851 3013
aaa aaa
bbb ccc ddd bbb ccc ddd
aaa
ccc bbb ccc
771
bbb
ddd ddd ddd ddd ddd ddd
abb abb abb abb
ccc ccc ccc bbb ccc
ddd ddd ddd ddd
abb abb abb abb
bbb
ddd ddd ddd ddd
ccc ccc bbb ccc bbb ccc
ddd ddd ddd ddd
bbb
aaa bbb
aaa aaa
666
aaa aaa
666
aaa aaa
bbb ccc ccc ccc bbb ccc bbb
aaa aaa
bbb
aaa
abb baa abb baa
aaa
bbb
abb abb abb abb abb abb abb a66
aaa
ccc bbb ccc
a66 a66
aaa
ccc ddd bbb ccc ddd
abb abb abb abb
aaa
aaa aaa
bbb 666 666
aaa
aaa
bbb ccc
aaa
aaa aaa
aaa
ace caa ace caa
baa baa baa baa baa baa baa baa baa baa
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa
caa caa caa caa caa caa caa caa
baa baa
a66 a66
baa
a66 a66
baa
bbb ccc
aaa
bbb
a66 abb
caa caa
aaa
ccc bbb ccc
abb abb
caa
bbb ccc
aaa
aaa aaa
aaa aaa
aaa
ccc bbb ccc
aaa
aaa
bbb
aaa
ccc bbb ccc
caa
a66 a66
baa
caa
baa
caa
baa
caa
baa
caa
ddd ddd
aaa
ccc ddd bbb ccc ddd
abb abb
ccc
aaa
aaa
bbb ccc
aaa
ddd ddd ddd ddd
aaa
bbb
aaa
ccc ddd bbb ccc ddd
aaa aaa
aaa
bbb
aaa
ccc bbb ccc
aaa aaa aaa
aaa
ccc ddd bbb ccc ddd
abb abb
aaa
bbb
aaa
ccc bbb ccc
aaa
aaa aaa
aaa aaa
abb abb a66 a66
ddd ddd
bbb
aaa
aaa
abb abb
abb abb abb abb
aaa
d d d
bbb
d d d
ccc
bbb ccc
ddd ddd
caa caa
bbb
aaa
baa
baa
aaa
aaa
baa
baa
a66 a66 abb abb
aaa
add add add add add add add add
abb abb
bbb ccc ccc bbb ccc
aaa
aaa
add daa add
add add add add add add add
baa baa baa baa baa baa
baa baa baa baa baa baa baa baa a66 baa
add add add ace ace ace ace ace ace ace ace
ace ace ace ace ace ace ace ace ace
add add add add add add add add add add add add add add add add add
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec
ebb bdd dbb
ebb
ebb ebb
ebb ebb
ebb ebb ebb ebb ebb ebb ebb
ebb ebb
ebb ebb
ebb ebb ebb ebb ebb ebb ebb
ebb ebb
ebb ebb
ebb ebb ebb ebb ebb ebb ebb
ebb ebb
ebb ebb
ebb ebb ebb ebb ebb ebb ebb ebb ebb
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd
dec abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd bed acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
2. CYCLES OF ALGEBRAS l 3 oi3-3013 3 oi3
852
aaa aaa
853
aaa
3013 3013 854 3013 855 3013 856 3013 857 3013 8583013 859 3 oi3 8603013 861 3013 862 3013 863 3013 8643013 865 3013 866 3013 867 3013 868 3013 8693013 870 3013 S713013 872 3013 87 3 3 013 874 3013 87 5 3 013 876 3013 877 3013 878 3013 879 3013 8803013 881 3013 882 3013 883 3013 884 3013 885 3013 8863013 887 3013 888 3013 88 93013 S903013 891 3013 892 3013 893 3013 894 3013 895 3013 896 3013 897 3013 8 9 8 3O 13 8"3013 9 003013 901 3013 902 3013 903 3013 904 3013 905 3013 906 3013 907 3013 9083013 9 9 0 3013 910 3013 911 3013 912 3013 913 3013 914 3013 915 3013 916 3013 9 7 l 3013 918 3013 919 3013 920 3013 921 3013 922 3013 923 3013 924 3013 925 3013 926 3013 927 3013 928 3013 929 3013 930 3013 931 3013 932 3013 933 3013
aaa
bbb bbb bbb
ccc ccc ccc
ddd ddd
aaa
aaa
bbb
aaa
aaa
bbb
ddd
ece ccc
ddd ddd
aaa
aaa aaa aaa aaa aaa aaa aaa
bbb bbb
bbb
ccc ccc
bbb
ccc ccc
bbb
ccc ccc
aaa
aaa
ddd ddd
bbb
aaa
aaa
ccc ccc
ddd ddd
bbb
aaa
aaa
bbb
ccc ccc ddd ddd
aaa
aaa
bbb
aaa
aaa
bbb
ccc ccc
ddd ddd
aaa
aaa
abb abb abb abb abb abb
baa baa baa baa baa baa baa baa baa baa
abb
baa
abb
baa
bbb
bbb
abb ccc ccc
bbb bbb
ccc ccc
abb abb ddd ddd
abb
ddd ddd
abb
abb abb
aaa
aaa
bbb
aaa
aaa
bbb
ccc ccc ddd ddd
aaa
aaa
bbb
aaa
aaa
bbb
ccc ccc
ddd ddd
aaa
aaa
abb
bbb
aaa
aaa
bbb
abb ccc ccc
aaa
aaa
bbb ccc
aaa
aaa aaa aaa aaa aaa
bbb ccc bbb bbb
aaa bbb
aaa
bbb
ccc ccc ccc ccc ccc ccc
aaa aaa
abb abb ddd
abb
ddd
abb
ddd ddd
abb
ddd ddd
abb
ddd ddd ddd ddd ddd ddd
abb
ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
ddd
aaa
aaa
bbb
ddd
bbb
ddd
ccc ccc bbb ccc bbb ccc
ddd ddd ddd ddd
aaa
aaa
bbb
aaa
aaa
ccc
bbb
ccc
aaa
aaa aaa aaa
ddd
bbb bbb
ddd
ccc ccc
aaa
aaa
baa baa baa baa baa baa baa baa
abb
aaa
aaa aaa aaa aaa aaa
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
ddd ddd
aaa
aaa
abb
bbb bbb ccc
aaa
ccc
bbb
ccc
ddd ddd
abb
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
ace caa ace ace ace ace ace ace ace caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa
abb abb baa baa baa baa baa baa baa baa baa baa baa baa ace ace ace ace ace ace
ace ace
baa baa baa baa baa baa baa
ace ace ace ace ace ace ace
add
daa
add add add add add add add
add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
bee
ebb
bec bec bec bee bee bee bee bee bec bec bec bec bec bec bee bee bee bee bee bec bec bec bec bec bee bee bee bee bee bee bec bec bec bec bec bee bee bee bee bee bee bec bec bec bec bec bee bee bee bee bee bec bec bec bec bec bec bee
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bee bee bee bee bec bec bec bec bec bee bee bee bee bee bee bec bec bec bec bec bec bec bec bec
bdd
abc
abd
acd bed
abc
abd
abc.
abd
abc abc
abd abd
abc
abd
abc
abd
abc
abd
abc
abd
abc.
abd
cdd
abc
abd
cdd
abc.
abd
cdd
abc
abd
cdd
abc.
abd
cdd
dbb cdd dbb cdd dbb cdd dbb cdd
dec
cdd
abc abc
abd abd
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
dbb dbb dbb
cdd
abc
abd
acd
cdd
abc
abd
acd
cdd
abc
abd
acd
dbb dbb dbb dbb dbb dbb dbb
cdd
abc
abd
acd
cdd
abc.
abd
acd
cdd
abc
abd
acd
cdd
abc.
abd
acd
cdd
abc
abd
acd
cdd cdd
abc. abc
abd abd
acd acd
dbb dbb dbb
cdd
abc
abd
acd
cdd
abc
abd
acd
cdd
abc
abd
acd
dbb dbb dbb dbb dbb dbb dbb dbb
cdd
abc
abd
acd
cdd
abc
abd
acd
cdd
abc.
abd
acd
cdd
abc
abd
acd
cdd
abc.
abd
acd
cdd
abc
abd
acd
cdd cdd cdd cdd cdd cdd cdd cdd
abc. abc
abd abd
abc
abd
abc
abd
abc
abd
abc
abd
abc
abd
abc.
abd
cdd
abc
abd
cdd
abc.
abd
cdd
abc
abd
cdd cdd cdd cdd cdd cdd
abc. abc
abd abd
abc
abd
abc
abd
abc
abd
abc
abd
cdd
abd
cdd
abc. abc.
cdd
abc
abd
cdd
abc.
abd
cdd
abc
abd
cdd cdd cdd cdd cdd cdd
abc.
abd abd
cdd
abc. abc.
abd
cdd
cdd
abc
abd
cdd
abc.
abd
cdd
abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
cdd cdd cdd cdd cdd cdd
cdd cdd cdd cdd cdd cdd
cdd
abc abc abc abc abc
cdd
abc. abc.
cdd
abc
cdd
abc.
cdd
abc
cdd
abc.
cdd
abc
cdd
abc.
cdd
abc
abd
abd abd abd abd abd
4329 FINITE INTEGRAL RELATION ALGEBRAS aaa 3 0 1 3 aaa 935 3013 936 3 0 1 3 aaa 937 3013 938 3 0 1 3 aaa 939 3013 94 <>3013 aaa 941 3013 942 3 0 1 3 aaa 934
944
3013 94 53013 946 3013 947 3013 948 3013 949 3013
bbb ccc bbb ccc
bbb ccc ccc ccc bbb ccc bbb
666
bbb ccc ccc
aaa
aaa 3013 3013 953 3013
bbb
ccc
bbb
ccc ddd
aaa
aaa
ddd bbb
ddd
bbb
ddd
955
3013 956 3013 957 3013
aaa aaa aaa
959
3013 ^^3013 aaa 3 0 1 3 aaa 962 3 0 1 3 aaa 963 3013 964 3 0 1 3 aaa 965 3013 966 3 0 1 3 aaa 967 3013 968 3 0 1 3 aaa
bbb bbb
ccc ccc ccc ccc
bbb
961
ccc bbb ccc ccc ccc 6 6 6 ccc bbb ccc
bbb
3O13 971 3013 972 3013 973 3013 974 3013 975 3013 976 3013 977 3013 978 3013 979 3013
aaa aaa
ccc ccc ccc bbb ccc
ddd ddd ddd ddd ddd ddd
aaa
abb
ddd ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
ddd ddd ddd ddd
bbb
aaa
aaa
bbb
ccc ccc
aaa
aaa aaa
982
aaa
ccc
ddd ddd ddd
ccc
ddd
bbb bbb
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
ddd
aaa
981
3013 3013 3013 984 3013
bbb
bbb
aaa
ddd ddd ddd ddd ddd ddd
9
970
ddd ddd ddd ddd
aaa
aaa
abb
ddd ddd ddd ddd
bbb
951 952
ddd
983
aaa 666
986
3013 3013 3013 989 3013
aaa
bbb
987 988
"°3013 991
aaa
aaa
3013 " 2 3 0 1 3 aaa "33013 " 4 3 0 1 3 aaa "53013 996 3 0 1 3 aaa 997 3013 998 3 0 1 3 aaa 999 3013 i o o o 3 0 1 3 aaa IOOI3013 1002 3O13 aaa 1003 3O13 1 0 0 4 3 O 1 3 aaa 10063O13 aaa 1007 3013 1 0 0 8 3 0 1 3 aaa 1009 3013 ioio 3 0 1 3 aaa 1011 1012
1014
ccc 666
3013 3013
aaa
3013
aaa aaa
bbb
ccc ddd ddd
bbb
ddd
bbb
ddd
ccc ccc bbb ccc bbb ccc
ddd ddd ddd ddd
bbb
bbb ccc ccc bbb
ccc
bbb
ccc ddd ddd
666
bbb ccc ccc 6 6 6 ccc bbb ccc
ddd ddd
ddd ddd ddd ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
baa baa baa baa baa baa baa baa baa baa
ace caa ace ace ace ace ace ace ace ace ace
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
baa baa baa baa baa baa baa baa baa baa baa baa ace ace ace ace ace ace ace ace
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
add
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa add
dac1 dac i daa dac . dac 1 dac 1 dac 1 dac 1 dac 1 dac . l dac 1 dac 1 dac . dac 1 dac 1 dac 1 dac 1 dac 1 dac 1 daa dac . daa dac . daa dac 1 dac1 dac dac dac dac daa dac daa dac daa dac dac dac dac dac dac daa dac daa dac daa dac dac dac dac dac dac daa dac daa dac daa dac dac dac dac dac dac daa dac daa dac dac dac dac dac dac dac dac daa dac daa dac daa dac daa dac
be z be z be z be z be z be z be z be z be z be z be be z be z be z be z be z be z be z be z be z he z be z be z be z be z be z be z
ebb bdd ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
dbb cdd
be
ebb
bee
ebb
dbb cdd dbb cdd dbb cdd
be
ebb
dbb
cdd
bee hcc
ebb ebb
dbb
cdd
dbb
cdd
be
ebb
dbb
cdd
hcc
ebb
dbb
cdd
be
ebb
dbb
cdd
hcc
ebb
be
ebb
dbb dbb
bee
ebb
dbb
be
ebb
dbb
bee
ebb
be
ebb
dbb dbb
bee hcc
ebb ebb
dbb
be
ebb
dbb
hcc
ebb
dbb
cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd edd cdd edd cdd edd cdd cdd cdd cdd cdd cdd cdd cdd cdd
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
edd
dbb
edd
dbb dbb
cdd
dbb
cdd
dbb
cdd
dbb
cdd
dbb dbb
cdd cdd
dbb
be
ebb
dbb
hcc
ebb
be
ebb
bee
ebb
dbb dbb dbb
be
ebb
dbb
bee
ebb
dbb
be be
ebb ebb
dbb
hcc
ebb
dbb
be
ebb
dbb
hcc
ebb
dbb
be
ebb
dbb
hcc
ebb
be
ebb
bee
ebb
dbb dbb dbb
be
ebb
dbb
bee
ebb
be
ebb
dbb dbb
be
ebb
dbb
hcc
ebb
dbb
dbb
be
ebb
dbb
hcc
ebb
dbb
be
ebb
dbb dbb dbb dbb dbb dbb
bee
ebb
be
ebb
bee
ebb
be
ebb
bee
ebb
be be
ebb ebb
hcc
ebb
be
ebb
hcc
ebb
be
ebb
hcc
ebb
be
ebb
hcc
ebb
be
ebb
cdd cdd cdd cdd edd cdd edd cdd cdd cdd cdd cdd cdd cdd cdd
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
cdd
cdd
dee
abc
abd
acd
abc abc abc abc abc abc abc abc abc
abd
acd acd acd acd acd acd acd acd acd
"abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd
lid acd acd acd acd
abd
acd
abd
acd
abd
acd
abd
acd
abd
acd
abd
acd
abd
acd
abd
acd
abd abd abd
acd acd
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
bed
2. CYCLES OP ALGEBRAS l3013-3013 30 i 3 aaa
10163013 aaa 1017 3013 aaa 1018 3013 aaa 1020 3 O 1 3
aaa
1021
3O13 10223O13 1023
1024
aaa
bbb ccc bbb ccc bbb ccc ccc ccc bbb ccc bbb ccc
3O13
3013 1025 3013 1026 3013 1027 3013 1028 3013 l° 2 9 3013 1030
3O13 10313O13 1032 3O13 1033 3O13 1034 3O13
aaa aaa aaa
aaa
ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd
bbb bbb
ddd ddd
ccc ccc 6 6 6 ccc bbb ccc
ddd ddd ddd ddd
aaa
aaa
bbb ccc
aaa
aaa
bbb
ccc
1035
3013 aaa 3013 aaa 1037 3013 aaa 1038 3013 aaa 1039 3013 1036
bbb ccc bbb ccc
ddd ddd ddd ddd
abb
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
aaa 1041
3O13 10423O13
bbb
aaa
bbb
1043
3O13 10443O13 1 0453O13 1046 1047
ccc
3013 aaa
3013 1048 3 0 1 3 1049 3013 1050 3013 10513O13 1052 3O13 1053 3O13
aaa aaa
ccc ccc ddd ddd ddd ddd
bbb bbb
ccc ccc bbb ccc bbb ccc
ddd ddd ddd ddd
666
bbb ccc 666
bbb
ccc ddd
aaa
3O13
KICCSOIS aaa 1067
3013 1068 3 0 1 3 aaa 1069 3013 1070 3013 aaa 1071 3013 aaa 1072 3013 aaa 1073
bbb
bbb
aaa
aaa 105*3013 1 ^53013 1056 3 O 1 3 aaa 1057 3013 1058 3013 aaa 1059 3013 1060 3 0 1 3 aaa 1061 3013 1062 3 O 1 3 aaa 1063 3O13 1 0643O13 1065
ccc
aaa
ddd bbb
ddd
bbb
ddd
ccc ccc 6 6 6 ccc bbb ccc bbb
aaa
3O13 3 O 1 3 aaa 1075 3 O 1 3 aaa 1076 3 O i3 aaa 1077 3 O 1 3 aaa 1078 3013 aaa 1074
ddd ddd ddd ddd
ccc
bbb
ccc ddd
bbb
ddd
ccc bbb ccc
ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
1079
3013 1080 3 0 1 3 aaa 10813013 1082 3013 aaa 1083 3O13 1 0843O13
aaa
10853O13 aaa 1087
ccc 666
bbb
ccc
ccc ccc bbb ccc bbb ccc
ddd ddd ddd ddd
3O13 aaa
1089
3013 1090 3013 1091 3013 1092 3013 1093 3013 1094 3013 1095 3013 1096 3013 1097 3ni3
aaa
bbb bbb ccc
aaa bbb aaa
ccc
bbb
aaa 666
ddd ddd ddd
baa ace caa
abb abb abb
abb abb abb abb abb abb abb abb abb abb abb
baa baa baa baa baa baa baa baa baa baa baa baa
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
baa baa baa baa baa baa baa baa baa baa bac bac bac bac bac bac bac bac bac
add dac 1 be 2 ebb bdd dbb dbb add daa be z ebb dbb add dac 1 be ; c 6 6 dbb ; c 6 6 daa be add dbb add dac 1 be ; e b b ; ebb dbb add dac 1 be dbb add dac 1 be 2 ebb dbb add dac 1 be 2 ebb dbb add dac 1 be 2 ebb dbb add dac 1 be ; c 6 6 dbb ; c 6 6 add dac 1 be dbb add dac 1 be ; c 6 6 dbb add dac 1 be ; c 6 6 ; c 6 6 1 be dac dbb add dbb add dac 1 be ; c 6 6 dbb add dac 1 be ; ebb
ace ace ace
add add add
ace ace ace
add add add
ace ace
add add
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa zaa zaa zaa zaa zaa zaa zaa zaa
dac dac dac dac dac dac dac dac dac dac dac da
1 1 1 1 1 1 1 1 1 1 1 i
daa da
i
daa daa daa daa daa daa da
i
daa da
i
daa da
i
daa daa daa daa daa daa da
i
daa da
i
daa da
i
daa daa daa daa daa daa da
i
daa da
i
daa da
i
daa daa daa daa daa daa da
i
daa da
i
daa da
daa daa daa daa daa daa daa daa daa
i
be 2 be 2 be 2 be 2 be ; be ; be ; be ; be ; be ; be 2 be 2 be 2 be 2 be 2 be = be = be = be = be = be 2 be 2 be 2 be 2 be 2 be 2 be = be = be = be = be = be 2 be 2 be 2 be 2 be 2 be z be = be = be = be = be = be 2 be 2 be 2 be 2 be 2 be z be = be = be = be = be 2 be 2 be 2 be 2 be 2 be 2 be z be = be = be = be = be = be = be = be =
edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd
dbb
edd
ebb
dbb
edd
ebb
dbb
edd
ebb c66
dbb
edd
dbb dbb dbb dbb dbb
edd
ebb
c66 c66 c66 c66 ebb
ebb ebb ebb ebb ebb c66 c66 c66 c66
c66 ebb
ebb ebb
ebb ebb ebb c66 c66 c66 c66
c66 ebb
ebb ebb
ebb ebb ebb c66 c66 c66 c66
c66 ebb
ebb ebb
ebb ebb ebb c66 c66 c66
c66 ebb ebb
ebb ebb
ebb ebb ebb c66 c66 c66 c66 c66 c66 c66
c66
dbb dbb dbb dbb dbb dbb
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
dbb dbb dbb dbb dbb dbb dbb dbb dbb
edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd
dec
abc
abd
acd bed
abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS aaa bbb ccc 3013 aaa bbb ccc 3013 ccc noo 3 0 1 3 aaa bbb ccc noisois 1102 3O13 aaa bbb ccc 1103 3O13 aaa 1104 3O13 aaa bbb ccc 1105 3 O 1 3 aaa 1106 3013 aaa bbb ccc 1107 3013 aaa 1108 3013 aaa bbb 1109 ccc 3013 aaa 1110 3013 aaa bbb ccc im 3013 1112 3013 aaa 1113 bbb 3013 1114 3013 aaa bbb 1115 ccc 3013 1116 ccc 3013 aaa 1117 bbb ccc 3013 1118 aaa bbb 3013 1119 3013 1120 3013 aaa 1121 bbb 3013 1122 3013 aaa bbb 23 ccc H 3013 1124 ccc 3013 aaa 112 bbb ccc 5 3 013 1126 3013 aaa bbb ccc 1127 3013 1128 3013 aaa 1129 666 3013 1130 3013 aaa bbb 1131 3013 1132 ccc 3013 aaa 1133 bbb ccc 3013 1134 3013 aaa bbb ccc 1135 3013 1136 3013 aaa 1137 bbb 3013 113 83013 aaa bbb 1139 ccc 3013 1140 ccc 3013 aaa 1141 bbb ccc 3013 1142 3013 aaa bbb ccc 1143 ccc 3013 aaa H 44 3013 aaa bbb ccc 4 H 53013 aaa bbb ccc ccc 11463Oi3 aaa 1147 3013 aaa bbb ccc 1148 aaa ccc 3013 1149 3013 aaa bbb ccc 1150 ccc aaa 3013 1151 3013 aaa bbb ccc 1152 ccc 3013 aaa 1153 3013 aaa bbb ccc ccc H54 3 0 1 3 aaa 11553Oi3 aaa bbb ccc H563013 aaa bbb ccc 1157 ccc 3013 aaa H583013 aaa bbb ccc ccc H593013 aaa 1160 3013 aaa bbb ccc 1161 ccc 3013 aaa 1162 3013 aaa bbb ccc 1163 aaa ccc 3013 1164 3013 aaa bbb ccc 11653Oi3 H663013 aaa bbb H673013 H683013 aaa bbb ccc H693013 ccc H703O13 aaa 1171 6 6 6 ccc 3013 1172 3013 aaa bbb ccc 1173 666 3013 1174 3013 aaa bbb 1175 6 6 6 ccc 3013 1176 30 i 3 aaa bbb ccc 1177 3013 1178 3013 aaa 666 n793ni3
ddd abb
1098
ddd
1099
ddd ddd ddd ddd
ddd ddd
ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb
ddd ddd ddd ddd
ddd ddd ddd ddd
ddd ddd ddd ddd
ddd ddd ddd ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
ddd ddd abb abb ddd abb ddd abb abb abb ddd abb
ddd ddd abb abb
ddd abb ddd abb
ddd ddd
ddd ddd abb abb abb
baa ace caa baa caa baa caa baa caa baa caa baa caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa baa ace caa
ace ace ace ace ace ace ace ace ace ace ace
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
add add add add add add add add
ace ace ace
baa baa baa baa baa baa baa baa
add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add
add add add
caa caa caa caa caa caa caa caa caa caa caa
add add add add add add add add add add add daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
edd dec abc edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd
abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd bed acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
2. CYCLES OP ALGEBRAS l 3 oi3-3013 3 oi3 aaa 3013 aaa "813013
1180
]_1HO „ 1 8 3 3013 8 4 1 3013 aaa 1 8 5 3013 1 863013 aaa 1 8 ? 3013 1 8 8 3013 aaa 1189
3013 H9°3013 3013 H923013 1193 3013 119*3013 H953013 H963013 11973013 1198 3 oi3 H993013 1200 3013 12013013 1202 3013 1203 3013 1204 3O i3 1205 3O i3 I2O63013 120?3O13 I2O83013 1209 3O i3 1210 30 13 1211 3013 12123013 !21 3 3013 1214 30 13 l 2 l 5 3013 12163013 1217 3013 12183013 12193013 I22O3013 12213013 !222 3 oi3 1223 3O l3 1224 3 0 1 3 1225 30 13 I2263013 122?3013 1228 3 oi3 1229 3 oi3 1230 3 oi3 123 l3013 12523013 1233 3013 12 3 4 30 13 1235 3013 12 3 6 3 013 12373O13 12383O13 1239 3 oi3 1240 3 oi3 12413013 1242 3 0 1 3 1243 3 0 1 3 !2443013 !2453013 1246 3 0 1 3 12473013 1248 3 oi3 1249 3 oi3 1250 3 oi3 12513013 12523O13 1253 3013 1254 3 0 1 3
aaa
1191
12553QI3
bbb ccc bbb ccc bbb
bbb
ccc ccc ddd ddd ddd ddd
bbb
bbb ccc ccc ccc bbb ccc 666
aaa
ddd
ddd ddd ddd ddd
abb abb abb
baa baa baa
ace caa ace ace
abb abb abb abb abb abb abb abb abb abb
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
aaa bbb
aaa
bbb
aaa bbb
ccc ccc ccc ccc
aaa
bbb
aaa
bbb
aaa
ccc bbb ccc
ddd ddd
bbb bbb
ddd ddd
aaa bbb
aaa
bbb
aaa 666
aaa
bbb
ccc ccc ccc ccc ddd ddd ddd ddd
aaa bbb
aaa aaa
bbb ccc ccc ccc bbb ccc bbb
aaa
ddd ddd ddd ddd
aaa bbb
aaa
bbb
aaa bbb
ccc ccc ccc ccc
aaa
bbb
aaa
bbb
aaa
ccc bbb ccc
ddd ddd
bbb 666
ddd ddd
aaa 666
aaa
bbb
aaa bbb
aaa
bbb
ccc ccc ccc ccc ddd ddd
bbb
aaa
bbb
aaa
ccc bbb ccc
aaa
bbb
aaa
ccc bbb ccc
bbb
aaa
ccc
aaa
aaa
bbb
aaa
aaa
bbb
ccc ccc
aaa
aaa
bbb
aaa
ccc bbb ccc
1256 30 13 aaa 1257 3013 aaa 1258 3O l3 aaa 1259 3O l3 aaa 1260 3 0 1 3 aaa 1261 3 O i 3 aaa
bbb
ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
ddd ddd abb abb abb abb ddd abb ddd abb ddd abb ddd abb
ccc ccc
ccc bbb ccc
ddd ddd abb
baa baa baa baa baa
add
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa add add add add add add add add add add add add
caa caa caa caa caa caa caa caa caa caa caa caa
add add add add add add add add add add add add add add add add add add add add add add add add add add add add
daa daa daa
bec
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
ebb bdd dbb ebb bdd dbb ebb bdd dbb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd
dec
abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
abc abd abd abc abd abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd bed acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
3::: acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
1262
3013 3013 1264 3013 1 2 65 3O 13 12663013 12673013 1268 3013 1269 3013 1270 3013 1271 3013 1272 3013 1273 3013 1274 3013 1275 3013 12763O13 1277 3013 12783O13 1279 3013 1280 3O13 1281 3013 12823O13 1283 3013 1284 3013 1285 3013 1286 3013 287 1 3O13 1288 3013 12893O13 1290 3O13 1291 3013 1292 3013 1293 3013 12943O13 12953O13 1296 3013 1297 3013 12983O13 1299 3013 1300 3O13 1301 3O13 1302 3O13 1303 3013 1304 3013 1305 3013 1306 3013 1307 3013 1308 3O13 1309 3O13 1310 3O13 13H3O13 1312 3013 1313 3013 1314 3013 1315 3013 1316 3013 1317 3013 1318 3013 1319 3013 1320 3O13 1321 3013 13223O13 1323 3013 1324 3013 1325 3013 1326 3013 1327 3013 1328 3013 13293O13 1330 3O13 1331 3013 1332 3013 13333O13 13343O13 13353013 13363013 1337 3013 1338 3013 1339 3013 1340 3013 1341 3013 1342 3013 1343 3013 1263
aaa aaa
bbb ccc ddd abb baa abb baa bbb
aaa
ccc bbb ccc
aaa
ddd ddd
aaa
aaa
bbb
aaa
ccc ddd bbb ccc ddd ccc bbb ccc
aaa aaa
aaa
ccc
aaa
aaa
bbb ccc
abb abb abb abb
abb abb
ac c caa add add add add
baa baa baa baa baa baa
ddd ddd
add add add ac c
add add
ac c
add
ac c
add
ac c
abb abb
ac c
add add
ac c
add
ac c ac c
add add
ac c
add
aaa
bbb
ddd ddd
abb abb abb abb
ac c
add
aaa
ccc ddd bbb ccc ddd
abb abb
ac c
add
ac c
add add
aaa
aaa
bbb
aaa
ccc bbb ccc
aaa aaa
aaa aaa
aaa
bbb
aaa
ccc bbb ccc
aaa aaa
aaa
bbb
aaa
aaa
ddd ddd
bbb
ccc ccc
ddd ddd
abb abb
aaa
aaa
bbb ccc
aaa
aaa
bbb ccc ddd ddd
aaa
aaa
bbb
aaa
ccc ddd bbb ccc ddd ccc bbb ccc
aaa aaa
aaa
ccc
aaa
aaa
bbb ccc bbb
aaa
ccc bbb ccc ddd ddd
aaa
aaa
bbb
aaa
ccc ddd bbb ccc ddd ccc bbb ccc
aaa
aaa
ccc
aaa
aaa
bbb ccc
aaa
aaa
bbb ccc
aaa
aaa
bbb ccc ddd ddd
aaa
aaa
bbb
aaa
ccc ddd bbb ccc ddd ccc bbb ccc
aaa aaa
aaa aaa
aaa
ccc bbb ccc
add add add add add add add add add add add
caa caa caa
add add add
caa caa
add add
caa caa caa
add add add
caa caa caa
add add add
caa caa
add add
caa caa caa
add add add
baa
caa caa caa
add add add
baa baa baa
caa caa caa
add add add
abb abb baa baa baa baa
abb abb
baa
abb abb abb abb
baa
abb abb
add
caa caa
abb abb abb abb
ddd ddd
add
add add add add
abb abb
aaa
aaa
abb abb
ac c ac c ac c ac c ac c ac c ac c ac c ac c ac c ac c ac c ac c ac c ac c ac c
ddd ddd
aaa
aaa
abb abb abb abb
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
baa baa
ddd ddd
ac c
caa
add
ac c
caa
add
ac c
caa
add
ac c
abb abb
ac c
caa caa
add add
ac c
caa
add
ac c
caa caa caa
add add add
aaa
bbb
ddd ddd
abb abb abb abb
ac c
caa
add
aaa
ccc ddd bbb ccc ddd
abb abb
ac c
caa
add
ac c
caa caa
add add
aaa
aaa
bbb ccc
aaa
aaa
bbb ccc
aaa
aaa aaa
aaa
bbb
aaa
ccc bbb ccc
aaa aaa
d d d
aaa
bbb
d d d
aaa
ccc bbb ccc
ddd ddd
aaa aaa
aaa aaa
bbb ccc
baa baa baa baa baa baa baa baa abb baa abb baa abb baa
ac c ac c
ac c ac c ac c ac c ac c ac c ac c ac c ac c ac c ac c
caa
add
caa caa
add add
caa
add
caa
add
caa
add
caa caa
add add
caa
add
caa
add
daa bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd
dec abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd bed acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
2. CYCLES OF ALGEBRAS l 3 oi3-3013 3 oi3
13443013 13453013 13463013 13 47 3013 13483013 1349 3 oi3 13503013 13513013 1352 30 13 13533013 1354 30 13 13553013 1356 30 13 13573013 13583013 13593013 1360 30 13 13&13013 1362 30 13 1363 30 13 13643013 1365 30 13 13663013 1367 30 13 13683o 13 1369 30 13 137<>3013 13713013 1 372 3O13 13733013 1374 30 13 13753013 13763013 13773013 1378 3 oi3 1379 3 oi3 1380 30 13 13813013 1382 30 13 1383 30 13 13843013 1385 3 oi3 1386 3 oi3 1387 30 13 1388 3 oi3 1389 30 13 13903013 13913013 1392 3 oi3 1393 3 oi3 1394 3 oi3 1395 3 oi3 1396 30 13 1397 3 oi3 13983013 1399 3 oi3 140030i3
aaa aaa aaa aaa
bbb bbb
abb
ccc
abb abb abb abb abb
ddd
bbb
ddd ddd ddd
aaa bbb
ccc ccc
aaa
ccc
aaa bbb
ccc
aaa
ccc ddd ccc ddd
aaa
aaa aaa aaa aaa aaa aaa aaa
bbb
bbb
ccc
abb
ccc
abb
.
bbb
ddd ddd
ccc ddd aaa bbb ccc ddd
abb abb abb abb
ccc aaa
ccc
bbb bbb
ccc ccc
ccc aaa ccc bbb ccc aaa bbb ccc
ddd ddd ddd ddd
aaa 666
aaa
bbb ccc
aaa aaa
ccc
bbb bbb
ccc ccc ddd
aaa
ddd ddd
666
aaa bbb
ddd
ccc ccc bbb ccc aaa bbb ccc aaa
aaa aaa aaa aaa aaa aaa
ddd ddd ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
bbb
bbb ccc
aaa
ddd
bbb
ddd
ccc ddd bbb ccc ddd
abb abb abb abb abb abb abb abb
aaa bbb
aaa bbb ccc ccc bbb
ccc
bbb
ccc ddd ddd ddd ddd
bbb bbb
ccc ccc 6 6 6 ccc aaa bbb ccc aaa
ddd ddd ddd ddd
aaa 666
aaa
ace ace ace ace ace
ccc ddd bbb ccc ddd
aaa bbb
aaa
baa baa baa baa baa baa baa baa baa baa baa
ccc
ccc
3013 "023013 aaa 1 403 3013 1 404 3013 aaa 1 406 3013 14063013 aaa
baa baa baa baa baa baa baa baa baa baa baa baa baa
ccc
aaa
aaa aaa aaa
ace ace ace ace ace ace
abb
aaa
aaa
baa baa baa baa baa baa
abb
bbb
1401
l«73013 1408 30 i3 1409 3 0 i 3 l 4 l°3013 "113013 l 4 l 2 3013 "133013 l 4 l 4 3013 "153013 U163O13 l 4 l 7 3013 l«83013 H193013
ccc ddd
bbb ccc
aaa
ccc
bbb bbb
ccc
ccc 112<>3O13 aaa H2l3013 11223013 aaa bbb 11233013 11213013 aaa bbb ccc 11253013
ddd
ddd ddd ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb
ace ace ace ace ace
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
caa caa caa caa caa caa
add add add add add add
daa
bec
ebb
bdd
dbb
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd bdd bdd
dbb dbb dbb
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
bee bee bee bec bee bee bee bee bee bee bee bee bee bee bec bec bec bec bec bee bee bee bee bee bec bec bec bec bec bec bee bee bee bee bee bec bec bec bec bec bec bee bee bee bee bee bec bec bec bec bec bee bee bee bee bee bee bec bec bec bec bec bee bee bee bee bee bec bec bec bec bec bec bee bee bee bee bee bee bee bee bee
cdd cdd edd
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb
bdd
dbb
edd cdd
bdd
dbb
cdd
bdd
dbb
cdd
bdd
dbb
cdd
bdd
dbb
cdd
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb
edd
bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb
cdd
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb
edd
bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb
cdd cdd cdd cdd cdd cdd
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb
edd
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb
cdd cdd cdd cdd cdd edd
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb dbb dbb dbb
edd cdd cdd cdd cdd cdd
edd edd
edd edd
edd
edd
edd edd
edd cdd cdd cdd cdd cdd edd
edd edd
edd
edd
edd edd
edd
edd edd
edd edd
edd cdd cdd cdd cdd cdd edd
edd edd
edd edd cdd cdd cdd cdd cdd cdd edd
edd edd
edd edd
edd edd
edd edd
dec
abc
abd
acd
abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abe abc abc abc abc abc abc abc abc abc abc abe abc abc abc abc abc abc abc abc abc abc abe abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd aed acd aed aed acd aed acd acd acd acd acd aed aed acd aed acd acd acd acd acd acd acd aed aed acd aed acd aed acd aed acd
bed
4329 FINITE INTEGRAL RELATION ALGEBRAS aaa bbb ccc aaa ccc 6 6 6 ccc 1428 3013 aaa bbb ccc 1426
3013
1430 3O i3 bbb 3013 1432 3013 aaa bbb 1433 3013 1434 3 0 1 3 aaa 1435 666 3013 1436 3 0 i 3 aaa bbb 1437 3013 1438 3013 aaa 666 14393O13 144 03O13 aaa bbb 1441 3O i3 1431
aaa
ddd ddd ddd ddd
caa
ccc ccc ccc ccc
ddd ddd ddd ddd abb abb abb abb
ccc
bbb
aaa 666
1504
3013 aaa bbb 1505 3 0 1 3 1506 3013 aaa 666 15073ni3
ac 2 caa add dac1 be z ac z daci be z ac z daa he z ac z dac. be z caa caa caa caa caa caa caa caa caa caa
3013 aaa bbb 1473 ccc 3013 1474 30 i 3 aaa ccc bbb ccc 1476 3O i3 aaa bbb ccc 1477 3013 1478 ccc 3013 aaa 666 14793O13 1480 3 0 1 3 aaa bbb ccc 14813013 ccc 1482 ccc 3013 aaa 1483 bbb ccc 3013 1484 3O i3 aaa bbb ccc 1485 3O i3 1486 3O i3 aaa 1487 bbb 3013 1488 3 0 1 3 aaa bbb 1489 ccc 3013 1490 3 0 1 3 aaa 1491 ccc bbb 3013 aaa bbb 1493 3 oi3 1494 3 0i3 aaa bbb 1495 3 oi3 I4963013 aaa bbb ccc 1497 3 oi3 ccc I4983013 aaa 6 6 6 ccc 1499 3 0 1 3 1500 3013 aaa bbb ccc 3013
baa baa baa baa
ccc ccc
1472
1502
abb abb abb
ccc
bbb ccc 1443 30 i 3 I4443013 aaa bbb ccc 1445 ddd 3013 ddd 1446 3 0 1 3 aaa ddd bbb 1447 3 0 1 3 1448 ddd 3013 aaa bbb 1449 ccc ddd 3013 ccc ddd 1450 3 oi3 aaa bbb ccc I45I3013 ddd 1452 3O i3 aaa bbb ccc ddd ccc 1453 3O i3 14 4 ccc 5 3013 aaa bbb ccc 1455 3 oi3 1 4 5 6 3 Q I 3 aaa bbb ccc 1457 ccc ddd 3013 1458 ccc ddd 3013 aaa 6 6 6 ccc 1459 3 0 1 3 ddd 1460 3 0 1 3 aaa bbb ccc ddd 1461 3O i3 l « 2 3 0 1 3 aaa bbb 1463 3O i3 1464 3O i3 aaa bbb ccc 1465 3O i3 ccc 1466 3O i3 aaa 1467 bbb ccc 3013 1468 3 0 1 3 aaa bbb 1469 ddd 3013 ddd 1470 3 0 1 3 aaa
14713QI3
abb
ccc
ddd ddd
ddd ddd ddd ddd
abb abb abb abb abb abb abb abb abb abb abb
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
caa caa caa caa caa caa caa caa caa caa caa caa caa caa
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
caa caa
caa caa
caa caa caa caa caa caa caa
caa caa
caa caa
caa
baa baa baa baa ac z ac
z caa
ac z ac
ddd ddd ddd ddd
ddd ddd ddd ddd
ddd ddd ddd ddd
caa caa caa caa caa caa caa
z caa
ac z
caa
ac z caa ac 2 caa ac 2 caa
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
dac1 1 dac1 dac1 dac1 dac. dac1 dac. dac1 dac. dac1 dac1
1 dac1 dac1 dac1 dac. dac1 dac. dac1 dac. dac1 dac1 dac dac dac dac
be z
ebb ebb
be z
ebb
be z be z
ebb ebb
be z
ebb
be z
ebb
be z
ebb ebb
be z
be z be z be z be z be z be z be z be z be z be z be z be z be z be z be bee be bee
ebb ebb ebb ebb ebb ebb ebb ebb
ebb ebb ebb ebb ebb
be
ebb
daa hcc ebb dac
be
ebb
daa hcc ebb dac dac dac dac dac dac
be
bee
ebb ebb
be
ebb
bee be
ebb ebb
bee
ebb
be
ebb
daa hcc ebb dac
be
ebb
daa hcc ebb dac dac dac dac dac dac
bee
ebb ebb
be
ebb
be
bee be be
ebb ebb ebb
dac
be
ebb
daa hcc ebb dac
be
ebb
daa hcc ebb dac
be
dac
bee
ebb ebb
be
ebb
dac
bee be
ebb
dac daa
be hcc
ebb ebb
be hcc
ac z
caa caa
ac z
caa
dac
ac z caa ac z caa ac 2 caa
daa dac dac
be bee
ebb
ebb
dac
be
ac 2 caa
dac
bee
dac dac
be
bee
ebb ebb
be be
ebb ebb
caa
- - - ac 2
caa
dac
ac z
caa
dac
ac z ac z ac z ac z ac z ac z ac z ac z
caa caa
caa caa
caa caa
caa caa
dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd bdd
ebb ebb
be
ebb
daa hcc ebb dac
be
ebb
daa hcc ebb dac
be
ebb
daa hcc ebb dac
be
ebb
dbb dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb
bdd bdd bdd bdd
dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb
dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb
bdd
dbb dbb dbb dbb dbb dbb dbb dbb dbb
daa hcc ebb bdd dac
dbb dbb dbb dbb dbb
dbb dbb dbb dbb dbb
bdd bdd ebb bdd ebb bdd ebb bdd
caa
ac 2 caa
bdd bdd bdd bdd bdd
daa hcc ebb bdd
dac
- - - ac 2
dbb dbb dbb dbb dbb dbb
daa hcc ebb bdd dac
cdd cdd cdd cdd edd cdd edd cdd cdd cdd cdd cdd cdd cdd cdd
bdd bdd bdd bdd bdd bdd
daa hcc ebb bdd dac
cdd
dbb dbb dbb dbb dbb dbb dbb dbb
bdd bdd ebb bdd ebb bdd ebb bdd ebb
dbb
bdd bdd bdd bdd bdd
ebb
ac 2 caa
- - - ac 2
bdd
bdd ebb bdd ebb bdd ebb
ac 2 caa ac z
baa baa baa baa baa baa baa
be z
ebb
bdd bdd bdd bdd bdd bdd bdd
edd cdd edd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd edd cdd edd cdd edd cdd cdd cdd cdd cdd cdd cdd cdd cdd
dee
abc
abd
acd bed
abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
2. CYCLES OP ALGEBRAS l 3 oi3-3013 3 oi3
1508
3013 3013 1510 3013 15H3013 1512 3013 1513 3013 1514 3013 I5I53013 1516 3013 1517 3013 1518 3013 1519 3013 1520 3013 1521 3013 1522 30 13 1523 3013 1524 3 0 1 3 1525 3O i3 I5263013 1527 3 0 1 3 1528 3013 1529 3 0 1 3 1530 3013 1531 3O l3 1532 3013 1533 3O i3 1534 3O i3 1535 3 oi3 1536 3O i3 1537 3013 1538 3013 1539 3013 1540 3013 1541 3 0 i 3 1542 3 0 1 3 1543goi3 1544goi3 1545goi3 1546 3 oi3 1547goi3 1548 3O i3 1549 3 0 1 3 1550 3013 1551 3O l3 1552 3013 1553 3013 1554 3O i3 1555 3 oi3 1556 3 oi3 1557goi3 1558 3O i3 1559 3013 1560 3013 1561 3013 1562 3013 1563 3013
aaa aaa
bbb ccc bbb ccc
1509
15643QI3
1565 3O i3 I5663013 1567 3O i3 I5683013 15693013 1570 3013 1571 3013 1572 3013 1573 3013 1574 3013 1575 3 oi3 1576 3 oi3 15 77 3013 15783O13 15793013 1580 3O i3 1581 3013 1582 3013 1583 3013 1584 3013 1585 3013 1586 3013 1587 3013 1588 3013 1589 3013
ddd ddd ddd ddd
aaa bbb
aaa aaa
bbb ccc ccc ccc bbb ccc bbb
aaa
ddd abb
ddd ddd ddd ddd
aaa 666
aaa
bbb
aaa bbb
aaa
bbb
ccc ccc ccc ccc ddd ddd ddd ddd
aaa bbb
aaa aaa
aaa
bbb ccc ccc bbb ccc bbb ccc
aaa
bbb
aaa
ccc bbb ccc bbb
aaa
aaa
bbb
ccc ccc
aaa
aaa
bbb
aaa
ccc bbb ccc
aaa aaa
bbb
aaa aaa
aaa
bbb
ddd ddd abb abb abb abb ddd abb ddd abb ddd abb ddd abb
ccc ccc ccc ccc
ccc ccc bbb ccc bbb ccc
ddd ddd ddd ddd
aaa bbb
aaa
bbb ccc
aaa
aaa
ccc 666
ccc
bbb
ccc ddd
aaa
ddd 666
aaa aaa
aaa
ddd ddd
bbb ccc ccc bbb ccc bbb ccc
aaa
bbb
aaa
ccc bbb ccc bbb
aaa
aaa
bbb
ccc ccc
aaa
aaa aaa
aaa
bbb
ccc bbb ccc
bbb
aaa 666
aaa
bbb
ccc ccc ccc ccc ddd
add add add add add add add add add add add add add add add add add add
ace ace ace ace ace ace ace ace ace ace ace ace
abb abb abb abb ddd abb ddd abb ddd abb ddd abb
666
add
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
ddd ddd
aaa
aaa
add
ccc
aaa
aaa
add add add add add
ccc
aaa aaa
ddd ddd ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
add daa
add add add add add add
ccc
aaa
aaa
ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa
ccc
aaa aaa
ddd ddd ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
baa baa baa baa baa baa baa baa baa
ace ace ace ace ace ace ace ace ace
add add add add add add add add add add add add add add add add add add add add add add add add add add
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
bec bec bec bec bec bec bec bec bec bec bee bee bee bee bee bec bec bec bec bec bee bee bee bee bee bec bec bec bec bec bec bee bee bee bee bee bec bec bec bec bec bec bee bee bee bee bee bec bec bec bec bec bee bee bee bee bee bee bec bec bec bec bec bee bee bee bee bee bec bec bec bec bec bec bee bee bee bee bee bee bee bee bee
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd
dec abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd bed acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
1590
3013 3013 1592 3013 1593 3013 !5 94 3013 15953013 !5 9 63013 1597 3013 15983O13 15993O13 1600 3013 1601 3013 1602 3013 1603 3013 160*3013 1605 3O i3 I6O63013 1607 3 O 1 3 i608 3 O 1 3 1609 3013 1610 3013 1611 3013 1612 3013 1613 3013 1614 3013 1615 3013 I6I63013 16173013 I6I83013 !6 19 3013 1620 3013 1621 3013 1622 3013 1623 3013 1624 3013 1625 3013 1626 3O i3 1627 3013 1628 3O i3 1629 3013 1630 3O13 1631 3013 1632 3013 1633 3013 1634 3013 1635 3013 1636 3O i3 1637 3013 1638 3013 1639 3013 16*0 30 13 1641 3013 16423O13 1643 3013 1644 3013 1645 3013 16463O13 1647 3013 1648 3O i3 !6 49 3013 1650 3 O 1 3 1651 3O i3 1652 3013 1653 3013 1654 3013 655 1 3O13 1656 3013 1657 3 0 1 3 1658 3 0 1 3 1659 3 0 1 3 I66O3013 I66I3013 1662 3 0 1 3 1663 3013 1664 3013 1665 3013 1666 3013 1667 3013 1668 3013 1669 3013 1670 3013 167 i3ni3 1591
aaa bbb ccc ddd abb baa aaa d d d baa bbb d d d baa d d d aaa bbb baa ccc ddd baa aaa ccc ddd baa bbb ccc ddd baa aaa bbb ccc ddd baa abb baa aaa a66 baa 666 a66 baa a66 baa aaa bbb ccc a 6 6 baa aaa ccc a 6 6 baa 6 6 6 ccc a 6 6 baa abb baa aaa bbb ccc ddd abb baa ddd abb baa aaa bbb ddd abb baa ddd abb baa aaa bbb ccc ddd abb baa aaa ccc ddd abb baa bbb ccc ddd abb baa aaa bbb ccc ddd abb baa ccc aaa ccc bbb ccc aaa bbb ccc aaa
aaa
ccc ccc bbb ccc bbb ccc
ddd ddd ddd ddd
a66 a66 a66 a66
aaa 666
aaa bbb aaa
aaa
ccc ccc bbb ccc bbb ccc
aaa bbb
aaa bbb ccc ccc ccc aaa bbb ccc ccc aaa ccc bbb ccc aaa bbb ccc aaa
bbb
aaa
aaa
ccc ccc 6 6 6 ccc bbb ccc
ddd ddd ddd ddd
abb abb abb abb abb abb abb abb
ddd ddd ddd ddd
abb abb abb abb baa baa baa baa
ddd ddd ddd ddd
bbb
aaa bbb ccc ccc ccc bbb ccc
aaa bbb
aaa bbb ccc ccc ccc aaa bbb ccc ccc aaa ccc 6 6 6 ccc aaa bbb ccc aaa
bbb
aaa
ccc ccc ccc bbb ccc 666
aaa aaa
666
baa baa
ddd ddd ddd ddd
abb abb abb a66 abb abb abb abb
ddd ddd ddd ddd
abb abb abb abb
bbb
aaa
baa
a66 a66 abb abb
aaa
aaa
baa
ddd ddd ddd ddd
a66 a66 a66
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
ace caa ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa
add daa add add add add add add add add add add add add add add add add add add add add add add add
add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
bec bee bee bee bec bec bec bec bec bee bee bee bee bee bee bec bec bec bec bec bee bee bee bee bee bec bec bec bec bec bec bee bee bee bee bee bec bec bec bec bec bec bee bee bee bee bee bec bec bec bec bec bee bee bee bee bee bee bec bec bec bec bec bee bee bee bee bee bec bec bec bec bec bec bee bee bee bee bee bee bee bee bee
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
edd dec abc edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd
abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd bed acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
2. CYCLES OF ALGEBRAS l 3 oi3-3013 3 oi3
16723013 16733013 16743013 1675 3013 1676 301 3 167?3013 1678 301 3 1679 30 13 I6803013 I68I3013 I6823013 1683 3 oi3 1684 3 oi3 1685 3 oi3 1686 301 3 1687 30 13 !6883013 1689 30 13 1690 30 13 16913013 1692 30 13 1693 30 13 16943013 16953O13 1696 301 3 1697 30 13 1698 30 13 1699 30 13 17003013 17°l3013 1702 30 13 17033013 17043013 17053013 17063013 1 707 3013 17083013 17093013 "103013 1711 3013 17123013 1713 3 oi3 17143013 1715 30 13 17163013 1717 3 oi3 m8 3013 17193013 17203013 17213013 1722 3013 17233013 1724 30 13 17253013 1726 30 13 17273013 17283013 17293013 17303013 1731 3013 17323013 1733 3013 17343013 1735 30 13 17363013 1737 30 13 1738 3 oi3 173«3013 1 740 3013 17«3013 1742 3013 17«3013 1744 3013 17453013 1746 30 13 17473013 1748 3 oi3 1749 3 oi3 17503013 17513013 1752 30 13 17533013
aaa aaa
bbb ccc bbb
aaa 666
aaa
bbb
ccc ccc ccc ccc ddd ddd ddd ddd
aaa 666
aaa aaa
aaa
ddd abb
bbb ccc ccc bbb ccc bbb ccc
ddd ddd ddd ddd
aaa 666
aaa
bbb
aaa
bbb
aaa
bbb
ccc ccc ccc ccc .
aaa bbb
aaa aaa
aaa
ddd ddd ddd ddd
bbb ccc ccc 6 6 6 ccc bbb ccc
ddd ddd ddd ddd
aaa bbb
aaa
bbb
aaa 666
aaa
bbb
ccc ccc ccc ccc ddd ddd ddd ddd
aaa 666
aaa
bbb ccc ccc
aaa
bbb ccc
aaa
bbb ccc
ddd ddd ddd ddd
baa
abb abb abb abb abb abb abb abb abb abb abb abb abb
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa
aaa
aaa aaa aaa
bbb bbb ccc bbb ccc
aaa
aaa
bbb
aaa
ccc ccc
aaa
bbb
aaa
ccc bbb ccc
aaa
ddd abb abb abb abb ddd abb ddd abb
aaa
aaa
baa
bbb
aaa
ccc ccc
aaa
bbb
aaa
ccc bbb ccc
aaa aaa
aaa
bbb
aaa
ccc ccc
aaa
bbb
aaa
ccc bbb ccc
aaa aaa
aaa aaa
bbb bbb
ccc
aaa
aaa aaa
bbb bbb ccc
ddd ddd abb abb abb abb ddd abb ddd abb abb abb abb ddd abb ddd abb ddd abb
aaa
aaa
bbb
aaa
aaa
bbb
ccc ccc
aaa
ddd
aaa
bbb
aaa
ccc bbb ccc
aaa aaa
ddd
ddd ddd abb
baa baa baa baa baa baa baa baa baa baa baa ace ace ace ace ace ace
baa baa baa baa baa baa baa baa baa
ace ace ace ace ace ace ace ace ace
add add add. add add add add add add add. add add. add add. add add add add add add add. add add. add add. add add add add add add add. add add. add add. add add add add add add add. add add. add
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
bec bec bec bec bec bec bec bec bec bee bec bec bec bec bec bec bec bec bec bec bee bec bec bec bec bec bec bec bec bec bec bee bec bec bec bec bec bec bec bec bec bec bee bec bec bec bec bec bec bec bec bec bee bec bec bec bec bec bec bec bec bec bec bee bec bec bec bec bec bec bec bec bec bec bee bec bec bec bec bec bec bec bec
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
cdd cdd
dec
cdd. cdd cdd cdd cdd cdd cdd
cdd. cdd
cdd. cdd
cdd. cdd cdd cdd cdd cdd cdd
cdd. cdd
cdd. cdd
cdd. cdd cdd cdd cdd cdd cdd
cdd. cdd
cdd. cdd
cdd. cdd cdd cdd cdd cdd cdd
cdd. cdd
cdd. cdd
cdd. dec cdd cdd cdd cdd cdd cdd
cdd. cdd
cdd. cdd
cdd. cdd cdd cdd cdd cdd cdd
cdd. cdd
cdd. cdd cdd cdd cdd cdd cdd cdd cdd
cdd. cdd
cdd. cdd
cdd. cdd
cdd. cdd
dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec
abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd
acd bed
abd.
acd
abd abd abd abd abd abd
acd acd acd acd acd acd acd acd acd. acd acd. acd acd
abd. abd
abd. abd
abd. abd abd abd abd abd abd
acd
acd acd acd acd
abd.
acd
abd
acd
abd.
acd.
abd
acd
abd.
acd. acd
abd abd abd abd abd abd
acd acd acd acd acd
abd.
acd
abd
acd
abd.
acd.
abd
acd
abd.
acd. acd acd acd acd acd acd acd acd acd. acd acd. acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
abd abd abd abd abd abd
abd. abd
abd. abd
abd. abd abd abd abd abd abd
abd. abd
abd. abd
abd. abd abd abd abd abd abd
abd. abd
abd. abd abd abd abd abd abd abd abd
abd. abd
abd. abd
abd. abd
abd. abd
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
1754
3013 3013 1756 3013 1 7 5?3O13 1768 3013 "593013 1760 3O13 1761 3013 1762 3013 1763 3013 1764 3013 1765 3013 1766 3013 1767 3013 1768 3O 13 1769 3013 1 77 «3O13 1771 3013 1772 3013 1773 3013 1774 3013 1775 3013 1776 3013 1777 3013 1778 3013 779 1 3O13 1780 3O13 !7«l3013 1782 3013 1783 3013 1784 3013 1785 3013 1786 3013 1787 3013 1788 3013 1789 3013 179<>3O13 1791 3013 1 792 3O13 1793 3013 1794 3013 1795 3013 1796 3013 1797 3013 1798 3013 1799 3013 1 8 0«3013 1S013O13 1802 3O13 1803 3O13 1804 3O13 1805 3013 1806 3013 1807 3013 1808 3013 1809 3013 1810 3013 1811 3013 l8l23013 1813 3013 1 8 "3O13 1816 3013 1816 3013 1817 3013 1818 3013 1819 3013 1820 3013 l 8 2 l3013 1822 3013 1823 3013 1824 3013 1825 3013 18263O13 1827 3013 1828 3013 1829 3013 1830 3013 1831 3013 1832 3013 1833 3013 1834 3013 18353O13 1755
aaa aaa aaa
aaa aaa
aaa aaa
aaa
bbb ccc ddd abb baa 666 o66 baa ccc o 6 6 baa c c c o 6 6 baa bbb ddd abb baa ddd abb baa bbb ccc ddd abb baa bbb ccc ddd abb baa baa
aaa
baa
ace caa add ace ace ace ace ace ace ace caa caa
666
aaa
666
aaa
ccc 666 ccc
baa
666
aaa
aaa aaa
baa
ddd
baa
bbb
ddd
baa
bbb
ddd
baa
bbb
ccc
ddd
baa
bbb
ccc
ddd
baa
a66 o66 a66 o66
aaa 666
aaa
666 ccc
aaa
aaa
baa baa baa
bbb
ccc
abb
baa
ddd
abb
baa
ddd
abb
baa
abb
baa
ddd
666 ccc ccc 666 ccc 666 ccc
aaa
bbb bbb
ccc
aaa
bbb
ccc
aaa 666
666 666
ddd ddd ddd ddd ddd
bbb
ccc ccc
abb abb abb abb abb abb abb abb abb abb abb
ddd
abb
ddd ddd ddd
abb abb abb
ddd ddd
abb abb abb abb
aaa
aaa aaa aaa
o66
abb
bbb
aaa
bbb bbb ccc bbb ccc ddd
aaa
666
aaa
ccc 666 ccc
aaa
aaa
666
ccc
ddd
ccc
ddd
aaa
bbb ccc
aaa
bbb
aaa
ccc ddd bbb ccc ddd
aaa
ccc
baa baa baa
baa baa baa baa baa baa baa baa baa baa baa baa
ace ace ace ace ace ace ace ace ace ace ace ace ace
add
abb
ace
add
abb
ace
add
ace ace ace ace ace ace ace ace ace ace ace ace
add
abb
aaa
baa
add
abb abb
aaa
baa
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa
ace
aaa
aaa
baa
abb
aaa
aaa
baa
ccc
bbb
aaa
baa
ccc
aaa
aaa
baa
bbb
aaa
caa caa caa
baa
abb
abb abb
baa baa baa baa baa baa baa baa baa baa baa baa
add add add add add add add add add add add
baa
caa
add
baa
caa
add
bbb
baa
caa
add
aaa
666
baa
caa
add
bbb ccc bbb ccc
baa
caa
add
aaa
baa
caa
add
ddd
baa
caa
add
ddd
baa
caa
add
bbb
ddd
baa
caa
add
bbb
ddd
baa
caa
add
baa
caa
add
aaa
aaa
aaa aaa
666
ccc
ddd
666
ccc
ddd
aaa 666
aaa
666
aaa 666
baa
caa
add
o66 a66 o66 a66
baa
caa
add
baa
caa
add
baa
caa
add
baa
caa
add
ccc
o66
baa
caa
add
ccc
o66
baa
caa
add
ccc
o66
baa
caa
add
daa
bec
ebb
bdd
dbb
edd
dec
abc
abd
acd bed
bec bec bec bec bec bec bec bec bec bec bec bec bec bec bee bee bee bee bee bec bec bec bec bec bee bee bee bee bee bee bec bec bec bec bec bee bee bee bee bee bee bec bec bec bec bec bee bee bee bee bee bec bec bec bec bec bec bee bee bee bee bee bec bec bec bec bec bee bee bee bee bee bee bec bec bec bec bec bec bec bec bec
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd bdd bdd
dbb dbb dbb dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb
bdd
dbb
bdd
dbb
bdd
dbb
bdd
dbb
bdd
dbb
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb
bdd bdd bdd bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb dbb dbb dbb
dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec
abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd
bdd bdd bdd bdd bdd
edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
2. CYCLES OP ALGEBRAS l3013-3013 30 i 3 aaa 18363013 aaa 1837 3013 1838 3013 aaa 1839 3013 aaa 1841 3013 1842 3013 aaa 1843 3013 1844 3013 aaa 1845 3013 1846 3013 aaa 1847 3013 1848 3013 aaa 1849 3013 1860 3O13 aaa 1861 3013 1862 3013 aaa I8533013 aaa 1855 3013 1856 3013 aaa 1857 3013 1858 3013 aaa 1859 3013 aaa 1S613013 aaa 18633O13 aaa I8653013 1866 3013 aaa 1867 3013 1868 3013 aaa 1869 3013 1870 3013 aaa 1871 3013 1872 3013 aaa 1874
3013
aaa
18763O13 aaa 3013 3013 aaa 1879 3013 1880 3013 aaa 1881 3013 aaa 1883 3013
bbb ccc bbb ccc
ddd abb ddd ddd ddd ddd
bbb
bbb ccc ccc ccc bbb ccc bbb
ddd ddd ddd ddd
bbb
bbb bbb
bbb
ccc ccc ddd ddd ddd ddd
bbb
bbb 6 6 6 ccc 666 ccc
ddd ddd
666
bbb bbb
bbb
ccc ccc
ccc bbb ccc bbb
ddd ddd
bbb
abb ddd abb abb ddd abb
bbb ccc ccc
ccc ccc ccc ccc ccc ccc
ddd ddd ddd ddd abb ddd ddd abb
ccc
ccc ccc
ccc ccc bbb ccc ccc ccc 6 6 6 ccc 666 ccc bbb
666
666 666
zaa
ddd
ddd ddd
666
bbb
bac bac bac bac
ccc
6 6 6 ccc 666 ccc
bbb bbb 666 bbb 666 666 666 bbb bbb bbb bbb
caa caa caa caa
ccc
ddd ddd ddd
bbb
bbb
bbb
baa baa baa baa
a c c
ccc ccc ddd
bbb
caa caa
. . .
666
666
aaa
3013 I8863013 aaa 1887 3013 1888 3013 aaa 1889 3013 1890 3013 aaa 1891 3013 1892 3013 aaa 1893 3013 aaa I8953013 I8963013 aaa 1897 3013 aaa 1898 3013 aaa 1899 3013 aaa 1900 3013 aaa 1901 3013 aaa 1902 3013 aaa 1903 3O13 aaa 1 9 0 4 3013 aaa aaa I9O63013 aaa 1907 3O13 aaa 1909 3013 1910 3013 aaa 1911 3013 aaa 1913 3013 1914 3013 aaa 1915 3013 1916 3013 aaa 1917 3013
caa caa
baa baa
baa baa baa baa baa baa baa baa
ddd ddd ddd ddd
1878
666
baa baa
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
ccc ccc
ccc ccc bbb ccc bbb ccc
bbb
ace caa caa caa caa caa caa caa caa caa caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa ace caa
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
ccc bbb
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
666
bbb
1877
1886
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
ccc
ddd ddd ddd ddd ddd ddd
abb abb abb abb ddd abb ddd abb ddd abb ddd abb ddd abb
zaa zaa
baa baa baa
zaa caa caa caa
baa baa baa
caa caa caa
baa
caa
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa
add add add add add add add add
caa caa caa caa acc caa acc caa
add add add add add add add add
caa
baa baa baa
caa caa caa
baa baa
caa caa
acc acc acc acc acc
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
add
acc acc
baa
baa baa baa baa baa
add daa add add add add add add add add add add add add add add add add add add add add add
caa caa caa caa caa
daa daa daa daa daa daa daa daa daa daa daa
be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be be
z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z z
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd
dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec dec
abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
bed
bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed
4329 FINITE INTEGRAL RELATION ALGEBRAS
19183013 19W3013 192«3013 l»l3013 19223013 19233013 192*3013 19253013 19263013 19273013 19283013 19293013 19303013 19313013 19323013 19333013 193*3013 19353013 19363013 3013 1937 303 19383013 19393013 1940 3 0 13 19413013 19423013 19433013 19443013 19453013 19463013 19473013 19483013 3 o 3 19513013 1952 3 013 19533013 19543013 19553013 19563013 19573013 19583013 1959'3013
1960 3 0 13 '13013 1962 3 0 13 1963 3 013 1964 3 0 13 19653013 W663013 1967 3 0 13 1968 3 oi3 19703013 19713013 1972 3 013 19733013 19743013 19753013 1976 3 oi3 19773013 1978 3 oi3 1979 3 oi3 19813013 1982 3 0 13 1983 3 013 1984 3 0 13 1985 3 0 13 W863013 1987 3 0 13 1988 3 oi3 1989 3O 13 I99O3013 19913013 1992 3 013 19933013 1994 3 0 13 19953013 19963013 19973013 19983013 19993013
ddd ddd
abb ba abb bdd
dec
Q > b b
d e c
cQ>Q>
dec
caa
d d o
abb bdd 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666
666 666 666
666 666
666 666 666 666 666
666 666
OCLCL CLCC OCLCL CLCC
caa caa
add add
dcLCL dcLCL
OCLCL CLCC odd dec dec dec bdd dec bdd dec
caa caa
aacL aad
acLCL . . . add . . . hec hec hec hec hec bec . . . bec bec . . . bec bec . . . bec hec . . . bec hec hec bec bec bec bec bec
ddd
abb
ddd ddd ...
. . . bdd bdd bdd bdd abb bdd abb baa abb baa
. . . abb abb abb abb abb abb
ddd
abb
ddd ddd
abb abb
bcLCL bcLCL . . . bcLCL CLCC bcLCL CLCC bcLCL CLCC bdd dec bdd dec bdd dec bdd dec dec ace bcLCL CLCC baa ace baa ace baa ace
. . . . . . . . . . . . add add add add add add
caa
. . . caa caa caa caa . . . caa . . . caa caa
add
add add add add add add add
baa
. . .
caa
add
- - -
ace ace
caa caa
add add
bdd . . . bdd . . . baa abb ba abb ba
ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd
caa caa caa caa caa caa caa caa caa caa
abb
•
•
abb
•
•
166 ba 266 ba 166
••
166
••
166 166 266 166
ba ba ba ba
166
••
266
••
166
••
166 166 166 166
ba ba ba ba
dec dec ace
caa caa caa
add add add add add add add add add add add add
bdd
dbb add da
. . .
. . .
. . .
. . .
0 , 0 c dbd dbc dbd abd
acd acd acd
bed bed bed
. . . CLOCabd . . . CLOC
acd
bed
. . .
ddd
abb abb
abb abb
ddd ddd ddd
d d d
ctoo aoo abb abb abb abb abb abb abb
acLa ada ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd
ddd
Q>dd Q > d d add add
ebb
. . . . . .
. . . . . .
. . . . . .
. . . . . .
. . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . .
. . . . . . CLOC . . . . . . 0,0c dbc dbc dbc dbc dbc CLbc . . . . . . CLbc CLbc . . . . . . CLbc CLbc . . . . . . 0,0c dbc . . . . . . 0,0c dbc dbc abc abc abc abc abc
bec
. . .
. . . . . .
bec hec hec hec bec bec bec
. . .
bec
- - -
bec bec
h . . . Q . . . Q
abc
. . . . . . . . .
. . . . . . . . . . . . . . . . . . . . .
. . .
. . .
. . . . . . 0,0c dbc dbc dbc . . . . . . 0,0c . . . . . . abc abc . . .
. . .
abc abc abc
be be be be be be be ba be ba be be be be be be be be ba be ba be be be be be
be be be be be be be be be be
abd dbd dbd dbd dbd dbd dbd abd
acd bed acd bed acd bed acd bed acd bed acd bed acd bed acd bed
abd
acd bed
abd bd bd bd bd bd bd abd
acd bed
abd abd abd abd abd abd abd abd abd abd abd abd
acd bed acd bed acd bad ed bed ed bed ed bed ed bed ed bed ad bad acd bad acd bed acd bed
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
bed bed bed bed bed bed bad bad bad bad bad bed bed bed bed bed bed bad bad bad bad bad bed bed bed bed bed bed
abd
acd
bed
abd abd abd abd abd abd abd abd abd abd abd
acd
bed bad bed bed bed bed bed bed bed bed bed
acd acd acd acd acd acd acd acd acd
2. CYCLES OP ALGEBRAS l 3 oi3-3013 3 oi3
2000
3013 2001 3013 20023013 2003 3O13 20043ol3 2006
3O13 20063oi3 2007 3Ol3 2008.3013 2009 3 013 2010 3 013 20H3013 20123013 20133013
20193013 2020 3 013 20213013 2022 3 013 20233013 2 24 « 3013 2026 3Ol3 20263oi3 2 27 « 3013 2 28 « 3013 20293ol3 2030.'3013 20313013 2032 3 013 2033 3 013 2034 30 13 2 «353013 2 «363013 2 «373013 2 «383013 20393ol3 204 °3Ol3 2041.3013 2042 30 13 2043 30 13 2044 30 13 2045 30 13 2046 30 13 2 47 « 3013 204830i3 2049 3O13 2060 3O13 20513013 2053 30 13 2054 30 13 2055 30 13 2056 3 oi3 2 05730i3 2068
3O13 2059 3 o i3 2 06030i3
33oi3 2064 30 13 2065 30 13 2O663013 20673oi3 2 06830i3 2 0693 O i3 2070 3O13 2
0723 O i3 2073 30 13 2074 30 13 2075 30 13 2076 3 oi3 2077 30 13 2078 3 oi3 2079 30 13 2O8O3013 2O8I3013
666 666 666 666 666 666 666 666 666 666 666 666 666
ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd
abb
ba
ebb bdd
abb
add
da
add
da
add
da
add
da
add
da
add
da
abb abb
666 666
666 666
666 666 666 666 666 666 666 666 666
ddd ddd ddd ddd ddd ddd ddd ddd
abb
add
666 666 666 666 666 666
666 666 666 666 666
acd
bed
acd acd acd acd acd acd acd
bed bed hed hed hed hed hed bed
abd
acd
bed
add
abd abd ahd ahd ahd ahd ahd abd
acd
be he he he he he
acd acd acd acd acd acd
bed bed hed hed hed hed hed bed
abd
acd
bed
acd
he he he he he he
abd ahd ahd ahd ahd ahd ahd abd
bed hed hed hed hed hed hed bed
abd
acd
bed
acd
he he he he he be
abd ahd ahd ahd ahd ahd abd abd
bed hed hed hed hed hed bed bed
da
add
166 266 166 166 166 166 166
da
ba ba ha ha ha ha ha
hee hee hee hee hee hee
166
ebb ebb ebb ebb ebb
266
166 166 166
ha ha ha
• ••
dd
• ••
dd
dd
ddd ddd
hee hee • •• hee hee • •• • •• hee - - - bee
dd
dd
666 666 666
ddd ddd ddd ddd
acd acd acd acd acd acd
166
dd
ebb ebb ebb ebb ebb ebb
666 666
666 666
hed hed hed bed bed bed bed bed hed hed hed hed hed hed bed bed bed bed bed hed hed hed hed hed bed
abd
da
666 666
666 666
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
abd abd ahd ahd ahd ahd ahd abd
be he he he he he
ddd ddd ddd ddd
ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd
ahd ahd ahd abd abd abd abd abd ahd ahd ahd ahd ahd ahd abd abd abd abd abd ahd ahd ahd ahd ahd abd
abb
666 666
666 666
dee he he he be be be be be he he he he he he be be be be be he he he he he
abb
ddd ddd
dbb edd
caa
add
caa
add
caa
add
caa
add
caa
add
caa
add
caa
add
caa
add
•• •• •• •• •• •• •• ••
• • • • • • • •
hee hee hee hee hee hee hee hee hee
ebb ebb ebb ebb ebb ebb ebb ebb ebb
he he he he he he he he he
acd acd acd acd acd acd
abd
acd
bed
abd ahd ahd ahd ahd ahd ahd ahd ahd ahd
acd
bed hed hed hed hed hed hed hed hed hed
acd acd acd acd acd acd acd acd
4329 FINITE INTEGRAL RELATION ALGEBRAS ddd abb ba 20823013 2°833013 20843013 2086 3O13 20863013 2087 3O13 20883013 20893013 2»903013 20913013
20953013 2096 3 0 1 3 2098 3 0 1 3 2099 3 0 i 3 21013013 21023013 21033013 2104 30 13 21053013 2106 3 o i 3 2107-JO13 2IO83013 2109 3 oi3 21103O13 21113013 2 3013 2H33013 2H43013 2H53013 2H63013 2H73013 21183013 2H93013 21203013 3013 2121 21223013 !3 3013 21243013 !5 3013 21263013 21273013 21283013 21293013 21303013 21313013 21323013 21333013 2134 30 13 21353013 l6 3013 21373013 2138! 3013 21393013 21«3013 2141 3013 21123013 21 4 3 3013 21«3013 214530i3 21463013 21473013 2148 3 0 13 21*93013 21503O13 21513013 21523013 21533013 21543013 21553013 21563013 2157 3 013 '83013 21593013 '03013 21613013 i2 3013 21633Q13
666 666 666 666 666 666 666 666
666 666 666
666 666
666 666 666 666 666 666 666 666
666 666 666 666 666
ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd
166 ba 166 ba 66 ba 66 ba
dd dd dd dd dd dd dd dd
66 66 66
66 ba 66 ba 66 ba
166 166 166 166 166 166 166 166 [66 166
ba ba ba ba ba ba ba ba ba ba
dan i be : be 3 be = be = be : be = be : be = dac i be : dac . be = dac i be = dac . be = dac i be = dac . be = dac i be = dac i be : dac i be = dac i be : dac i be = dac i be : dac . be = dac i be = dac . be = dac i be = dac . be = dac i be z
abd acd bed abd acd bed be be be be be be
abd abd abd abd abd abd
abd acd bed abd acd bed abd acd bed be be be be be be
abd abd abd abd abd abd
bed bed bed bed bed bed
abd acd bed
[66
bee bee bee bee bee bee
(66
66
66 66 66 166
ba ba ba ba
abd acd bed be be be be be be
abd abd abd abd abd abd
acd acd acd acd acd
bed bed bed bed bed bed
abd acd bed abd acd bed
ddd ddd
bee bee bee bee bee bee
ddd ddd ddd ddd
abb
ba
abb
ba
abb
ba
ddd ddd ddd ddd ddd ddd
abb
ba
abb
add
abb
add
abb
add
bee bee bee bee bee bee
add add abb
add add
cc ddd abb ddd ddd dd
•• •
b
dd
•• •
b
dd
•• •
b
dd
•• •
b
abb
dd
•• •
b
abb
dd
•• •
b
abb
dd
•• •
b
abb
dd
•• •
b
dd
•• •
b
ddd ddd ddd ddd
abd acd bed
ebb ebb ebb ebb ebb ebb ebb ebb
666 666 666 666
666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666 666
abd acd bed
abd acd bed
666 666
666 666
ebb bdd dbb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
be be be be be be be be be be be be be be be be be be be be be be be be be be
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed
abd acd bed abd acd bed abd acd bed be be be be be be be be be be
abd abd abd abd abd abd abd abd abd abd
acd acd acd acd acd acd acd acd acd
bed bed bed bed bed bed bed bed bed bed
2. CYCLES OF ALGEBRAS l 3 oi3-3013 3 oi3
2164
3013 2165 3 0 1 3 2166 3013 21 7 6 3013 2168 301 3 21693013 2170 3013 2171 3013 2172 3013 2173 3013 7 21 4 3 013 2175 3013 2176 3013 2177 3013 217 8 3 013 2179 3013 21 80 3 0 13 2181 3013 2182 3013 2133 3 0 1 3 2184 3 0 1 3 2185 3013 2186 3 0 1 3 2187 3013 21 8830l3 2 189 3 013 21 903013 2191 S01S 2192 3013 2193 3013 2194 3 0 1 3 2195 3013 2196 3 0 1 3 2197 3013 2198 3 0 1 3 2199 3013 22 00 3 0 13 2201 3013 22 2 0 3013 2203 3013 22 4 0 3013 22 05 3 0 13 2206 3013 22 7 0 3013 2208 3 0 1 3 2209 3 0 1 3 2210 3013 2211 3013 2212 3013 221 3 3 013 2214 3013 2215 3013 22 16 3 0 13 2217 3013 22 133013 2219 3013 222 0 3 013 2221 3013 2222 3013 2223 3013 2224 3013 2225 3013 2226 3 0 1 3 2227 3013 2228 3013 2229 3013 2230 3013 22 31 3 013 2232 3013 22 33 3 013 2234 3013 22 35 3 013 2236 3013 2237 3013 22 33 3 013 2239 3013 2240 3 0 1 3 2241 3013 2242 3013 2243 3013 2244 3 0 1 3 22453nl3
aaa aaa aaa aaa
aaa
bbb c :c ddd abb bbb bbb c -.c bbb c ddd ddd
bbb bbb bbb
c zc ddd bbb c zc ddd bbb
aaa aaa aaa aaa
bbb bbb bbb bbb bbb bbb bbb
aaa
aaa
bbb
aaa
bbb
bbb
aaa
aaa aaa aaa
bbb bbb
c c -.c c -.c c zc c zc c zc c zc c zc c -.c c -.c c -.c c -.c
ddd ddd
bbb
aaa
aaa
bbb
aaa
bbb bbb
c zc c zc
bbb
aaa aaa
aaa aaa
aaa
ddd ddd ddd
abb abb abb abb abb abb abb abb
ddd
c zc ddd bbb c -.c ddd ddd ddd bbb ddd bbb ddd c zc ddd c zc ddd bbb c zc ddd bbb c zc ddd
aaa
- -
aaa
bbb
-
c
aaa
aaa
ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd
abb abb abb abb abb abb abb abb abb abb
bbb c c
aaa
aaa
bbb c
aaa
bbb
abb abb abb abb abb abb abb abb abb abb abb -.c abb -.c ddd abb -.c ddd abb
bbb bbb
aaa aaa
c
zc
bbb c zc bbb c zc ddd bbb c zc ddd
aaa
aaa
bbb bbb c
aaa bbb
aaa aaa
aaa aaa
aaa aaa
aaa aaa
aaa aaa
aaa aaa
aaa aaa
aaa aaa aaa
c c
-.c zc
bbb c zc c zc c zc bbb c zc bbb c -.c c
ddd ddd ddd ddd
-.c
bbb c -.c c -.c ddd bbb c -.c ddd c zc c
zc
bbb c zc c zc ddd c zc ddd bbb c zc ddd c
bbb c -.c c -.c bbb c -.c bbb c bbb c -.c bbb c -.c bbb c -.c c
ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
ddd ddd abb
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa
add daa add add add add add add add add add add add add add add add
a a a a
baa
a a
baa
a a
baa
a a
baa
a a
baa
a a
baa
baa baa baa baa baa baa baa baa baa baa baa baa
aa
ace ace
a a
ace
a a
ace
a a
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
baa baa baa baa baa baa ace ace ace ace
baa baa baa baa baa
ace ace ace ace ace
a a
a a a a a a a a
aa a a a a a a a a a a a a a a
aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa
add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee bee
ebb
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd dbb edd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
dec abc abc
abc. abc abc abc abc abc abc
abc. abc. abc. abc. abc. abc. abc abc abc abc abc
abc. abc. abc. abc. abc. abc abc abc abc abc abc
abc. abc. abc. abc. abc. abc abc abc abc abc abc
abc. abc. abc. abc. abc. abc abc abc abc abc
abc. abc. abc. abc. abc. abc. abc abc abc abc abc
abc. abc. abc. abc. abc. abc abc abc abc abc abc
abc. abc. abc. abc. abc. abc. abc. abc. abc.
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed
4329 FINITE INTEGRAL RELATION ALGEBRAS aaa 2246
3013 2247 3 0 1 3 2248 3 0 1 3 2249 3 0 1 3 2250 3O13 22513013 2252 3O i3 2253 3O i3 2254 3 0 1 3 2255 3 0 1 3 2256 3 0 1 3 2257 3 0 1 3 2258 3 0 1 3 2259 3 0 1 3 2260 3O i3 22613013 2262 3 0 1 3 2263 3O i3 2264 3 0 1 3 2265 3 0 1 3 2266 3 0 1 3 2267 3 0 1 3 2268 3 0 1 3 2269 3 0 1 3 2270 3 O 1 3 22713013 2272 3 0 1 3 22733013 2274 3 0 1 3 2275 3 0 1 3 2276 3 0 1 3 2277 3 0 1 3 2278 3 0 1 3 2279 3 0 1 3 2280 3 0 1 3 2281 3 oi3 2282 3 0 1 3 22833013 2284 3 0 1 3 2285 3 0 1 3 2286 3 O i 3 2287 3 0 1 3 2288 3 0 1 3 2289 3 0 1 3 2290 3 0 1 3 2291 30 13 2292 3 0 1 3 22933013 2294 3 0 1 3 2295 3 0 1 3 2296 3 0 1 3 2297 3 0 1 3 2298 3 0 1 3 2299 3 0 1 3 2300 3 0 1 3 2301 30 13 2302 3 0 1 3 2303 3 O 1 3 2304 3 O 1 3 2305 3 O 1 3 2306 3 O i 3 2307 3 O 1 3 2308 3 0 1 3 2309 3 0 1 3 2310 30 13 23113013 2312 3 oi3 2313 3 oi3 23143013 23153013 23163013 2317 30 13 23183013 2319 30 13 2320 3 0 1 3 2321 30 13 2322 3 0 1 3 23233013 2324 3 0 1 3 2325 3 0 1 3 2326 3 0 1 3 23273nl3
bbb zee
aaa
aaa aaa
666
zee
bbb
zee
zee zee zee bbb zee bbb
aaa aaa
ddd ddd ddd ddd
zee zee
aaa
bbb
aaa
zee bbb zee
aaa
ddd abb
zee
ddd ddd
aaa
aaa
bbb zee zee
aaa bbb
zee
aaa
bbb
zee
aaa
zee zee bbb zee
aaa aaa
ddd ddd ddd
zee zee
aaa
bbb
aaa
zee ddd bbb zee ddd bbb zee ddd bbb zee ddd
aaa aaa
zee aaa
aaa aaa
aaa
zee bbb
zee
bbb
zee
zee zee 6 6 6 zee bbb zee
aaa
ddd ddd ddd ddd
zee zee
aaa
bbb
aaa
zee ddd bbb zee ddd
aaa aaa
bbb
aaa
bbb zee ddd bbb zee ddd
aaa bbb
bbb
aaa bbb
aaa
bbb
zee zee zee zee
ddd ddd ddd ddd
aaa 666
aaa aaa
aaa
bbb zee zee bbb zee bbb zee
aaa
abb abb abb abb abb abb abb abb abb abb abb abb
ddd ddd
bbb
aaa
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
ddd ddd ddd ddd
zee zee
aaa
bbb
aaa
aaa
zee ddd bbb zee ddd
aaa
bbb
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
bbb bbb
zee zee
aaa
bbb
aaa
bbb
aaa
zee ddd bbb zee ddd
ddd ddd
bbb bbb
aaa 666
aaa
bbb
aaa 666
aaa
bbb
aaa 666
zee zee zee zee
abb abb abb abb abb abb abb abb ddd abb ddd abb ddd abb
baa baa baa baa baa baa baa baa
a cc a cc a cc a cc a cc a cc a cc a cc
aaa caa caa caa caa caa caa caa
add daa add add add add add add add
a
a
cc
a a cc a a cc a cc a a cc a a cc a a cc a
baa baa baa baa baa baa baa baa baa baa
caa caa caa caa
baa baa baa baa baa baa baa baa baa baa
caa caa caa caa caa caa caa caa caa a
cc
caa caa
a
cc
caa
a
cc
caa
a
cc
caa
a cc
caa caa
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a
cc
a
cc
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa add add
cc - - - add
a
cc a cc a cc a cc a cc a cc a
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
caa
add add add add add add
a cc - - - add add a cc a cc - - - add add a cc a cc - - - add add a cc add a cc add a cc add a cc add a cc add a cc add a cc add a cc add a cc
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
bec
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd dbb edd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
dec abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed
2. CYCLES OP ALGEBRAS l 3 oi3-3013 3 oi3
2328
3013 2329 3 0 1 3 2330 3013 23313013 2332 3013 2333 3O i3 2334 3013 23353013 2336 3013 2337 3013 2338 3013 2339 3013 2340 3013 2341 3013 2342 3013 2343 3013 2344 3013 234 5 3 013 2346 3013 2347 3013 2348 3013 2349 3013 2350 3013 23 51 3 013 2352 3013 2353 3O i3 2354 3O i3 2355 3 oi3 23563013 2357 3013 2358 3013 2359 3013 2360 3013 2361 3013 2362 3013 2363 3O i3 2364 3O i3 2365 3O i3 2366 3O i3 2367 3013 23683013 2369 3013 2370 3013 237 l3013 2372 3013 2373 3013 2374 3013 2375 3013 2376 3013 2377 3013 2378 3013 2379 3013 2380 3013 2381 3013 2382 3013 2383 3013 2384 3013 2385 3013 2386 3O i3 2387 3013 2388 3O i3 2389 3013 2390 3013 239 l3013 2392 3013 2393 3013 2394 3013 2395 3013 2396 3013 2397 3013 2398 3013 23 "3013 24 00 3 O 13 2401 3013 2402 3 0 1 3 2403 3013 2404 3 0 1 3 2405 3013 2406 3 0 1 3 2407 3013 2408 3 0 1 3 2409 3ni3
aaa aaa aaa
aaa
bbb ccc bbb ccc ccc bbb ccc bbb ccc
aaa
bbb
aaa
ccc bbb ccc ccc
aaa
bbb
ccc
aaa
ccc bbb ccc 666
aaa
bbb
ccc
bbb
ccc
ccc ccc bbb ccc bbb ccc
aaa
bbb
aaa
ccc bbb ccc
abb abb abb abb abb abb abb abb abb
ddd ddd
ddd ddd ddd ddd
ccc
aaa aaa
ddd ddd
ccc ccc
aaa
aaa
ddd ddd ddd ddd
ccc
666
aaa
ddd
ccc
aaa aaa
ddd abb
ccc
ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb
bbb
aaa
bbb bbb
ccc
aaa
bbb
ccc
aaa
bbb
aaa
ccc bbb ccc
bbb
ddd ddd
666
ddd ddd
aaa bbb
aaa
bbb ccc ccc
aaa
aaa
bbb
ccc
bbb
ccc
ddd aaa
ddd ddd ddd
bbb
aaa aaa
bbb ccc ccc ccc bbb ccc bbb
aaa
ddd ddd ddd ddd
aaa
aaa
bbb ccc
aaa
aaa
bbb
ccc
aaa
ddd
aaa
bbb
aaa
ccc bbb ccc
aaa
ddd
ddd ddd
aaa
aaa
bbb ccc
aaa
aaa
ccc
bbb
ccc
ddd ddd
aaa
aaa
bbb
aaa
ccc ccc bbb ccc
aaa aaa
ddd
ccc
aaa
bbb
aaa
ccc bbb ccc 6 6 6 ccc bbb ccc
aaa aaa
ccc
ccc aaa
aaa
ddd ddd ddd
ccc 666
ccc
bbb
ccc
aaa 666
ccc ccc ccc
ddd ddd ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
abb abb abb abb ddd abb ddd abb ddd abb
baa baa baa baa baa baa
a cc caa add dac 1 bcc ebb add dac ebb a cc add daa ebb a cc dac cc add ebb a add dac ebb a cc ebb a cc - - - add dac dac dac dac
caa
add
caa caa caa
add add add
baa baa baa baa baa baa
caa caa caa
add add add
dac
caa caa caa
add add add
daa
baa
caa caa caa
add add add
caa caa caa
add add add
baa baa baa baa baa
cc a cc a cc cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc cc cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a cc a
a
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa a a
baa baa baa baa baa baa baa baa baa baa baa baa
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa
daa daa
dac dac dac dac dac dac dac daa
dac
add daa add dac add daa add dac add dac add dac add dac add dac add dac add dac add dac add dac add dac add dac add dac add dac add dac add dac add dac add dac add dac add dac add dac add dac add dac add dac add dac add dac add add add add add add add add add add add add add add add add add add add add
c a a
dac
c a a
dac
c a a
dac
c a a
dac
baa
c a a
dac
baa
c a a
daa
baa
c a a
dac
baa
c a a
daa
baa
c a a
dac
baa
c a a
daa
baa
c a a
dac
baa
c a a
daa
baa
c a a
dac
bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc
1 1 1 1 1 1 1 1 1
bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd dbb edd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
dec aba abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed
4329 FINITE INTEGRAL RELATION ALGEBRAS
2410 3 0 1 3 2411 3 oi3 2412 3013 241 33013 2414 3 0 1 3 2415 3 0 1 3 2416 3013 2418 3 0 1 3 2419 3 0 1 3 2420 3 0 1 3 2421 3013 2422 3 0 1 3 2423 3013 2424 3 0 1 3 2425 3O i3 2426 3 0 1 3 2427 3013 2428 3 0 1 3 2 2 4 9 3 0 13 2430 3 0 1 3 2 431 3 0 13 24 323013 2 4333013 2434 3 0 1 3 2435 3O i3 2436 3O i3 24373013 24383013 2439 3O i3 2440 3 0 1 3 2441 3013 2442 3013 2443 3013 2444 3013 2445 3O i3 2446 3O i3 2447 3 0 1 3 2448 3O i3 244 9 3 013 2 4 50 3 O i3 2451 3013 2452 3013 2453 3013 2454 3013 2455 3013 2456 3O i3 2 4 57 3 0 l3 2 4 58 3 O i3 2 44 59 3 O i3 2 60 3 O i3 2461 3013 2462 3013 2463 3013 24643Q13 2465 3013 2466 3013 2467 3 0 1 3 2468 3O i3 2 4 69 3 O i3 2 4 70 3 O i3 247 l3013 2472 3013 2473 3013 2474 3013 2475 3013 2476 3O i3 2 4 77 3 0 l3 24 78 3 O 13 2 4 79goi3 2 4 80 3 O i3 2 4 81 3 013 24 82 3 O 13 24833013 2484 3013 2485 3013 2486 3013 2487 3 0 1 3 2488 3013 2489 3O i3 2490 3013 24 9l3013
aaa aaa
bbb ccc bbb ccc
ddd abb ddd abb
aaa
aaa
bbb
aaa
aaa
bbb
ccc ccc
aaa
ddd ddd
aaa
bbb
aaa
bbb ccc 666
ddd
aaa
bbb
ddd
aaa
6 6 6 ccc bbb ccc
bbb
bbb
aaa bbb
aaa
bbb
ccc ccc ccc ccc ddd ddd
aaa
ddd ddd
bbb
aaa aaa
aaa
bbb ccc ccc bbb ccc bbb ccc
ddd ddd ddd ddd
aaa
aaa
bbb
aaa
aaa
bbb
ccc ccc ddd
aaa
aaa
bbb
aaa
ccc bbb ccc
aaa
ddd
ddd ddd
aaa
aaa
bbb
aaa 666
ccc ccc ccc ccc
aaa
bbb
aaa
ccc ccc bbb ccc
aaa aaa
bbb
aaa
aaa
ccc bbb ccc
aaa
bbb
aaa
ccc bbb ccc
666
bbb
ccc ccc
aaa
bbb
ccc
aaa
aaa
ccc ccc bbb ccc bbb ccc
ddd ddd
aaa
bbb
ddd ddd ddd ddd
ddd ddd
aaa
bbb
aaa
ccc bbb ccc
aaa
ddd ddd
ccc ccc
aaa
bbb
aaa
bbb
aaa
ccc bbb ccc
666 666
aaa 666
ddd ddd
ddd ddd abb abb abb
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa add add add add add add add add add add add add add
ace ace ace ace ace ace ace ace ace ace
baa baa baa baa baa baa baa baa ace ace ace ace ace ace ace ace
baa baa baa baa baa baa baa baa baa baa baa
ace ace ace ace ace ace ace ace ace ace ace
daa daa daa daa daa daa daa
caa
ace
baa baa baa baa baa baa baa baa baa baa
add daa
caa caa caa caa
ace ace ace ace ace ace ace
baa
bbb 666
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
baa
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
bbb
aaa
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
baa
ccc ccc
aaa
ace
baa
bbb
aaa
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
ddd ddd
aaa
aaa
ace ace ace ace ace ace
abb abb
ccc ccc
666
aaa
ddd ddd ddd
ccc ccc
aaa
abb abb abb abb abb
ddd ddd
ace caa
baa
ddd abb
aaa
aaa
baa
add add add add add
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa
add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
bdd dbb edd bdd bdd bdd bdd bdd bdd bec ebb bdd bec ebb hdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bee ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bee ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bee ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bee ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bee ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bee ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bec ebb bdd bee bec bec bec bee bec bec
ebb ebb ebb ebb ebb ebb ebb
dec abc abc abc abc abc abc abc
abd abd abd abd abd abd abd
acd acd acd acd acd acd acd
bed bed bed bed bed bed bed
abc
abd abd acd
bed bed
abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
2. CYCLES OF ALGEBRAS l 3 oi3-3013 3 oi3
2492 3O i3 2493 3O i3 2494 3O i3 2495 3 0 1 3 2496 3 0 1 3 2497 3 0 1 3 2498 3 0 1 3 2499 30 13 2500 3 0 i3 2501 3013 25O23Oi3 25033013 25O43Oi3 25O53Oi3 2506 3 0 1 3 2507 3 0 1 3 2508 3 0 1 3 2509 3 0 1 3 2510 3 0 1 3 2511 3 oi3 25123013 2513 3O i3 25143013 2515 3O i3 2516 3 0 1 3 2 517 3 013 2518 3 oi3 25193013 2520 3 0 1 3 2521 3 oi3 2522 3O i3 2523 3 oi3 2524 3O i3 2525 3 oi3 2526 3O i3 25273o 13 2528 301 3 2529 3 0 1 3 2530 3 0 1 3 25313013 2532 301 3 2533 3O i3 2534 3 oi3 2535 3O i3 2536 3 oi3 2537 3O i3 2538 3 0 1 3 2539 3 0 1 3 2540 3 0 1 3 25413013 2542 3 0 1 3 25433Qi3 2544 3O i3 25453Qi3 2546 3 oi3 25473Qi3 2548 3O i3 2549 3 0 1 3 2550 3 0 1 3 2551 301 3 2552 3 0 1 3 2553 301 3 2554 3 oi3 2555 3 oi3 2556 3 oi3 2557 3O i3 2558 3O i3 2559 3 0 1 3 2560 3 0 1 3 25613013 2562 301 3 2563 301 3 2564 301 3
aaa aaa
bbb ccc bbb
aaa bbb
aaa
bbb
ccc ccc ccc ccc ddd ddd ddd ddd
aaa bbb
aaa
bbb
aaa
aaa aaa
aaa
bbb bbb
bbb
aaa
aaa
bbb
aaa
aaa aaa aaa
bbb bbb bbb bbb bbb
ccc ccc ccc ccc ccc ccc ccc ccc ccc ccc ccc
ddd
ccc ccc
bbb
aaa
ccc ccc ccc bbb ccc ccc bbb ccc
aaa
bbb
bbb
aaa aaa
ddd ddd ddd ddd ddd ddd
bbb
aaa
ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
ddd
aaa
aaa
ddd abb
ddd ddd ddd ddd ddd ddd
abb abb abb abb abb abb abb abb abb abb
bbb bbb
ccc ccc
aaa
bbb
aaa
bbb ccc bbb ccc
ddd ddd
aaa
aaa
bbb bbb ccc
aaa bbb
aaa aaa
aaa
bbb
ccc ccc ccc
ccc ccc bbb ccc bbb ccc
ddd
aaa
aaa aaa
aaa
bbb
ddd
ccc bbb ccc
aaa
bbb
aaa
ccc ccc bbb ccc
aaa
ddd ddd ddd ddd ddd
aaa
bbb
aaa
ccc bbb ccc
aaa
ddd ddd ddd ddd ddd
aaa
aaa
ddd ddd ddd ddd
ddd ddd
aaa
aaa
bbb
aaa bbb
aaa
25653QI3
25663013
aaa
25673QI3
aaa
2568 3O i3 aaa 2569 3O i3 aaa 257O3Oi3 aaa 25713013 aaa 2572 3O i3 25733013 aaa
bbb
ccc ccc ccc ccc
ccc ccc bbb ccc bbb ccc bbb ccc bbb
bbb
ddd ddd ddd ddd ddd
ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
baa baa baa baa baa baa baa baa baa baa baa baa baa baa
ace ace ace ace ace ace ace ace ace ace ace ace ace ace
caa caa caa caa caa caa caa caa caa caa caa caa caa caa
add add add add add add add add add add add add add add
caa caa baa baa baa
baa baa baa baa baa baa baa baa baa baa baa baa
caa caa caa ace ace
caa
ace ace ace ace ace ace ace ace ace ace ace ace
caa
ace ace
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
caa caa caa caa caa caa caa caa caa caa caa caa
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa
add add add add add add add add add add add add add add add add add add add add
caa
ace caa ace
caa
ace caa
baa baa baa baa baa baa
baa baa baa baa baa baa baa baa baa baa
baa baa
ace ace ace ace ace ace
caa caa caa caa caa caa
caa caa caa caa caa caa caa caa caa caa caa caa caa caa ace caa ace caa ace caa ace caa ace caa ace caa
add add add add add add add add add add add add add add add add add add add add
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
bec bec bec bec bec bec bec bec bee bec bec bec bec bec
bec bec bec bec bec bee bee bee bee bee bec bec bec bec bec bee bee bee bee bee bee bec bec bec bec bec bec bec bec bec
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
dbb edd
dec abc abc
abc. abc abc abc abc abc abc
abc. abc
abc. abc
abc. dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
abc abc abc abc abc abc
abc. abc
abc. abc
abc. abc abc abc abc abc abc
abc. abc
abc. abc
abc. abc abc abc abc abc abc
abc. abc
abc. abc
abc. abc abc abc abc abc
abc. abc. abc
abc. abc
abc. abc abc abc abc abc
abc. abc. abc
abc. abc abc abc abc abc abc abc
abc. abc. abc
abc. abc
abc. abc
abc. abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS aaa aaa
bbb ccc ddd 6 6 6 ccc bbb ccc
aaa
bbb
aaa
bbb
2574
3013 3013 2576 3013 25^3013 2578 3013 2579 3 0 1 3 2580 3O i3 258I3013 2582 3013 2583 3013 2584 3013 2585 3013 2586 3013 2587 3013 25883013 2589 3 0 1 3 2590 3 O 1 3 25913013 2592 3 0 1 3 2593 3013 2594 3013 2595 3013 2596 3013 2597 3013 2598 3 0 1 3 2599 3 0 1 3 2600 3 O i 3 2601 3 O i 3 2602 3 O 1 3 2575
26033QI3 2604
666
bbb
ccc ccc
ddd ddd ddd ddd
aaa bbb
aaa
bbb
aaa bbb
aaa
bbb
ccc ccc ccc ccc
bbb
ddd ddd ddd ddd
ccc ccc ccc bbb ccc
ddd ddd ddd ddd
aaa bbb
aaa aaa
666
aaa aaa
aaa
bbb ccc
aaa
aaa aaa
aaa aaa
3013 aaa 2605 3013 2606 3013 aaa 2607 3013 aaa 2608 3013 2609 3 O i 3 aaa 2610 3 O i 3 aaa 2611 3013 aaa 2612 3013 aaa 2613 3013 aaa 261*3013 aaa 2615 3013 aaa 2616 3013 aaa 2617 3013 aaa 2618 3013 aaa 2619 3013 aaa 2620 3 O i 3 aaa 262 l oi3 262 3 2 3 0 1 3 aaa 262 33Oi3 2624 3 0 1 3 aaa 2625 3013 2626 3013 aaa 2627 3013 aaa 2628 3013 2629 3013 aaa 2630 3013 aaa 2631 3013 2632 3013 aaa 2633 3 O i 3 2634 3 0 1 3 aaa 2635 3 O i 3 2636 3013 aaa 2637 3013 2638 3013 aaa 2639 3013 2640 3013 aaa 26413013 2642 3 0 1 3 aaa 2643 3 O i 3 2644 3 0 1 3 aaa 2645 3 O i 3 26*63013 aaa 2647 3013 2648 3013 aaa 2649 3013 aaa 2650 3013 aaa 2651 3013 2652 3013 aaa 2653 3013 2654 3013 aaa 2655 3ni3
bbb ccc ccc ddd bbb ccc ddd
abb baa baa baa baa baa baa baa abb baa abb baa a66 bac ^ a66 bac 1 a 6 6 bac 1 a 6 6 bac 1 a 6 6 bac 1 a 6 6 bac 1 abb baa abb baa abb baa abb baa abb baa abb baa abb baa abb baa a66 a66 abb abb
ace ace ace ace ace ace ace ace ace ac ac ac ac ac ac ace ace ace ace ace ac ac ac ac ac ace ace ace ace
caa caa caa caa caa caa caa caa caa zaa zaa zaa zaa zaa caa caa caa caa caa zaa zaa zaa zaa zaa caa caa
caa abb caa abb abb baa ace caa abb baa ace caa a66 baa ace caa bbb ccc a 6 6 baa ace caa ccc a 6 6 baa ace caa a 6 6 baa ace caa bbb ccc ccc ddd abb baa ace caa ccc ddd abb baa ace caa bbb ccc ddd abb baa ace caa ace abb bbb ace abb bbb ccc ace ddd abb bbb ac c bbb ccc ddd abb bbb a66 baa ac c ccc a 6 6 bbb baa ac c ddd abb baa ac c bbb bbb ccc ddd abb baa ac c a66 bbb ccc caa bbb ccc ddd abb caa bbb
ccc
bbb ccc bbb ccc ddd bbb ccc ddd
abb baa abb baa abb baa abb baa
666
bbb bbb ccc bbb
d d d
bbb bbb ccc
d d d
ddd
abb abb
bbb
bbb bbb
bbb
ccc ccc ddd ddd
bbb
bbb
bbb ccc ddd bbb ccc ddd bbb
bbb
abb abb a66 a66
ddd ddd
abb abb abb abb
ccc ddd bbb ccc ddd
abb abb
bbb
bbb
ccc ccc
abb abb abb abb
bbb
bbb bbb
666
bbb bbb ccc bbb ccc ddd a66 a66
666
bbb 666
bbb 666
ccc ccc ddd
a66 a66 abb
baa baa baa baa baa baa baa baa baa baa baa baa baa baa .. .
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
baa baa baa baa baa baa baa baa baa
ace ace ace ace ace ace ace ace ace
add add add add add add add add add add add add add add add add add add add add add add add add add add add add add
add add add add add add add add add
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
add add add add add add add add
add add
caa caa caa caa
add add add add
caa caa caa caa caa caa caa caa caa caa caa caa caa caa
add add add add add add add add add add add add add add daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
edd
edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd
dec abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed
2. CYCLES OP ALGEBRAS l 3 oi3-3013 3 oi3
2656
3013 2657 3 0 1 3 2658 3013 2659 3 0 1 3 2660 3O i3 2661 3O i3 2662 3 0 1 3 26633013 2664 3013 2665 3013 2666 3013 2667 3013 2668 3 0 1 3 2669 3013 267 °3013 2671 3013 26 72 3013 2673 3013 2674 3013 2675 3013 2676 3013 2 77 6 3013 2678 3 0 1 3 2 79 2 6 3013 680 3 O 1 3 268I3013 2682 3013 2683 3O i3 2 6843013 26853013 2686 3 0 1 3 2687 3013 2688 3 0 1 3 2689 3013 2690 3013 2 69!3013 2 69 2 3013 2693 3013 2694 3O i3 2 9 6 53013 2 9 6 63013 2 97 6 3013 2698 3013 2699 3013 2700 3013 27 °l 013 2702 3 3O13 2703 3O13 2704 3O13 2705 3O13 2706 3O i3 2707 3013 2708 3013 2709 3013 2710 3013 2711 3013 27 2 1 3O13 2713 3013 2714 3013 2715 3013 271 63013 2717 3013 2718 3013 2719 3013 2720 3013 272 l3013 2722 3013 2723 3013 2724 3013 272 5 3 013 2726 3013 2727 3013 2728 3013 2729 3013 27 30 3 013 2731 3013 2732 3013 2733 3013 27 34 3 0 13 2735 3013 27 36 3 013 2737 3013
aaa aaa aaa
bbb ccc bbb bbb ccc bbb ccc
aaa bbb
aaa aaa
aaa
bbb
ddd abb ddd
ddd ddd
ccc ccc ccc ccc
ccc ccc 6 6 6 ccc bbb ccc
ddd ddd ddd ddd
aaa 666
aaa
bbb ccc ccc
aaa
aaa
bbb
ccc
bbb
ccc ddd ddd
aaa bbb
aaa aaa
aaa
ddd ddd
bbb ccc ccc bbb ccc bbb ccc
ddd ddd ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
bbb
aaa
bbb
aaa
bbb
bbb
ccc ccc ddd ddd
666
aaa
bbb
aaa
ccc bbb ccc 666
ddd ddd
aaa bbb
aaa
bbb
aaa bbb
aaa
bbb
ccc ccc ccc ccc ddd ddd
aaa
ddd ddd
666
aaa aaa
aaa
bbb ccc ccc bbb ccc bbb ccc
ddd ddd ddd ddd
666
aaa
bbb
aaa
bbb
666
ccc ccc ddd ddd
666
aaa
bbb
aaa
ccc bbb ccc bbb
aaa bbb
aaa aaa
aaa
bbb
aaa aaa
bbb
aaa
bbb
aaa aaa
bbb
aaa
bbb
ace caa ace ace ace
baa baa baa baa baa baa baa baa
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
caa caa caa caa caa caa caa ace ace ace ace
caa
ace
caa
ace
caa
ace
caa
ace
caa
ace
caa
ace
caa
ace
caa
ace
caa
ace ace
caa caa
ace
caa
ace
caa
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
caa
baa
ddd
ddd ddd ddd ddd
baa
abb abb abb abb abb abb abb abb abb abb abb abb
add daa
caa
baa
ccc ccc ccc ccc
ccc ccc ccc bbb ccc bbb
ddd ddd ddd ddd
ccc ccc
bbb bbb ccc
aaa
aaa
ccc ccc ccc ccc
ccc ccc 6 6 6 ccc bbb ccc bbb
ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
baa baa baa baa
baa baa baa baa baa baa baa baa ace ace ace ace
caa caa caa
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa add add add add add add add add
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa
add add add add add add add add add add add add add add add add add add add add add add add
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec
ebb bdd dbb edd
bdd
edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd
bdd
edd
bdd
edd
bdd
edd
bdd
edd
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
bdd
edd
bdd
edd
bdd
edd
bdd
edd
bdd bdd
edd edd
bdd
edd
bdd
edd
bdd
edd
bdd
edd
bdd
edd
bdd
edd
bdd
edd
bdd
edd
bdd
edd
bdd
edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
dec abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS aaa bbb ccc ddd 2738
3013 3013 2740 3013 2739
2742
3013
274
33013 27443013
aaa
ccc 666
aaa bbb
ccc ddd ddd ddd ddd
aaa bbb
aaa bbb 2746
3013 2747 3 0 1 3 2748 3013 2749 3013 2750 3013 2751 3013 27 52 3 013 2753 3013 27543013 2755 3013 27563QI3
ccc ccc ccc aaa bbb ccc aaa
666
bbb
aaa bbb bbb
aaa bbb
ccc ccc
bbb
ddd ddd
aaa bbb
ccc ddd aaa bbb ccc ddd bbb
27583Q13 2759-JQI o
2760
3013
2761 3013 2762
3013
aaa 666
aaa bbb aaa
bbb 2764 3 0 1 3 2765 3013 aaa bbb 2766 3013
ccc ccc ccc ccc
aaa
2768OQI o
bbb
27693Q13
aaa bbb
2770 2771
3013 3013
2772 3013 2773
3013 3013 2775 3013
aaa aaa
bbb bbb
ccc ccc ccc ccc
2774
aaa
aaa bbb 2777 3013 aaa bbb
ccc
2779
3013 aaa 2780 3013 aaa bbb 2781 3013 aaa bbb ccc 2782 3013 2783 3013 aaa bbb
2785 3 ni 3 aaa bbb bbb ccc
27863QI3
3013 aaa bbb ccc 2788 3013 2789 3013 aaa 2790 bbb 3013 aaa bbb 2792 bbb ccc 3013 aaa bbb ccc 2787
2794-JQI o
2795
3013
2797
3013 aaa bbb
aaa bbb
2799
3013 aaa 666 2800 3 0 1 3 2 8 0 1 3 0 1 3 aaa bbb 2802 3013 2803 3013 aaa 666 2804 3 0 1 3 2 8 0 5 3 O 1 3 aaa bbb 2807
3O13
ddd ddd ddd ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb
aaa
ccc ccc ccc ccc
ccc ccc bbb ccc bbb ccc
2809 3 ni 3 aaa 2 810 3O 13 2811 3013 aaa 2812 bbb 3013 2813 3013 aaa bbb 2814 bbb 3013 2815 3013 aaa bbb 2816 3013 2817 3013 aaa bbb 2818 3 0 1 3 28 9 1 3O13 aaa bbb
ccc ccc
abb abb abb abb abb abb abb abb ddd abb ddd abb ddd abb ddd abb ddd abb ddd abb ddd abb ddd abb abb abb abb abb ddd abb ddd abb ddd abb ddd abb abb abb abb abb abb abb ddd abb ddd abb ddd abb ddd abb ddd abb ddd abb abb abb abb abb abb abb abb abb ddd abb ddd abb ddd abb ddd abb ddd abb ddd abb ddd abb ddd abb abb abb abb abb abb abb dddabb dddabb dddabb dddabb
i ace ace ace ace ace ace ace ace ace ace ace ace ace baa ace bac i ace bac i ace bac i ace bac i ace bac i ace bac i ace baa ace bac i ace baa ace bac i ace baa ace bac i ace bac i ace bac i ace bac i ace bac i ace bac i ace baa ace bac i ace baa ace bac i ace baa ace bac i ace bac i ace bac i ace bac i ace bac i ace bac i ace baa ace bac i ace baa ace ace ace aCc bac
caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add caa add
acc aCc acc acc acc ace acc ace acc
baa ace t acc i acc i ace i acc
bac bac bac bac bac bac bac bac bac bac bac bac bac bac bac bac bac
i i i i i i
acc acc acc acc acc acc
i acc t
acc
i i
acc acc
caa caa
baa ace caa bac i
acc
caa
baa ace caa bac i
acc
caa
baa ace caa bac i
acc
caa
baa ace caa bac i
acc
caa
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc bcc
ebb
bdd dbb cdd dec
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd cdd
abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed
2. CYCLES OP ALGEBRAS l 3 oi3-3013 3 oi3 aaa 2820
3013 28213013 2822 3013 2823 3013 2824 3013 2825 3013 2826 3013 2827 3 0 1 3 2828 3013 2829 3013 2830 3013 2831 3013 2832 3013 2833 3013 2 8343013 2835 3013 2836 3O i3 2837 3013
aaa
3013 3013 28413013 2842 3013 2843 3013 2844 3013 2845 3O i3 2 8463013 2847 3013 2848 3013 2849 3013 2850 3013 2851 3013 28 2 5 3013 2853 3013 2854 3 0 1 3 2 8553013 2856 3O i3 2857 3013 2858 3O i3 2 8593013 28 60 3 O 13 28613013 2862 3013 2863 3013 2864 3013 2865 3013 2866 3O i3 2867 3 0 1 3 28 683013 2 8693013 2870 3O13 2871 3013 2872 3013 2873 3013 2874 3 0 1 3 2875 3013 2876 3013 2877 3013 2878 3O i3 2879 3013 2 880 3 O 1 3 2881 3013 2882 3013 2883 3013 2884 3 0 1 3 2885 3013 2886 3013 2887 3 0 1 3 2888 3013 2889 3013 2 890 3 O 1 3 2 891 3 013 2892 3013 2893 3013 2894 3 0 1 3 2895 3013 2896 3013 2897 3013 2898 3013 2899 3013 2900 3013 2901 3ni3
ddd abb ddd abb ddd abb
aaa bbb
aaa
bbb bbb
aaa
bbb
ccc ccc ddd ddd ddd ddd
aaa bbb
aaa
bbb
aaa
bbb ccc bbb ccc
aaa
bbb
ddd ddd
bbb
aaa
bbb
ccc ccc ddd ddd
bbb
aaa
bbb
aaa
ccc bbb ccc
2840
666
ddd ddd
aaa bbb
aaa
bbb
aaa bbb
aaa
bbb
ccc ccc ccc ccc ddd ddd ddd ddd
aaa bbb
aaa
bbb
aaa
ccc ccc bbb ccc bbb ccc
aaa aaa
bbb ccc bbb ccc
aaa
bbb
aaa bbb
aaa aaa
bbb
ddd
ccc ccc ccc ccc
ccc ccc ccc bbb ccc
ddd ddd ddd ddd
aaa 666
aaa
bbb
aaa
bbb
666
ccc ccc ddd ddd ddd ddd
aaa bbb
aaa
bbb
aaa
bbb ccc bbb ccc
ddd ddd
aaa bbb
aaa
bbb
aaa bbb
aaa
bbb
ccc ccc ccc ccc ddd ddd ddd ddd
aaa bbb
aaa aaa
bbb ccc ccc ccc bbb ccc 666
aaa aaa
666
aaa
bbb 666
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
ccc
bbb
aaa
ddd ddd ddd ddd
ccc
ddd ddd ddd ddd
baa baa baa
abb abb abb abb abb abb abb abb abb abb abb abb
bbb
28383QI3 2839
bbb ccc 6 6 6 ccc bbb ccc
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
ace caa ace caa ace caa
add add add add add add add
ace ace ace ace ace ace ace ace ace ace ace ace
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
add add add add add add add add add add add add
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
baa baa baa baa baa baa baa baa baa baa baa
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
add daa
add add add add add add add add add add add add add add add add add
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa
add add add add add add add add add add add add add add add add add add add add add add add
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa
caa caa caa caa caa
add add add add add
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
dbb
edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd
dec abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
2902
3013 3013 2904 3013 2905 3 O 1 3 2906 3 O 1 3 2907 3 O 1 3 2908 3 O 1 3 2909 3 O 1 3 2910 3013 2911 3013 2912 3013 2913 3013 2914 3013 2915 3013 2916 3O is 29173013 2918 3 oi3 2919 3O i3 2920 3 O 1 3 2921 3013 2922 3013 2923 3013 2924 3013 2925 3013 2926 3 O i 3 2927 3 0 1 3 2928 3 0 1 3 2929 3 0 1 3 2930 3 O 1 3 2931 3 oi3 2932 3013 2933 3013 29 34 3 0 13 2935 3013 2936 3013 29373013 2938 3 O i 3 2939 3 0 1 3 2940 3 O 1 3 29413013 2942 3 0 1 3 2943 3013 2944 3013 2945 3013 2946 3013 2947 3013 2948 3 0 1 3 2949 3 0 1 3 2950 3 O 1 3 2951 3O is 2952 3 0 1 3 2953 3013 2954 3 0 1 3 2955 3013 2956 3013 2957 3013 2958 3013 2959 3 0 1 3 2960 3 O 1 3 2961 3 O i 3 2962 3 0 1 3 2963 3 O i 3 2964 3013 2965 3013 2966 3013 2967 3013 2968 3013 2969 3 0 1 3 2970 3 O 1 3 2971 30 13 2972 3O i3 29733013 2974 3 0 1 3 2975 3013 2976 3013 2977 3013 2978 3013 2979 3013 2980 3013 2981 3013 2982 3013 298 33013
aaa aaa
2903
aaa
bbb ccc ddd bbb ccc bbb ccc ddd bbb ccc ddd
aaa
aaa
bbb ccc ccc
aaa
aaa
bbb ccc ddd ddd ddd
aaa
aaa
bbb
aaa
ccc ddd ccc ddd bbb ccc ddd
aaa aaa
aaa
bbb
aaa aaa
ccc bbb ccc bbb ccc ddd bbb
aaa bbb
aaa aaa
aaa
bbb ccc ccc bbb ccc bbb ccc
bbb
ddd ddd ddd ddd
ccc ccc bbb ccc bbb ccc
ddd ddd ddd ddd
aaa 666
aaa aaa
aaa aaa
bbb
aaa aaa
bbb ccc ccc ccc bbb ccc bbb
aaa
bbb
ddd ddd ddd ddd
ccc ccc 6 6 6 ccc bbb ccc
ddd ddd ddd ddd
aaa bbb
aaa aaa
aaa aaa
666
aaa aaa
aaa
bbb ccc ccc bbb ccc bbb ccc
ddd ddd ddd ddd
abb abb abb abb
ccc ccc
bbb ccc bbb ccc ddd
aaa 666
aaa aaa
aaa
baa
ccc ccc ccc bbb ccc
aaa
aaa aaa
abb abb abb abb a66 a66 a66 a66
bbb bbb
aaa
baa
ddd ddd ddd ddd
bbb
aaa
a66 a66 a66 a66 abb abb abb abb
abb abb abb abb abb abb abb abb
aaa
aaa
abb baa baa abb baa abb baa abb baa abb baa abb baa abb baa abb baa a 6 6 baa abb baa abb baa abb baa abb baa abb baa abb baa baa baa baa baa baa baa a66 baa a66 baa a66 baa abb baa abb baa abb baa abb baa abb baa abb baa abb baa abb baa abb baa abb baa abb baa abb baa abb baa abb baa abb baa abb baa abb baa
bbb ccc ccc 6 6 6 ccc bbb ccc 666
ddd
baa baa baa baa baa baa baa baa baa baa
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
abb abb abb
baa
abb a66 a66 a66 a66
baa
a66 a66 a66 a66 abb
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace ace
baa baa
baa baa baa baa baa baa baa baa baa
ace ace ace ace ace ace ace ace ace
caa caa caa caa
add add add add
caa caa caa caa caa caa caa caa caa caa caa caa add add add add add add add add add add add add add add add add add add add add add add
caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa caa
add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add add
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec bec
ebb
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd edd
dec abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed
3. FAILURES OF (J), (L), (M) AMONG l i 3 i 6 - 1 3 1 6 1 3 1 6 AND l 3 oi3-3013 3 oi3 aaa 2984 3 0 i 3 aaa 2985 3 0 1 3 2986 3 0 1 3 aaa 2987 3013 2988 3013 aaa 2989 3013 299 °3013 aaa 2991 3013 aaa
bbb ece bbb bbb
bbb
bbb bbb
30<>13013 aaa 300 2 3013 aaa 300330i3 3004 3 0 1 3 aaa 3 0 0 5 3 0 1 3 aaa 300730i3
aaa
aaa
300 9 3013 3 1 " <'3O13 aaa 3011 3 0 1 3 aaa 3 12 " 3013 aaa aaa
ddd ddd ddd ddd
666
2993 3 S1 3 aaa bbb 2994 3 0 1 3 2 9 9 5 3 0 1 3 aaa 2 9 9 6 3 0 1 3 aaa 299730i3 2998 3013 aaa 2999 3013 aaa
ccc ccc
ccc ccc ccc
bbb
bbb bbb ccc
ddd ddd ddd
bbb ccc ccc
bbb ccc bbb ccc ccc
bbb ccc bbb bbb ccc bbb ece
ddd ddd ddd ddd ddd ddd
ddd
abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb abb
baa baa baa baa
baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa baa
ace ace ace ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac ac
c
c c c c c c
c c c c c
caa add caa add caa add aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa aa
add add add add add add add add add add add add add add add add add add add add add add add add add add add add
daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa daa
bee
bee bee bee bee bee bec bec bec bec bec bec bee bee bee bee bee bec bec bec bec bec bee bee bee bee bee bee
ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb ebb
bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd bdd
dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb dbb
cdd cdd cdd cdd edd edd edd edd edd cdd cdd cdd cdd cdd cdd edd edd edd edd edd cdd cdd cdd cdd cdd cdd edd edd edd edd edd
dec
dee dee dee dee dee
abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc abc
abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd abd
aed acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd acd
bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed bed
3. Failures of (J), (L), (M) among I1316—1316i3ie and I3013-3OI33013 For an explanation of the tables below, see Chapter 6.§64 alg. 36l316 40l316 67l3l6 711316 76l316 79l316 OO1316
931316 96l3l6 98l316 1001316 104i316 1141316 128l316 1331316 136l316 138l316 1401316 1441316 154l316 162i3i6 164l316 167l316
(J)
(L)
(M)
arffraa arfaaaa arffraa raaarff arfaaaa arffraa arfaaaa arffraa raaarff arfaaaa aabrfbb aarbbbr aabrfbb raaarff aarbbbr rarrrrr aaarrff raaafrr raaafff rffaaar raaafrr raaafff rffaaar raaaffa raaarfa arfaaaa raaaffa raaarfa arfaaaa aarrrrr aarrrfr aarfffa rarrrrr aaarrff raaafrr raaafff rffaaar raaafrr raaafff rffaaar raaaffa raaarfa arfaaaa raaaffa raaarfa arfaaaa aarrrrr aarrrfr aarfffa aabbbrr aabbbrr aabrrab aabrrab abbrraa aabbbrr aabbbrr aarbbbr
alg. 38l316 42l316 69l316 73l316 77l3l6 8O1316 89l316 951316 971316 99l316 1021316 1061316 H61316 1291316 1351316 1371316 1391316 1421316 1461316 156l316 163l316 1661316 1681316
(J)
(L)
(M)
arffraa arfaaaa arffraa raaarff arfaaaa arffraa arfaaaa arffraa raaarff arfaaaa aabrfbb aarbbbr aabrfbb rbbbrff aarbbbr rarrrrr aaarrff aaarrff raaafrr aaarrff raaafrr raaaffa raaarfa arfaaaa raaaffa raaarfa arfaaaa aarrrrr aarrrfr aarfffa rarrrrr aaarrff aaarrff raaafrr aaarrff raaafrr raaaffa raaarfa arfaaaa raaaffa raaarfa arfaaaa aarrrrr aarrrfr aarfffa aabbbrr aabbbrr aarbbbr aabbbrr aabbbrr aabrrab aabrrab abbrraa
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS alg.
(J)
(L)
1801316
(M)
alg.
(J)
(L)
rarrrrr 177l3l6
176l316 abbrfbf
183l3l6
abbrfbf
rafffff rafffff
rafffff 185l3l6
1841316
(M) rarrrrr
1861316
abbrfbf
1991316
aabbbrr aabbbrr
aabrrba
1891316 aarrrrr aarrrrf rarrraa 2001316 aabbbrr aabbbrr aarbbbf
2011316
aabbbrr
aabrrba
202i3i6
aabbbrr
203i3ie
aabbbrr aabbbrr
aabrrba
204i3i6
aabbbrr
205i3ie
aabbbrr
aabrrba
2061316
aabbbrr
207i3ie
aabrrbb rafbbbf
aarbbbr
2081316
aabrrbb
209i3ie
aabrfrb
bbraaar
2101316
aabrrrb
2111316
aabrrbb rarbbbf
aarbbbr
2121316
aabrrbb
2131316
aabrrfb
bbraaar
2141316
aabrrrb
brrafbr
215l316
aabarbr aarafbb
aabrrbr
2161316
aabrrbb
aabrrbr
217i3i6
aarbbrr
aabrrbr
2181316
aabrrbb
2191316
aabrrbb
aarbbbr
2211316
aabrrbb
raffbff
aabrrfb
222i3i6
aabrrbb raffbff
aabrrrb
223i3i6
aarbbrr
raffbff
aabrrfb
224i3ie
aabrrbb
aarbbbr
225i3i6
aabrrbb
229i3ie
abfrbbb
arfbbbb
230i3i6
barfabb
234i3ie
abbrffa
arfaaaa
238i3i6
aabrrbb
rabbbaa
236i3i6 aabrffa 239i3i6 aabfrbb
241i316
aaabfrf aaabrrb
aaabrbf
243i3ie
aabrrbb abbbfrb
abbrrrr
242i3i6 aaabfrf aaabfrr aaabfff 244i3i6 aabfrbb abbbfrb abbrfrf
245i3i6
abbrrrr abrrbrr
abbrrrr
246i3i6
abbrrrr
abfrbrr
abbrfrf
247i3ie
abbbrab abbbrrb
aarbbab
248i3i6
abbbffa
abrrbrr
aarbrbr
250i3i6 252i3i6
aabfrbb
abbbfrb
barbbff
abffrrb
abfrbrr
barrbff
abfrbrf
abbbfrr aaaffrr
bbbrrff aabbbrr
aarbbbf
rafbbbf
aarbbbr
bbbrrff brrafbr rafbbbf
aarbbbr
aarbbbr
aarbbbr abbbrrb
249i3ie
aabrrbb abbbrrb
babrrar
251i3i6
abbrrra abrrbrr
babrrar
253i3i6
abfrbrf abbbfrr
aabbbar
255i3i6
abfrbrf baaabfa
257i3ie
baaabfa abbbrrr
254i3ie aarrrab 256i3i6 aabbbar 2581316
baafrbb
abbbfrr
259i3ie 262i3i6
baaabfa baaabfa
abbfaar
261l316
abbbrab
abbbfrr aarbbab
aaabfrf aaabrrb
aaabrbf
263i3i6
abfrbrf raarbrr
264i3ie
aaabrrr aaabrrr
aaabrrr
265i3i6
aabfrbb
2661316
aabrrbb abbbrrr
abfbarr
267i3i6
abfrbrf
abfbarr
2681316
abrrbrr
abfbarr
269i3i6
abbbrab
abbbfrr aarbbab
abfrbrf barfafr aaaffrr barbbff aarrrrb
abbbfrr abfbarr
270i3i6
abbbrab abbbrrr
aarbbab
271i3i6
abfrrab
rabafbr
aafbffb
272i3ie
abfrrab rabafbr
aafbffb
273i3i6
aabfrbb
abbbfrr
barbbff
274i3ie
aabrrbb abbbrrr barbbff
277i3i6
abbbrar
abbbfrb aarrbbr
2781316
abbbrar aaabrrb
babarrr
abbbrar rabafbf
abbbrar
abbbfrb aarrbbr
282i3i6
abbbrar aaabrrb
279i3i6 aaraaab 2811316 aaabrbf 283i3i6
abbbrar
28O1316
abbbrar
babarrr
284i3ie
abbbrar rabafbf
aabbbbr
aabbbbf aarrbbr
aaabrbf
aafffrb abbarfa
2861316
aabbbbf aabbbbr
aaraaab 285i3i6 aarrbbr 287i3i6
raabrrr
abbrrff
2881316
raabrrr
abbrrrr
289i3i6
aabbbbr
aabbbbf aarrbbr
290i3i6
aabbbbf aabbbbr
aarrbbr
2911316
aabbbrr
abbrrff
292i3ie
aabbbrr
abbrrff
293i3i6
abbbrar
abbbfrb aafbbbr
3. FAILURES OF (J), (L), (M) AMONG lisi B -131«lSia AND l s 0 is-3013 s 0 is
294i3iB 296i3iB 298i3ie 3001318 302i3i8 304 1 3 ie 306i3ie 308i3ie 3101316 312l31B 314l3lB 3161316 318131B 3201316 322i3ie 324i3iB 326i3ie 328i3i6 330i3iB 339i3ie 341l3X6 343i3iB 345x3X6 348x3X6 350i3iB 352x3X6 354x3X6 364i3iB 368x3X6 372x3X6 376i3iB 383x3X6 389x3X6 391i3iB 397x3X6 410x3X6 412l31B 422x3X6 426x3X6 428i3iB 430x3X6 433x3X6 437x3X6 447i3iB 449i3iB
(J) abbbrar abbbrar abbbrar abbbrar aabbbbr rrarbbr aabbbbr aabbbrr rabbrrb abrrbbb rabbrrb abrrbbb
(M) aarbbbr abrrrrb aarbbbr bbbarfa baarbbr bbbrrrr baarbbr barabrr arrbbbb arrbbbb rbbbrrb arrbbbb arrbbbb abbrrrr abbrrrr
(L) abbbrrb abrrbrr abbbrrb abrrbrr aabbbbr abrrbrr aabbbbr abrrbrr rbbbrrb
rabrrrb rabrrrb
babraar rabarbb babraar rabbbar rabarbb rabbbar rbbrabb
rabbbbf rabbbbr aabbbbr aabbbbr aarbbra aarbbfa aarbbra brrrrrb
abbbrrb abbbrrb aabbbbr aabbbbr
baraabb brraara baraabb abrbaar abrbaar arrabbb bbbraar arrbbbb arrbbbb arrbbbb arrbbbb barbbbb barbbbb baarbbr baarbbr aarrrab bararfa bararfa rabrrrr aaraaab aaraaab
abbrrba arfbabb brrrraa arrrraa raaarrr arraaaa raabrrr raabrrr arrbabb arraaaa raaarrr raaarrr arraaaa babbrbb aabrrar
alg. 295isi8 297isi8 299isi6 301isie 303isi6 305i3ie 307isie 309i3ie 3II1316 313isie 315l316 317l316 319isie 3211316 323i3ie 325isie 327i3ie 329isie 331isi6 340i3i6 342isie 344isie 347i3ie 349isie 351isi6 353i3ie 363isie 367isie 3711316 375isie 382isi6 388i3ie 390isi6 396isie 398i3ie 411isi6 413isie 425i3i6 427isi8 429isi8 4311316 435isi6 446isi6 448isi6 450isi6
(J) abbbrar abbbrar abbbrar aabbbbr rrarbbr aabbbbr aabbbrr aabbrra aabbrra aabbrra aabbrra aabbrra aabbrra aabbrra aabbrra babarar babarar babarar babarar
(L) abrrbrr abbbrrb abrrbrr aabbbbr abrrbrr aabbbbr abrrbrr baaarra baaarra baaarra baaarra baaabra baaabra baaabra baaabra raaafbr raaarbr raaarbr raaarbr
rbbrabb
rabbbbr rabbbbr aabbbbr aabbbbr aarbbra aarbbra aarbbfa abbrrbf
abbbrrb abbbrrb aabbbbr aabbbbr raaabra raaabfa
arrrraa brrrraa raabrrr raaarrr
raaarrr
(M) abrbaar aarbbbr barrbar baarbbr bbbrrrr baarbbr barabrr abraaaa abraaaa abraaaa abraaaa abbraar abbfaar abbraar abbraar abrbaar abrbaar arraaaa arraaaa brraabb brfafra brraabb arrbbbb abrbbaa arrbbbb abrbbaa barbbbb barbbbb baarbbr baarbbr aarbrrb aarrrra aarrfra rabrrrr rabrrrr aaraaab aaraaab arraaaa arrbabb arrbabb arraaaa arraaaa babbrbb babbrbb aabrrar
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS alg.
(J)
(L)
451l316
(M)
alg.
barbbrr
468i3i6
aarbrbr aarbbbf aarbbar aarbfbr aarbbbf aarbbaf
(J)
(L)
(M)
469i3i6
aarbfbr
aarbbbf
abrbafr
470i3i6
471i3i6
aarbfbr
aarbbbf
abbbbar
472i3i6
abbbrbr abbbrbf barbbaf
473i3i6
babbarf
barbbrf
474i3i6
aarfabb abbbrbf abbbbar
475i3ie
aarfabb
abbbbar
476i3i6
aabbbrb aabbbrb aabbbra
477i3ie
babrfrr
barffrb
478i3i6
abbbrbr abbbrbf aarfbfa
479i3ie
babrfrr
barfrrr
480i3i6
aabbbrb aabbbrb aabbbra
4811316
babrrrr
barffrb
482i3i6
abbbrbr abbbrbf rabrrab
483i3ie
babrrrr
484i3i6
abbbrar aarbbbf aarfbfa aarfabb aarbbbf aarfbfa
babbbra
485i3ie
abbbrar
aarbbbf
babbffr
486i3i6
487i3ie
aarrabb
aarbbbf
abbbbar
488i3i6
abbbrbr abbbrbf arfaaaa
489i3ie
babbafr
barbbrr
490i3i6
aarfabb abbbrbf abbbbar
491i3i6
aarrabb
abbbbar
492i3i6
aabbbrb aabbbrb aabbbfa
493i3ie
babrrrr
barffrb
494i3i6
abbbrbr abbbrbf aarfbfa
495i3ie
babrrrr
496i3i6
aabbbrb aabbbrb aabbbfa
497i3ie
babrrrr
498i3i6
abbbrbr abbbrbf rabrrab
499i3ie
babrrrr
500i3i6
abbbrbr abbbrbf
502i3ie
abbbrbr
abbbrbr
504i3ie
abbbrbr
babbbra
barffrb babbrbb
503i3i6
babbrbb
abbbrbr aarbbar
506i3i6
abbbrbr abbbrbf aarbbar
babbrbb
5O81316
abbbrbr abbbrbf
babbrbb
511i3i6
507i3ie 510i3i6
abbbrbr
abbbrbf
514l316
aabbbrb
aabbbrb
516i3i6
abbbrbr abbbrbf
5I81316
aabbbrb
aabbbrb
520i3i6
abbbrbr abbbrbf
522i3ie
aabbbrb
aabbbrb
524i3i6
abbbrbr abbbrbf
babbrbb
526i3i6
babbrbr
527i3i6
barrrrr
528i3i6
babbrbr
529i3i6
barrrrr
aaaabrb
5311316 aaaabbr aaaabbr aaaabrb 533i3i6 aaaabbr aaaabbr aaaabrb
536i3i6
barbbrr
537i3i6
538i3i6
barbbrr
539i3i6
barrrrr
530i3i6
aaaabbr
aaaabbr
aaaabrb
532i3ie
aaaabbr
aaaabbr
barrrrr
540i3i6
abrffrr
abffrff
abrrabr
541i3i6
abrffrr abffrff arrrarr
542i3ie 544i3i6
aaaabbr
aaaabbr
aaaabfb
543i3i6
abbfrba abffrff arrrarr
abrffrr
abffrff
arrrarr
545i3i6
babbrbr
546i3ie
barrrrr
547i3i6
babbrbr
548i3i6
barfrrr
549i3i6 aaaabbr aaaabbr aaaabfb barrrrr 551i3i6
550i3ie 552i3i6 554i3i6
aaaabbr
556i3i6
aaaabbr
aaaabfb
barfrrr
barrrrr
553i3i6
barfrrr
555i3i6
arrbabb
barrabb
arrbabb
557i3i6
babarff barbrfr abrabbr
559i3ie babbarf 562i3i6 aaarraa baaaraf
abrabbr aabaaar
561l316 aaaabrb aaaabrb aaaabbr 563i3i6 baaarra baaarfa rabbbfr abffafa 567i3i6 aaarffa
565i3i6 baaarra
baaarfa
568i3ie aaarffa 570i3i6 rarbafr 572i3i6 aaarffa
abffafa baaaraf
arrrrar
569i3i6 babbafr arrrrar 571i3i6 aaarffa baaaraf aabaaar
aabaaar
573i3i6
abbrfba baaarfa arrfrar
3. FAILURES OF (J), (L), (M) AMONG l i 3 i 6 - 1 3 1 6 1 3 1 6 AND l 3 oi3-3013 3 oi3 alg.
(J)
(L)
(M)
alg.
(L)
(M)
604i3i6 6O61316
rafbbrb
6O81316 612l3l6
rafbbrb
abrbbbb abrbbbb
abrrfff abrrrff 617l3l6 aarrrbr aarbrrr aarfffa 6211316 rabbrar barrrbb 628i3i6 raffbbb 631l316 629i3ie barbrbr 635i3i6 632i3i6 rabbrbr 637i3i6 abrrfff abfrrff rrafarr 639i3i6
abrrfff aarrrbr rabbrar abrffff abrffff baarfab
abrrrff aarbrrraarfffa
rarbafr
576i3i6
barrabb
578i3i6
barrabb
580i3ie 582i3i6
arrfrar 575i3i6 barrrbr 577i3i6
(J)
arfbbbb arfbbbb barrrrr bbrrfrf rabfrrf baaarar baaaraf aabaaar abrfrbr baaarafaabaaar baaarar baaaraf aabaaar barrrrr rabfrrf aarbbab abrrfff abrrrff abrbbbb
574i3ie
579i3i6
bbrrfrf
5861316 baaarar baaaraf
abrfrbr baaaraf 590i3ie baaarar baaaraf 5881316 592 1 3 i 6 594i3ie 599i3ie
abrrfff abrrrff 605i3i6 aarbrbr aarbrrr 607i3ie aarbrbr aarbrrr 603i3ie
6II1316
barrrrr rabfrrf aabaaar aabaaar aabaaar barrrrr rabfrrf aarbbab abrbbaa aarrfba aarrfba abrbbaa
581l316 585i3i6 587i3i6 589i3i6 591i3i6 593i3i6 597i3i6 6OI1316
615l316 6191316 627i3i6
barrrbb
643i3ie 647i3i6 650i3ie 657i3i6
abrrfff abfrrff bbrbffb abrffff abfrrff aabfrrf aafbfrf raaafbf barrffa barbbfa barrffa
645i3i6 649i3i6
bbrbrbr
655i3i6 659i3i6
aarfffa aarfbfa aarfbfa arraaab arraaab aarfbfa aarfbfa aarfffa aarfffa
663i3i6
brfbbbb brfbbbb
6881316
barrfbr aarbrrr 702i3ie barfrbf aarbrrr aaafbbr 710i3i6 aaabrbr aaafbbr 7121316 aaabrbr
7011316
7141316
arrbbab
7161316
arrbbab
7151316 717l3l6
66I1316 667i3i6 669i3i6 671i3i6 673i3i6
babarar 677i3i6 babarar 679i3ie aarrrbr 68I1316 aarrrbr 675i3i6
687i3i6 6911316
barrffa barrffa aarbrrr aarrrff aabrbfb
695i3ie
7181316 7201316 723i3ie
raafabr raafabr
6681316 670i3i6 672i3i6 674i3ie
raffbbb aafbfrf aarrfba abfrrff aafbfrfaarfffa aaabrbf aaabrrr aaabrbf aaabrrr arrbabb arrbabb
676i3i6 raaafbf 678i3i6 raaafbf 68O1316 682i3i6 692i3i6 709i3i6 7111316 7131316
7191316 7211316 arfaaaa
aabfrrf abrffff aabfrrf baarfab aaabrbr aaabrbr brffraa
bbfafar
abfrrff barbrbr abfrrffrrafarr
725i3i6
aarrrbr aarbrrraarfffa aarrrbr aarrrff aarfffa aabrbfb brfbbbb brfbbbb barfrbf aarbrrr aarfbfa raabaar aarfbfa barbbfa arrabaa arrabaa aarfbfa babarar babarar aarfbfa arfaaaa raafaar brfbbbb
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg.
(J)
(L)
(M)
brfbbbb brfbbbb 729i3i6 rarrraf 733i3i6 raafaar arfbbbb 7411316 rabffbb 74313ie arfbbbb 745i3i6 abrrrrf aarfffa aarrrbr 753i3i6 755i3i6 aarrrbr abrrrrf aarfffa brfbbbb 761l3l6 765i3i6 aarrrbr arrrfff brfbbbb 76713ie aarrrbr arrrfff brfbbbb 770i3i6 781l316 abrrfrr arrrfff babbrbb 790i3i6 bbbrrbb aabaaar 792 1 3 i 6 aabrbrr barbarr 794i3i6 aabbbrr baffbfb 796i3ie abrrbfb babbrbb 798i3ie bbbrffb aabrffb aabaaar 8001316 rafabfb 802i3i6 aabrffb 726i3i6
8O61316 8O81316 8II1316 814i316 8161316 8181316 82O1316 822i3i6 824i3ie 8261316 8281316 830i3i6 832i3i6 834i3ie 836i3ie 838i3i6 840i3ie 842i3ie 844i3ie 846i3ie 848i3ie 850i3ie 852i3i6 854i3ie 856i3i6
babbrbb babbrbb aabrrfa abrbrar aaabrrr aaabrbf abrbfar aaabrrr aaabrbf abrbrar aarbbrr aaarrff aarrabb aarbbrr aaarrff abrbrar aarbbrr aaarrff aarrabb aarbbrr aaarrff rabrbrr aaarrff aaarrff raaarrr rabfbff aaarrff rabrbrr aaarrff raaarrr aaarrff raaarrr aaarrff abrbfra aaabrfb abrffbf abrbfra aaabrfb abrffbf abrbrra aarbbfa abbffrr abrbrra aarbbfa abbbbar abrbrra aarbbfa abbffrr abrbrra aarbbfa abbbbar abrrbrr abrrbrr abrffbf abrfbrf abrrbrr abrffbf abrrbrr abrrbrr abbffrr abrrbrr abrrbrr abbffrr
alg.
(J)
727i3i6 raafaar 730i3i6 735i3i6 raafaar 742i3i6 744i3i6 746i3i6 754i3ie 756i3i6 762i3i6 766i3i6 769i3i6 779i3i6 789i3i6 791i3i6 793i3i6 795i3i6 797i3i6 799i3i6 8OI1316 805i3i6 807i3i6 809i3i6 8131316 815l316 817l3l6 8191316 8211316 823i3i6 825i3i6 827i3i6 829i3i6 831l3l6 833i3i6 835i3i6 837i3i6 839i3i6 841l316 843i3i6 845i3i6 847i3i6 849i3i6 851l316 853i3i6 855i3i6 857i3i6
(L)
(M) rarrraf brfbbbb rarrraf arfbbbb rabffbb arfbbbb
aarrrbr aarrrbr brfbbbb brfbbbb brfbbbb abrrfrr arrrfff bbbrrbb babbrbb aabbrfr aabaaar aabbbrr aabrrar abrrbfb barfrbr bbbrffb babbrbb aabbrfr aabaaar aabbrfr aabfrra
babbrbb babbrbb aabrrar abrbfar barafbb abrarbf abrbfar barbbrr abrrabf abbbrbr aarafbb abbarrr aarrabb aarafbb abbarbb abbbrbr aarbbrr abbarfa aarfabb aarbbrr abbarbb rabfbff aabarrr aabrrff aabbarr aabarrr aabrrff aabbbrb aabarrr aabbbra aabbbrr aabarrr aabrrff aabbarr aabarrr aabbbra aabbarr aabarrr aabrrff abrbfra abrrffb abrarbf abrbfra abrrbrr abrffbf abbbrbr aarafbb abbarrr abbbrbr aarafbb abbarbb abbbrbr aarbbfa abbafra abbbrbr aarbbfa abbarbb abrrbrr aabafff abrffbf abrfbrf aabarrr abrffbf aabbbrb aabafff aabbbfa aabbbff aabafff abbafra aabbbrb aabafff aabbbfa
3, FAILURES OF (J), (L), (M) AMONG l i s i a - 1 3 1 8 l S 1 8
(J) 858i3iB 86O131B 865i3ie 868131B 871l31B 873i3ie 877i3iB 88I131B 885i3ie 889i3iB 893i3iB 897i3ie 899i3iB 9011316 903i3ie 905i3iB 907i3ie 909i3ie 911131B 913x3X6 915x3X6 9171316 919x3X6 921x3X6 923i3iB 925i3ie 927i3ie 929i3iB 931x3X6 933i3ie 937i3iB 941x3X6 945i3ie 947i3iB 949i3ie 951x3X6 953i3iB 955i3ie 957i3i6 959i3iB 961x3X6 963i3i6 965i3i6 967i3iB 969i3iB
abrrbrr abrrbrr ahbhrhr bbbrrbb abbbrbr aabrbrr aabrbrr aabbbrb aabbbrb aabbbrb aabbbrb aarrbrb aarrbfb aarbbrb aarrbrb aarbbfb aarrbrb rarrrrb raafarf aabbbrb abbbrrb aabbbrb abbbrrb aarrbfb aarrbfb aarbbrb aarrbfb aarbbfb aarrbrb aabrrrb aabbbrb aabbbrb abrrbfb abrrbfb aarbbrb abbbrbr aarbbfb abbbrbr abrrbrr abrrbrr aabbbrb abbbrrb aabbbrb abbbrrb abrrbrb
(L)
(M)
abrrbrr abbfrrr abrrbrr abbrrrr aararbb abrarbr babarbb abbbrbr abbarbb aarbrrr aarrrba aarbrrr aarffba aabbbrb aabrbra aabbbrb aabbbrb aabrbra aabbbrb barbbra abrarbr barbbfa abrfabr aarbbra abrarbr aarbbra abrarbr aarbbfa barfbrb aarbbra babbrbb barrarr baafrrr barrarr baafrrr aabbbrb baarrrr abbbrrb baafrrr aabbbrb baafrrr abbbrrb baarrrr barbbfa abrarbr barbbfa abrfabr aarbbra abrarbr aarbbfa abrarbr aarbbfa arraaaa aarbbra arraaaa
alg.
(J)
859isi8
aabbbff abrbrrr abbbrbr abbbrbr bbbrrbb abrrbrr baabbar aabrbrr abbbrrb aabrbrr abbbrrb aaabrrb aaabrrb babrrrb aarrabb babrrrb aarrabb rarrrrb raafarf rarbrrb rarrrrb baarrrr raararr aaabrrb aaabrrb babrrrb babrrrb babrrrb babrrrb aabrrrb aabrrrb aabrrrb abrrbfb abrrbfb abrrbrr abrrbrr abrrbrr abrrbrr abrrbrr abrrbrr abrrbrr abrrbrr abrrbrr abrrbrr abrrbrb
8611316 867i3ie
869ISIB 872isi6 875i3ie 879isie 883i3ie 887i3ie 891isie 895i3ie 898i3ie 900isi6 902i3ie 904i3ie 906isi6 908i3i6 910isi6 912isi6 914l3X6 916isi6 918isi6 920i3i6 922isi6 924isi6 926i3i6 928isi6 930isi6 932i3ie 935isi6
aabbbrb aabbbrb abrrbrr abrrbrr abbbrbr abbbrbr abbbrbr abbbrbr abrrbrr abrrbrr aabbbrb abbbrrb aabbbrb abbbrrb
rabfbfa rabrbra abrarbr arraaaa abrarbr abrarbr arraaaa arraaaa
939isi6 943i3ie 946isi6 948isi6 950i3i6 952isi6 954isi6 956i3i6
958ISIB 960ISIB 962i3ie
964ISIB 966isi6
968ISIB
abrarbr
A N D
970isi6
lsois-3013 s 0 is
(L)
(M)
aabafrr abbarra abrrrrb abrarbr aararbb abbarbb abbbrbf babarbb abrrrrb barbaar barbaar aarbrrr aarrrba abbbrrb aarbrrr aarffba abbbrrb aaabrrb aaabrbr aaabrrb aaabrbr aarbbra aaarrrr aarbbra aaarrrr aarbbra aaaffrr aarbbra aaarrrr bafrarf aaaffrr bafrarf aaaffrr barrarr aaarrrr bafrarf aaaffrr bafrarf aaaffrr barrarr aaarrrr aaabrrb abrrabr aaabrrb abrrabr aarbbra barrbrb aarbbra babbrbb aarbbra bafrbrb aarbbra babbrbb abbbrrb abbbrrb abrrbfr abrfbfr abrrbrr abrrbfr abrrbfr abrrbrr abrfbfr abrfbfr abrrbrr abrrbfr abrfbfr abrrbfr
arrbrfb bafrbrb brrabrr babbrbb brrabrr babbrbb
barrbrb
6SS
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. 9711316 973i3ie 976i3ie 979i3ie 9811316 985i3ie 9911316 995i3ie 999i3ie 10031316 10061316 IOO81316 IOII1316 10131316 10161316 1025i3i6 10301316 1032i3ie 1035i3i6 1037i3ie 1040l316 1049i3ie 1059i3ie 1062i3ie 1065i3ie 1067i3ie 1070l316 1083i3ie 10911316 1097i3ie
1099i3ie 11011316 1103l316 11051316 11071316 11091316 11111316 11131316 11151316 11171316 11191316 11211316 11231316 11251316 11271316
(J) abrrbfb aarbbfb bbbrffb abbbrbr aarfrff aabfrrf aarrrrf abbbffb aabfrrf abbbrfb abrfbaa abrfbaa abbbrbr aarbbfb
(L)
(M) baffbfb abrarbf babbrbb babbrbb aarrfba abrrffa abrrffa
alg.
972i3i6 abbbrbf 975i3i6 977i3i6 abbbrbr 980i3i6 aafbrrf 983i3i6 aafbfrf 989i3i6 aafbrrf 993i3i6 abbbrfb 997i3i6 aafbfrf abrrffa IOOI1316 abbbrfb 10051316 10071316 1009l316 abbbrbf babbrbb 10121316 abbbrbf 10151316 babbrbb 10211316
aabbbrb aabbbrb 1029i3ie abfrbaa 10311316 abfrbaa 1033i3ie abbbrbr abbbrbf arfaaaa 1036i3ie aarbbfb abbbrbf arfaaaa 1039i3ie babbrbb 1045i3ie aabbbrb aabbbrb 1058i3ie aarbbfb abbbrbf 10611316 babbrbb 1063i3ie abbbrbr abbbrbf aarbfra 10661316 aarbbfb abbbrbf 1069i3ie babbrbb 1079i3ie aabbbrb aabbbrb 1087i3ie aabbbrb aabbbrb 1096i3ie aaabrrr aaabrbf 1098i3ie raaafrr aaabrrr aaabrbf 11001316 babaraf abbarfa 1102i316 babaraf abbarfa 11041316 raaafrr babarrr abbarfa 11061316 raaafrr babarrr abbarfa 11081316 aabrrff 11101316 aaarrff 11121316 aaarrff 11141316 raaafrr raaaffa abrrffb arfaaaa 11161316 raaaffa abfrbrf arfaaaa 11181316 raaaffa abfrbrf arfaaaa 11201316 raaaffa abfrbrf arfaaaa 11221316 raaaffa abfrbrf abbafra 11241316 raaaffa abfrbrf abbafra 11261316 raaaffa abfrbrf abbafra 11281316
(J) abrrbfb abbbrbr aarbbfb bbbrffb abrfbfr aabbbrb aabbbrb aabbbrb aabbbrb raaafbf
(M) baffbfb abbbrbf abrarbf abbbrbf brrbrba babbrbb (L)
aabbbrb aabfbfa aabbbrb aabbbrb aabfbfa aabbbrb raaafbr brfaaaa brfaaaa aarbbfb abbbrbf babbrbb abbbrbr abbbrbf babbrbb aabbbrb aabbbrb arfaaaa raafaar arfaaaa aarbbfb abbbrbf arfaaaa babbrbb abbbrbr abbbrbf arfaaaa aabbbrb aabbbrb babbrbb abbbrbr abbbrbf babbrbb aarbbfb abbbrbf aarbfra babbrbb abbbrbr abbbrbf babbrbb aabbbrb aabbbrb aabbbrb aabbbrb aaabrbf aaabrbf raaafrr raaafff rffaaar raaafrr aaabrrr aaabrbf aaarrff aaarrff raaafrr aaarrff raaafrr aaarrff aaarrff raaafrr aabrrff raaafrr aaarrff raabffa aaabrfb aaafbbr raabffa aaabrfb arfbabb raabffa aaabrfb arfbabb raabffa aaabrfb arfbabb abfrbrf abbffrr abfrbrf abbffrr raafbff abfrbrf abbffrr
3, FAILURES OF (J), (L), (M) AMONG luie-131flisie AND 1SQIS-3013 SO IS
alg11291318 11311316 11331316 11351316 11371316 11391316 11411316 11431316 11451316 11471316 11491316 11511316 1155l316 1163x3X6 1169x3X6 11771316 11851316 1193x3X6 11951316 11971316 11991316 1203i3ie 12131316 12151316 12171316 12211316 1225i3i6 1228i3ie 1234i3i6 1240i3i6 1242i3ie 1244i3i6 1249i3i6 1256i3ie 1258i3i6 1262i3i6 1265i3ie 1269i3i6 1277i3i6 1297i3i6 1305i3i6 543013 573013
(J)
(L)
raaarra abrrbrr abrrbrr abrrbrr raafbrf abrrbrr raarbrr abrrbrr abrrbrr abrrbrr raarbrr abrrbrr raarbrr abrrbrr raabraf abrrrrb raabrar bararbb raabraf aarrrbr aabrrrr aarrrrr aabrrrr raaarra raaarrb raaarrb raaarra raaarra raaarar raarbbr
(M) alg. abbarra 11301316 arrrbbr 1132l3 1 6 bbbrrrr 113413X6 arrrbbr 1136l316 bbbrrrr 1138l316 abbrrrr 11401316 abbrrrr 11421316 abbrrrr 114413X6 abbrrrr 1146x3X6 arrbbbb 11481316 bbbarrr 1150l3X6 arrbbbb 115213X6
babarar aarbrrr aarbrrr aarbrrr aarbrrr raaarra arraaaa aaabrfb arrbabb aaabrrb arrbabb raaarra arraaaa raaarra arraaaa arraaaa
raaarar baarfbr aarbrrr baarrbr aarbrrr raarbbr raarbbr raafbar bbrrrbf rbbrbbr rbabbfb rbbbrbr
aarrrbr aarbrrr aabrrrr aarbrrr raaarar abbrrbr aabccbb aabccbb 59sois aacbbce 71sol3 aabddbb
11571316 116413X6 1171X3X6 11791316 1187l3X6 11941316 H96l316 119813X6 12011316 1205i3i6 121413X6 12161316 brrbbbb 12191316 arraaaa 1223i3X6 arraaaa 1227i3i6 1233i3i6 1239i3X6 arrbbbb 12411316 1243i3i6 arrbbbb 1247i3X6 1255i3i6 1257i3i6 brrbbbb 1261l3X6 brrbbbb 1263i3i6 brrbbbb 1266i3ie 127113X6 1279i3ie 1299i3i6 533013 aabeebc 553013 aabccbc 583013 aabeebc 703013 aabddbd 72soi3
(J)
(L)
raarbrr abfrbrf abrrbrr abrrbrr raarbrf abfrbrf raarbrr abrrbrr abrrbrr abfrbrf raarbrr abrrbrr raarbrr abrrbrr rbbbraf rarbbbf rbbbrar
(M)
abbrfrr arrrbbr bbbrrrr arfrbbr bbbrrrr abbrrrr abbrfrr abbrrrr abbrrrr arrbbbb arrbbbb
raabraf bbrrrbr aabrrrr aarrrrr aabrrrr raaarrb raaarra raaarrb raaarra raaarra raarbbr raaaraf aarrrbr aabfrrf raarbar raafbar
babaraf aarbrrr aarbrrr aarbrrr aaabrrb aaafbbr raaarfa arraaaa aaabrrb arrbabb raaarfa arraaaa raaarfa arraaaa aaarbbr afraaaa afraaaa arraaaa aarbrrr aarbrrr arrbbbb bbbraar arfbbbb
raarbar aarrrbr aafbfrr brrbbbb rbbrbbr aabrrrr aarbrrr brrbbbb aabfrrf aafbfrr brfbbbb aarrrbr aarbrrr aabfrrf aafbfrr raaaraf aabccbc aabccbb aabccbc aacbbce aabccbc aabccbb aabddbd aabddbb aabddbd aadbbdd
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. 733013 753013 793013 813013 1043013 1063013 1093O13 1133013 H63013 H83013 1233013 1253013 1273013 1323013 1343013 1453013 1533013 1863013 1883013 1913013 1953013 1983013 2003013 2053O13 2073O13 2093013 2143013 2163013 2273013 2353013
(J) aabddbb aadbbdd aabccbb aadbbdd
(L)
aaaaccb aaaaccb aaaaccb aabbbcb
aaaaccb aaaaccb aaaaccb aabbbcb
aabbbcb aabbbcb
aabbbcb aabbbcb aabbbcb aabbbcb
aaaaccb aaaaccb aaaaccb aabbbcb
aaaaccb aaaaccb aaaaccb aabbbcb
aabbbcb aabbbcb
babbcbb babbcbb aabccac aaaacbc aaaacbc aaaacbc aabbbca abcaacc aabbbca abccccc abccccc
alg. 743013 783013 8O3013 1033013 1053013 1073013 1123013 1143013 1173013 1193013 1243013 1263013 1313013 1333013 1413013 1493013 1853013 1873013 1893013 194 3 oi3 1963013 1993013 2013013 2063013 2083013 2133013 2153013 2233013 2313013
aabbbcb aabbbcb 2473oi3 aadbcdd aabddbd 2493oi3 aadbcdd aabddbd 2513013 aadbbbd 2533013 aadaaab 2583013 abdbbbb 264 3 oi3 aacaaab 2723013 aacaaab 2743oi3 daaabad daaabad aadddab 2873013 cbbddad 3093013 cbbddad abcbbbb 3123013 cbbddbc abcbbbb 3143013 cbbddad 3163013 cbbddbc 3203013 aaaacbc aaabcdb aaabcbd 3243oi3 aaaacbc aaabcdb aaabcbd 3263013
aabbbcb aabbbcb 248soi3 aabddbb 2503013 aadbbdd 2523013 aabddbb 2573013 2633013 2713013 2733013 2813013 3073O13 3H3013 3133013 3153013 3193013 3233013 3253013
(M) aabddbd aabddbd aabccbc aabddbd babbcbb babbcbb aabccac aaaacbc aaaacbc aaaacbc aabbbca abcaacc aabbbca abccccc abccccc
(J) aabddbb aabccbb aacbbcc
(L)
aaaaccb aaaaccb aaaaccb aabbbcb
aaaaccb aaaaccb aaaaccb aabbbcb
aabbbcb aabbbcb
(M) aabddbd aabccbc aabccbc babbcbb babbcbb aabccac aaaacbc aaaacbc aaaacbc aabbbca abccccc abccccc aabbbca abcaacc
aabbbcb aabbbcb aabbbcb aabbbcb
aaaaccb aaaaccb aaaaccb aabbbcb
aaaaccb aaaaccb aaaaccb aabbbcb
aabbbcb aabbbcb aabbbcb aabbbcb aabddbb aacddcc aabddbb aacddcc
babbcbb babbcbb aabccac aaaacbc aaaacbc aaaacbc aabbbca abccccc abccccc aabbbca abcaacc
aabbbcb aabbbcb aadbcdd aabddbd aadbcdd aabddbd aadbbbd aadbccd aadaaab abdbbbb aacaaab aacaaab daabdbb dabadbb abdddbb cbbddbc abcbbbb abcbbbb cbbddad cbbddbc aaabdbd aaabcdb aaabcbd abcdbaa aaabcdb aaabcbd
3. FAILURES OF (J), (L), (M) AMONG Ii3i 6 -1316 1 3 1 6 AND 13013-30133013
(M) alg. (L) (J) 3273013 aacddcc abcbddd aacddcd 3283013 abcdbdd 329 3 oi3 aacddcc bacbbda abdacdb 3303013 abcddab 33I3013 aacddcc abcbddd aabddad 3323013 abcdbdd abdacdc 334 3 oi3 ccdddab 3333013 aacddcc aacbcad aacbcdd aacddcd 3353013 3363013 aaaacbc aadbdac abcbddd aacddcd 3373013 3383013 aaaadbd 3393oi3 aacbcad bacbbda aadcbbd 3403013 aaaacbc 34I3013 abcddba bacbbda aadcbbd 3423oi3 abcdbaa 3433oi3 aacbcad abcbddd aacddcd 3443013 aacddcc 345 3 oi3 aacbcad abcbddd aacddcd 3463013 aacddcc 347 3 oi3 aadbdac abcbddd aacddcd 3483oi3 aadccdd 3493oi3 aadbdac abcbddd aacddcd 35O3013 aadccdd aadcccd 3523013 aacddcc 35I3013 aacbcad aadcccd 3543oi3 aacddcc 3533013 aacbcad abbacda 3563013 bccddab 3553013 abcddba abbacda 3583013 bacdabb 3573013 accddab 3593oi3 aacbcad abcbddd aacddcd 36O3013 aacddcc 36I3013 aadccdd abcbddd aacddcd 3623013 aadccdd aadcccd 3643013 aacddcc 3633013 aacbcad accddab badbcad 3673013 aacbcad 3653013 abcbddd aacddcc aacddcd 3683013 3693013 aacbcad 37O3013 aacddcc abcbddd aacddcd 37I3013 aadccdd 3723013 aadccdd abcbddd aacddcd 3733013 aadccdd 3743oi3 aadccdd abcbddd aacddcd 3753013 aacbcad aadcccd 3773013 aacbcad 3763013 aacddcc aadcccd 3793013 abbddba 3783013 aacddcc badbcad 3833013 caaddbd 38I3013 accddab aacaaab 3873013 caaddbd 3863013 caaddbd aacaaab 3893013 3883013 aacaaab 39I3013 3903013 392 3 oi3 caaddbd 3933oi3 caaddbd 394 3 oi3 caaddbd 4OI3013 aacbcad 402 30 13 aaaacbc aaabcdb aaabcbd 4033013 aaaacbc aacddcd 4053013 aaaadbd 4043O13 aadbdac aaabcdb aaaadbd aaabcbd 4073013 accddaa 4O63013 aaabcdb bccddaa aaabcbd 4093013 cacddba 4O83013 aacddcd 4II3013 aacddcc 4IO3013 aacbcad aacddcd 4133013 aacddcc 412 30 13 aacbcad aacddcd 4153013 aadccdd 414 30 13 aadbdac aacddcd 4173013 aadccdd 4163013 aadbdac abbacda 4203013 cacddaa 4183013 cacddaa aacddcd 423 3 oi3 aacddcc 422 3 O i3 aacddcc aacddcd 4253013 aadccdd 424 3 O i3 aacddcc aacddcd 427 3 oi3 aadccdd 4263013 aadccdd 4583013 babddcd 4563013 babddcd aadbdcd alg.
(J)
(M) (L) abcbddd aacddcd bacbbda abdacdb abcbddd aabddad aaabcdb aaabcdb aaabcdb aaabcdb abcbddd abcbddd abcbddd abcbddd
abcbddd abcbddd abcbddd abcbddd abcbddd abcbddd
aaabcbd aaabcbd aaabcbd aaabcbd aacddcd aacddcd aacddcd aacddcd aadcccd aadcccd badbcbd babbdbb aacddcd aacddcd aadcccd aacddcd aacddcd aacddcd aacddcd aadcccd aadcccd badbcad aacaaab aacaaab aacaaab
aacbcdd aacddcd aaabcdb aaabcbd aaabcdb aaabcbd ccdaaad aaabcdb aaabcbd aacddcd aacddcd aacddcd aacddcd abbacda aacddcd aacddcd aacddcd aadbdcd
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. 4603O13 462 3 oi3 472 3 O i3 476 3 oi3 478 3 oi3 496 3 oi3 5123013 5163013 5203013 5243013
(J) babddcd babddcd babddcd babddcd babddcd bacccbc bacccbc bccddbd bacddbd bccddbd
(L)
(M) alg. abddddd 4613oi3 abddddd 4633013
aadbdcd
474 3 O i3
aacbcdc aacbcdc
5OO3013 514 3013 5I83013
aadbdcd
5223013
5373013
5393oi3 54I3013
5433oi3 5453013
babbcbb 534 3 O i3 babbcbb 5363013 aabccad 5383013 aabccad 540 3 O i3 aacbbad 542 3 oi3 aacbbad 544 3 oi3 aabddad 548 3 oi3 aaaadbd 5503013 aaaadbd 5523013 abcdacc 554 3 O i3 abcdacc 5563013 babbcdd 5583013 abbbbad 560 3 oi3 babbcdd 5623013 abbbbad 5643oi3 abdbadd 5663013 abbbbad 5683013 abdbadd 5703013 abbbbad 5723013
5493oi3 aaaaddb 55I3013 aaaaddb 5533013 aaddacc 5553013 aaddacc 5573013 abbbcad 559 3 oi3 abbbcad 56I3013 abbbcad 5633013 abbbcad 5653013 abbbcad 5673013 abbbcad 5693013 abbbcad 57I3013 abbbcad 5743oi3 abbbcbd 5783013 abbbcbd
aaaaddb aaaaddb aaddbdc aaddbdc aadbbbc aadbbbc aadbbbc aadbbbc aadbbbc aadbbbc aadbbbc aadbbbc abbbcbd abbbcbd
58I3013
abddddd abddddd abddddd abddddd babbcbb babbcbb babbdcc babbdcc abbbcbd aacbbac abbbcbd babbcbb abbbcbd aacbbac abbbcbd babbcbb
5873013
5893oi3 5913013 5933013 5953013 5983013 6OO3013
abbbcbd abbbcbd
6033O13 6O63013 6O83013 6H3013
abbbcbd abbbcbd
5763013 58O3013 5823013 5843013 5863013
abddddd abddddd bacccbc aacbcdc bacddbd aadbdcd bacddbd aadbdcd bccddbd
aaaaddb aaaaddb aaddbdc aaddbdc abbbcad abbbcad abbbcad abbbcad abbbcad abbbcad abbbcad abbbcad aabbbcb aabbbcb aabbbcb abbbcbd aabbbcb abbbcbd
aaaaddb aaaaddb aadcbcc aadcbcc aadbbbc aadbbbc aadbbbc aadbbbc aadbbbc aadbbbc aadbbbc aadbbbc aabbbcb aabbbcb aabbbcb abbbcbd aabbbcb abbbcbd
5883013 5903013 592 3 oi3 594 3 O i3 5963013
abbbcbd abbbcbd
5993013 602 30 13 604 3 013
abbbcbd abbbcbd abbbcbd abbbcbd
607 3 013 6IO3013 6I23013
(M) abddddd abddddd
babddcd aadbdcd
5323013
5353013
5853013
(L)
abddddd 4773oi3 abddddd 4793013
5333013
5833013
(J)
abbbcbd abbbcbd aabbbcb aabbbcb
babbcbb babbcbb aabccac aabccac aacbbad aacbbad aabddad aaaadbd aaaadbd aabccac aabccac aacbbac aacbbac aacbbad aacbbad aacbbac aacbbac aacbbad aacbbad aabbbda aabbbda aabbbda abdaadd aabbbda abdaadd babbcbb babbcbb aabccac aabccac aacbbac babbcbb babbcbb aacbbac babbcbb babbcbb
3, FAILURES OF (J), (L), (M) AMONG luie-131flisie AND lsois-3013SOis
alg6143013 6183013 6223013 6263013 6293013 631.3013 6333013 6353013 6373013 6393013 641 3 O i3 6433013 6453013 6493013 65I3013 6533013 6553013 6573013 6593013 66I3013 6633013 6663013 6673013 6693013 6773013 6793013 68I3013 6833013 6853013 6873013 6893013 69I3013 6933013 6953013 6973013
(J) abbbcbd abbbcbd abbbcbd abbbcbd
(L) abbbcbd abbbcbd abbbcbd abbbcbd
alg.
aaaaddb bacccda bacccda bacccda bacccda bacccda bacccda bacccda bacccda
aaaaccb aaaacdb cabccdb bbbccdd bbbccdd aaaabbd aaaabbd
aaaaccb aacbcdb
aaaabbd aaaabbd
(L)
634soi3 cbbddba
6363013 6383013 6403013 642 3 oi3 644 3 oi3 bccddca 6483013 aaaaddb aaaaddb aaaadbd 65O3013 aaaaddb aaaaddb aaaadbd 6523013
aaaaddb ahbccda abbccda aaddacc aaddacc abbccda abbccda aaddacc aaddacc
(J)
(M)
6I63013 aabbbcb aabbbcb 62O3013 aabhbcb aabbbcb 6243013 aabbbcb aabbbcb babbdbc 6283013 habbdhb 63O3013 babbdbb babbdbc 6323013 babbdbb
babbdbb aabccad aabccad aabccad aabccad aabddad
6993oi3 7OI3013 7033013 7I83013 72O3013 7223013 7243013 7263013 7283013 73O3013
(M)
aaaadbd babbdcc babbdcc abcdacc abcdacc abdcadd abdcadd abcdacc abcdacc abddddd abddddd abddddd babbdbb babbdbc babbdbb babbdcc babbdcc babbdcc babbdcc babbdcc babbdcc babbdcc babbdcc aaaacbc aabaadb abccccc babbcbb babbcbb aaaabdb aaaabdb
654soi3 6663013 6583013 66O3013 6623013
664soi3 6663013 6683013 6763013 6783013 68O3013
cbbddba bccddca aaaaddb aaaaddb aaaaddb abbbdbc abbccda aaddacc aaddacc abbbdbc abbccda aaddacc aaddacc
aaaaddb aaaaddb aaaaddb abbbcbd bacccda abbbcbd bacccda abbbcbd bacccda abbbcbd bacccda
682soi3 684soi3 6863013 6883013 6903013
abbbdbc abbbcbd
6923oi3 abbbdbc abbbcbd 694soi3 696soi3 abbbdbc abbbcbd 6983013 7OO3013 7023013 7173013 7193013 7213013 7233013
725soi3 727soi3 729soi3 73I3013
abbbdbc abbbcbd aaaabbd aaaaccb dcddcbb bbdccbb bbbccdd aaaabbd aaaabbd aaaabbd
aaaabbd aaaaccb
aaaabbd aaaabbd aaaabbd
aabcbda aabcbda aabcbda aabcbda aabddad aabddad aaaadbd aaaadbd aaaadbd aabbbda aabccad aabbbda aabccad aabbbda aabccad aabbbda aabccad abdaadd abdaadd abdaadd babbdbc babbdbb babbdbb babbdcc babbdcc babbdcc babbdcc babbdcc babbdcc babbdcc babbdcc aaaabdb aaaacbc dacbbdd babbcbd babbcbb aaaabdb aaaabdb aaaabdb
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. 7323013 734 3O i3 7363013 7383013 7403013 742 3 oi3 744 3 oi3 746 3 oi3 7483013 7503O13 7523013 754 3 oi3 7563013 7583013 76O3013 7623013 764 3O i3 7663013 7683013 77O3013 7723013
(J) aaaabbd aaaabbd aabbdcc aabbdcc aabbdcc aabbdcc aaccbdd aabbadd aaccbdd aaccbdd aaccbdd aaccbdd aabccdd aabccdd aabbadd aabbadd aabccdd aabccdd aabccdd aabccdd
7743oi3 babccdc 7763013 7783013 babccdc 78O3013 7823013 cacddbd 7843013 cacddbd 7873013 abbbccd 7903013 cacddbd
7923oi3 cacddbd 7943oi3 7963013 799 3 oi3 8033013 8O63013 8O83013 8IO3013 8I23013 8143013 8163013 8183013 8203013 8253013 8273013
abbbccd abbbccd bbcccad baddacc aaaabbd aabcdad aabcdad aacbcbd caaabad abddbaa babcccc bbcccad 8293oi3 aaaabbd
(M) alg. (L) aaaabbd aaaabdb 7333013 aaaabbd aaaabdb 7353013 aabccac 7373013 aabccad 7393013 aabccac 741 30 13 aabccad 743 3 oi3 aacbcdb aacddad 745 3 oi3 aacbcdb abccccc 747 3 oi3 aaccbdd aacddad 749 3 oi3 aaccbdd aacddad 75I3013 aaccbdd bacdddd 7533013 aaccbdd abccccc 7553013 aacbcdd aacddad 7573013 abcbddd aacddad 7593013 aacbcdd abdbbbb 76I3013 abcbddd abdbbbb 7633013 aacddad 7653013 aacddad 7673013 bacccdd 7693oi3 bacdddd 77I3013 abccccc 7733013 aacbcdc acddddd 7753013 acddddd 7773013 abccccc 7793oi3 abccccc 78I3013 aadbdcd 7833013 aadbdcd 7853013 aabacad accabdd 7893013 acddddd 79I3013 acddddd 7933oi3 acddddd 7953013 acddddd 7973013 aabacad baacaad 8OI3013 aabacad baacaad 8053013 badbccc bbcccda 8073013 baccdcc 8093013 aaaabbd aaaabdb 8H3013
caaabad caaabad badbbdb badbccc aaaabbd
baccdcc aacaaab aacaaab bbbadbd babbdbd babbdbd aaaabdb
8133013 8153013 8173013 8193013 8213013
8263oi3 8283013 8303013
(J) aaaabbd aabbbdc aabbbdc aabbbdc aabbbdc aabbdcb aabbadd aabdbdc aabdbdc aabdbdc aabdbdc aabbdcb aabbdcb aabbadd aabbadd aabccdd aabccdd aabccdd aabccdd abccddb aabdbdc abbbccd aabdbdc abbbccd aabdbdc abbbccd aabdbdc aabdbdc abbbccd aabdbdc abbbccd abbbccd abbbccd babacdc babacdc aaaabbd aabcdad aabcdad aacbcbd caaabad aaaabcb bacccbc bbcccad bbcccad aaaabbd
(M) (L) aaaabbd aaaabdb aabcbda aabcbda aabcbda aabcbda aabbdcb aacddad aabbdcb abccccc aacbcdc aacddad aaccbdd aacddad aacbcdc abbccbd aaccbdd abbccbd aabbdcb aacddad aabbdcb aacddad aabbdcb accbcdd aabbdcb acdbadd aacddad aacddad bacbbdd bacbbdd aabacad abccccc aabacad abbacbd aabacad abbadcc aabacad abbacbd aabacad abbadcc aabacad abbacbd aabacad accabdd aabacad abbacbd aabacad abbacbd aabacad accabdd aabacad abbacbd aabacad accabdd aabacad baacaad aabacad baacaad bacbccc abcabbc abcabbc aaaabbd aaaabbc baaacda aaabacd baaacda aaabacd aacbcdc aacaaab caaabad aacaaab aabbdac aacbcdc badbccc bacdddd baccdcc aaaabbd aaaabdb
3. FAILURES OF (J), (L), (M) AMONG Ii3i 6 -1316 1 3 1 6 AND 13013-30133013
alg. 831.3013 8333013 8353013 8373013 8393013 841 30 13 8433013 8453013 8473013 8493013 85I3013 8533013 8553013 8573013 8593013 86I3013 8633013 8653013 8673013
8693oi3 87I3013 8733013 8753013 8773013 8793013 88I3013 8833013 8853013 8873013 8893013 89I3013 8933013 8953013 8973013
8993oi3 9OI3013 9033013 9053013 907 30 13 9093013 9II3013 9133013 9153013 9173013 9193013
(M) (L) aabddcc bacbccc bacdddd aabddcc bacadcc bbdccdd babbdbd bbdccdd babbdbd bbddbcc babbdbd babbdbd bbddbcc aaaabbd aaaabbd aaaabdb aaaabbd aaaabbd aaaabdb aaaabbd aaaabbd aaaabdb aaaabbd aaaabbd aaaabdb bacdddd aabddcc baccdcc aabddcc bacdddd aabddcc baccdcc aabddcc aacbcbd aacbcdc aacaaab acdddcb abcdcdd aacaaab aacbcbd aacbcdc aacaaab caaabad caaabad aacaaab abcbdda abcbddd aacddad aabbadd abcbddd acdbadd bacccbc aacbcdc aacddad aacddad bacccbc aacbcdc bacdddd bacdddd aacbcbd aacbcda bbdccdd aacddab aacbcbd aacbcda bbddbcc aacddab aabcdbc aacbcdd aacddad abcbdda abcbddd aacddad aabbadd aacbcdd accbcdd aabbadd abcbddd acdbadd aacddad aacddad dbbddcc bacdddd dbbddcc bacdddd aaaaddc aaaaddc aaaadcd aaaaddc aaaaddc aaaadcd aabadbc bacadcc aabadcb aabadbc bacadcc aabadcb aadcdcd babaccc aadcdcd aadcdcd bacadcc aadcdcd aadcdcd babaccc aadcdcd aadcdcd bacadcc aadcdcd aaaaddc aaaaddc aaaadcd
(J)
alg.
(J)
(L)
8323013 aabddcc 8343013 aabddcc 8363013 bbdccdd 8383013 bbdccdd 8403013 bbddbcc 842 3 O i3 bbddbcc 844 3 oi3 aaaabbd aaaabbd
8463oi3 aaaabbd 8483013 aaaabbd 85O3013 aaaabbd 8523013 aabddcc 8543oi3 aabddcc 8563013 aabddcc 8583013 aabddcc 86O3013 aacbcbd 8623013 acdddcb 8643013 aacbcbd 8663013 caaabad 8683013 abcbdda 87O3013 aabbadd 8723013 8743013 8763013 8783013 88O3013 8823013 8843013 8863013 8883013 8903013 8923013 894 3 O i3 8963013 8983013 9OO3013 902 3 013 9043013 9O63013 9O83013 9IO3013 912 3 013 9143013 9163013 9183013 9203013
aaaabbd aaaabbd aaaabbd
abcdcdd abcdcdd caaabad caaabad abcbddd abcbddd
dcdddca aacbcbd bbdccdd aacbcbd bbddbcc aabcdbc abcbdda aabbadd aabbadd
aacbcdd abcbddd aacbcdd abcbddd
dbbddcc dbbddcc aaaaddc aaaaddc aaaabcd aaaabcd aadcdcd aadcdcd aadcdcd aadcdcd aaaaddc
aaaaddc aaaaddc daccddd daccddd bacbccc daccddd daccddd daccddd aaaaddc
(M) bacdddd baccdcc bacdddd baccdcc bacdddd baccdcc aaaabdb aaaabdb aaaabdb aaaabdb bacdddd baccdcc bacdddd baccdcc aacaaab aacaaab aacaaab aacaaab aacddad acdbadd aacddad aacddad bacdddd bacdddd aacbcda aacddab aacbcda aacddab aacddad aacddad accbcdd acdbadd aacddad aacddad bacdddd bacdddd aaaadcd aaaadcd aaaabbc aadaacd aadcdcd aadcdcd aadcdcd aadcdcd aaaadcd
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. 921 3 oi3 923 3 oi3 925 3O i3 9273013 929 3 oi3 93l3oi3
933soi3 9353013 9373013 9393013 9413013 9433013
945soi3 9473013 9493013 9513013 9533013 955 3 oi3 957 3 oi3 9593013 96I3013 9633013 965 3 oi3 967 3O i3
(J) aaaaddc aaaaddc aaaaddc aadbdbc aadbdbc aadbdbc aadbdbc abdcdac abdcdac aaddacc aaddacc aaddcbd aaddcbd aaddacc aaddacc abddbcc abddbcc aaddacc aaddacc aacbcbd abccdad
(L) aaaaddc aaaaddc aaaaddc aadbdcd aadbdcd aadbddc aadbddc abdcccd abdcccd abdcccd abdcccd aadbdcd aadbdcd aadbddc aadbddc abdcccd abdcccd abdcccd abdcccd aacbcdc aadbccd
bacccbc aacbcdc 969soi3 dacdcac
97I3013 973 3 oi3 9753013 9773013 979 3 oi3 9813013 9833013 9853013 9873013 99I3013
9933oi3 995soi3 9973013 999 3 oi3 IOOI3013 10033013 1007 30 13 10093013 10113013 10133013
aacbcbd abbccad aacbcbd abbccad aacbcbd aacbcbd abddbcc aacbcbd aacbcbd abddbcc abddbcc abddbcc abddbcc abddbcc abddbcc abddbcc abddbcc abddbcc
aadbdcd cacbcdd aadbdcd aadbdcd abdccdc abdccdc abdccdc abdccdc abdccdc aadbdcd aadbdcd abdccdc abdccdc abdccdc abdccdc abdccdc
(M) aaaadcd aaaadcd aaaadcd aadbaba aadbaba aadbaba aadbaba aadbaba aadbaba aadbaba aadbaba bccacdd bccacdd baccdcc baccdcc acddddd acddddd acddddd acddddd acddddd acddddd acddddd acddddd acddddd acddddd acddddd acddddd accbcdd dacbdbb accbcdd acddddd accadcb accadcb baabdad accadcb accadcb acddddd acddddd bccacdd bccacdd acddddd acddddd acddddd acddddd
alg. 922 3 oi3 924 3 oi3 9263013 9283013 9303013 932 3 oi3
9343oi3 9363013 9383013 9403013 942 3 oi3 944 3 oi3
9463oi3 9483013 95O3013 952 3 oi3 954 3 oi3
9563oi3 9583oi3 9603013
9623oi3 9643013 9663013 9683013
9703oi3 9723oi3 9743013 9763013 978 3 oi3 9803013 982 3 oi3 984 3 oi3 9863013 9893013 992 3 O i3
9943oi3 9963oi3 9983013 IOOO3013 10023O13 10053013 10083013 10103O13 10123O13 10143013
(M) aaaadcd aaaadcd aaaadcd abcccbb cabdbbc baccdcc baccdcc abcccbb acddddd acddddd acddddd daaccbd daaccbd baccdcc baccdcc acddddd acddddd acddddd acddddd acddddd acddddd acddddd acddddd bacccbc aacbcdc acddddd acddddd acddddd acddddd aacbcbd aadbdcd accbcdd abbccad aacbcbd cacbcdd accbcdd abbccad acddddd cacddbd aadbdcd cabdbbc cacddbd aadbdcd cabdbbc abddbcc abdccdc dacadbb cacddbd acddddd cacddbd acddddd acddddd acddddd cacddbd aadbdcd cacddbd aadbdcd abddbcc abdccdc cacddbd acddddd cacddbd acddddd acddddd acddddd
(J) aaaaddc aaaaddc aaaaddc aaddcbd aaddcbd aaddacc aaddacc acccdbd acccdbd aaddacc aaddacc aaddcbd aaddcbd aaddacc aaddacc acccdbd acccdbd aaddacc aaddacc aacbcbd abccdad
(L) aaaaddc aaaaddc aaaaddc aadbdcd aadbdcd aadbddc aadbddc abdcccd abdcccd abdcccd abdcccd aadbdcd aadbdcd aadbddc aadbddc abdcccd abdcccd abdcccd abdcccd aadbccd aadbccd
3, FAILURES OF (J), (L), (M) AMONG luie-131flisie AND lsois-3013SOis
alg10153O13 10173O13 10193013 10213O13 10233O13 10253013 10273O13 10293O13 10313013 10333O13 10353O13 10373013 10393O13 10413013 10433013 10453O13 10473013 10493013 10513O13 10533013 10553013 10573O13 10593013 10613013 10633O13 10653013 10673013 10693O13 10713013 10733013 10753O13 10773013 10793013 10813O13 10833013 10853013 10883013 10913013 10953013 10973O13 11013013 11043013 11063013 11083013 11103013
(J) aadbbce aadbbcc baaccad baaccad baaccab baaccad baaccab baaccad aadbbcc aadbbcc aadbbcc aadbbcc aadbdbc aadbdbc aadbdbc aadbdbc abcddcc abcddcc abcddcc abcddcc abbddcc abbddcc abbddcc abbddcc abbddcc abbddcc abbddcc abbddcc aacbcbd abbddad aacbcbd cbbbcad abcbdad abcbdad baaccad baaccad bacccbc abccddd baaccad baaccad baaccad aacbcbd bbbccad aacbcbd bbbccad
(M) (L) bacbccc aadbbab aadbbab bacadcc abcadcb bacadcc abcadcb babaccc cabbbcc bacadcc cabddcc babaccc bacadcc bacadcc baccdcc aadbbab aadbbab aadbbab aadbbab abccddd aadccab abccddd aadccab abccddd aadccab abccddd aadccab abdcccd aadccab abdcccd aadccab abdcccd aadccab abdcccd aadccab abccddd aadddca abccddd aadddca abccddd aadddca abccddd aadddca abdcccd cabddcc abdcccd cabddcc abdcccd baccdcc abdcccd baccdcc aacbcdc abdbdda abcdcdd abdbdda aacbcdc bacddbb bacddbb abccddd baabcad abccddd badbcad bbccacb cbcacdd aacbcdc abccddd cbcacdd aacbcdc cabcaad cabcaad cbcacdd cabcabd
alg. IOI63013 IOI83013 IO2O3013 1022 3 oi3 1024 3 013 IO263013 IO283013 10303013 10323013 10343O13 10363013 10383013 10403O13 10423013 1044 3 013 10463013 10483013 10503O13 10523O13 10543013 10563013 10583013 10603013 10623O13 1064 3 oi3 IO663013 IO683013 IO7O3013 10723013 10743O13
10763oi3
10783013 IO8O3013 10823O13 1084 3 013 10873O13 10893O13 10933013 10963013 10993O13 11033013 11053O13 11073O13 cabcabd 11093O13 11113013
(M) (J) (L) aadbbcc badbccc aadbcac aadbbcc aadbcac badcbcc abccbbc abdbbac badbbcd babcccc bacbccc cabbbcc cabddcc cbcccba baccdcc cbcccda baccdcc aadbbcc aadbcac aadbbcc aadbcac aadbbcc aadbcac aadbbcc aadbcac abcbdad abcccbb abcbdad cabddcc abcbdad baccdcc abcbdad baccdcc accddab abcccbb accddab cabddcc accddab baccdcc accddab baccdcc cbbddcc cabddcc cbbddcc cabddcc cbbddcc baccdcc cbbddcc baccdcc cbbddcc cabddcc cbbddcc cabddcc cbbddcc baccdcc cbbddcc baccdcc aacbcbd abcdcdd abdbdda abbddad abcdcdd abdbdda aacbcbd bbcccda bbbccad dadbbcb bbccacb dadbbcb bbccacb abccddd aacbcdc cabcaad abccddd abccddd cabcaad abccddd abccddd cbcacdd bacccbc aacbcdc baaccad cbcacdd aacbcbd bacddbb bacddbb bbdccdd bacddbb aacbcbd bacddbb bbddbcc aacbcbd abccddd accadcb
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. 11133013 11173013 11213013 11253013 11293013 11333013 11373013 11413013 11443013 11463013 11483013 11503013 11523013 11543013 11563013 11583013 11603013 11623013 H663013 11683013 11703013 11723013 11743013 11763013 11783013 11803013 11823013 11843013 H863013 11883013 11903013 11923013 11943013 11963013 11983013 12003013 12023013 12043013 12073013 12113013 12153013 12193013 12233013 12263013 12283013
(J) aacbcbd abccddd aacbcbd abcddcc abbddcc abbddcc abbddcc abbddcc aaaabbc aaaabbc
abcccbd abcccbd cacbbdb bacbbcc cabdacc bacbbcc bacbbcc bacbbcc
cacccda cacccda caccadd caccadd caccadd caccadd cacbbdb cacbbdb cacbbdb cacbbdb cacbbdb cacbbdb aacccbc abccccd aacccbc abccccd abccccd
(M) (M) alg. (L) (J) (L) abccddd accadcb 11153013 abccddd abccddd abccddd 11193013 aacbcbd abdccdc accadcb abdccdc accadcb 11233013 abcddcc abdccdc abdccdc 11273013 abbddcc abccddd abccddd 11313013 abbddcc abccddd abccddd 11353013 abbddcc abdccdc abdccdc 11393013 abbddcc abdccdc babbcbc abdccdc 11433013 baccccc baccccc 11453013 aaaabbc aaaabcb 11473013 aaaabbc aaaabbc aaaabcb aaaabbc aaaabcb 11493013 aaaabbc aaaabbc aaaabcb baccccc bacbbcc 11513013 baccccc bacbbcc 11533013 aacddad aacbbab 11553013 cabccbd 11573013 abcccbd abcbdcc acdacbd abcbdcc acdacbd 11593013 abcccbd abcbdcc acdacbd cabcddd abcbdcc acdacbd 11613013 cabcddd 11653013 abcbdca abccccd abdaaaa baabdcc 11673013 abcbdca abccccd abdaaaa bacbbcb baabdcc 11693013 abcbdca abccccd abdaaaa cabcacc accbacc 11713013 abcbdca abccccd abdaaaa bacbbcb accbacc 11733013 abcbdca abccccd abdaaaa bacbbcb baabdcc 11753013 abcbdca abccccd abdaaaa bacbbcb accbacc 11773013 abccccd abccccd cabccad cabccdd 11793013 abccccd abccccd cabccad cabccdd 11813013 abccccd abccccd accccad cacccda accccad 11833013 abccccd abccccd accccad cacccda accccad 11853013 abccccd abccccd cabccad daccddd cabccdd 11873013 abccccd abccccd cabccad daccddd cabccdd 11893013 abccccd abccccd accccad cacccda accccad 11913013 abccccd abccccd accccad cacccda accccad 11933013 aacbcbc aacbccc aacccba bddbadc 11953013 aacbcbc aacbccc aacccba cabdbbc 11973013 abccccd abccccd bacbdac 11993013 abccccd abccccd bacbdac 12013O13 aacbcbc aacbccc aacccba cabdbbc 12033O13 abccccd abccccd bacbdac 12053013 aacccbc aacbccc aacccda aacbccc aacccda 12093O13 abccccd abccccd abccccd 12133013 aacccbc aacbccc aacccda aacbccc aacccda 12173013 abccccd abccccd abccccd 12213013 abccccd abccccd abccccd 12253013 abccccd abccccd bacbbcc bacbbcc 12273013 abccccd abccccd baccccc baccccc 12293013 abccccd abccccd
3, FAILURES OF (J), (L), (M) AMONG luie-131flisie AND lsois-3013SOis
algI23I3013 12333013 12373013 1241 3 oi3 12453013 12473013 1249 3 oi3 I25I3013 12533013 I2563013 I2583013 12603013 I2623013
(J) abceeed aacccbc abceced aacccbc bacbdad bbcbdac babcccc cbcccba babcccc
(L) abceced aacbccc abceced aacbccc daebbdb daebbdb bacbccc bacbccc
baaacad baaacad baaacad baaacad
1264soi3 12673013 cbcccba 1269 3 oi3 bbcbdac daebbdb 12713013 bbcbdac daebbdb 12733013 12763013 12773013
1279soi3 I28I3013 12833013 12853013 12873013
abcccbd baaacad abcccbd baaacad
baaacad baaacad baaacad baaacad
1289soi3 12913013 12933013
1295soi3 1297soi3 bacbdad caaabad 12993oi3 caaabad caaabad I3OI3013 aacbcbd aacbede 13033013 caaabad caaabad 13053013 aacbcbd aacbede 13073013 caaabad caaabad 13093013 cabcbdb I3II3013 cabcbdb 1314 3 013 13163013 13213013 dbbbdca daebbdb 13233013 dbbbdca daebbdb 13253013 aacbcbd 13273013
13293oi3 aacbcbd I33I3013
(M) alg. baccccc 12323oi3
abeebbe abeebbe cabbbec baccdcc cabbbec baccdcc aabaaac aabaaac cabdedd baccdcc baccdcc aedbbbb aedbbbb badcede baccdcc badcede baccdcc aabaaac aabaaac aabaaac aabaaac badcede baccdcc badcede baccdcc aacaaab aacaaab aacaaab aacaaab aacaaab aacaaab bbccacb bbccacb cabdedd cabdedd aacddad aedbbbb aaebeda aacddad aaebeda cadecbd
12353013 12393013 1243 3 oi3 12463013 12483013 I25O3013 I2523013 12563013 12573013 12593013 I26I3013 12633013 12663013 I2683013 I27O3013 12723013 1274 3 oi3 12763013 I2783013 I28O3013 12823013 1284 3 oi3 12863013 12883013 12903013 1292 3 oi3 1294 3 oi3 12963013 1298 3 oi3 I3OO3013 13023013 13043O13 13063013 13083013 13103O13 13133013 13153013 13173013 13223013 1324 3 oi3 13263013 13283013 13303O13 13323013
(J)
(L)
(M) baccccc
aacccbc aacbccc abceced abceced abceced abceced abdbdda bacbdad baccdcc bacdabb cabdedd baccdcc cbcccba baccdcc baaacad baaacad aabaaac baaacad baaacad aabaaac babcccc bacbccc cabbbec cbcccba baccdcc babcccc bacbccc cabbbec baccdcc bacdabb baccdec bacdabb baccdcc badcede baccdcc badcede baccdec abcccbd baaacad aabaaac baaacad baaacad aabaaac abcccbd baaacad aabaaac baaacad baaacad aabaaac badcede baccdec badcede baccdcc baebbaa caaabad aacaaab baebbaa caaabad aacaaab aacbcbd caaabad aacaaab caaabad caaabad aacaaab aacbcbd caaabad aacaaab caaabad caaabad aacaaab cabdedd baecebe aacbede cabdedd cabdedd baecebe aacbede bacdabb aacddad bacdabb badecbd aacbcbd aaebeda aacddad aacbcbd aaebeda cadecbd
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. 13333013 13353013 13373013 13393013 1342 3 oi3 1344 3O i3 13493013 13513013 13533013 13553013 13573013 1359 3 oi3 I36I3013 13633013 1365 3 oi3 13673013 1369 3 oi3 13733013 13753013 13773013 1379 3 oi3 I38I3013 1383 3 oi3 13853013 13873013 13893013 13913013 13933013 13953013 13973013 13993013 1401 3 oi3
(J) abcccbd
(L)
abcccbd
aaaadbc aaaadbc aaaaddc aaaaddc aaaaddc aaaaddc
aaaadbc aaaadbc aaaaddc aaaaddc aaaaddc aaaaddc
daccddd daccddd baaccab baaccab
daccddd daccddd babaccc babaccc
baaccab daccddd baaccab daccddd aaaaddc aaaaddc aaaaddc aaaaddc aaaaddc aaaaddc abdcdac abdcdac aaddacc aaddacc abdcdac abdcdac aaddacc aaddacc baaccab
babaccc daccddd babaccc daccddd aaaaddc aaaaddc aaaaddc aaaaddc aaaaddc aaaaddc
14033013 daccddd 14053013 daccddd 14073013 daccddd 14093013 daccddd 14113013 14133013 14153013 14173013 aaddacc 14193013 aaddacc 14213013 baaccab daccddd 14233013 caccadd daccddd 14253013 aaddacc daccddd 14273013 aaddacc daccddd
(M) acdaccd bbdccbd acdaccd bbdccbd cabdcdd cabdcdd aaaadcb aaaadcb aaaadcd aaaadcd aaaadcd aaaadcd aadcdab aadcdab abccbbc abdaaaa cabbbcc baccdcc baccdcc cabbbcc cddacdd baccdcc baccdcc aaaadcd aaaadcd aaaadcd aaaadcd aaaadcd aaaadcd abcccbb abdaaaa abdaaaa abdaaaa abcccbb abdaaaa abdaaaa abdaaaa dabcccc dabcccc baccdcc baccdcc cadccdd cadccdd baccdcc baccdcc
alg. 13343013 13363013 13383013 13413013 13433013 13453013 1350soi3 13523013 13543013 13563013 13583013
(J) abcccbd
(M) acdaccd cabdcdd acdaccd cabdcdd cabdcdd
aaaadbc aaaadbc aaaaddc aaaaddc aaaaddc aaaaddc aaaabcb
aaaadcb aaaadcb aaaadcd aaaadcd aaaadcd aaaadcd aaaabbc aaddcab aaaabbc baccdcc cabbbcc baccdcc baccdcc cabbbcc cddacdd baccdcc baccdcc aaaadcd aaaadcd aaaadcd aaaadcd aaaadcd aaaadcd abcccbb cabdbbc baccdcc baccdcc abcccbb cabdbbc baccdcc baccdcc dabcccc dabcccc baccdcc baccdcc cadccdd cadccdd baccdcc baccdcc
abcccbd bccddca bccddca aaaadbc aaaadbc aaaaddc aaaaddc aaaaddc aaaaddc aaaabdb aaaadbd aaaabdb acddcaa babcccc bccddaa
13603013 13623013 1364 3 oi3 13663013 13683013 I37O3013 13743013 I3763013 13783013 babcccc 13803O13 daccddd 13823013 bccddaa 1384 3 oi3 daccddd I3863013 aaaaddc I3883013 aaaaddc 13903013 aaaaddc 1392 3 oi3 aaaaddc 13943013 aaaaddc 1396 3 oi3 aaaaddc 1398soi3 1400soi3 14023013 14043O13 14063O13 1408 3 oi3 1410 3 oi3 14123013 1414 30 13 14163013 14183013 14203013 14223013 1424 3 oi3 1426soi3 14283013
(L)
daccddd daccddd bacbccc
bacbccc daccddd daccddd daccddd aaaaddc aaaaddc aaaaddc aaaaddc aaaaddc aaaaddc
aaddacc aaddacc caccadd caccadd aaddacc aaddacc
daccddd daccddd daccddd daccddd
aaddacc aaddacc caccadd caccadd aaddacc aaddacc
daccddd daccddd daccddd daccddd
3. FAILURES OF (J), (L), (M) AMONG Ii3i 6 -1316 1 3 1 6 AND 13013-30133013
(M) aaccbcb 1429 3 oi3 aaccbcb 14313013 bacbbda aaccbcb 1433 3 oi3 dacddbc bacbbda aaccbcb 14353013 aacbcdc aacdcdb aacbcda 14373013 aacbcda 14393013 aacdcdb aacdada 1443 3 oi3 babacad 1446 3 oi3 bacccbc aacbcdc cadbcdd cadbcdd 1448 3 oi3 dacddbc cadbcdd 14503013 dacddbc cadbcdd 1452 3 oi3 dacddbc badcbdb 1454 3O i3 badcbdb 1458 3 oi3 1462 3O i3 bacccbc aacbcdc 14703013 bacccbc aacbcdc abddbdb 14783013 cacbbda abcbbad 14803013 bacbbda acdbadd 1482 3O i3 cacbbda abcbbad 1484 3 oi3 bacbbda abbccad bccacda 1486 3 oi3 bccacda I4883013 abbccad 14903013 abbccad 1492 3O i3 abbccad bccacda 1494 3 oi3 abbccad bccacda 1496 3 oi3 abbccad cadbcdd 1498 3 oi3 abbccad cadbcdd I5OO3013 abbccad cabdbbc 15023013 cabdbbc 1504 30 13 cabdbbc I5IO3013 cabdbbc 15123013 1534 3O i3 aadbcac daaabca aaacbad baccdcc I5363013 aadbcac aadbcac I5383013 baccdcc 1540 3 oi3 aadbcac aadbcac 1542 3O i3 baccdcc 1544 3 oi3 aadbcac abccbbc 1546 3 oi3 bccddad baccdcc 1548 3 oi3 abccbbc 15503013 baccdcc 1552 3O i3 1554 3O i3 babcccc bacbccc cabbbcc baccdcc I5583013 bccddad baccdcc I56O3013 1562 3O i3 babcccc bacbccc cabbbcc alg.
(J)
(L)
alg. 1430 3 oi3 1432 3 oi3 1434 3 oi3 1436 3 oi3 1438 3 oi3 14413013 14453013 14473013 1449 3 oi3 1451 3 oi3 14533013 14573013 14613013 1469 3 oi3 1477 3 oi3 14793013 14813013 1483 3 oi3 1485 3 oi3 14873013 14893013 14913013 1493 3 oi3 1495 3 oi3 1497 3 oi3 1499 3 oi3 1501 3 oi3 15033O13 15093013 I5II3013 15333013 15353013 15373013 15393013 15413013 1543 3 oi3 1545 3 oi3 1547 3 oi3 15493013 15513013 15533013 15573013 1559 3 oi3 I56I3013 15653013
(M) (J) (L) aaaadbc aacaabc aaaadbc aacaabc aaaadbc aacaabc aaaadbc aacaabc bacccbc aacbcdc aacdada babacad aacdcdb aacbcdc aacbcda aacbcda aacdcdb aacdada babacad aacdada babacad badcbdb badcbdb bacccbc aacbcdc bacccbc aacbcdc abddbca cabacad abcbbad bacbbda abddbca cabacad abcbbad bacbbda aacdcdb abccccd aacbcda aacdcdb abccccd aacbcda abddbca abbccad abddbca abbccad aacdcdb abccccd aacbcda aacdcdb abccccd aacbcda abddbca abbccad abddbca abbccad cabcaad abdcdac cabcaad abdcdac cabcaad abdcdac cabcaad abdcdac aadbcac daaabca aaacbad abccbbc aadbcac aadbcac bacbccc cabbbcc baccdcc aadbcac aadbcac bacbccc cabbbcc baccdcc aadbcac abccbbc bccddad baccdcc abccbbc baccdcc baaccab babaccc cabbbcc baaccab babaccc baccdcc baccdcc baaccab babaccc cabbbcc baaccab babaccc baccdcc
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg.
(J)
I5663013 cbcccba I5683013 15703013 bacdabb 15723013 bacdabb 15743013 15763013 15783013 15803013 I5823013 15843013 I5863013 I5883013
1590soi3 1592 3 oi3 15943013 15963013 1598 3 oi3 I6OO3013 16023013 1604 30 13 I6O63013 I6O83013 I6IO3013 16123013 16143013 16163013 16183013 16203013 1622 3 oi3 16253013
bccddad bbbbdac
(L)
(M) baccdcc baccdcc baccdcc baccdcc caccdcb baccdcc caccdcb baccdcc abcccbb dabcccc baccdcc baccdcc abcccbb dabcccc baccdcc baccdcc dabcccc dabcccc baccdcc baccdcc dabcccc dabcccc baccdcc baccdcc aaccbcb aaccbcb aaccbcb aaccbcb
bbbbdac bacccbc aacbcdc babbdac 1629soi3 babbdac aacbcdc bbdccba I63I3013 babbdac I6353013 babbdac bbccacb 16383013 bbccacb 1642 3 oi3 bacccbc aacbcdc 16463oi3 16543oi3 bacccbc aacbcdc acdbbbb I6623013 cabdcbb I6643013 bbbbdac acdbbbb I6663013 cabdcbb I6683013 bbbbdac 16713013 abbcdcc abccccd 16753013 babbdac 1679soi3 abbcdcc abccccd 1683 3 oi3 babbdac
alg. 15673013 1569 3 oi3 I57I3013 15733013 15753013 15773013 15793013 I58I3013 15833013 15853013 15873013 1589 3 oi3 15913013 1593 3 oi3 15953013 15973013 1599 3 oi3 I6OI3013 16033O13 16053013 16073O13 16093O13 I6H3013 16133013 16153013 16173013 16193013 16213013 1623 3 oi3 I6273013 16303O13 I6333013 16373013 16413013 1645 3 oi3 16533013 I66I3013 I6633013 I6653013 I6673013 1669 3 oi3 16733013 16773013 I68I3013 17173013
(J) bbcbdac bbcbdac
baaccab baaccab baaccab baaccab bccddad bbbbdac
(M) baccdcc acdbbbb acdbbbb caccdcb baccdcc caccdcb baccdcc abcccbb dabcccc baccdcc baccdcc abcccbb dabcccc baccdcc baccdcc dabcccc dabcccc baccdcc baccdcc dabcccc dabcccc baccdcc baccdcc aaccbcb aaccbcb aaccbcb aaccbcb aacbcdc bbdccba (L)
bbbbdac babbdac babbdac babbdac bacccbc aacbcdc babbdac
bbccacb bbccacb bacccbc bacccbc daabbac bbbbdac daabbac bbbbdac abbcdcc babbdac abbcdcc babbdac
aacbcdc aacbcdc acdbbbb bbcdbca acdbbbb bbcdbca abccccd bbdccba abccccd bbdccba abccbcb
3, FAILURES OF (J), (L), (M) AMONG luie-131flisie AND lsois-3013SOis
I7I83013 I72O3013 I7223013 1724 3 oi3 I7263013 I7283013 I73O3013 I7323013 17343013 I7363013 I7383013 17403013 17423013 1744 3 oi3 1746soi3 17483013 17503013 1752 3 oi3 1754 3 oi3 17563013 I7583013 1760 3 oi3 17623013 17643013 I7663013 I7683013 1770soi3 1772 3 oi3 17743013 I7763013 I7783013 I78O3013 17823013 1784 3 oi3 I7863013 1790soi3 1792 3 oi3 17943013 17963013 1798 3 oi3 I8O63013 I8O83013 I8IO3013 18193013 I8233013
(M) (J) 20 bacdabb bacbbda bacdabb bacbbda bbbacad abcdddd cabdacc abcdddd cabdacc aaacdaa baaacad aabaaac aaacdaa baaacad aabaaac aaacdaa baaacad aabaaac abcdddd abcdddd cabdacc cabdacc abcdddd babbadd dabcadd baaacad baaacad aabaaac baaacad baaacad aabaaac baaacad baaacad aabaaac baaacad baaacad aabaaac abcdddd abcdddd caccadd dabcadd aaaabcb aaaabdb aaabadc aaaacbc aabcabd dbbccaa abcdddd aaaabcb aaaabdb aaabadc aaaacbc bacacda dbbaada abcdddd cbbddba abcdddd abcdddd dbbccba abcdddd dbdacdc cbbddba dbdacdc dbdddba bccddca abcdddd abcdddd abcdddd bccddca dcdddca baaacad baaacad aabaaac baaacad baaacad aabaaac baaacad baaacad aabaaac abcaaaa abcaaaa
17193013 17213013 17233013 1725 3 oi3 17273013 17293013 17313013 17333013 17353013 17373013 17393013 1741 3 oi3 1743 3 oi3 17453013 17473013 1749 3 oi3 17513013 17533013 17563013 17573013 1759 3 oi3 I76I3013 17633013 17663013 17673013 17693013 I77I3013 17733013 17753013 17773013 1779 3 oi3 I78I3013 17833013 17863013 17893013 17913013 1793 3 oi3 17953013 1797 3 oi3 I8O53013
(J) bacdabb cadcbab babbacc babbacc aaaabcb aaaabcb aaaabcb baaacda baaacda baaacda
caccadd baaacad baaacad baaacad baaacad cbbddba
(L) (M) bacbbda abcdddd abcabbc abcabbc abcabbc aaaabcb aaaabbc aaaabcb aaaabbc aaaabcb aaaabbc baaacda abcdddd baaacda abcdddd baaacda abcdddd abcdddd baaacad aabaaac baaacad aabaaac
baaacad aabaaac baaacad aabaaac abcdddd abcdddd
caccadd dabcadd
baaddab baaddab baaddab baaddab baaddab caaddac
aabcacb aabcabd aabcabd abcaaaa abcaaaa abcaaaa abcaaaa abcdddd abcdddd abcdddd abcdddd dbdacdc dbdacdc dcdabdb abcdddd abcdddd abcdddd dbdacdc dbdacdc
baaddab caaddac baaacad baaacad aabaaac 18073013 baaacad baaacad aabaaac 18093O13 baaacad baaacad aabaaac abcaaaa 18173013 abcaaaa 18213013 abcaaaa 1825soi3
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg.
(J)
I8273013 18333013 18413013 18473013 18533013 I8583013
baaddab baaddab caaddac caaddac
(L)
(M) alg. (J) abcaaaa 18293oi3 baaddab I8373013 baaddab 18453013 baaddab I85I3013 baaddab
(L)
18573013
aabcacb
aabcacb 18983oi3 bbbcdbb aabaaac cabcacc aabbcdd 1899soi3 1900soi3 aabbbcd 19023013 aabdcdd dabdadd addbadd 19033013 aabbbdc 1904 30 13 aabbbdc dacdadd addcadd 19053013 aabbbdc badbadd 19073O13 abccddb 1906soi3 aabbbdc 19093013 aabbbcb aabbbcb aabbbca I9H3013 aabbbcd 19133013 aabbbcb aabbbcb aabbbda 19153013 aabbbdc 19173013 aabbbdc abbbccd babbaad 19193013 aabbbcb 19213013 aabcbdc aacbccc aacdcba 19233oi3 aabdbcd 19253013 abbbccd abbbccd 19273013 babbcbb 19293013 19283013 babdacc aabccda 193l3oi3 19303013 aabbdcc aabcdac 19333013 19323oi3 dabaadc 19393013 abddbcc 19353013 cbddbaa babbcbb 1942 3 oi3 cbdccdd 19413013 dbcdddd dabdadd aabaaac dadddba 19443013 aabbdcc 19433oi3 aabccac dbcdddd 19453013 19463013 aabbdcc 19473013 aaccbdd dacdadd aacaaab 1948 3 oi3 abccddd abccccc 1950soi3 abccddd 19493oi3 cadbcdd 19513013 cadbcdd dabdadd abccccc 19523013 abccddd abccccc 19543013 abccddd 1953 3 oi3 19553oi3 dadddca dacdadd abccccc 19563013 dbcdddd aacbdab 19583013 abccddd 19573013 dbcdddd 1959 3 oi3 accddca aacdcdd dabaadc 19603013 abccddd 1962 3O i3 abccddd aacdcdd addabdd 1963soi3 accddca 1964 3 oi3 abccddd abccddd addabdd 1965soi3 dadddba 19663013 abccddd abccddd 1968 3 oi3 abbddcc 19703oi3 abccddd abccddd addabdd 19713013 dbcdddd 19723oi3 abbddcc abccddd addabdd 19733013 dbcdddd aadaaab 19753013 aadbdcb 19743013 aadbdcb abcccac 19773013 aaddacc bcccdad 19763oi3 babbccc 19793013 babdacc bcccdad 1978soi3 19803013 bacccdc bacccdc abccccc 19813013 bbbcdad abccccc 19833013 1982 3O i3 baccdad 19843013 aabbbcb aabbbcb abccccc 19853013 bacccdc abccccc 19873oi3 19863oi3 babcdad cadadbc 1989soi3 aadcdbc 19883oi3 aadcdbc dacdabc 199l3oi3 bbbcdad 19903013 cbcbdad cadadbc 19943oi3 abddbcc 19923013 aadcdbc 19963013 aabbbcb aabbbcb badadcb 19983oi3 babcdad
(M)
babbcbb aabccac bababdc abccddb abbbccd aacbccc aabbbcb aadbdcd
dabdadd abccddd abccddd abccddd abccddd aacdcdd abccddd aacdcdd dabdadd abccddd
bacccdc
bacbaad bababcd aacccda aabcbda babbcbb aabccac aaacacd aabcdcd dbcadcc babbcbb aabaaac aabccda aabacac aabacac aabcdca aabcdca aacbcda cadddab cadddab addbadd addbadd dbcadcc baddddd baddddd aadaaab dabcdcc babbdcc abccccc abccccc abccccc abccccc babbcbb babbcbb dabdaac dabdaab
3. FAILURES OF (J), (L), (M) AMONG Ii3i 6 -1316 1 3 1 6 AND 13013-30133013
alg. 2OOO3013 2004 3 O i3 2OO63013 2OO83013 2OIO3013 2012 3 013 20143013 2OI63013 2OI83013 20203013 2022 3 oi3 2024 3 O i3 20263013 20283013 2032 3 O i3 20363013 2040 3 oi3 2044 3 oi3 2048 3 oi3 2052 3 O i3 2057 3 oi3 20593013 2O6I3013 2063 3 oi3 2O653013 2O673013 2069 3 oi3 20713013 2074 3 O i3 2076 3 oi3 2079 3 oi3 2O833013 2O853013 20873013 2089 3 oi3 20913013 2093 3 oi3 20953013 2097 3 oi3 2IOO3013 2104 30 13 2IO83013 2III3013 21133013 21153013
(L) (J) aabbbcb aabbbcb aadbdcb aadddcb aadddcb crndddbc bacccdc aadbdcd aadbccd aadddbc abccddd aabbbcb aabbbcb aadbdcd aadbdcd aabbbcb aabbbcb aadddcb abccddd aadcdbc aadddbc aadcdbc aadbccd aadcdbc abccddd aabbbcb aabbbcb aabbbcb aabbbcb aabbbcb aabbbcb aabbbcb aabbbcb abddcbc abcbddc dbcdddd dadddba dabdadd dbcdddd dbcdddd abcdddd abdcddd abcdddd abdcddd abbddba aabdbdd abcdddd abdcddd abbddba aabdbdd dadddca dacdadd abcdddd abcdcdd abbddbc abcbddc abcdddd abcdcdd abcdddd abdcddd aadbbcb aadbdcb aaddabc bbcdcad bbcdcad aadbbcb abddcbc abcbddc babcdad aadbdcb aaddabc aadbbcb
(M) badadcb aadbbac abcccac babbccc abccccc aadddba abccccc aadbdca aadddca abccccc abccccc
aadcdba dacdaab aadbdca aadbdca
bacddbd aabaaac aabddac aabddad abcaaaa abcaaaa dabddac dabddac addcadd addcadd addabdd
aadaaab aadaaab bbcadba dabdacb dabdacb badadcb dabdaab dabdaab aadbbac abcccda cabddcc
alg. 2002 3 oi3 2005 3 oi3 20073013 2009 3 oi3 2OH3013 20133013 20153O13 20173013 20193013 2O2I3013 2023 3 oi3 20253013 2027 3 oi3 2030 3 oi3 2034 3 oi3 2038 3 oi3 2042 3O i3 2046 3 oi3 2050 3 oi3 20563013 2058 3 oi3 2O6O3013 2062 3O i3 2O643013 2O663013 2O683013 2070 3 oi3 2073 3 oi3 20753013 2077 3 oi3 2O8I3013 2084 3O i3 2O863013 2O883013 2090 3 oi3 2092 3 oi3 2094 3 oi3 2096 3 oi3 2098 3 oi3 21023O13 2IO63013 2HO3013 21123013 21143013 21163013
(J) abddbcc aadbdcb aadddcb aadddcb aadddbc
(L)
bacccdc bacccdc bacccdc bacccdc aadcdbc aadddbc aadcdbd aadddbc aadddbd aadddbd abccddd abbddcc dbcdddd dbcdddd dadddba dbcdddd dbcdddd badcbdd badcbdd abbddba abbddba abcdddd abbddbc abcdddd dbcdddd dbcdddd dbcdddd aadbdcb aaddabc aadbbcb aadbbcb aaddabc babcdad babcdad aadbbcb aadbdcb aaddabc aadddcb
aadbccd abccddd aadbdcd aadbdcd abccddd abccddd
(M) aadbbba abdccda babbdcc abccccc abccccc abccccc abccccc abccccc abccccc abccccc babbcbb babbcbb aadddba dacdaab
bacddbb bacddbd dabdadd aabaaac aabddac aabddad bbcadbd dabdadd addbadd dacaadb addabdd abdcddd addabdd abcbddc abdcddd baddddd baddddd baddddd aadaaab abcccda badadcb badadcb abcadbb dabdaab dabdaab aadbbac badadcb abdccda cabddcc
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. 21173013 21193013 21233013 21273013 21313013 21353013 21393013 21433013 21453013 21473013 2149 3 oi3 21513013 21533013 21553013 21573013 21593013 2I6I3013
(J) aadbbcb aadbdcd aadbbcb aadbbcb aadddbd aadddbd abcdddd
aaccadd babcadd
dbdddac 21633oi3 accddca
21653013 2I673013 accddca
21693oi3 dadddac 21713013 21733013 21753013 21773013 2179 3 oi3 2I8I3013 21833013 21853013
dadddab dadddab bacccdc aabbbcb
21873oi3 badddcd 2189soi3 badddcd 21913013 daaddac 21933oi3 daaddac 21953013 aabbbcb 21973013 daaddac 21993oi3 aabbbcb 22OI3013 daaddac
(M) dabddcc aadbcdd aadddba aadbdcd aadbdca abcbddd dabdaac aadbdcd aadbdcd abcdcdd babbcbb babbcbb aabccad aacaaab aabacac aabacac aabcdca aabcdca aacbbad aacbcda abcddaa abcddaa abcddaa abcddaa babbcdd babbcdd babbcdd babbcdd bacccdc abccccc abccccc aabbbcb abccccc abccccc badcddd abddddd badcddd abddddd abddddd abddddd aabbbcb abddddd abddddd aabbbcb abddddd abddddd babbcbb babbcbb (L)
alg. 2II83013 212I3013 21253013 21293013 21333013 21373013 21413013 2144 3 oi3 21463013 21483013 21503013 2152 3 oi3 21543013 21563013 21583013 2I6O3013 2162 3 oi3 2164 3 oi3 2I663013 2I683013 21703O13 21723013 21743013 21763013 21783013 2I8O3013 2I823013 21843013 2I863013 2I883013
(J) aadddcb aaddabc aadbdcd aadddcb aadddbd abbddbc abcdddd
aaccbdd aaccadd babcadd dbdddac accddca accddca
bacccdc
2190soi3
2192 3 oi3 21943013 21963013 2198 3 oi3 22OO3013 2202 3 oi3 22O63013 2204 3 oi3 22O83013 22H3013 22153013 22133013 caaccad 222I3013 2219 3 oi3 aabbbcb aabbbcb 22253013 22233013 aabbbcb aabbbcb 22273013 badddca bacdadd aacaaab 22283013 aacaaab 2230soi3 22293013 aaccbdd 223I3013 abbddba abcbddd cabdddd 22323013
badddcd badddcd
(M) dabddcc abddcdd abcadbb aadbdcd aadddca abddcdd dabdaac aadbdcd abcbddc abddcdd babbcbb aabccac aabccda aacaaab abccccc abccccc abccccc abccccc aacbbad aacbdab abcddad abcddad cabccdd cabdcdd babbcdd babbcdd babbcdd babbcdd abccccc abccccc bacccdc abccccc abccccc abddddd abddddd abddddd abddddd badcddd abddddd abddddd badcddd abddddd abddddd babbcbb (L)
caaccad aabbbcb aabbbcb caaccad caaccad aacaaab aaccbdd aacaaab abbddba bacdadd cabdddd
3, FAILURES OF (J), (L), (M) AMONG luie-131flisie AND lsois-3013SOis
(J) 22333013 22353013 22373013 2239 3 oi3 2241 3 oi3 2243soi3 2245 3 oi3 22473013 2249soi3 2251 3 oi3 22533013 22553013 22573013 226O3013 22623013 2264 3 oi3 22663013 22683013 227O3013 22723013 2274 3 oi3 22783013 2280soi3 22823013 2284 3 oi3 22863013 22883013 229O3013 2293soi3 2297soi3 2299 3 oi3 2301soi3 2303soi3 2305 3 oi3 2307soi3 2309soi3 23II3013 23133013 23153013 23173013 2319soi3 23223013 23243013 23263013 2329 3 oi3
20
abbddba aaccbdd abdddcb abccbdd abdddbc abdddcb abbccdd abbcedd aadbddb aadbdcb aadbdcb aadbdcb aadcdbc aadbdcb
abcdbdd abcbddd abcdbdd abcbddd aadbdcd badcddd aabadcb aabadcb abcccdc aabadcb
(M) cabdddd dadbcdd aacbbba aacbbba aacbdba aacbdba cabdddd cabdddd dadbcdd dbdacdd aadaaab aadaaab aabcbba aabcbba abcbcda aabcbba abddddd
aaccdad abddddd abcbbbb badddcd aadbdcd badddcd badcddd abddddd
abddddd aaccdad abddddd bbcdcbc cabbbdb abcbbbb abcbbbb badddcd aadbdcd baaddac aadbdcd aacccbe aacbccc abddddd aacccbe aacbccc abddddd baaddac badcddd abddddd daaddac abddddd aadbdcb aadbdea aadbdcb aadecab aadccbe aadeced abcbbbb aadcdbc aadeced abcbbbb aadccbe abcccdc abcbbbb aadcdbc abcccdc abcbbbb aadbdcb aabadcb aabcbba aadccbe abcccdc abcbcda aadbdcb bacbdec baccccc aadbdcb aadbdcb aabadcb aabcbba
2234 3 oi3 22363013 22383013 224Q3oi3 22423013 22443013 2246 3 oi3 22483013 22503013 2252 3 oi3 22543013 22563013 22583013 226I3013 22633013 22663013 22673013 2269 3 oi3 227I3013 22733013 22773013 2279 3 oi3 228I3013 22833013 22863013 22873013 2289 3 oi3 229I3013 2294 3 oi3 2298 3 oi3 23OO3013 2302 3 oi3 2304 3 oi3 23O63013 23O83013 23IO3013 2312 3 oi3 2314 3 oi3 23I63013 23I83013 232I3013 23233013 2325soi3 2327 3 oi3 23303013
(L) (M) (J) abbeddd abcbddd dadbcdd daccadd aacdbda aaccbdd aacdbda abcbbbb abcbbbb baccbdd cabdddd cabdddd dadbcdd dbccbdd dbccbdd aadbdcb daaabac aadaaab aadbdcb aadaaab aadbdcb aadbdcd badadeb aadbdcb aadbdcd bacbdec baccccc aadbdcb badcddd abddddd aaccdad aadbdcd baebbbb badddcd badcddd abddddd abcadbb aadbdcb aadbdcd badadeb aadbdcb badcddd abddddd abddddd aaccdad aadbdcd baebbbb badddcd badcddd abddddd aacccbe aacbccc abcbbbb abcbbbb daaddac aacccbe aacbccc aacccbe aacbccc badddcd aadbdcd badddcd badcddd abddddd abddddd badddcd badcddd abddddd abddddd aadbdea aadbdcb aadecca aadbdcb acccdad aadeced abcbbbb acccdad aadeced abcbbbb baebcad cabbbdb abcbbbb abcbbbb baebcad aadbdcb aadbdcb aabadcb aabcbba aadcdbc abecedc abcbcda aadbdcb aabadcb aabcbba aadccbe abecedc abcbcda aadbdcb bacbdec
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. 23313013 23333013 23353013 23373013 2339 3 oi3 2341 3 oi3 23473013 2350 3 oi3 23523013 23543013 23563013 2358 3 oi3
2360soi3 23633013 23693013 23733013 23773013 2379 3 oi3 238I3013 23833013 23853013 23873013 2389 3 oi3 23913013 23943013 23973013 2399 3 oi3 24013013 2403 3 oi3
24073oi3 2409soi3 2411 3 oi3 2413 3 oi3 24153013 24173013 2419 3 oi3 24213013 2423 3 oi3 2427 3 oi3 24313013 24333013 24353013 24373013 24393013 2441 3 oi3
(M) (M) alg. (J) (L) (J) (L) aadcdbc abcccdc abcbcda 23323013 cbbccdd baccccc bacbbbb 23343013 aadddbc dabddbb aadddbc bacbbbb 23363013 aadddbc aadddbc aadddbc abcadbb 23383013 abcbbbb aadddbc abcadbb 2340 3 oi3 abcbbbb aadbdcb aadbdcb abcbddd 23453013 bacbbbb abccbdd 23493013 aadddbc dabddbb 235I3013 aadddbc aadddbc bacbbbb aadddbc 23533013 aacccbc aacbccc abcbbbb bbcdcbc cabbbdb abcbbbb 23553013 aadddbc abcbbbb abcbbbb 23573013 aacccbc aacbccc abcbbbb bbcdcbc cabbbdb abcbbbb 2359 3 oi3 aadddbc abcbbbb abcbbbb 236I3013 aacccbc aacbccc aacccbc aacbccc 23653013 abdddbc abcbddd aacccbc aacbccc 237I3013 aacccbc aacbccc abbccdd 23753013 abbccdd aacddab 23783013 bccddcb bccddca aacddad aacddab 2380soi3 aacddad aacddab 23823013 bccddcb bccddca aacddad aacddab 2384 3 oi3 dbdddac dbdddac aacddad abbddbc abcbddc cabdddd 23863013 bccddca cabdddd cabdddd 23883013 abbddbc abcbddd cabdddd cabdddd 23903013 cabdddd abbddbc abcbddc dadbcdd 23923oi3 bccddca dadbcdd abbddbc abcbddd dadbcdd 2395soi3 dbdddba dadbcdd aaccdad aadbdcd dacdabb 23983013 aaccdad badddcd badcddd abddddd 24OO3013 daaddbc abddddd abcadbb 2402 3 oi3 abddddd aadbbcb aadbdcd badadcb 2404 3O i3 badddcd aadbdcd aadbbcb badcddd abddddd 2408soi3 badddcd badcddd abddddd abddddd 2410soi3 abddddd aaccdad aadbdcd aadcdba 2412 3 oi3 aaccdad bbcdcdd aadcdba aaccdad aadbdcd dacdabb 24143013 aaccdad aadccbc badcddd abddddd 24163013 aadccbc bbcdcdd abddddd badddcd badcddd abddddd 24I83013 daaddbc abddddd aadccbc abddddd 2420soi3 abddddd daaddac abddddd 24223013 abddddd abddcbc aadbdcd 2424 3 oi3 badddcd aadbdcd baaddac aadbdcd 24283013 badddcd aadbdcd abddcbc abcbddc abddddd 24323013 badddcd badcddd abddddd daaddac abddddd 2434 3 oi3 abddddd baaddac badcddd abddddd 2436soi3 badddcd badcddd abddddd daaddac abddddd 24383013 abddddd aadbbcb aadbbac 2440soi3 aadbdcb aadbbac aadbbcb aadbdca 2442 3 oi3 aadbdcb aadbdca
3, FAILURES OF (J), (L), (M) AMONG lisia-1316isia
24433oi3 24453oi3 24473013 24493oi3 24513oi3 2453soi3 24553oi3 24583oi3 2460soi3 24633oi3 24693oi3 24743013 24763013 2478soi3 2480soi3 24833oi3 2487soi3 24913013 24973oi3 25013013 25123013 25I63013 25263013 25283013 25323013 25363013 25543oi3 25583013 256I3013 25653013 25733013 25753013 25823013 25863oi3 25923oi3 2605soi3 26II3013 26133013 26I53013 26193oi3 262I3013 26233013 26253013 26283013 263I3013
(M) alg. (J) (L) aadbbcb aadbbac 24443oi3 aadbbcb aadecab 24463oi3 aadbbcb aabadeb abbadbc 24483oi3 cabddce 24503oi3 dabddec 24523oi3 aadbbcb dabddec 24543oi3 dacbdec 24573oi3 aadbbcb dabddbb 24593013 aadddbc aadddbc 24613oi3 aadddbc abcadbb 24653oi3 aadbbcb 24733oi3 aadccbc dabedbb 24753013 aadddbc dabddbb 24773oi3 aadccbc dabedbb 2479soi3 aadddbc 24813oi3 aadddbc bbcddba 24853oi3 aadddbc bbcddba 24893013 accddcb 24933oi3 abbddbc abcbddc 24993oi3 abbddbc 25033oi3 aacccbe aacbccc 25133013 aacccbe aacbccc 25I83013 aacccbe aacbccc 25273013 aacedbd aadbded 25293oi3 aacccbe aacbccc 25343oi3 aacddbd aadbded 25383013 aacdeae aacbede 25563013 aacddbd aacbede 25593oi3 aacddbd aadbded 25633013 abbddbc 25723013 bbccdbd 25743013 bbccdbd 258O3013 aacddbd aadbded 25843013 aacddbd aadbded 25883013 abbddbc 26O23013 abbecbd 26O83013 26I23013 babbebb babbebb aabeeea 26I73013 aacaaab 262O3013 abccccc 2622soi3 abecece 26243013 aceddea 2626soi3 aceddea 26293oi3 caaddab 2633soi3
AND
(J) aadbdeb aadbdeb aadbbcb aadbbcb aedddeb aadbbcb aadddbc aadddbc aadddbc aadbbcb aadccbc aadddbc aadccbc aadddbc aadccbc aadccbc abbddbc abbddbc accddcb daaddac bbedebe aacccbe bbccdbd bbccdbd aacccbe aacddbd aacdeae baacebc aacddbd aacedbd aacedbd aacddbd aacddbd abbddbc abbecbd abbecbd
lsois-3013 s0 is
(L)
(M) aadbbac
cabddce aabadeb abbadbc dabddec aabadeb abbadbc baeddbb baeddbb abcadbb abcbddd baeddbb baeddbb baeddbb baeddbb bbcddba bbcddba abcbddc abcbddd
aacbccc
aacbccc aadbded aacbede aadbded aadbded aadbded aadbded aadbded
babbebb babbebb aabeeea aacaaab abccccc abcecec aceddea aceddea caaddac
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. 26353013 2639 3 oi3 2641 3 oi3 26433013 26453013 26473013
(J) caaddab abbbcbd abbbcbd abbbcbd abbbcbd
(L) abbbcbd abbbcbd abbbcbd abbbcbd
(M)
acdaccb babbcbb acdaccb babbcbb abdaaaa dbcdddd 2649soi3 babbccc 2652 3 oi3 dbcdddd 2654 3 oi3 babbccc 26563013 266O3013 bacccdc bacccdc abccccc abccccc 26623013 26643oi3 bacccdc bacccdc abccccc abccccc 26663013 cddbdbc 26683013 babbcbb 26703013 dbcdddd 2672 3 oi3 babbcbb 26743oi3 26773013 abbbcbd abbbcbd aacbcca 26793013 aacbbdb abbbcbd babbcbb 26823013 dbcdddd 26843013 dbcdddd 26863013 dbcdddd 2692 3 O i3 dbcdddd 2694 3 oi3 dbcdddd 26963013 dbcdddd 26983oi3 27033013 aabbbcb aabbbcb babbccc 27O83013 babbccc 27113013 27153013 aacbbdb abbbcbd abccccc 27173013 abbbcbd abbbcbd abccccc 27193oi3 aacbbdb abbbcbd abccccc 27213013 abbbcbd abbbcbd abccccc abccccc 27233013 abccccc 27253013 bacccdc bacccdc abccccc 27273013 abccccc 2729 3 oi3 273I3013 bacccdc bacccdc abccccc abccccc 27333013 27363013 abbbcbd abbbcbd aacbcca 27383013 aacbbdb abbbcbd babbcbb 27413013 27443013 abbbcbd abbbcbd aacbcca 27463013 aacbbdb abbbcbd
alg. 26373013 2640 3 oi3 2642 3 oi3 26443013 2646 3 oi3 2648 3 oi3 26513013 2653 3 oi3 26553013 26593013 266I3013 26633013 26653013 26673013 26693013 267I3013 2673 3 oi3 26753013 26783013 268I3013 26833013 26853013
26913oi3 2693soi3 2695soi3 26973013 26993013 2707 3 oi3 2709 3 oi3 27123013 27I63013 27I83013 27203O13 27223013 27243013 27263013 27283013 27303013 27323013 27343013 27373013
2740soi3 27423oi3 27453013 27483013
(M) (J) (L) caaddac daaabac daaabac aadaaab daaabac daaabac aadaaab aadaaab aadaaab cabcccc daacdab babbccc daacdab dbcdddd babbccc aabbbcb aabbbcb abccccc abccccc aabbbcb aabbbcb abccccc abccccc aacbbdb abbbcbd aacbcca abbbcbd abbbcbd aacbcca aacbbdb abbbcbd dbcdddd abbbcbd abbbcbd babbcbb aacbbdb abbbcbd aacbcca babbcbb abbbcbd abbbcbd babbcbb dbcdddd dbcdddd aabbbcb aabbbcb dbcdddd dbcdddd aabbbcb aabbbcb dbcdddd dbcdddd aabbbcb aabbbcb daacdab babbccc daacdab babbccc bacccdc bacccdc abccccc abccccc bacccdc bacccdc abccccc abccccc abccccc aabbbcb aabbbcb abccccc abccccc aabbbcb aabbbcb abccccc abccccc aacbbdb abbbcbd aacbcca babbcbb abbbcbd abbbcbd babbcbb aacbbdb abbbcbd aacbcca babbcbb abbbcbd abbbcbd babbcbb
3. FAILURES OF (J), (L), (M) AMONG Ii3i6-1316 1 3 1 6 AND 13013-30133013
alg. 2749 3 oi3 2762 3 O i3 2770 3 oi3 27753013 2779 3 oi3 27833013 27853013 27873013 2789 3 oi3 27913013 2794 3 oi3 2796 3 oi3 2798 3 oi3 2800 3 oi3 28O23013 2806 3 oi3 28103013 2812 3 O i3 2814 3 oi3 28I63013 28233013 28253013 28283013 2830 3 oi3 2834 3 oi3 2842 3 O i3 2844 3 O i3 28473013 2851 3 oi3 2854 3 O i3 286I3013 2869 3 oi3 28753013 288I3013 28833013 2889 3 oi3 2891 3 oi3 2893 3 oi3 28953013 29053013 2907 3 oi3 2912 3 O i3 2914 3 O i3 29I63013 2940 3 oi3
(J)
(L)
(M) alg. (J) babbcbb 27583013 aabbbcb
aabbbcb aabbbcb bccddca bccddca aadbbcb aadccbc daaabac aadbbcb aadccbc aadbbcb
aabbbcb aabbbcb
27663013 27743013 27783013 27823013 2784 3O i3 27863013 27883013 27903013 2793 3 oi3 27953013 27973013 27993013 2801 3 oi3 2803 3 oi3 28O73013 28II3013 28133013 28153013 2822 3O i3 2824 3 oi3 28263013 2829 3 oi3 283I3013 28383013 28433013 28463013 285O3013 28523013 28553013 28653013 2871 3 oi3 28773013 28823013 28843013 2890 3 oi3 2892 3 oi3 2894 3O i3 28963013 2906 3 oi3 29113013 29133013 29153013 29393013 29473013
aadbbcb aadbbcb aadbbcb abddcbc
abddcbc aadbbcb aadccbc aadbbcb aadccbc aadccbc aadbbcb accddcb aadbbcb aadbbcb aadbbcb aadbbcb abbddbc abbddbc caaddbd caaddbd cadddbd cadddbd
caaddbd caaddbd cadddbd
baaccbc
daaabac aadaaab daaabac aadaaab daaabac aadaaab aadaaab aadaaab abdabbc dbcdddd abdabbc dbcdddd abdabbc abdabbc dbcdddd dbcdddd dbcdddd
abcabbc abcbcca
abdabbc
abdabbc
aadbdcd aadbdcd cadbddd acddddd cadbddd acddddd acddddd acddddd aadbdcd aadbdcd cadbddd acddddd acddddd acddddd aacbcdc
aabbbcb abbddbc abbddbc aadbbcb aadccbc
daaabac aadbbcb aadccbc aadbbcb aadbbcb
(M) (L) aabbbcb aabbbcb abcbddc abcbddc babacad abcabbc babacad abcbcca babacad dbcdddd abcabbc abcbcca aadaaab dbcdddd dbcdddd dbcdddd dbcdddd
aadbbcb aadbbcb dbcdddd dbcdddd dbcdddd aadbbcb babacad abcabbc aadccbc babacad abcbcca daaabac babacad aadbbcb aadccbc aadccbc aadbbcb aadbbcb abdabbc aadbbcb abdabbc accddcb aadbbcb aadbbcb accddcb accddcb caaddbd aadbdcd caaddbd aadbdcd cadddbd cadbddd acddddd cadddbd cadbddd acddddd acddddd acddddd caaddbd aadbdcd cadddbd cadbddd acddddd cadddbd cadbddd acddddd acddddd baaccbc aacbcdc baaccbc aacbcdc
680
8. 4328 FINITE INTEGRAL RELATION ALGEBRAS
(J)
alg.
(L)
(M)
29483013 baaccbc aacbcdc 29773013 aabccdc aacbccc
alg.
(J)
(L)
(M)
29753013 aabccdc aacbccc 29833013 aabccdc aacbccc
4. 5-dimensional basis data for I1318—1316i3i8 and I3013—30133013 For an explanation of the tables below, see Chapter 6.§66. alg.
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 lO9isi0 5 I1316 4l31B 7l31B 10l316 13l316 I613IB 19l316 22l31B 25l31B 28l316 31131B 34l3lB 37l316 4O131B 43l31B 46l316 49l31B 52l31B 55l316 58131B 61131B 64l3l6 67l31B 70131B 73l316 76131B 79l31B 82l316 85l31B 88131B 91l316 94l31B 97l31B 1001316 103x316 1061316
c 6 8 7 8 7 7 8 5 7 6 7 7 8 8 10 5 5 5 7 7 7 8 6 8 8 9 10 4 7 8 10 7 8 7 9 9 9
q 14 22 13 23 18 13 23 11 18 12 19 20 29 28 39 11 10 13 19 22 21 27 17 27 26 36 43 6 20 29 41 23 29 26 37 38 35
b 14 22 13 23 16 11 21 11 18 12 19 20 29 0 38 11 10 13 19 22 21 27 0 27 0 0 0 6 20 0 41 23 0 0 0 0 35
/
alg. 2x316 5l31B 8l31B Hl316 14x3X0
2 2 17x3X0 2 201316
23isie 26isie 29l316 32isi6 35l316 38l316 41x3X0 1 44l316 47l316 501S16 53l316 56l316
59isie 62l316 65l316 681316 71x3X6 74l316
77isie 8O1316 83l316 861318 89l316 92i3ia 95isi6
98isia lOlme 1041318 1071318 HO13I8
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 7 6 8 8 8 8 9 6 5 7 7 8 8 9 4 6 5 6 5 5 6 6 7 7 9 10 11 5 7 9 6 8 8 8 8 10 8
q 18 9 17 23 24 19 29 14 8 15 20 24 26 35 8 14 10 16 12 11 17 16 24 23 33 45 52 10 19 33 19 27 29 33 34 45 38
b 18 9 17 23 24 19 29 14 8 15 20 24 0 34 8 14 10 16 10 9 15 16 24 0 32 0 0 10 19 0 19 0 0 0 0 45 37
/
alg. 3l316 6l310 9lS16 12l316 15x3X0
18x3X0 21x3X6 24isi6 27isi6 301316 33isi6 36l316 39l316
1 42isie
2 2 2
1
1
45l316 481316 511310 54l316 57l316 6O1S16 63l316 661316 69isi6 72l316 75l316 781S16 811316 84l316 87isi6 901316 93l316 96isi8 991316 1021316 1051318 1081318 1H131B
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 7 7 7 9 9 9 10 6 6 6 8 7 9 9 5 4 6 6 6 6 7 7 7 8 9 11 12 6 8 9 7 7 9 8 9 8 9
9 18 13 19 27 30 25 35 15 11 16 23 22 33 32 11 7 13 16 17 16 22 19 20 30 34 54 61 16 23 37 23 25 33 30 41 31 48
6 / 18 13 19 27 30 25 35 15 11 16 23 0 33 0 11 7 13 16 17 16 22 19 0
29 1 34 54
59 2 16 23 37 0 0 0 0 41 31 48
4. B-DIMBNSIONAL BASIS DATA FOR I 1 3 1 6 - 1 3 1 6 i 3 i 6 AND l 3 oi3-3O13 3 oi
alg. 1121316 115l3l6 II81316 1211316 1241316 1271316 1301316 133l3l6 136l3l6 1391316 1421316 145l316 1481316 1511316 154i3i 6 1571316 1601316 1631316 1661316 1691316 172i316 1751316 1781316 1811316 1841316 187l3l6 1901316 1931316 1961316 199i316 202i3ie 205i3ie 2081316 2111316 2141316 2171316 2201316 223i3i6 2261316 229i3ie 232i3ie 235i3ie 238i3ie 2411316 244i3ie
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 9 9 9 11 5 7 8 6 6 8 7 8 7 8 7 9 9 11 11 13 7 9 10 9 10 11 7 9 11 9 11 11 11 11 13 12 13 13 14 9 8 10 10 10 11
q 42 36 49 63 13 19 32 18 20 27 23 35 26 41 21 34 45 65 65 86 26 34 52 38 51 62 27 37 67 47 65 65 71 73 94 74 101 82 118 35 27 47 53 49 64
6 41 36 49 63 13 19 32 0 0 0 0 35 26 41 0 34 45 0 0 84 26 34 52 38 0 62 27 32 66 0 0 0 0 0 0 0 101 0 118 0 27 47 0 0 0
alg. 0 / 1 113l316 5 H61316 5 1191316 5 1221316 5 1251316 5 1281316 5 131l316 5 134i3i6 5 137l3l6 5 1401316 5 1431316 5 146i316 5 1491316 5 152i3i6 5 155l3l6 5 1581316 5 1611316 5 164l316 5 167l3l6 5 2 1701316 5 1731316 5 1761316 5 1791316 5 182l3l6 5 185l316 5 1881316 5 1911316 5 5 1941316 5 1 1971316 5 2001316 5 203i3i6 5 2061316 5 209i3i6 5 2121316 5 2151316 5 2181316 5 2211316 5 224i3i6 5 227i3i6 5 230i3i6 5 233i3i6 5 236i3i6 5 239i3i6 5 242i3i6 5 245i3i6 5
c 10 9 10 3 6 7 9 6 7 6 8 8 8 8 8 8 10 11 12 5 8 9 11 10 11 12 8 10 11 10 10 12 11 12 10 11 11 12 4 9 10 10 11 11 11
q 52 30 59 5 16 24 35 17 24 20 30 31 29 34 31 42 55 62 77 10 32 41 58 46 59 70 43 47 71 59 59 77 68 85 50 77 58 94 10 41 50 51 65 55 62
c q b / alg. 0 b f 52 0 114l316 5 8 26 0 1171316 5 10 40 40 59 1201316 5 10 53 53 5 8 8 1231316 5 4 16 1261316 5 6 16 16 0 0 1291316 5 8 27 35 132l3l6 5 5 14 14 17 0 135l3l6 5 7 21 0 0 138l3l6 5 7 23 0 0 1411316 5 7 27 0 0 144i3i6 5 7 28 0 1471316 5 9 38 38 29 1501316 5 7 31 30 1 33 1 153l3l6 5 9 44 44 31 0 156i316 5 8 24 42 1591316 5 9 52 52 55 0 162i316 5 10 53 0 165l316 5 12 74 72 2 0 0 1681316 5 12 74 7 3 1711316 5 6 16 16 32 1741316 5 8 28 28 0 0 1771316 5 10 47 8 58 5 0 30 1801316 46 0 183l316 5 9 43 0 0 1861316 5 10 54 70 0 1891316 5 6 17 43 1921316 5 9 53 53 47 0 1951316 5 10 57 71 1981316 5 12 81 81 0 0 2011316 5 10 53 0 0 204i3i6 5 11 71 0 0 207i3i6 5 10 59 0 0 2101316 5 12 80 0 0 2131316 5 12 82 0 0 2161316 5 11 62 12 0 5 89 0 2191316 0 0 222i3i6 5 12 70 0 0 225i3i6 5 13 106 10 228i3i6 5 8 33 33 0 2311316 5 10 50 50 50 0 234i3i6 5 9 38 0 237i3i6 5 11 63 63 0 240i3i6 5 12 77 77 0 0 243i3i6 5 10 53 0 0 246i3i6 5 12 73
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg.
a
c
247 13 ie 5 11
250i3i6 253i3i6 256i3i6 259i3ie 262i3ie 265i3i6 268i3ie 271i3i6 274 13 i6 277 13 i6 28O1316 283i3i6 2861316 289i3ie 292 13 i6
295i3ie 298i3ie 301i3i6 304i3ie 307i3ie 310i3i6 3131316 316i3i6 3191316 322i3i6 325i3i6 328i3i6 331i3i6 334i3ie 337i3i6 340i3i6 343i3ie 346i3ie 349i3ie 352i3ie 355i3i6 358i3i6 361i3i6 364i3i6 367i3i6 370i3i6 373i3ie 376i3i6 379i3ie
5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
12 10 12 12 11 11 13 12 13 8 10 10 10 10 12 10 11 10 12 12 10 10 12 11 12 9 11 11 11 12 11 11 13 11 12 11 13 13 11 11 13 12 13 11
q 69 86 53 73 80 61 68 91 81 104 41 54 56 63 62 81 61 81 69 92 90 61 64 81 77 90 52 68 73 77 90 81 85 105 77 97 86 112 113 83 86 107 99 117 92
b / alg. 0 c q b / alg. 0 c q b f 0 248i3i6 5 12 75 0 249i3ie 5 11 71 0 0 252i3i6 5 13 95 0 25I1316 5 12 80 0 254i3i 6 5 11 61 0 0 255i3i6 5 11 65 0 0 0 258i3ie 5 12 80 0 257 13 ie 5 11 68 92 5 13 0 0 26O1316 2611316 5 10 53 0 0 0 263i3i6 5 11 62 264i3i6 5 12 70 0 12 5 79 0 0 267i3i6 5 12 80 0 2661316 0 0 270i3i6 5 12 84 0 269i3i6 5 11 72 0 0 273i3i6 5 12 89 0 272i3i6 5 13 93 0 0 276i3ie 5 14 116 0 275i3i6 5 13 101 0 0 2781316 5 9 49 279i3i6 5 9 46 0 0 0 28I1316 5 9 51 282i3i6 5 10 59 0 0 0 285i3i6 5 9 52 0 284i3ie 5 11 64 0 0 2881316 5 11 71 0 287i3i6 5 10 60 0 0 291i3i6 5 11 70 0 290i3i6 5 11 73 0 0 294i3ie 5 10 68 0 293i3i6 5 9 56 0 0 297i3i6 5 10 69 0 296i3i6 5 11 73 0 300i3i6 5 12 86 0 299i3ie 5 11 74 0 0 303i3ie 5 11 77 0 302i3ie 5 11 84 0 11 82 5 0 0 0 305i3i6 306i3i6 5 12 97 9 52 5 5 0 13 105 0 0 308i3i6 309i3ie 11 5 5 0 10 60 0 69 0 311i3i6 3121316 0 0 3141316 5 11 73 0 3151316 5 11 72 0 0 317l3l6 5 10 66 0 3181316 5 11 78 0 0 3211316 5 11 78 3201316 5 12 89 0 0 0 323i3i6 5 12 89 0 324i3i6 5 13 101 0 326i3i6 5 10 60 0 327 13 ie 5 10 60 0 0 329i3ie 5 10 65 0 330i3i6 5 11 73 0 0 332i3i6 5 12 81 0 333i3i6 5 10 66 66 77 335i3i6 5 12 88 88 336i3i6 5 11 79 79 90 338i3i6 5 13 101 101 339i3ie 5 10 69 0 0 341i3i6 5 11 77 0 342i3i6 5 12 89 0 0 344i3ie 5 12 97 0 345i3i6 5 12 93 0 0 0 347 13 ie 5 10 69 348i3ie 5 11 81 0 12 5 89 0 0 350i3i6 351i3i6 5 11 85 0 12 5 93 0 0 353i3i6 354i3ie 5 13 105 0 12 5 101 86 101 357i3i6 5 12 97 97 356i3i6 112 360i3i6 5 13 117 117 359i3i6 5 12 102 102 113 362i3i6 5 14 128 128 363i3i6 5 10 71 0 0 365i3i6 5 11 80 74 6 366i3i6 5 12 92 92 0 368i3i6 5 12 98 0 369i3i6 5 12 95 95 107 371i3i6 5 11 87 0 372i3i6 5 12 102 0 97 2 374i3i6 5 13 114 112 2 375i3i6 5 12 102 0 0 377i3i6 5 13 114 112 2 378i3i6 5 14 129 127 2 92 380i3i6 5 12 102 102 38I1316 5 13 112 112
4. 5-DIMENSIONAL BASIS DATA FOR I 1 3 1 6 - 1 3 1 6 i 3 i 6 AND l 3 oi3-3013 3 oi3
alg. 382i3i6 385i3i6 388i3i6 3911316 394i3ie 397i3i6 4001316 403i3ie 406i3i6 409i3ie 412i316 415l3l6 4181316 4211316 424i3i 6 427i3i6 430i3i6 433i3i6 436i3i6 439i3i6 442i3i6 445i3ie 448i3i6 451l3l6 454i3i6 457i3i6 460i3i6 463i3i6 466i3ie 469i3i6 472i3i6 475i3i6 478i3i6 4811316 484i3i6 487i3i6 490i3ie 493i3i6 496i3i6 499i3ie 502i3i6 505i3i6 508i3i6 511l316 514i3i6
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 11 12 11 13 13 12 13 13 14 6 8 8 9 10 11 11 12 11 12 11 12 7 12 13 10 11 10 12 12 9 9 11 10 11 9 11 11 11 11 13 11 11 11 13 11
q 67 102 65 89 121 90 125 100 144 28 37 43 50 52 74 63 72 72 81 80 89 26 65 80 69 63 61 90 94 39 41 54 56 66 44 61 61 75 71 96 68 59 76 97 80
b / alg. a c q b / alg. a c q b 0 0 383i3i6 5 12 79 384i3ie 5 11 90 90 102 386i3i6 5 12 102 102 387i3i6 5 13 114 114 0 0 0 389i3ie 5 12 77 390i3i6 5 12 77 0 393i3i6 5 13 121 121 392 13 ie 5 12 109 109 121 0 396i3ie 5 11 75 395i3ie 5 14 133 133 12 5 5 13 0 105 110 110 0 399i3ie 398i3ie 125 0 402i3ie 5 12 85 4011316 5 14 140 140 0 0 404i3ie 5 14 115 405i3i6 5 13 129 129 144 408i3ie 5 5 21 21 407i3i6 5 15 159 159 28 0 0 4111316 5 8 35 4101316 5 7 30 0 0 414i3i6 5 7 34 29 4131316 5 9 42 43 416l316 5 9 52 52 4171316 5 8 41 36 50 0 420i3i6 5 9 44 4191316 5 10 59 59 0 0 422i3ie 5 9 50 423i3ie 5 10 62 62 74 0 0 425i3i6 5 9 47 426i3ie 5 10 55 0 0 0 428i3i6 5 10 56 429i3i6 5 11 64 0 0 432i3ie 5 11 72 72 4311316 5 10 61 0 0 434i3i6 5 12 83 83 435i3ie 5 11 70 12 73 8 437i3ie 5 81 0 438i3ie 5 13 92 84 80 441i316 5 13 110 110 440i3ie 5 12 95 95 104 5 13 0 96 8 443i3ie 444i3ie 5 14 119 111 11 5 26 55 0 0 446i3ie 447i3ie 5 11 43 0 0 0 449i3ie 5 12 70 450i3i6 5 12 58 0 452i3ie 5 9 52 52 453i3ie 5 10 58 58 69 455i3ie 5 11 75 75 456i3ie 5 10 57 57 63 458i3ie 5 11 80 80 459i3ie 5 12 86 86 61 462i3ie 5 11 82 82 461l316 5 11 69 69 90 464i3ie 5 11 67 67 465i3ie 5 12 75 75 94 0 467i3ie 5 13 102 102 468i3ie 5 8 32 0 0 0 470i3ie 5 9 38 4711316 5 10 45 0 0 0 473i3ie 5 10 48 474 13 ie 5 10 47 0 0 0 476i3ie 5 9 46 477i3ie 5 10 57 0 0 0 479i3ie 5 11 67 480i3ie 5 10 55 0 0 483i3i6 5 12 76 482 13 ie 5 11 65 0 0 0 0 485i3ie 5 10 55 486i3ie 5 10 50 11 5 5 10 0 55 66 0 0 488i3ie 489i3ie 12 72 5 5 10 0 60 0 0 492 13 ie 4911316 0 0 0 494i3ie 5 11 70 495i3i6 5 12 85 0 0 0 497i3i6 5 12 86 498i3ie 5 12 81 0 0 0 5001316 5 10 62 5011316 5 11 77 0 0 0 504i3ie 5 10 44 503i3ie 5 12 83 0 0 0 506i3ie 5 11 50 507i3ie 5 12 65 0 0 0 509i3ie 5 12 91 510i316 5 12 82 0 512l3l6 5 11 73 73 513l316 5 12 83 83 0 0 515l3l6 5 12 99 99 516l316 5 12 90
/
5 5
8 8
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. 517l3l6 520i3i6 523i3i6 526i3i6 529i3ie 532i3ie 535i3i6 538i3i6 541i3i6 544i3ie 547i3ie 550i3i6 553i3i6 556i3i6 559i3ie 562i3i6 565i3i6 5681316 571i3i6 574i3i 6 577i3i6 580i3i6 583i3i6 5861316 589i3ie 592i3ie 595i3ie 598i3ie 6OI1316 604i3ie 607i3ie 6IO1316 613l3l6 6161316 619l316 622i3ie 625i3i6 6281316 631l3l6 634i3ie 637i3ie 640i3ie 643i3i6 646i3i6 649i3ie
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 13 12 13 9 11 10 10 11 11 12 11 12 12 10 10 11 11 11 11 13 11 12 12 12 12 13 13 11 9 11 10 11 10 11 10 12 12 11 10 12 11 12 11 13 11
q 109 72 113 45 59 49 54 65 55 71 65 69 79 46 48 58 61 57 60 92 66 81 82 78 79 102 99 75 57 77 48 85 70 91 58 86 94 70 62 84 81 95 83 105 61
alg. 0 alg. 0 c q b f b / 0 109 5I81316 5 11 62 5191316 5 0 522i3i6 5 521i3i6 5 13 91 91 524i3i 6 5 13 104 0 113 525i3i6 5 0 0 528i3i6 5 527 13 ie 5 10 50 0 0 530i3i6 5 9 40 531i3i6 5 11 534i3i6 5 54 5 0 0 533i3i6 54 5 0 56 10 537i3i6 5 536i3i6 0 0 539i3i6 5 12 74 540i3i6 5 0 0 543i3i6 5 542i3i6 5 11 52 0 0 545i3ie 5 10 55 546i3i6 5 0 0 548i3i6 5 12 73 549i3i6 5 0 0 552i3i6 5 551i3i6 5 11 69 0 0 554i3i6 5 13 91 555i3i6 5 0 0 557i3i6 5 9 31 558i3i6 5 0 0 560i3i6 5 11 59 561l3l6 5 0 0 564i3ie 5 563i3i6 5 10 44 0 0 5661316 5 12 76 567i3i6 5 0 0 569i3ie 5 11 62 570i3i6 5 0 0 572i3i6 5 12 71 573i3i6 5 0 0 575i3i6 5 10 54 576i3i6 5 12 74 5 0 0 579i3ie 5 578i3i6 11 54 5 0 0 582i3ie 5 581l316 82 585i3i6 5 584i3i6 5 13 93 93 0 0 587i3i6 5 11 51 5881316 5 0 590i3ie 5 13 90 0 5911316 5 0 0 594i3i6 5 593i3i6 5 12 71 94 5 596i3ie 5 14 114 114 597i3ie 5 0 599i3ie 5 11 83 0 6OO1316 5 0 602i3i6 5 10 72 72 603i3i6 5 0 0 6O61316 5 605i3i6 5 9 43 0 0 609i3ie 5 6O81316 5 11 63 0 85 612i3i6 5 6II1316 5 11 75 70 614l3l6 5 11 79 79 615l316 5 0 91 617l3l6 5 11 81 6181316 5 0 621i316 5 6201316 5 11 77 77 11 10 75 5 85 86 624i3ie 5 623i3i6 85 9 626i3i6 5 13 113 113 627i3i6 5 0 0 630i3i6 5 629i3i6 5 11 73 0 0 632i3i6 5 11 73 633i3i6 5 0 0 636i3i6 5 635i3i6 5 10 69 0 0 639i3i6 5 638i3i6 5 12 96 0 641l 3 l6 5 12 92 89 3 642i3i6 5 644i3i 6 5 12 91 0 0 645i3i6 5 0 0 647i 3 i6 5 11 79 648i3ie 5 0 0 650i3i6 5 12 76 651l3l6 5
c 12 12 14 10 10 9 11 10 11 11 11 12 9 10 10 11 10 12 12 11 11 12 11 12 12 13 10 12 10 10 10 12 10 12 11 12 10 12 11 11 11 13 12 12 12
q 81 94 123 54 45 45 65 47 59 63 59 81 38 42 47 59 49 73 77 62 70 65 67 62 87 86 70 88 62 58 70 90 72 100 67 104 62 81 73 84 80 107 97 94 93
b f 81 0 123 0 0 0 0 0 0 0 0 0 0 30 12 0 59 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 100 0 104 0 0 0 0 0 107 0 0 0
4. B-DIMBNSIONAL BASIS DATA FOR I 1 3 1 6 - 1 3 1 6 i 3 i 6 AND l 3 oi3-3O13 3 oi
alg. 652i3i6 655i3ie 658i3ie 66I1316 664i3i 6 667i3i6 670i3ie 673i3i6 676i3i6 679i3ie 682i3ie 685i3ie 6881316 6911316 694 13 i 6 697i3ie 700i3i6 703i3ie 706i3i6 709i3ie 712i316 7151316 7181316 7211316 724i3ie 727i3ie 730i3i6 733i3ie 736i3i6 739i3ie 742i3ie 745i3ie 748i3i6 7511316 754i3i6 757i3ie 760i3ie 763i3i6 766i3i6 769i3ie 772i3ie 775i3ie 778i3i6 781l316 784i3ie
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 13 11 13 12 13 8 10 10 10 9 11 11 10 10 12 10 12 11 12 9 11 11 11 11 13 11 12 11 13 13 11 11 13 12 12 12 14 12 12 12 14 12 14 13 14
q 108 89 120 83 122 42 54 61 59 40 58 74 63 67 85 71 97 74 93 53 69 74 77 79 101 81 94 88 118 116 82 86 106 97 79 102 128 101 83 106 132 111 145 104 146
6 0 0 120 0 122 0 0 0 0 0 0 0 0 0 85 0 97 0 93 0 0 0 0 0 101 0 0 0 117 116 0 0 0 0 0 102 128 97 0 0 132 105 145 0 146
/
alg.
653i3i6 656i3i6 659i3i6 662i3i6 665i3i6 6681316 671l3l6 674i3i 6 677i3i6 68O1316 683i3i6 6861316 689i3i6 692i3i6 695i3i6 698i3i6 701i3i6 704i3i6 707i3i6 710i3i6 7131316 7161316 7191316 722i3i6 725i3i6 728i3i6 7311316 734i3i6 1 737i3i6 740i3i6 743i3i6 746i3i6 749i3i6 752i3i6 755i3i6 758i3i6 761l316 4 764i3i 6 767i3i6 770i3i6 773i3i6 6 776i3i6 779i3i6 782i3i6 785i3i6
0
5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 11 12 11 13 13 9 9 11 10 10 10 12 10 11 10 11 10 12 12 10 10 12 11 12 10 12 12 12 12 14 11 12 11 13 12 13 11 13 12 13 12 13 12 14 14
q 82 108 71 102 115 46 53 65 63 47 63 81 67 74 63 82 59 85 97 61 66 82 77 90 70 92 94 103 101 131 78 98 86 112 75 117 90 116 79 121 98 130 89 123 142
c q b / alg. 0 b f 82 654i3ie 5 12 94 94 108 0 657i3ie 5 12 101 0 66O1316 5 12 90 90 102 0 663i3i6 5 12 103 106 9 6661316 5 14 134 134 0 0 669i3i6 5 9 50 0 0 672i3i6 5 10 57 0 0 675i3ie 5 9 52 0 0 678i3i6 5 11 70 0 0 68I1316 5 10 51 0 684i3i6 5 11 70 70 81 0 687i3i6 5 9 56 0 0 690i3i6 5 11 74 0 693i3i6 5 11 78 78 0 696i3i6 5 11 78 78 82 0 699i3i6 5 11 86 0 0 702i3i6 5 11 70 85 705i3i6 5 11 82 82 97 708i3i6 5 13 108 108 0 0 711i3i6 5 10 61 11 74 5 0 0 7141316 10 5 0 0 66 7171316 0 0 7201316 5 12 88 90 0 723i3i6 5 12 90 0 0 726i3i6 5 11 81 0 0 729i3i6 5 11 83 94 732i3i6 5 13 105 105 102 1 735i3i6 5 12 103 0 101 738i3i6 5 13 116 116 131 0 741i3i6 5 10 70 0 0 744i3i6 5 12 90 0 0 747i3i6 5 12 94 0 0 750i3i6 5 12 101 0 0 753i3i6 5 11 64 0 0 756i3i6 5 13 90 5 13 117 113 113 759i3i6 0 0 762i3i6 5 12 105 116 0 765i3ie 5 11 68 0 768i3i6 5 13 94 94 0 7711316 5 13 117 117 98 774i3i6 5 13 113 113 130 777i3i6 5 13 126 120 6 0 780i3i6 5 13 108 108 123 783i3i6 5 13 127 127 142 786i3i6 5 15 161 161
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. 787i3i6 790i3i6 793i3ie 796i3ie 799i3ie 802i3ie 805i3ie 8O81316 8II1316 8141316 817l3l6 8201316 823i3i6 8261316 829i3ie 832i3i6 835i3i6 838i3i6 8411316 844i3ie 847i3ie
850i3ie 853i3i6 856i3i6
859i3ie 862i3i6 865i3i6 8681316 8711316 874i3ie 877i3i6 88O1316 883i3i6 8861316 889i3ie 892i3ie
895i3ie 898i3i6 901i3i6 904i3i6 907i3ie 910i3i6 9131316 916i3i6 9191316
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 9 11 11 11 11 13 11 13 13 8 7 9 9 9 8 10 10 9 8 10 10 10 9 11 11 10 9 11 11 10 10 12 10 11 10 12 12 9 8 10 10 10 9 11 11
q 38 59 61 61 61 89 56 96 80 33 32 42 42 46 42 60 56 45 42 56 55 60 54 76 71 64 59 77 76 57 49 95 56 92 56 82 94 41 39 52 54 57 52 73 71
b f 25 13 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 57 0 95 0 92 0 82 0 0 0 0 0 0 0 0 0
alg.
0
788i3i6 791i3i6 794i3i6 797 1 3 ie
5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
8OO1316 803i3i6 8O61316 809i3i6 812i3i6 815l316 8181316 8211316 824i3i6 827i3i6 830i3i6 833i3i6 836i3i6 839i3i6 842i3i6 845i3i6 848i3i6 851l316 854i3i6 857i3i6 86O1316 863i3i6 8661316 869i3i6 872i3i6 875i3i6 878i3i6 88I1316 884i3ie 887i3i6 890i3i6 893i3i6 896i3i6 899i3i6 902i3ie 905i3i6 908i3i6 911i3i6 914i316 9171316 920i3i6
c 10 10 12 11 12 11 12 12 14 8 8 8 10 9 9 9 11 9 9 9 11 10 10 10 12 10 10 10 12 10 11 9 11 11 11 11 13 9 9 9 11 10 10 10 12
q 48 47 71 62 73 66 81 74 114 36 39 39 49 46 53 49 67 47 53 52 66 59 69 64 86 66 74 73 91 66 64 49 75 80 75 87 113 46 46 48 61 59 63 61 82
b / alg. 0 c q b f 39 9 789i3ie 5 10 49 0 0 0 792i3i6 5 11 57 0 0 795i3i6 5 10 49 0 0 798i3i6 5 12 74 0 0 8011316 5 12 77 12 81 5 81 66 804i3i6 0 0 807i3i6 5 12 62 0 0 8IO1316 5 13 99 0 0 813l3l6 5 7 29 0 0 8161316 5 9 40 0 0 819l316 5 8 35 0 0 822i3i6 5 9 46 0 0 825i3i6 5 8 39 0 0 8281316 5 10 53 0 0 831l3l6 5 9 49 0 0 834i3i6 5 10 60 0 0 837i3i6 5 8 37 0 840i3ie 5 10 55 0 0 843i3ie 5 9 45 0 0 0 846i3i6 5 10 63 0 849i3ie 5 9 49 0 0 852i3ie 5 11 70 0 0 0 855i3i6 5 10 61 0 0 858i3i6 5 11 79 0 0 86I1316 5 9 52 61 5 864i3ie 5 11 78 75 3 0 0 867i3ie 5 10 62 0 870i3ie 5 11 88 71 17 0 0 873i3i6 5 9 42 0 876i3i6 5 11 81 81 64 879i3ie 5 11 80 0 0 882i3i6 5 10 68 68 75 0 885i3i6 5 10 73 0 8881316 5 12 99 99 75 0 8911316 5 11 63 0 894i3i6 5 12 106 106 113 0 897i3i6 5 8 37 0 0 900i3i6 5 10 50 0 0 903i3ie 5 9 45 0 0 906i3ie 5 10 55 0 0 909i3i6 5 9 50 0 0 9121316 5 11 66 0 0 9151316 5 10 62 0 0 9181316 5 11 72 0 0 9211316 5 9 47
4. B-DIMBNSIONAL BASIS DATA FOR Ii3i6-1316i 3 i 6 AND l 3 oi3-3O13 3 oi3
alg. 922i3ie 925i3ie 928i3ie 9311316 934i3i6 937i3ie 940i3ie 943i3ie 946i3ie 949i3ie 952i3i6 955i3ie 958i3ie 9611316 964i3i 6 967i3ie 970i3i6 973i3ie 976i3ie 979i3ie 982i3i 6 985i3ie 988i3ie 991i316 994i3ie 997i3ie IOOO1316 10031316 IOO61316 1009l316 10121316 10151316 10181316 10211316 1024i3i6 1027i3i 6 10301316 1033i3i 6 1036i3i6 1039i3i6 1042i3i6 1045i3i6 1048i3i6 10511316 1054i3i6
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 10 9 11 11 11 10 12 12 10 9 11 11 11 10 12 12 11 10 12 12 11 11 13 11 12 11 13 13 10 9 11 11 11 10 12 12 11 10 12 12 12 11 13 13 12
q 55 52 69 70 74 68 93 90 56 52 69 70 74 67 92 89 77 72 93 94 69 62 114 71 109 69 98 116 55 52 68 73 74 68 92 93 72 68 88 92 94 87 115 115 96
alg. 0 c q b f 6 / alg. 0 c q b f 0 0 0 923i3i6 5 10 59 924i3i6 5 11 67 0 0 0 926i3i6 5 10 63 927i3i6 5 10 58 0 0 0 929i3i6 5 10 64 930i3i6 5 11 75 0 0 0 932i3i6 5 12 81 933i3i6 5 10 63 0 0 935i3i6 5 11 75 936i3i6 5 12 86 86 0 0 0 938i3i6 5 11 83 939i3i6 5 11 78 12 0 95 0 5 95 9411316 5 11 80 942i3i6 944i3i 6 5 13 105 105 0 0 945i3i6 5 9 48 0 0 0 947i3i6 5 10 60 948i3i6 5 11 68 0 0 0 950i3i6 5 10 63 9511316 5 10 58 0 0 0 954i3i6 5 11 75 953i3i6 5 10 64 0 0 0 956i3i6 5 12 81 957i3i6 5 10 63 0 0 0 959i3i6 5 11 75 960i3i6 5 12 86 962i3i 6 5 11 82 0 0 0 963i3i6 5 11 77 0 0 0 965i3i6 5 11 79 966i3i6 5 12 94 0 0 0 968i3i6 5 13 104 969i3i6 5 10 65 972i3i 6 5 12 93 0 0 0 971i3i6 5 11 81 0 0 0 974i3i6 5 11 87 975i3i6 5 11 78 0 0 0 977i3i6 5 11 88 978i3i6 5 12 103 0 0 0 980i3i6 5 13 109 9811316 5 10 54 12 69 98 98 5 0 983i3i6 5 11 83 984i3i6 0 0 986i3i6 5 12 77 77 987i3i6 5 12 99 114 0 989i3i6 5 10 61 990i3i6 5 11 80 80 0 0 992i3i6 5 12 90 90 993i3i6 5 11 90 109 0 995i3i6 5 12 100 996i3i6 5 13 119 119 0 0 998i3i6 5 12 88 88 999i3i6 5 12 79 98 0 1002l316 5 13 125 125 IOOI1316 5 12 106 0 0 10041316 5 14 135 135 10051316 5 9 51 0 0 0 10071316 5 10 63 IOO81316 5 11 67 0 0 IOH1316 5 10 61 lOlOisie 5 10 59 59 0 0 10141316 5 11 71 71 10131316 5 10 64 0 0 10161316 5 12 80 10171316 5 10 67 67 74 10191316 5 11 79 79 10201316 5 12 86 86 0 1022i3i6 5 11 79 79 1023i3ie 5 11 81 77 4 11 92 5 80 0 1025i3i6 10261316 5 12 91 91 89 4 1028i3i6 5 13 104 104 0 1029i3ie 5 10 64 11 5 12 0 79 0 87 0 5 1032i3ie 10311316 1034i3i 6 5 11 79 79 0 0 1035i3ie 5 11 77 0 0 1037i3i6 5 11 83 1038i3ie 5 12 94 94 0 0 10401316 5 13 103 10411316 5 11 83 83 94 1043i3i6 5 12 98 98 1044i3ie 5 13 109 109 0 1046i3i6 5 12 102 102 1047i3ie 5 12 100 95 5 115 0 1049i3i6 5 12 102 10501316 5 13 117 117 110 5 1052i3i6 5 14 130 130 1053i3ie 5 11 84 82 2 96 1055i3i6 5 12 103 103 1056i3ie 5 13 115 115
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. 1057i3ie IO6O1316 1063i3i6 IO661316 1069i3ie 1072i3i6 1075i3ie 1078i3ie IO8I1316 1084i3ie 1087i3ie 1090l316 1093i3ie 1096i3i6 1099i3i6 11021316 11051316 11081316 11111316 11141316 11171316 11201316 11231316 11261316 11291316 11321316 11351316 11381316 11411316 11441316 11471316 11501316 11531316 11561316 11591316 1162i316 1165l316 11681316 11711316 11741316 11771316 11801316 11831316 H861316 11891316
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 11 12 11 13 13 12 12 14 12 13 12 14 14 8 9 9 9 11 11 12 9 10 9 11 11 10 10 12 11 12 9 11 11 11 11 13 10 12 11 12 10 12 12 12 12
q
71 106 66 90 119 86 81 140 91 132 88 120 145 46 55 59 61 75 89 98 55 71 64 82 83 75 76 94 93 109 67 83 87 98 99 121 83 105 69 114 74 104 115 102 120
alg. 0 c alg. 0 b / c q b f b f q 0 0 1058i3ie 5 12 80 0 1059i3ie 5 11 91 106 0 0 1062i3ie 5 13 115 IO6I1316 5 12 100 0 0 0 1064i3i6 5 12 81 1065i3i6 5 12 75 0 IO681316 5 13 125 125 1067i3ie 5 12 110 0 0 1071i3i6 5 11 71 60 11 1070i3i6 5 14 134 0 5 12 106 86 106 1074i3ie 5 13 121 121 1073i3i6 5 13 96 0 96 107713i6 5 13 125 125 1076i3ie 140 IO8O1316 5 12 97 97 1079i3i6 5 11 78 0 0 81 10 1082i3i6 5 13 110 110 1083i3ie 5 12 113 132 1085i3ie 5 13 126 120 6 IO861316 5 14 145 145 0 0 1089i3ie 5 13 101 IO881316 5 13 107 107 120 0 1092i3ie 5 14 151 151 1091i3i6 5 13 132 139 6 1094i3ie 5 15 164 164 1095i3i6 5 7 42 42 0 0 0 1098i3ie 5 8 51 1097i3i6 5 9 50 0 0 0 HOI1316 5 8 52 HOO1316 5 10 59 0 0 0 11031316 5 9 59 11041316 5 10 66 0 0 0 11071316 5 10 68 11061316 5 10 68 0 0 0 11101316 5 10 78 11091316 5 9 67 0 0 0 11131316 5 11 87 11121316 5 10 76 0 0 0 11161316 5 9 59 11151316 5 8 51 9 5 10 0 63 0 63 5 0 11191316 11181316 11 5 10 0 75 0 67 5 0 11211316 11221316 0 0 0 11241316 5 10 75 11251316 5 10 71 0 0 0 11281316 5 11 87 11271316 5 10 76 0 0 0 11311316 5 9 64 11301316 5 12 94 0 0 0 1133l3l6 5 10 71 11341316 5 11 82 0 0 0 11361316 5 11 87 11371316 5 11 83 0 0 0 11401316 5 11 97 11391316 5 10 82 0 0 0 1142i316 5 12 108 11431316 5 11 94 0 0 0 11461316 5 13 120 11451316 5 12 105 0 0 0 11491316 5 10 71 11481316 5 10 79 0 0 0 11521316 5 11 95 11511316 5 10 83 0 0 0 11551316 5 10 83 11541316 5 12 99 98 0 11581316 5 12 105 105 11571316 5 11 90 99 11611316 5 12 106 106 11601316 5 12 114 114 121 5 10 60 0 0 1163l316 11641316 5 11 75 11 5 11 90 83 98 90 5 98 H661316 11671316 105 0 0 11701316 5 11 77 11691316 5 10 62 0 11731316 5 11 99 99 11721316 5 12 84 84 114 11761316 5 13 121 121 11751316 5 12 106 106 0 0 11791316 5 11 85 11781316 5 11 93 93 104 11811316 5 11 104 104 11821316 5 12 123 123 115 0 11841316 5 13 134 134 11851316 5 11 83 102 0 1187l3l6 5 12 94 H881316 5 13 113 113 120 11901316 5 13 139 139 11911316 5 13 131 131
4. 5-DIMENSIONAL BASIS DATA FOR I 1 3 1 6 - 1 3 1 6 i 3 i 6 AND l 3 oi3-3013 3 oi3
alg.
0
11921316
5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
11951316 11981316 12011316 1204i3i6 1207i3i6 12101316 12131316 12161316 12191316 1222i3i6 1225i3i6 1228i3i6 12311316 1234i3i6 1237i3i6 1240i3ie 1243i3ie 1246i3i6 1249i3i6 1252i3ie 1255i3i6 1258i3ie 12611316 1264i3i6 1267i3i6 1270i3ie 1273i3i6 1276i3ie 1279i3ie 1282i3i6 1285i3i6 1288i3i6 12911316 1294i3ie 1297i3ie 13001316 1303i3ie 1306i3ie 1309i3i6 1312i316 13151316 23013 53013 83013
c 14 11 12 11 12 11 12 9 10 10 12 12 11 12 12 13 11 11 13 12 13 11 12 11 13 13 12 12 14 13 14 11 12 12 13 12 14 14 13 14 14 15 7 7 9
q 150 78 93 90 105 101 116 64 79 80 102 106 87 116 95 131 94 101 121 113 136 76 117 76 102 132 109 127 161 116 165 104 127 98 143 97 127 166 131 176 145 199 18 18 26
b / 150 0 0 0 105 0 116 0 0 0 102 0 0 116 0 131 0 0 0 0 136 0 0 0 102 132 109 127 161 0 165 100 4 127 92 6 143 0 127 166 131 176 145 199 18 18 26
alg. 11931316 11961316 11991316 1202i3ie 1205i3i6 1208i3i6 1211i3i6 12141316 12171316 12201316 1223i3ie 1226i3i6 1229i3i6 1232i3ie 1235i3i6 1238i3i6 1241i316 1244i3i6 1247i3i6 1250i3i6 1253i3i6 1256i3i6 1259i3ie 1262i3ie 1265i3i6 1268i3i6 12711316 1274i3i6 1277i3i6 1280i3i6 1283i3i6 1286i3i6 1289i3ie 1292i3ie 1295i3i6 1298i3i6 13011316 1304i3ie 1307i3i6 13101316 13131316 13161316 33013 63013 93013
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 9 10 10 12 12 12 13 10 11 11 11 13 12 13 13 14 11 12 11 13 13 12 12 12 12 14 12 13 12 14 14 12 13 13 13 13 13 15 14 15 15 16 7 8 7
q 62 77 79 101 105 116 131 72 87 91 95 117 102 131 110 146 90 113 102 128 132 91 113 91 121 147 105 146 101 135 161 116 139 113 143 112 151 181 150 195 164 218 18 22 18
b / 0 0 0 0 0 0 131 0 0 91 0 117 102 131 110 146 0 0 0 128 132 0 113 0 0 147 0 146 0 135 161 114 2 139 108 5 143 112 151 181 150 195 164 218 18 22 18
alg. 11941316 11971316 1200i3i6 1203i3ie 1206i3i6 1209i3i6 12121316 12151316 1218i3i6 1221i3i6 1224i3i6 1227i3i6 1230i3i6 1233i3i6 1236i3i6 1239i3ie 1242i3i6 1245i3i6 1248i3ie 1251i3i6 1254i3i6 1257i3i6 1260i3i6 1263i3i6 1266i3i6 1269i3i6 1272i3ie 1275i3i6 1278i3i6 1281l316 1284i3ie 1287i3i6 1290i3i6 1293i3ie 1296i3i6 1299i3ie 1302i3ie 1305i3i6 1308i3i6 13111316 13141316 13013 4-3013 73013 103013
a c 5 10 5 11 5 11 5 11 5 13 5 13 5 14 5 11 5 12 5 11 5 12 5 10 5 11 5 11 5 12 5 10 5 12 5 12 5 12 5 12 5 14 5 11 5 13 5 12 5 13 5 11 5 13 5 13 5 13 5 13 5 15 5 13 5 14 5 12 5 14 5 13 5 14 5 12 5 13 5 13 5 14 5 6 5 8 5 8 5 8
q 70 85 90 94 116 131 146 80 95 91 106 72 101 80 116 82 102 109 117 121 147 102 128 87 136 90 124 142 120 146 180 128 151 128 158 112 166 112 157 126 180 14 22 22 22
b f 0 0 0 0 116 0 146 0 0 0 106 0 101 0 116 0 0 0 117 121 147 0 128 0 0 0 124 142 120 146 180 128 151 128 158 0 166 0 157 126 180 14 22 22 22
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. H3013 143013 173013 203O13 233013 263013 293013 323013 353013 383013 413013 44 3 oi3 473013 503013 533013 563013 593013 623013 653013 683013 713013 743013 773013 803O13 833013 863013 893013 923013 953013 983013 1013013 104 30 13 1073013 1103013 1133013 H63013 1193013 1223013 1253013 1283013 1313013 1343013 1373013 1403013 1433013
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 8 9 7 8 8 9 7 9 8 10 7 9 9 10 9 12 12 9 10 11 10 11 13 14 4 7 7 10 10 10 11 10 10 12 9 9 8 10 10 10 10 12 11 12 10
q 22 26 18 22 22 26 19 29 23 33 20 30 28 36 30 54 50 30 36 42 41 45 61 74 8 19 21 32 36 43 47 36 42 51 28 27 26 42 39 38 35 51 50 54 44
b 22 26 16 20 20 24 17 29 21 33 18 30 26 36 0 54 0 28 34 42 0 0 61 0 8 19 21 32 36 43 47 0 0 0 0 0 0 42 0 0 0 0 50 54 40
/
2 2 2 2 2 2 2 2
2 2
4
alg.
0
123013 153013 I83013 213013 24 30 13 273013 303013 333013 363013 393013 42 3 O i3 453013 483013 513013 543013 573013 603013 633013 663013 693013 723013 753013 783013 813013 843013 873013 903013 933013 963013 993013 1023013 1053013 1083013 1H3013 1143013 1173013 1203O13 1233013 1263013 1293013 1323013 1353013 1383013 1413013 144 30 13
5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 9 9 8 9 9 10 8 9 9 10 8 8 10 10 10 10 13 9 11 12 11 12 12 15 5 8 8 9 11 11 12 10 11 7 10 10 9 9 11 10 11 9 10 9 11
q 26 26 24 28 28 32 25 31 29 35 26 24 34 36 38 34 58 30 42 48 49 53 54 84 12 27 25 32 42 49 53 35 47 18 33 32 34 31 47 38 43 34 38 36 55
b 26 26 24 28 28 32 25 31 29 35 26 22 34 36 0 0 58 28 42 48 0 0 0 0 12 27 25 32 42 49 53 0 0 14 0 0 0 0 0 0 0 30 34 0 55
/
2
2
4
4 4
alg.
0
133013 I63013 193013 223013 253013 283013 313013 343013 373013 403013 433013 463013 493013 523013 553013 583013 613013 643013 673013 703013 733013 763013 793013 823013 853013 883013 913013 943013 973013 1003O13 1033O13 1063013 1093O13 1123013 1153013 H83013 1213013 1243013 1273013 1303O13 1333013 1363013 1393013 1423013 1453013
5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 8 10 9 10 10 11 8 10 9 11 8 9 9 11 11 11 8 10 10 9 10 12 13 16 6 9 9 10 9 10 9 11 11 8 8 11 9 10 9 11 11 10 11 10 10
q 22 30 30 34 34 38 23 35 27 39 24 30 32 40 46 42 24 36 36 33 37 57 64 94 15 31 28 38 37 41 31 40 46 23 22 37 34 39 30 46 43 42 46 47 44
b 22 30 30 34 34 38 21 35 25 39 22 30 32 40 0 0 20 36 34 0 0 57 0 94 15 31 28 38 37 41 0 0 0 0 18 0 0 0 0 46 0 42 46 47 0
/
2 2 2
4 2
4
4. B-DIMBNSIONAL BASIS DATA FOR I 1 3 1 6 - 1 3 1 6 i 3 i 6 AND l 3 oi3-3O13 3 oi
alg. 1463013 1493013 1523013 1553013 1583013 1613013 1643013 1673013 1703013 1733013 1763013 1793013 1823013 1853013 1883013 1913013 1943013 1973013 2003O13 2033013 2063013 2093013 2123013 2153013 2183013 2213013
2243oi3 2273013 2303013 2333013 2363013 2393013 242 3O i3 2453013 2483013 2513013 2543013 2573013 2603013 2633013 2663013
2693oi3 2723oi3 2753013 2783013
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 11 10 12 12 11 11 14 6 9 9 10 9 10 9 11 11 8 8 11 9 10 9 11 11 10 11 10 10 12 11 12 10 13 13 14 14 17 7 10 10 11 8 11 10 11
q 55 40 59 56 60 53 86 15 32 29 40 40 44 33 42 49 25 24 39 37 42 33 49 46 45 49 51 48 67 52 63 54 87 80 89 86 125 22 47 39 55 32 51 51 57
6 55 0 59 53 60 53 86 15 32 29 40 40 44 0 0 0 0 20 0 0 0 0 49 0 45 49 51 0 67 48 63 54 87 80 0 0 122 0 47 0 55 32 0 45 51
/
alg.
1473013 I5O3013 I533013 3 I563013 1593013 162 3O i3 1653013 1683013 1713013 1743013 1773013 1803013 1833013 1863013 1893013 1923013 1953013 4 1983013 2013013 2043013 2073013 2103013 2133013 2163013 2193013 2223013 2253013 2283013 2313013
4 2343oi3 2373013 2403013 2433013 2463013 2493013 2523013 3 2553013 2583013 2613013 2643013 2673013 2703013 2733013 6 2763013 6 2793013
0
5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 11 11 11 13 12 12 4 7 7 10 10 10 11 10 10 12 9 9 8 10 10 10 10 12 11 12 10 11 10 12 12 11 11 14 15 15 5 8 7 11 11 9 11 11 12
q 52 51 48 67 71 64 7 19 22 33 38 46 50 38 45 54 30 29 29 45 42 41 38 54 53 57 48 59 44 63 60 65 58 91 102 99 12 28 22 45 53 38 51 61 67
b 49 51 0 67 71 64 7 19 22 33 38 46 50 0 0 0 0 0 0 45 0 0 0 0 53 57 44 59 0 63 57 65 58 91 0 0 8 0 0 0 53 38 0 61 67
alg. 0 / 3 1483013 5 I5I3013 5 154 3 oi3 5 1573013 5 1603013 5 1633013 5 1663013 5 1693013 5 1723013 5 1753013 5 1783013 5 1813013 5 1843013 5 1873013 5 1903013 5 1933013 5 1963013 5 1993013 5 2023013 5 2053013 5 2083013 5 2H3013 5 2143013 5 2173013 5 2203013 5 2233013 5 4 2263013 5 2293013 5 2323013 5 2353013 5 3 2383013 5 2413013 5 2443013 5 2473013 5 2503013 5 2533013 5 4 2563013 5 2593013 5 2623013 5 2653013 5 2683013 5 2713013 5 2743013 5 2773013 5 28O3013 5
c 12 11 12 10 13 13 5 8 8 9 11 11 12 10 11 7 10 10 9 9 11 10 11 9 10 9 11 11 11 11 13 12 12 13 16 16 6 9 8 10 12 10 12 12 13
q 63 48 59 49 82 75 11 28 26 34 44 52 56 37 50 20 35 34 37 34 50 41 46 37 41 40 59 56 55 52 71 76 69 76 115 112 18 41 28 47 61 45 57 71 77
b 63 44 59 49 82 75 11 28 26 34 44 52 56 0 0 16 0 0 0 0 0 0 0 33 37 0 59 53 55 0 71 76 69 0 0 0 18 41 28 47 61 0 0 71 77
/ 4
4
4 4
3
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. 28I3013 284 3 O i3 2873013 2903013
2933oi3 2963oi3 2993oi3 302 3 013 3053013 3O83013 3H3013 3143013 3173013 3203013 3233013 3263013
3293oi3 3323oi3 3353013 3383013 34I3013 3443013 3473013 3503013 3533013 3563013
3593oi3 3623013 3653013 3683013 37I3013 3743013 3773013 38O3013 3833013 3863013
3893oi3 392 3 oi3 3953013 3983013 4OI3013 404 30 13 4073013
410soi3 4133013
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 7 10 9 13 13 11 13 13 14 8 10 12 11 12 12 14 14 15 12 14 14 13 13 15 14 15 13 15 15 14 14 16 15 16 8 10 12 10 11 12 12 13 14 13 15
q 24 53 35 74 84 57 78 88 99 32 41 55 57 63 56 76 80 108 60 82 83 78 79 100 85 101 78 103 101 101 98 127 108 124 34 47 61 53 61 69 66 79 92 83 107
b 0 53 0 74 84 57 76 88 99 32 0 0 57 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 120 0 0 0 0 55 63 0 0 0 0 0
/
2
4
6 6
alg.
0
2823013 2853013 2883013 2913013 294 3 oi3 297 3 oi3 3OO3013 3033013 3O63013 3093O13 3123013 3153013 3183013 3213013 324 3 O i3 3273013 3303013 3333013 3363013 3393013 342 3 oi3 345 3 oi3 348 3 oi3 35I3013 3543013 3573013 36O3013 3633013 3663013 3693013 3723013 3753013 3783013 38I3013 384 3 O i3 3873013 3903O13 3933013 3963013 3993013 402 30 13 4053O13 4O83013 4II3013 414 3 O i3
5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 8 11 10 12 14 12 14 14 15 8 11 10 12 12 13 13 15 15 13 13 15 13 14 13 15 15 14 14 16 14 15 14 16 16 9 11 12 11 12 13 13 14 15 14 14
q 35 69 46 73 95 67 87 101 112 30 49 49 65 63 69 73 93 102 69 70 92 75 91 76 97 98 90 88 113 98 114 95 124 121 42 53 63 63 71 79 75 88 101 95 96
b / alg. 0 c q b / 35 2833013 5 9 42 38 4 69 2863013 5 12 80 80 46 0 2893013 5 12 63 73 2923oi3 5 13 84 84 95 2953oi3 5 10 46 37 9 0 0 2983013 5 13 76 86 1 3OI3013 5 12 75 71 4 101 304 30 13 5 13 86 82 4 112 0 3073013 5 7 24 0 3IO3013 5 9 38 38 0 0 3133013 5 11 47 0 0 3163013 5 11 57 65 0 3193013 5 11 55 63 3223013 5 13 71 71 0 0 3253013 5 13 63 0 0 3283013 5 14 86 0 0 3313013 5 14 95 0 3343oi3 5 16 115 0 0 0 3373013 5 13 73 0 0 34O3013 5 14 79 12 5 66 0 0 3433013 14 5 87 0 0 3463013 0 0 349 3 oi3 5 14 88 0 0 3523013 5 14 88 0 0 3553013 5 14 89 0 0 3583013 5 16 110 0 0 36I3013 5 14 91 0 0 3643013 5 15 100 109 4 3673013 5 13 85 0 0 0 37O3013 5 15 114 0 0 3733013 5 15 111 0 0 3763013 5 15 111 0 0 3793013 5 15 108 0 3823013 5 17 137 133 4 42 3853013 5 10 50 50 0 0 3883013 5 11 55 5 13 69 0 0 3913013 0 0 394 3 O i3 5 12 73 71 3973013 5 13 81 81 79 4OO3013 5 14 89 89 0 0 403 3 013 5 14 84 0 0 4O63013 5 15 97 0 0 4093O13 5 16 110 0 0 412 3 013 5 14 95 0 0 415 3 013 5 15 108
4. 5-DIMENSIONAL BASIS DATA FOR I 1 3 1 6 - 1 3 1 6 i 3 i 6 AND l 3 oi3-3013 3 oi3
alg.
0
4I63013 4193013 422 3 O i3 4253013
5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
4283oi3 4313013 4343013 4373013 4403013 443 3 oi3 446 3 oi3 449 3 oi3 4523013 4553013 4583013 46I3013 464 3 O i3 467 3 O i3 4703O13 4733013 4763013 4793013 482 3 O i3
4853oi3 4883013 49I3013
4943oi3 4973013 5OO3013 5033O13 5O63013 5093013 5123013 5153013 5183013 5213013 5243013 5273013 53O3013 5333013 5363013 539 3 oi3 542 3 O i3 545 3 oi3 5483013
c 15 16 14 15 16 7 12 12 12 14 14 15 13 15 12 13 12 14 14 13 13 15 14 15 10 13 14 13 13 15 14 15 12 14 13 15 15 15 16 12 12 14 13 14 11
q 108 121 105 118 131 32 77 84 82 98 112 118 96 114 79 86 88 106 104 99 91 115 114 124 55 100 106 98 93 114 116 126 82 106 101 128 120 137 143 62 72 84 74 100 50
alg. a c q b / alg. a c q b f b f 0 0 0 417 3 013 5 16 120 4I83013 5 15 109 121 0 42O3013 5 16 121 42I3013 5 17 133 133 0 0 0 423 3 oi3 5 15 121 424 3 O i3 5 16 137 0 0 0 4263013 5 16 134 4273013 5 17 150 131 429 3 oi3 5 17 147 147 4303013 5 18 163 163 32 4323013 5 10 65 65 4333013 5 11 71 71 77 5 13 83 83 435soi3 436soi3 5 11 76 76 84 4383013 5 12 84 84 4393013 5 13 92 92 82 44I3013 5 13 90 90 442 3 oi3 5 13 90 90 98 444 3 oi3 5 12 90 90 445 3 oi3 5 13 101 101 112 447 3 oi3 5 13 96 96 448 3 oi3 5 14 107 107 118 4503013 5 12 88 88 4513013 5 13 98 98 96 454 3 oi3 5 14 104 104 4533oi3 5 14 106 106 114 457 3 oi3 5 12 81 81 4563oi3 5 11 71 0 0 0 460 3 oi3 5 12 76 4593013 5 13 89 89 0 0 0 4623013 5 13 84 4633013 5 14 94 88 465 3 oi3 5 13 98 98 466 3 oi3 5 13 96 96 106 4693oi3 5 14 106 106 4683013 5 13 96 96 104 4713013 5 15 114 114 4723oi3 5 12 86 0 474 3 O i3 5 13 97 99 0 4753oi3 5 14 110 110 14 104 0 0 5 0 477 3 oi3 4783013 5 14 102 14 0 116 5 5 13 103 116 103 4813013 4803013 114 484 3 O i3 5 14 111 111 483 3 oi3 5 15 127 127 124 4873oi3 5 16 135 135 4863013 5 15 122 122 0 4893oi3 5 11 65 65 490soi3 5 12 90 90 100 4933013 5 14 108 108 4923oi3 5 13 98 98 106 4953013 5 15 116 116 4963oi3 5 12 85 0 98 4983013 5 13 93 88 5 4993013 5 14 106 106 0 0 502 3 013 5 14 101 5OI3013 5 14 106 106 114 5053013 5 14 118 118 5043013 5 13 105 105 116 5O83013 5 14 113 113 5073013 5 15 129 129 126 5II3013 5 16 137 137 5IO3013 5 15 124 124 0 0 5143013 5 13 90 5133013 5 13 98 98 106 0 5173013 5 15 114 114 5163013 5 14 98 0 0 5203013 5 14 112 5193013 5 14 117 117 14 128 125 5 5 15 109 125 0 5233013 5223013 0 5263013 5 14 121 121 5253013 5 16 136 136 137 529 3 oi3 5 16 148 148 5283013 5 15 132 132 143 0 53I3013 5 17 159 159 5323013 5 11 56 0 0 5343oi3 5 12 62 0 5353013 5 13 68 0 0 0 5373013 5 13 78 5383013 5 13 78 0 0 5403oi3 5 12 68 0 54I3013 5 13 78 544 3 O i3 5 13 90 0 0 5433oi3 5 14 84 0 0 0 0 5463013 5 14 96 5473013 5 15 106 0 0 0 5493013 5 12 56 55O3013 5 12 56
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg.
a 5 554 3 oi3 5 5573013 5 56O3013 5 5633013 5 5663013 5 5693oi3 5 5723013 5 5753013 5 5783013 5 58I3013 5 584 3 O i3 5 5873013 5 5903013 5 5933013 5 5963013 5 599 3 oi3 5 602 30 13 5 6053013 5 6O83013 5 6II3013 5 6143013 5 6173013 5 6203013 5 6233013 5 6263013 5 6293013 5 6323013 5 6353013 5 6383013 5 64I3013 5 644 3 O i3 5 647 3 O i3 5 65O3013 5 6533013 5 6563013 5 659 3 oi3 5 662 3 O i3 5 6653013 5 6683013 5 67I3013 5 674 3 O i3 5 6773013 5 68O3013 5 6833013 5 55I3013
c
q
13 13 11 11 13 12 13 11 13 13 13 13 15 13 14 11 13 13 13 13 15 13 14 13 15 15 12 13 13 13 15 15 16 13 14 12 13 12 14 14 13 14 14 15 13
62 76 60 58 76 60 76 66 92 86 88 82 108 78 96 64 86 80 90 84 106 94 114 94 124 114 69 75 88 81 103 123 129 72 78 74 82 67 92 89 99 109 105 115 81
alg. b f 0 5523013 0 5553013 0 5583013 0 56I3013 0 564 3 O i3 0 5673013 0 5703O13 0 5733013 92 5763013 0 5793013 0 5823013 0 5853013 0 5883013 0 5913013 0 594 3 oi3 0 5973013 0 6OO3013 0 6033O13 0 6O63013 0 6093013 0 6123013 0 6153013 114 6183013 0 6213013 124 6243013 0 6273013 0 63O3013 0 6333013 0 6363013 0 6393013 0 6423013 0 6453013 0 6483oi3 0 65I3013 0 654 3 O i3 0 6573013 0 66O3013 0 6633013 0 6663013 0 6693013 99 6723013 0 6753013 0 6783013 0 68I3013 0 684 3 O i3
0
5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 12 14 11 12 11 13 13 12 12 14 13 14 12 14 14 12 12 14 13 14 12 14 14 14 14 16 13 14 13 14 13 14 11 12 11 13 13 13 13 15 13 15 14 16 14
q 70 82 54 70 54 72 70 82 76 102 82 98 68 84 100 80 74 96 80 100 84 114 104 114 104 134 78 84 84 94 97 103 54 60 61 86 83 79 76 101 96 125 102 131 90
alg. b f 0 5533013 0 5563013 0 559 3 oi3 0 5623013 0 5653013 0 5683013 0 57I3013 82 574 3 O i3 0 5773013 102 58O3013 0 5833013 0 5863013 0 5893013 0 5923013 0 5953013 0 5983013 0 6OI3013 0 6043O13 0 6073O13 0 6IO3013 0 6133013 114 6163013 0 6193013 114 6223013 0 6253013 134 6283013 0 63I3013 0 6343oi3 0 6373013 0 64O3013 0 6433013 0 6463013 0 6493013 0 6523013 0 6553013 0 6583013 0 66I3013 0 664 3 O i3 0 6673013 0 67O3013 0 6733013 125 6763013 0 6793013 0 6823013 0 6853013
0
5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c
q
13 10 12 12 12 12 14 12 13 12 14 14 13 13 15 12 13 12 14 14 13 13 15 14 15 11 12 12 14 14 14 15 12 13 12 12 14 13 14 12 14 13 15 12 13
76 48 66 64 66 64 82 76 92 72 98 92 74 90 106 70 90 74 96 90 104 94 124 104 124 60 66 75 97 90 110 116 63 69 73 70 95 80 88 83 112 89 118 72 82
b f 0 0 0 0 0 0 0 0 92 0 0 0 0 0 0 0 0 0 0 0 104 0 124 0 124 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 112 0 0 0 0
4. B-DIMBNSIONAL BASIS DATA FOR I 1 3 1 6 - 1 3 1 6 i 3 i 6 AND l 3 oi3-3O13 3 oi
alg.
a 5 689 3 oi3 5 692 3 O i3 5 6953013 5 698 3 oi3 5 7OI3013 5 7043O13 5 7073013 5 7IO3013 5 7133013 5 7163013 5 7193013 5 7223013 5 7253013 5 7283013 5 73I3013 5 7343013 5 7373013 5 740soi3 5 7433oi3 5 7463013 5 7493013 5 7523013 5 7553013 5 7583013 5 76I3013 5 764 3 O i3 5 7673013 5 77O3013 5 7733013 5 7763013 5 7793013 5 7823013 5 7853013 5 7883013 5 7913013 5 7943oi3 5 7973013 5 8OO3013 5 8033013 5 8O63013 5 8093O13 5 8123013 5 8153013 5 8183013 5 6863013
c 14 13 13 15 14 15 13 15 14 16 7 11 12 12 11 11 13 12 13 11 13 12 13 11 13 13 13 13 15 11 13 13 12 12 14 13 14 12 14 15 10 10 11 10 12
q 91 93 86 115 100 112 101 134 111 144 17 46 65 59 51 50 63 65 75 52 65 67 76 60 77 76 87 83 103 60 82 77 82 76 102 83 99 81 111 111 44 39 60 46 65
alg. 0 alg. 0 c q b f c q 6 / b f 0 0 0 6873013 5 15 100 6883013 5 12 77 0 0 0 69O3013 5 13 90 69I3013 5 14 106 0 0 0 694 3 O i3 5 14 99 6933013 5 14 102 0 0 0 6963013 5 13 87 6973013 5 14 103 0 0 0 699 3 O i3 5 15 116 7OO3013 5 14 96 5 0 5 0 15 16 109 0 125 7033013 702 3 013 121 14 14 121 114 13 101 5 5 0 7O63013 7053013 134 7O83013 5 15 127 114 13 7093013 5 16 147 147 0 7123013 5 15 124 112 12 7II3013 5 15 131 131 144 714 3 013 5 16 137 125 12 7153013 5 17 157 157 0 10 7 7173013 5 9 31 0 7183013 5 10 39 0 0 0 7213013 5 11 58 7203013 5 11 49 0 0 7233013 5 10 47 7243oi3 5 11 53 0 0 0 0 7263013 5 13 65 7273013 5 10 44 0 0 0 7293013 5 11 50 73O3013 5 12 57 0 0 0 7323013 5 12 57 7333013 5 12 56 0 0 0 7353013 5 11 59 7363013 5 12 69 0 0 7383013 5 13 75 7393oi3 5 12 65 0 0 0 7413013 5 13 71 7423oi3 5 14 81 0 12 0 5 59 0 744 3 oi3 7453oi3 5 12 58 0 11 0 0 5 60 0 747 3 oi3 7483013 5 12 70 12 0 0 5 5 13 77 66 0 7503013 75I3013 0 0 0 754 3 oi3 5 14 83 7533013 5 13 73 0 0 0 7563013 5 12 67 7573013 5 12 70 0 0 76O3013 5 13 73 7593oi3 5 12 66 0 0 0 0 7623013 5 14 83 7633013 5 12 77 0 0 0 7663013 5 14 97 7653013 5 13 87 0 0 0 7693013 5 14 93 7683013 5 14 93 0 0 0 7723013 5 13 71 77I3013 5 12 63 0 0 7753013 5 12 70 7743oi3 5 12 72 0 0 0 0 7783013 5 13 79 7773013 5 12 67 0 0 0 78I3013 5 11 66 78O3013 5 14 89 0 0 0 7843013 5 13 92 7833013 5 12 76 0 0 7873013 5 13 86 7863013 5 13 92 92 102 0 79O3013 5 13 89 7893oi3 5 12 73 0 14 0 0 5 5 13 99 83 0 7923oi3 7933oi3 14 0 0 5 5 15 93 109 0 7953013 7963oi3 0 0 7983013 5 13 101 101 7993013 5 13 91 111 0 8OI3013 5 14 101 8023013 5 15 121 121 0 0 8043013 5 16 131 131 8053013 5 9 35 QAQ 0 0 0 8073013 5 10 42 OUB3OI3 5 11 51 0 0 0 8103013 5 11 48 8113013 5 10 47 0 0 0 8133013 5 11 54 814 3 013 5 12 67 0 0 0 8163013 5 11 55 8173013 5 11 56 0 0 0 8193013 5 11 56 8203013 5 12 65
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. 82I3013 824 3 oi3 8273013 83O3013 8333013
8363oi3 8393oi3 842 3 O i3 8453013 8483013 85I3013 854 3 O i3 8573013 86O3013 8633013 8663013
8693oi3 8723013 8753013 8783013 88I3013 8843013 8873013 890 3 013
8933oi3 8963oi3 8993oi3 9023013 9053013 9O83013 9II3013 914 3 013 917 3 013 9203013
9233oi3 9263oi3 9293oi3 9323oi3 9353013 9383013 94I3013
9443oi3 9473013
950soi3 9533oi3
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 11 13 12 13 13 12 12 14 12 13 12 14 14 12 12 14 13 13 13 15 13 14 12 14 14 14 14 16 12 12 11 13 13 12 12 14 11 12 11 13 13 12 12 14 13
alg. 0 c q b f q 64 0 8223013 5 12 77 87 87 8253013 5 11 51 58 0 8283013 5 13 67 63 0 83I3013 5 12 64 71 0 834 3 O i3 5 14 84 68 0 8373013 5 12 68 65 0 8403O13 5 13 74 83 0 8433013 5 11 54 63 0 846 3 oi3 5 13 72 69 0 8493013 5 13 69 74 0 8523013 5 13 87 96 0 8553013 5 13 80 89 0 8583013 5 15 102 66 0 86I3013 5 12 67 63 0 864 3 O i3 5 13 72 82 0 8673013 5 12 66 72 0 87O3013 5 14 81 89 0 8733013 5 13 86 82 0 8763013 5 14 95 105 0 8793013 5 12 74 87 0 8823013 5 14 96 89 0 8853013 5 14 93 73 0 8883013 5 13 82 95 0 89I3013 5 13 79 92 0 8943oi3 5 15 101 109 0 8973013 5 14 109 102 0 9OO3013 5 15 115 128 0 9033013 5 11 50 57 0 9O63013 5 13 66 57 0 9093013 5 12 61 58 0 912 3 013 5 12 67 80 0 9153013 5 12 65 78 0 9183013 5 14 87 65 0 9213013 5 12 65 63 0 924 3 O i3 5 13 72 81 0 9273oi3 5 10 47 56 0 9303013 5 12 64 64 0 9333013 5 12 65 54 0 9363013 5 12 62 71 0 9393013 5 12 63 72 0 942 3 O i3 5 14 80 75 0 9453oi3 5 12 76 72 0 9483oi3 5 13 84 97 0 9513013 5 12 70 83 0 954 3 oi3 5 14 95
alg. 0 c q b f b f 0 8233013 5 12 74 58 16 0 0 8263013 5 12 60 0 0 8293013 5 12 54 0 0 8323013 5 13 77 0 0 8353013 5 11 59 0 0 5 13 77 8383013 74 0 0 5 13 84I3013 0 0 844 3 O i3 5 12 63 0 0 8473013 5 12 60 0 0 85O3013 5 14 78 0 0 8533013 5 13 83 0 0 8563013 5 14 93 0 0 8593013 5 11 57 0 0 8623013 5 13 76 0 0 8653013 5 13 73 0 0 8683013 5 13 75 0 0 87I3013 5 12 76 0 0 8743013 5 14 99 0 0 8773013 5 14 92 0 0 88O3013 5 13 83 0 0 5 13 80 8833013 102 0 0 5 15 8863013 0 0 8893013 5 13 86 0 0 8923013 5 14 88 0 0 8953013 5 13 96 0 0 8983013 5 15 122 0 0 9OI3013 5 15 115 0 0 9043O13 5 12 59 0 0 9073013 5 11 52 0 0 9IO3013 5 13 66 0 0 9133013 5 12 71 0 0 9163013 5 13 74 0 0 9193013 5 11 56 0 9223oi3 5 13 74 0 0 9253oi3 5 13 72 0 0 0 9283013 5 11 55 11 0 0 5 56 9313013 0 0 934 3 oi3 5 13 73 0 0 9373013 5 12 63 0 0 9403O13 5 13 71 0 0 943 3 oi3 5 11 63 0 0 9463013 5 13 88 0 9493oi3 5 13 85 0 0 9523oi3 5 13 82 0 0 0 9553013 5 13 79
4. B-DIMBNSIONAL BASIS DATA FOR I 1 3 1 6 - 1 3 1 6 i 3 i 6 AND l 3 oi3-3O13 3 oi
alg. 9563013 959 3 oi3 962 3O i3 9653013 968 3 oi3 97I3013 974 3 oi3 9773013 98O3013 9833013
9863oi3 9893oi3 9923oi3 9953013 9983013 IOOI3013 1004 30 13 1007 30 13 10103013 10133013 10163013 10193013 10223013 10253013 10283013 10313013 10343013 10373013 10403013 10433013 10463013 10493013 1052 30 13 10553013 10583013 10613013 10643013 10673013 10703013 10733013 10763013 10793013 1082 30 13 10853013 10883013
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 14 12 14 13 13 13 15 13 14 11 13 13 13 13 15 13 14 13 15 15 13 12 14 13 14 12 14 14 12 12 14 13 14 12 14 14 14 14 16 13 14 12 14 14 13
alg. 0 c b f q q 91 0 9573oi3 5 14 92 65 0 9603013 5 13 74 84 0 9633013 5 12 70 79 0 9663013 5 14 87 88 0 9693oi3 5 13 89 86 0 9723oi3 5 14 98 111 0 9753013 5 12 75 88 0 9783013 5 14 97 91 0 98I3013 5 14 95 66 0 9843013 5 12 78 87 0 9873oi3 5 12 79 88 0 9903013 5 14 100 85 0 9933oi3 5 13 82 86 0 9963013 5 14 98 107 0 9993013 5 12 85 98 0 10023O13 5 14 114 114 114 10053013 5 14 111 92 0 10083013 5 14 108 121 0 10H3013 5 14 105 118 0 10143013 5 16 134 75 0 10173O13 5 13 73 64 0 10203O13 5 13 73 82 0 10233013 5 12 72 85 0 10263013 5 14 98 92 0 10293013 5 14 92 71 0 1032 3 013 5 13 80 89 0 10353013 5 13 81 90 0 10383013 5 15 99 70 0 10413013 5 12 67 67 0 10443O13 5 13 79 88 0 10473O13 5 12 68 77 0 10503013 5 14 89 89 0 10533013 5 14 86 76 0 10563013 5 13 92 105 0 10593013 5 13 85 98 0 10623O13 5 15 114 102 0 10653013 5 14 99 95 0 10683013 5 15 111 124 0 10713O13 5 12 73 83 0 10743O13 5 14 92 92 0 10773013 5 14 93 74 0 10803O13 5 13 86 95 0 10833O13 5 13 84 93 0 10863013 5 15 105 98 0 10893013 5 13 95
alg. 0 c q b f b f 0 9583oi3 5 15 104 0 0 0 96I3013 5 13 75 0 0 964 3 O i3 5 13 78 0 0 9673013 5 12 76 0 0 97O3013 5 14 101 14 5 0 0 99 9733013 84 5 0 0 13 9763oi3 0 0 9793013 5 13 82 0 0 9823013 5 15 104 0 0 9853013 5 12 75 0 0 yoO3013 5 13 91 0 0 9913013 5 12 73 0 0 9943013 5 14 94 0 0 9973013 5 14 95 0 0 10003013 5 13 101 0 0 10033O13 5 13 98 0 10063013 5 15 127 127 0 0 10093O13 5 14 105 0 0 10123O13 5 15 121 0 0 10153013 5 12 66 14 82 5 0 0 10183013 5 0 0 13 73 10213O13 0 0 10243013 5 13 85 0 0 10273O13 5 13 79 0 0 10303O13 5 15 105 0 0 10333013 5 13 80 0 0 10363013 5 14 90 0 0 10393013 5 11 58 0 0 1042 30 13 5 13 79 0 0 10453O13 5 13 76 0 0 10483O13 5 13 80 0 0 10513013 5 13 77 0 0 10543O13 5 15 98 0 0 10573O13 5 13 89 0 0 10603013 5 14 101 5 0 0 13 86 10633013 0 0 10663013 5 15 115 0 0 10693013 5 15 108 0 0 10723O13 5 13 82 0 0 10753O13 5 13 83 0 0 10783013 5 15 102 0 0 10813O13 5 13 83 0 0 1084 3O 13 5 14 96 0 0 10873O13 5 12 82 0 10903013 5 14 111 111
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. a c 10913oi3 5 13 1094 3 013 5 15 10973013 5 14 HOO3013 5 15 11033013 5 13 HO63013 5 15 11093O13 5 15 11123013 5 13 11153013 5 13 11183013 5 15 11213013 5 14 11243013 5 15 11273013 5 13 11303013 5 15 11333013 5 15 11363013 5 15 1139 3 013 5 15 1142 3 013 5 17 11453013 5 14 11483013 5 13 11513013 5 14 11543013 5 13 11573013 5 13 11603O13 5 15 11633013 5 15 H663013 5 11 11693013 5 11 11723013 5 13 11753013 5 13 11783013 5 12 11813013 5 12 1184 3 013 5 14 11873013 5 13 11903O13 5 14 1193 3 013 5 11 11963013 5 13 11993013 5 13 1202 3 013 5 14 12053O13 5 12 12083013 5 14 12113013 5 14 1214 3 013 5 14 12173013 5 14 12203013 5 16 12233013 5 13
q 92 121 105 118 92 114 115 95 92 117 98 118 100 133 126 130 123 156 86 72 96 84 83 101 114 56 54 71 72 76 70 95 86 91 64 85 83 94 82 111 105 107 101 130 96
b 0 121 0 113 0 0 0 0 0 0 0 117 0 133 0 130 0 156 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 111 0 0 0 129 0
/
alg.
0
c
5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 12243oi3 5
14 13 15 15 14 14 16 13 14 13 15 15 14 14 16 15 16 12 12 14 14 14 14 14 16 11 12 12 14 12 13 12 14 14 12 12 14 14 13 13 15 14 15 12 14
10923O13 10953013 1098 3 013 5 HOI3013 1104 3 013 11073013 11103O13 11133013 11163013 11193013 11223013 1 11253013 11283013 11313013 1134 30 13 11373013 11403013 11433013 11463013 11493013 11523013 11553013 11583013 11613013 11643013 11673013 H703O13 11733013 11763013 11793013 11823013 11853013 H883013 11913013 1194 3 013 11973013 12003O13 12033013 12063013 12093013 1212 3 013 12153013 12183013 1 12213013
q 108 92 121 115 101 102 124 88 108 89 114 111 120 113 146 123 143 68 63 81 92 93 92 105 127 57 62 66 80 77 82 73 98 92 76 74 95 92 98 92 121 104 117 83 112
b 104 0 121 0 0 0 0 0 107 0 0 0 120 0 146 0 143 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 96 0 121 0 0 0 0
alg. 0 / 4 10933013 5 10963013 5 10993013 5 11023013 5 11053013 5 11083013 5 11113013 5 11143013 5 1 11173013 5 11203013 5 11233013 5 11263013 5 11293013 5 11323013 5 11353013 5 11383013 5 11413013 5 11443013 5 11473013 5 11503013 5 11533013 5 11563013 5 11593013 5 11623013 5 11653013 5 11683013 5 11713013 5 11743013 5 11773013 5 11803013 5 11833013 5 11863013 5 11893013 5 11923013 5 11953013 5 11983013 5 12013013 5 12043013 5 2 12073013 5 12103013 5 12133013 5 12163013 5 12193013 5 12223013 5 I2253013 5
c 14 14 14 16 14 15 12 14 14 14 14 16 14 15 14 16 16 13 13 13 15 15 14 15 10 12 12 13 11 13 13 13 13 15 12 13 13 15 13 14 13 15 15 13 13
q 105 108 102 131 105 111 79 104 101 105 102 127 113 133 110 143 136 77 72 83 105 102 92 118 48 65 63 74 64 89 83 85 79 104 73 86 82 104 95 108 91 120 114 99 89
b 0 0 0 131 0 0 0 0 0 98 0 0 0 133 0 143 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 106 0 119 0 0 0
f
7
2 1
4. 5-DIMENSIONAL BASIS DATA FOR I 1 3 1 6 - 1 3 1 6 i 3 i 6 AND l 3 oi3-3013 3 oi3
alg.
0
I2263013 12293013 I2323013 12353013 12383013 I24I3013 12443013 12473013 12503013 12533013 12563013 1259 3 oi3 12623013 12653013 12683013 I27I3013 12743013 12773013 12803013 12833013 I2863013 12893013 1292 3 oi3 12953013 1298 3 oi3 I3OI3013 13043013 13073013 I3IO3013 13133013 I3I63013 13193013 13223013 13253013 13283013 13313013 13343013 13373013
5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
13403oi3 13433oi3 13463013
13493oi3 13523oi3 13553013 13583013
c
14 14 16 14 15 15 17 12 12 12 14 13 13 13 15 13 13 13 15 13 14 13 15 15 13 12 14 14 14 13 15 15 14 13 15 15 14 14 16 15 16 11 13 12 13
alg. a c alg. a c q b f b f q q b / 0 105 0 0 12273013 5 14 102 I2283013 5 15 118 0 109 0 0 I23O3013 5 15 125 I23I3013 5 15 115 131 0 0 1234 3 oi3 5 14 123 123 12333013 5 13 103 0 116 0 I2363013 5 15 136 136 12373013 5 14 113 5 15 133 133 126 0 1239 3 oi3 1240 3 oi3 5 16 146 146 0 129 0 1242 3 oi3 5 16 149 149 1243 3 oi3 5 16 139 11 5 12 0 5 159 159 51 60 0 12453013 1246 3 oi3 0 60 0 0 12483013 5 13 69 1249 3 oi3 5 11 59 0 71 0 0 12523013 5 13 78 I25I3013 5 12 66 0 68 0 0 12543013 5 13 80 12553013 5 13 75 0 87 0 0 12573013 5 12 63 12583013 5 13 75 72 0 0 0 1260 3 oi3 5 14 84 I26I3013 5 12 75 91 0 0 0 12643013 5 14 98 12633013 5 13 82 84 0 0 0 12673013 5 14 91 12663013 5 14 100 107 0 0 0 I27O3013 5 13 73 12693013 5 12 64 73 0 0 0 12723013 5 14 82 12733013 5 12 73 85 0 0 0 12763013 5 14 94 12753013 5 13 82 82 0 0 0 1279 3 oi3 5 14 91 12783013 5 14 94 103 0 0 0 I28I3013 5 12 69 12823013 5 13 81 78 0 0 0 1284 3 oi3 5 14 90 12853013 5 13 78 14 90 0 5 15 0 5 87 99 0 I2883013 12873013 14 5 14 91 0 0 5 107 100 0 12913013 12903013 116 0 0 0 1294 3 oi3 5 15 116 1293 3 oi3 5 14 100 109 0 1296soi3 5 16 125 0 12973oi3 5 12 64 0 73 0 0 12993013 5 13 73 13003oi3 5 14 82 0 71 0 0 0 1302 3 013 5 13 83 13033013 5 13 81 93 0 0 13053013 5 13 80 13063oi3 5 14 92 0 90 0 0 0 I3O83013 5 15 102 13093O13 5 13 81 93 0 0 0 I3H3013 5 14 90 1312 30 13 5 15 102 93 0 0 0 13143013 5 14 109 13153013 5 14 103 119 0 0 13173013 5 14 102 13183013 5 15 118 116 2 112 0 0 13203013 5 16 128 126 2 13213013 5 13 81 90 0 0 0 13243013 5 15 99 13233013 5 14 90 88 0 0 0 13273013 5 14 101 13263013 5 14 100 113 0 0 0 13303013 5 15 109 1329 3 oi3 5 14 97 122 16 5 13 110 0 0 5 88 0 13333013 13323013 14 5 15 100 0 0 5 101 113 0 13363013 13353013 97 0 0 0 1339 3 oi3 5 15 110 13383013 5 15 109 122 0 0 0 13413013 5 14 113 13423013 5 15 129 126 0 0 0 13443013 5 16 142 13453013 5 15 122 138 0 0 0 13473013 5 16 135 1348 3 oi3 5 17 151 48 0 0 1350soi3 5 12 57 0 I35I3013 5 12 57 66 0 0 13533013 5 11 55 13543oi3 5 12 67 0 62 0 0 0 I3563013 5 13 74 13573013 5 12 64 76 0 0 0 1359 3 oi3 5 13 71 I36O3013 5 14 83
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. I36I3013 1364 3O i3 13673013 13703013 13733013 13763013 13793013 13823013 13853013 I3883013 13913013 13943013 13973013 14003oi3 14033013 14063013 14093013 14123013 14153013 14183013 14213013 14243013 14273013 14303013 14333013 14363oi3 14393oi3 14423013 1445 3 oi3 14483oi3 14513013 1454 3O i3 1457 3O i3 14603013 1463 3 oi3 14663oi3 14693oi3 14723oi3 14753oi3 14783013 14813013 1484 3O i3 14873013 14903013 14933oi3
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 11 13 13 12 12 14 13 14 12 14 13 14 11 13 13 13 13 15 13 14 13 15 15 12 12 14 12 13 12 14 14 13 13 15 13 14 13 15 15 13 13 15 13 14 13
0 c 0 6 / b / alg. alg. c b f q q q 0 58 0 0 13623013 5 12 63 13633013 5 12 70 0 75 0 0 1365 3 oi3 5 12 67 13663013 5 13 72 0 79 0 0 I3683013 5 14 84 1369 3O i3 5 11 66 0 75 0 0 13713013 5 12 82 13723013 5 13 91 0 73 0 0 13743013 5 13 82 13753013 5 13 89 5 12 84 0 98 75 5 0 0 13 13773013 13783013 5 14 82 0 91 100 5 0 0 13 13803013 I38I3013 91 0 0 0 13833013 5 14 98 1384 3O i3 5 15 107 60 0 0 0 I3863013 5 13 69 13873013 5 13 69 78 0 0 0 13893013 5 12 68 13903oi3 5 13 80 77 0 0 0 13923oi3 5 14 89 13933oi3 5 13 77 89 0 0 0 13963oi3 5 15 98 13953013 5 14 86 60 0 0 0 13983oi3 5 12 68 13993oi3 5 12 72 0 80 0 0 1401 3 oi3 5 12 69 1402 30 13 5 13 77 0 81 0 0 1404 3 013 5 14 89 14053013 5 12 69 0 77 0 0 14073O13 5 13 81 14083O13 5 14 89 0 78 0 0 I4IO3013 5 14 86 14113013 5 14 90 0 98 0 0 14143013 5 13 90 14133013 5 12 78 94 0 0 0 14163oi3 5 14 106 14173013 5 13 87 0 99 0 0 14203013 5 15 115 14193013 5 14 103 5 14 14 87 0 99 5 0 0 103 14233013 14223013 5 14 115 96 0 5 0 0 15 108 14263013 14253013 112 0 0 0 1429 3 oi3 5 11 59 14283013 5 16 124 64 0 0 0 14323013 5 13 73 14313013 5 12 68 68 0 0 0 14353013 5 13 77 14343013 5 13 73 82 0 0 0 14383013 5 12 70 14373013 5 11 62 74 0 0 0 14413013 5 12 72 14403O13 5 13 82 80 72 8 14433013 5 13 84 0 14443oi3 5 14 92 76 16 71 0 0 0 14473013 5 13 83 1446 3 oi3 5 13 79 91 0 0 0 14493oi3 5 13 81 14503oi3 5 14 89 93 0 0 0 14523013 5 15 101 14533013 5 12 76 84 0 0 0 14553013 5 13 88 1456 3 oi3 5 14 96 85 0 0 0 14583013 5 14 93 14593013 5 14 97 105 0 0 0 14613013 5 12 84 14623oi3 5 13 96 100 0 0 1464 3O i3 5 14 112 112 14653oi3 5 13 94 106 97 9 14673oi3 5 14 110 102 8 14683oi3 5 15 122 122 93 0 0 0 14713013 5 14 109 14703oi3 5 14 105 121 120 1 14733013 5 14 103 0 0 1474 3O i3 5 15 115 119 0 0 14763oi3 5 16 131 130 1 14773013 5 12 72 81 0 0 0 14803O13 5 14 90 14793013 5 13 81 81 0 0 0 1483 3 oi3 5 14 90 1482 3 oi3 5 14 90 99 0 0 0 14853oi3 5 12 75 14863oi3 5 13 87 87 0 0 0 14883oi3 5 14 99 14893oi3 5 13 88 100 0 0 0 14913oi3 5 14 100 14923oi3 5 15 112 84 0 0 0 14943013 5 14 96 14953013 5 14 96
4. B-DIMBNSIONAL BASIS DATA FOR I 1 3 1 6 - 1 3 1 6 i 3 i 6 AND l 3 oi3-3O13 3 oi
alg. a c 14963oi3 5 15 1499 3 oi3 5 15 15023013 5 13 15053013 5 13 15083013 5 15 15113013 5 14 15143013 5 15 15173013 5 13 15203013 5 15 15233013 5 15 15263013 5 15 1529 3 oi3 5 15 15323013 5 17 15353013 5 13 I5383013 5 13 15413013 5 13 1544 3 oi3 5 15 15473013 5 13 15503oi3 5 14 15533013 5 12 I5563013 5 14 15593013 5 14 1562 3 oi3 5 14 15653013 5 14 I5683013 5 16 I57I3013 5 14 1574 3O i3 5 14 15773013 5 14 15803013 5 16 1583 3 oi3 5 13 I5863013 5 14 1589 3 oi3 5 13 1592 3 oi3 5 15 15953013 5 15 1598 3 oi3 5 14 I6OI3013 5 14 16043013 5 16 16073013 5 15 I6IO3013 5 16 16133013 5 12 16163013 5 14 16193013 5 14 16223oi3 5 13 I6253013 5 13 16283oi3 5 15
alg. 0 c alg. 0 c q 6 / b f q b / q 108 0 14973oi3 5 14 97 0 14983oi3 5 15 109 0 0 109 0 0 I5OO3013 5 16 121 I5OI3013 5 12 79 0 91 0 0 15033013 5 13 91 15043013 5 14 103 92 0 0 15063oi3 5 14 104 0 15073O13 5 14 104 0 116 0 0 1509 3 013 5 13 88 I5IO3013 5 14 100 112 14 5 15 5 0 100 0 0 101 15123013 15133013 5 15 5 0 113 113 0 0 16 125 15153013 I5I63013 0 100 0 I5I83013 5 14 116 114 2 15193013 5 14 116 132 132 0 I52I3013 5 14 113 15223013 5 15 129 127 2 0 129 0 15243013 5 16 145 145 15253013 5 14 109 125 0 0 15273013 5 15 125 I5283013 5 16 141 140 1 122 0 0 0 15303013 5 16 138 15313013 5 16 138 154 153 1 15333013 5 12 63 0 0 15343013 5 13 72 0 76 0 15373013 5 12 73 15363oi3 5 14 85 0 0 85 0 0 15403013 5 14 92 15393013 5 13 80 0 86 0 0 15433013 5 14 93 15423013 5 14 98 0 105 0 0 1546 3 oi3 5 13 81 15453013 5 12 72 84 0 0 15483oi3 5 14 93 0 15493013 5 13 85 94 0 0 0 15513013 5 14 97 15523013 5 15 106 0 83 0 0 15553013 5 13 99 1554 3 oi3 5 13 96 112 0 14 5 13 5 0 90 0 103 I5583013 15573013 5 15 5 0 119 106 0 0 13 96 I56I3013 15603013 0 109 0 1564 3O i3 5 15 125 15633oi3 5 14 112 0 0 103 0 15673013 5 15 119 I5663013 5 15 116 0 132 0 15703oi3 5 14 86 0 15693oi3 5 13 77 0 0 90 0 0 I5723013 5 15 99 15733013 5 13 88 0 100 0 0 15763013 5 15 109 15753013 5 14 97 0 101 0 0 15793013 5 15 110 I5783013 5 15 113 122 0 0 0 1582 3 oi3 5 13 88 15813013 5 12 76 0 88 0 15843oi3 5 14 100 0 15853013 5 13 85 0 97 0 0 15873013 5 14 97 I5883013 5 15 109 0 89 0 0 15903013 5 14 101 15913013 5 14 101 0 113 0 0 15943013 5 15 110 15933013 5 14 98 0 110 0 0 15963013 5 16 122 15973013 5 13 97 0 113 0 0 1599 3 oi3 5 14 113 I6OO3013 5 15 129 122 122 5 15 5 0 106 0 15 0 16023O13 16033013 5 14 110 5 0 138 0 15 0 126 I6O63013 16053013 0 126 0 0 I6O83013 5 16 142 16093013 5 15 119 0 135 0 0 I6H3013 5 16 135 16123013 5 17 151 72 0 0 0 1614 3 013 5 13 81 16153013 5 13 81 0 90 0 0 16173013 5 13 85 16183013 5 14 94 94 0 0 0 16203013 5 15 103 16213013 5 12 78 90 0 0 1623 3 oi3 5 13 90 16243oi3 5 14 102 0 0 88 0 0 16263013 5 14 100 I6273013 5 14 100 112 0 0 0 1629 3 oi3 5 13 91 I63O3013 5 14 103
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. I63I3013 1634 3O i3 I6373013 16403013
16433oi3 16463oi3 16493oi3 1652 3 oi3 1655 3 oi3 16583013 I66I3013 1664 3O i3 I6673013 I67O3013 I6733013 I6763013 1679 3 oi3 I6823013 I6853013 I6883013 16913013 16943013 1697 3 oi3
17003oi3 17033013 I7O63013 17093013 17123013 17153013 17183013 17213013 1724 3 oi3 17273013 17303013 17333013 17363013 17393013 1742 3 oi3
17453oi3 17483013 17513013 17543013 17573013 17603013 17633013
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 14 15 13 15 15 14 14 16 15 16 13 15 15 14 14 16 15 16 13 15 15 15 15 17 15 16 15 17 17 11 11 13 11 13 12 14 12 13 12 14 14 14 14 16 12
q 103 113 92 116 117 119 113 145 132 142 87 109 109 109 106 134 118 135 97 125 122 126 123 151 137 154 134 170 163 53 56 77 54 75 70 95 71 80 68 92 89 103 96 124 76
6 0 106 0 0 0 0 0 145 130 136 0 0 0 0 0 0 0 0 0 125 110 119 0 151 123 154 121 170 151 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
/
alg.
I6323013 7 1635 3 oi3 I6383013 1641 3 013 1644 3O i3 16473013 16503013
16533oi3 2 I6563013 6 16593013 I6623013 I6653013 I6683013 I67I3013 1674 3O i3 I6773013 I68O3013 I6833013 I6863013
16893oi3 12 16923oi3 7 16953013 16983oi3 17013oi3 14 17043O13 17073013 13 17103O13 17133013 12 17163013 17193013 17223013 I7253013 17283013 17313013 17343013 17373013
17403oi3 17433oi3 17463oi3 17493013 17523013 17553013 17583013 I76I3013 1764 3O i3
0
c
5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
15 15 14 14 16 14 15 14 16 16 14 14 16 14 15 14 16 16 14 14 16 15 16 14 16 16 16 16 18 12 12 13 12 13 13 14 13 14 13 13 15 14 15 11 13
q 115 113 104 105 129 119 129 116 148 142 100 100 122 105 122 106 134 131 113 110 138 122 139 121 157 150 154 147 183 62 68 74 66 72 86 88 83 92 80 77 101 99 112 64 81
b 0 0 0 0 0 114 124 0 148 140 0 0 0 0 0 0 0 0 0 0 138 0 138 106 157 136 154 135 183 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
/
5 5
2
1 15 14 12
alg.
0
16333013 I6363013 1639 3O i3 1642 3 oi3 1645 3 oi3 1648 3 oi3 I65I3013 1654 3O i3 1657 3 oi3 I66O3013 I6633013 I6663013 1669 3 oi3 1672 3O i3 1675 3 oi3 16783013 I68I3013 1684 3 oi3 I6873013 16903013 16933013 I6963013 1699 3 oi3 17023O13 17053O13 I7O83013 17113013 17143013 17173013 17203O13 17233013 17263013 17293013 17323013 17353013 17383013 17413013 1744 3O i3 17473013 17503O13 17533013 I7563013 1759 3 oi3 17623013 1765 3 oi3
5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 14 16 14 15 13 15 15 15 15 17 14 15 13 15 15 15 15 17 14 15 14 16 16 15 15 17 16 17 10 13 12 14 12 14 13 15 14 15 13 14 13 15 15 12 13
q 101 125 104 117 103 135 129 132 126 158 96 113 93 121 118 122 119 147 109 126 110 138 135 141 134 170 150 167 44 71 65 86 63 84 79 104 95 104 80 89 87 115 108 69 88
b 0 116 0 0 0 135 124 0 0 158 0 0 0 0 0 0 0 0 0 123 0 138 124 141 120 170 138 167 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
/ 9
5
3
11 14 12
4. 5-DIMENSIONAL BASIS DATA FOR I 1 3 1 6 - 1 3 1 6 i 3 i 6 AND l 3 oi3-3013 3 oi3
alg. I7663013 17693oi3 I7723013 17753013 I7783013 17813013 17843oi3 17873013 17903013 17933013 I7963013 17993oi3 18023013 18053013 I8O83013 I8II3013 1814 30 13 18173013 18203013 I8233013 18263013 18293013 1832 3O i3 I8353013 I8383013 18413013 1844 3O i3 18473013 18503013 18533oi3 I8563013 18593oi3 I8623013 I8653013 I8683013 18713013 18743oi3 I8773013 I88O3013 I8833013 I8863013 18893oi3 1892 3O i3 1895soi3 18983oi3
c q b 5 14 93 0 5 13 85 0 5 15 102 0 5 13 95 0 5 14 100 0 5 13 88 0 5 15 113 0 5 15 116 0 5 14 110 0 5 15 129 0 5 15 119 0 5 16 138 0 5 14 101 101 5 13 85 0 5 15 109 0 5 14 107 101 5 16 135 135 5 12 77 0 5 14 97 0 5 13 89 0 5 15 109 0 5 13 95 0 5 15 123 121 5 15 123 123 5 15 119 117 5 15 119 0 5 17 147 147 5 15 132 0 5 17 164 164 5 16 144 0 5 18 176 176 5 13 93 0 5 15 113 0 5 13 99 0 5 15 127 123 5 15 127 122 5 16 135 135 5 14 120 116 5 16 152 150 5 15 132 132 5 17 164 164 5 15 144 144 5 17 180 180 5 18 192 192 5 11 48 0
0
/
alg. 17673013 17703013 17733013 17763013 17793oi3 1782 3O i3 17853013 I7883013 17913013 17943013 17973013 I8OO3013 18033013 I8O63013 18093013
6 18123013 18153013 18183013 18213013 1824 3O i3 I8273013 I83O3013
2 18333oi3 I8363013
2 18393oi3 1842 3O i3 18453013 I8483013 18513013 18543oi3 I8573013 I86O3013 I8633013 I8663013
4 18693oi3 5 I8723013 18753013
4 I8783013 2 I88I3013 I8843013 I8873013 18903013 18933oi3 18963oi3 18993oi3
q b 5 12 73 0 5 14 90 0 5 12 79 0 5 14 104 0 5 14 107 0 5 14 97 0 5 14 100 0 5 16 125 0 5 14 113 0 5 16 142 0 5 15 122 0 5 17 151 0 5 15 113 113 5 14 97 0 5 15 109 0 5 15 123 123 5 16 131 125 5 13 85 0 5 14 101 0 5 14 97 0 5 15 113 0 5 14 107 103 5 14 107 0 5 16 135 135 5 15 123 0 5 16 131 131 5 14 116 0 5 16 148 148 5 15 128 0 5 17 160 160 5 12 81 0 5 14 101 0 5 15 117 117 5 14 111 0 5 14 111 0 5 16 139 136 5 16 139 139 5 15 136 132 5 16 152 152 5 16 148 148 5 17 164 164 5 16 164 164 5 17 176 176 5 19 212 212 5 11 46 0
a c
/
alg. I7683013 I77I3013 17743oi3 17773013 17803013 17833013 I7863013 17893013 1792 3O i3 17953013 17983oi3 I8OI3013 18043O13 18073013 I8IO3013 18133013
6 18163013 18193013 I8223013 I8253013 I8283013
4 I83I3013 1834 3O i3 18373013 18403O13 18433oi3 I8463013 18493013 I8523013 18553013 I8583013 I86I3013 I8643013 I8673013 18703013
3 18733013 I8763013
4 I8793013 I8823013 I8853013 I8883013 18913013 1894 3O i3 18973oi3 I9OO3013
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c q b 13 78 0 14 97 0 13 88 0 13 91 0 15 116 0 14 104 0 15 109 0 13 97 0 15 126 0 14 106 0 16 135 0 13 89 89 16 125 125 14 97 0 16 121 0 15 119 113 17 147 147 13 89 0 15 109 109 14 101 0 16 121 121 14 111 0 15 119 119 14 107 0 16 135 135 16 135 135 15 132 132 16 148 148 16 144 144 17 160 160 13 89 0 14 105 0 16 125 125 14 115 111 15 123 0 15 123 123 17 151 151 15 136 134 17 168 168 16 148 148 18 180 180 16 160 160 18 196 196 8 18 10 12 61 0
/
6
4
2
8
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. 19013013 19043013 19073013 19103013 19133013 19163013 19193013 19223oi3 19253013 19283013 19313013 1934 3 oi3 19373013 19403013 1943 3 oi3 19463013 1949 3 oi3 1952 3 oi3 19553013 1958 3 oi3 19613013 19643013 1967 3 oi3 19703013 19733013 1976 3 oi3 19793oi3 19823oi3 19853oi3 19883oi3 19913013 19943oi3 19973oi3 20003013 20033oi3 20063oi3 20093oi3 2012 3 013 20153013 2OI83013 202I3013 20243013 20273013 20303oi3 20333oi3
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 10 12 10 11 10 12 10 12 13 11 11 10 11 13 11 13 11 11 13 10 12 12 12 12 14 11 13 11 12 11 13 12 12 12 14 12 14 11 13 12 13 12 14 12 13
0 c 0 alg. 6 / alg. c b f b f q q q 0 0 44 0 19023O13 5 11 47 19033013 5 11 59 62 0 0 0 19053013 5 12 76 I9O63013 5 13 79 44 0 0 I9O83013 5 11 52 52 19093013 5 10 48 0 60 60 19113013 5 11 55 19123013 5 12 67 67 54 0 0 1914 3 013 5 11 70 70 19153013 5 11 61 5 12 84 84 0 77 77 5 68 13 I9I83013 19173013 62 0 0 19213013 5 11 69 19203013 5 11 82 82 0 89 89 19233oi3 5 12 76 1924 3O i3 5 13 96 96 0 83 0 19263013 5 14 103 103 1927 3O i3 5 10 44 49 0 0 0 19293013 5 11 59 19303oi3 5 12 64 0 0 46 0 19323oi3 5 11 55 19333oi3 5 12 64 0 49 37 12 19353013 5 11 58 1936 3 oi3 5 12 67 48 19 0 0 63 50 13 19383oi3 5 12 76 19393013 5 12 72 0 0 85 0 19413013 5 11 56 1942 3O i3 5 12 61 0 0 55 0 19443013 5 12 60 19453013 5 12 72 0 0 77 0 19473013 5 12 57 19483013 5 10 48 0 0 56 0 19503013 5 11 51 19513013 5 12 59 0 0 61 0 19533013 5 12 73 19543013 5 12 64 0 0 76 0 19563oi3 5 12 68 19573013 5 13 77 0 0 55 0 19593013 5 11 67 19603013 5 11 64 12 0 5 11 0 76 5 58 0 70 19623oi3 19633013 11 0 5 13 0 67 5 79 0 71 19653013 I9663013 0 0 87 0 1968 3 oi3 5 12 80 1969 3 oi3 5 13 96 74 0 0 0 19713013 5 13 90 19723013 5 13 83 0 0 99 0 19743013 5 11 54 19753013 5 12 59 0 0 56 0 19773013 5 12 61 19783013 5 12 73 0 0 78 0 19803013 5 11 52 19813013 5 12 58 0 0 56 0 19833013 5 12 64 19843013 5 11 59 0 0 71 0 19863oi3 5 12 69 1987 3 oi3 5 13 81 0 0 63 0 19893oi3 5 12 69 1990 3 oi3 5 12 72 0 78 0 19923oi3 5 11 63 1993 3 oi3 5 12 75 75 72 0 0 19953013 5 13 84 84 1996 3 oi3 5 11 69 0 85 85 1998 3 oi3 5 12 79 19993013 5 13 95 95 0 78 0 2OOI3013 5 13 94 94 2002 3 oi3 5 13 88 104 104 0 0 2004 3 oi3 5 12 69 2005 3 oi3 5 13 74 5 13 0 0 71 5 76 0 13 90 2007 3 oi3 2OO83013 5 12 0 0 95 5 67 0 13 73 2OIO3013 2OH3013 0 0 60 0 20133013 5 12 72 2014 3 013 5 12 67 0 0 79 0 2OI63013 5 11 65 20173O13 5 12 81 0 0 75 0 20193013 5 13 91 20203013 5 12 72 0 0 88 0 20223013 5 13 82 20233013 5 14 98 0 0 80 0 20253oi3 5 13 86 2026soi3 5 13 89 0 95 0 20283013 5 11 69 20293oi3 5 12 85 85 0 78 0 20323oi3 5 12 76 20313oi3 5 13 94 94 92 92 0 20343013 5 13 85 20353013 5 14 101 101
4. B-DIMBNSIONAL BASIS DATA FOR I 1 3 1 6 - 1 3 1 6 i 3 i 6 AND l 3 oi3-3O13 3 oi
alg. 20363oi3 2039 3 oi3 2042 3 oi3 20453013 2048 3 oi3 20513013 20543oi3 20573013 2060 3 oi3 20633013 2O663013 20693oi3 20723oi3 20753013 2O783013 2O8I3013 2084 3 O i3 2087 3 O i3 2090 3 oi3 2093 3 oi3 2096 3 oi3 20993013 2102 3 013 21053013 2IO83013 2III3013 2114 30 13 21173013 21203013 21233013 21263013 21293013 21323013 21353013 21383013 21413013 21443013 21473013 21503013 21533013 21563013 21593013 21623oi3 21653013 2I683013
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 11 13 13 13 13 15 13 12 13 13 12 11 13 13 12 13 13 14 12 13 13 13 13 13 14 13 14 14 13 12 14 14 13 14 14 15 12 13 13 12 13 12 14 12 13
q 77 107 96 104 93 123 97 70 75 85 71 69 94 85 95 105 98 108 68 76 86 79 90 103 113 83 91 103 87 83 112 103 115 121 122 128 71 90 72 67 89 78 92 78 86
0 c 0 alg. alg. b / 6 / c b f q q 0 0 20373oi3 5 12 97 97 2038soi3 5 12 87 0 107 20403oi3 5 12 86 20413oi3 5 13 106 106 0 0 20433oi3 5 14 116 116 20443oi3 5 12 84 104 0 20463oi3 5 13 94 20473oi3 5 14 114 114 0 0 20493oi3 5 14 113 113 20503oi3 5 14 103 12 84 5 11 0 71 5 0 123 20523oi3 20533oi3 0 91 6 20553oi3 5 14 110 106 4 2056soi3 5 11 61 0 0 0 20583013 5 13 79 20593oi3 5 12 66 0 0 0 2O623013 5 13 89 2O6I3013 5 12 76 0 0 0 20653013 5 11 63 20643oi3 5 14 98 0 0 0 2O683013 5 13 74 20673oi3 5 12 66 0 0 0 207I3013 5 12 82 20703oi3 5 12 81 0 0 0 20743oi3 5 13 84 20733oi3 5 12 72 0 0 0 20763013 5 14 97 20773013 5 11 79 0 0 0 20793013 5 12 92 2O8O3013 5 13 108 0 0 0 2082 3 oi3 5 14 121 20833oi3 5 12 82 0 0 0 2085 3 oi3 5 13 95 2O863013 5 14 111 0 0 0 2O883013 5 15 124 20893oi3 5 11 59 0 0 0 2091 3 oi3 5 13 77 20923oi3 5 12 67 0 0 0 20953oi3 5 13 90 2094 3 oi3 5 12 77 5 14 12 99 0 5 0 0 71 2097 3 oi3 2098soi3 5 12 80 9 77 5 0 0 13 89 2IOI3013 2IOO3013 0 0 0 2104 3 013 5 12 87 21033013 5 14 102 0 103 21073O13 5 14 116 116 2IO63013 5 13 100 0 0 21093013 5 15 129 129 2HO3013 5 12 74 0 0 0 2II23013 5 14 92 2II33013 5 13 82 0 0 0 21153013 5 13 94 2H63013 5 14 107 0 0 0 21183013 5 15 116 21193013 5 12 75 0 0 0 21213013 5 13 82 21223013 5 14 94 0 0 0 21253013 5 13 96 21243013 5 13 99 0 0 21283013 5 14 106 96 10 21273013 5 13 90 0 0 0 213I3013 5 12 95 21303013 5 15 119 0 115 21343013 5 14 128 128 21333013 5 13 108 0 0 21373013 5 13 102 21363013 5 15 141 141 5 14 122 115 0 21403013 5 15 135 135 21393013 0 0 21433013 5 11 66 21423013 5 16 148 148 12 5 13 76 0 5 0 0 85 21453013 21463oi3 0 0 0 21483013 5 14 95 2149 3 oi3 5 12 67 0 0 0 21513013 5 11 62 21523013 5 12 70 0 0 0 21543013 5 13 75 21553013 5 12 77 0 0 0 21573013 5 13 82 21583013 5 14 94 0 0 0 2I6O3013 5 13 87 2I6I3013 5 13 83 0 0 0 21633oi3 5 11 69 21643oi3 5 12 81 0 0 0 2I663013 5 13 90 21673013 5 12 74 0 0 0 21693oi3 5 13 83 217O3013 5 14 95
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. 21713013 21743013 21773013 21803013 21833013
21863oi3 21893oi3 21923oi3 21953013 21983013 22OI3013 22043013
22073oi3 22IO3013 22133013 22I63013 22193013 22223013 22253013 22283013 223I3013 22343013 22373013 22403013 22433013 22463013
22493oi3 22523013 22553013 22583013 226I3013 2264 3 oi3 2267 3 O i3 22703013 22733013 22763013 22793013 22823013 22853013 22883013 229I3013 22943013 22973013
23003oi3 23033oi3
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 12 14 14 13 12 14 13 13 12 14 14 13 14 13 14 13 13 15 15 12 11 12 12 14 13 13 13 15 12 11 12 12 11 13 11 13 13 13 12 14 12 13 12 14 14
q
87 112 101 71 72 97 82 89 82 111 104 95 104 102 104 114 103 136 125 69 67 72 78 91 79 99 88 116 63 69 75 69 59 73 69 93 87 84 72 94 87 101 81 109 103
alg. 0 c alg. 0 b / c q b f b f q 0 0 0 21723013 5 13 103 21733013 5 13 96 0 0 0 21753013 5 13 92 21763013 5 14 108 0 0 0 21783013 5 15 117 2179 3 oi3 5 12 62 0 0 0 2I8I3013 5 12 70 2I823013 5 13 78 0 0 2185 3O i3 5 13 85 21843oi3 5 13 84 0 5 12 82 73 5 0 0 0 13 2I883013 21873013 5 14 12 91 5 0 0 0 77 21913013 21903oi3 0 0 0 21943013 5 14 98 21933013 5 13 86 0 0 0 21973013 5 13 95 21963013 5 13 98 0 0 0 22OO3013 5 14 107 21993013 5 13 91 0 0 0 22033013 5 12 86 22023013 5 15 120 0 0 0 22O63013 5 14 104 22053013 5 13 95 0 0 22O83013 5 15 113 22093oi3 5 12 86 68 18 102 0 22II3013 5 13 95 22123013 5 14 111 111 0 0 22143013 5 15 120 120 22153013 5 12 94 114 22173013 5 13 107 94 13 22I83013 5 14 127 127 0 0 22203013 5 14 123 123 222I3013 5 14 116 136 0 22233013 5 14 112 22243013 5 15 132 132 0 0 22263013 5 16 145 145 22273013 5 11 61 5 12 66 0 0 0 22293013 2230 3O i3 5 13 74 5 12 79 0 0 5 0 91 13 22323013 22333013 84 14 5 13 0 0 5 0 96 22353013 22363013 0 0 0 22383013 5 13 86 22393013 5 13 83 0 0 0 22413013 5 12 74 22423013 5 13 86 0 0 0 22443013 5 14 91 22453013 5 12 83 0 0 0 22473013 5 13 95 22483013 5 14 111 0 0 22513013 5 14 100 22503oi3 5 14 104 0 0 0 0 22543013 5 12 65 22533013 5 11 57 0 0 0 22573013 5 10 57 22563013 5 13 71 0 2260soi3 5 11 63 0 22593013 5 12 81 81 0 0 0 22633013 5 13 87 22623013 5 12 75 0 0 0 22663013 5 14 93 22653013 5 13 81 0 0 0 22693013 5 12 65 22683013 5 12 67 0 0 0 22723013 5 13 77 22713013 5 12 69 0 0 22753013 5 12 81 80 1 22743013 5 12 81 0 93 0 22783013 5 13 87 22773013 5 12 75 5 14 12 99 0 0 5 76 0 228I3013 22803oi3 0 0 0 2284 3O i3 5 14 90 22833013 5 13 82 0 0 0 22873013 5 13 82 22863013 5 13 84 0 0 22903oi3 5 12 91 0 22893013 5 11 75 0 0 22933013 5 12 85 22923013 5 13 103 103 0 0 2296soi3 5 14 113 113 22953013 5 13 97 0 0 2299 3 oi3 5 13 93 22983oi3 5 13 97 0 0 0 2302 3 oi3 5 14 107 23013oi3 5 13 91 0 0 0 2305 3O i3 5 12 74 23043oi3 5 15 119 0
4. B-DIMBNSIONAL BASIS DATA FOR I 1 3 1 6 - 1 3 1 6 i 3 i 6 AND l 3 oi3-3O13 3 oi
alg. a c q 23063oi3 5 13 82 23093oi3 5 11 64 23123013 5 13 82 23153013 5 13 79 23I83013 5 12 89 232I3013 5 12 79 23243013 5 14 107 23273013 5 13 94 23303013 5 14 104 23333013 5 12 76 23363013 5 14 93 23393013 5 13 85 23423013 5 13 101 23453013 5 13 94 23483013 5 15 122 23513013 5 14 104 23543013 5 13 97 23573013 5 13 90 23603oi3 5 15 116 23633013 5 13 105 23663013 5 14 123 23693013 5 13 102 23723013 5 15 134 23753013 5 15 124 23783013 5 13 96 238I3013 5 13 89 23843oi3 5 15 114 23873013 5 14 125 23903013 5 15 138 23933013 5 15 130 23963oi3 5 16 143 23993013 5 13 78 24023oi3 5 14 94 24053013 5 13 101 2408 3 oi3 5 14 103 24113013 5 12 82 24143013 5 14 107 24173013 5 14 101 24203oi3 5 14 104 24233013 5 12 95 24263013 5 14 127 24293oi3 5 14 124 24323013 5 14 117 24353013 5 14 114 24383oi3 5 16 146
alg. 0 c alg. 0 6 / c q b f q b / 0 0 23073oi3 5 13 83 0 2308 3 oi3 5 14 91 0 0 0 23II3013 5 12 70 23IO3013 5 12 76 0 0 0 2314 3O i3 5 13 85 23133013 5 12 73 0 0 0 23I63013 5 14 91 23173013 5 11 73 0 0 23203013 5 13 101 23193oi3 5 12 85 0 5 13 5 95 0 0 13 0 91 23233013 23223013 5 12 82 5 0 0 13 0 98 23263013 23253013 0 0 23283013 5 14 110 108 2 2329 3 oi3 5 13 88 0 0 0 23323013 5 15 116 233I3013 5 14 100 0 0 0 23353013 5 13 85 23343013 5 13 84 0 0 0 23383013 5 13 88 23373013 5 12 76 0 0 0 23413013 5 12 85 23403013 5 14 97 0 101 23443013 5 14 113 113 23433013 5 13 97 0 0 23473013 5 14 106 23463013 5 14 110 110 122 0 0 2350 3O i3 5 14 103 23493013 5 13 95 0 0 0 23523013 5 15 112 23533013 5 12 81 0 0 0 23553013 5 13 91 23563013 5 14 107 0 0 0 23583013 5 14 106 23593013 5 14 100 0 0 236I3013 5 12 93 23623013 5 13 113 113 0 0 2364 3 oi3 5 14 125 125 2365 3O i3 5 13 103 5 14 5 115 135 123 15 0 135 23683013 23673013 0 0 23713013 5 14 114 2370 3 oi3 5 14 122 122 134 0 23743013 5 15 132 132 23733013 5 14 112 0 0 23773013 5 12 84 23763013 5 16 144 144 0 0 2380soi3 5 14 109 0 23793013 5 13 97 0 0 0 23823013 5 14 101 23833013 5 14 102 0 0 0 23853013 5 12 93 23863013 5 13 109 0 0 0 23883013 5 13 106 23893013 5 14 122 0 0 0 239l3oi3 5 13 98 2392 3 oi3 5 14 114 0 0 2395soi3 5 15 127 23943oi3 5 14 111 0 0 0 2398soi3 5 13 84 23973oi3 5 12 72 0 0 0 2401 3 oi3 5 13 86 24003oi3 5 14 90 0 0 0 24033oi3 5 12 85 0 2404 3 oi3 5 13 97 0 0 2407 3 oi3 5 13 91 24063oi3 5 14 113 0 0 0 0 2409 3 oi3 5 14 107 2410 3 oi3 5 15 119 94 5 13 0 5 13 0 0 95 24123013 24133013 14 5 13 88 0 5 0 0 100 24153013 2416 3 oi3 0 0 0 24I83013 5 15 113 2419 3O i3 5 13 92 0 0 0 24213013 5 14 105 24223013 5 15 117 0 0 0 24243013 5 13 111 24253013 5 13 111 0 0 127 24273013 5 13 108 24283013 5 14 124 122 2 24303oi3 5 15 140 140 0 24313013 5 13 101 0 0 0 24333013 5 14 117 2434 3 oi3 5 15 133 0 0 24363oi3 5 15 130 0 24373013 5 15 130 0 0 0 2440 3 oi3 5 13 93 24393013 5 12 81
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. 24413013 2444 3 oi3 24473013 24503013 24533013
24563oi3 24593oi3 24623oi3 24653013 24683013 24713013 2474 3 oi3 24773013 2480 3 oi3 2483 3 oi3 24863013 2489 3 oi3 2492 3 oi3 24953013 2498 3 oi3 2501 3 013 25043013 25073013 25103013 25133013 25I63013
25193oi3 25223013 25253013
25283oi3 25313013 2534 3 oi3 25373013 25403013 2543 3 oi3
25463oi3 25493oi3 25523013 25553013 25583013 2561 3 oi3 2564 3 O i3 25673013 2570 3 oi3 25733013
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 13 14 12 13 15 16 14 14 13 15 15 14 14 16 14 15 13 15 15 15 15 17 12 13 13 12 14 14 15 13 15 13 14 14 16 14 14 15 14 12 13 15 16 15 14
q 90 102 89 98 130 139 98 105 101 133 126 113 110 135 114 126 113 149 142 142 135 171 81 88 86 87 115 109 115 89 115 107 125 115 147 107 123 136 103 93 103 135 145 126 115
6 0 0 0 0 0 0 0 0 0 132 0 0 0 0 0 0 0 149 130 142 0 171 81 0 0 0 115 96 0 0 113 0 125 0 147 107 123 136 0 0 0 135 145 0 0
/
alg.
0
c
24423013 24453013 24483013 24513013
5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
14 14 13 14 14 13 15 14 14 14 16 14 15 13 15 15 14 14 16 15 16 12 13 14 13 13 13 15 12 14 12 14 14 15 13 15 15 16 14 13 14 14 14 16 14
24543oi3 24573013
24603oi3 24633oi3 24663013
1 24693013 24723013 24753013
24783oi3 2481 3 oi3 2484 3 oi3 24873013 2490 3 oi3
24933oi3 12 24963oi3 24993013
25023oi3 25053013 25O83013 25113013 25143013 25173013 25203013 13 25233013 25263013 25293013 2 25323013 25353013 25383013 25413013 2544 3 oi3 25473013
25503oi3 25533013 25563013 25593013 2562 3 oi3 25653013
25683oi3 25713013 25743013
q 102 99 105 114 107 89 110 102 117 110 142 114 122 101 130 123 133 126 162 138 155 71 93 96 84 103 97 125 79 105 95 127 117 135 94 119 139 152 101 109 119 113 113 138 112
b 0 0 0 0 0 0 0 0 0 0 141 0 0 0 127 0 133 0 162 0 155 71 93 0 0 103 0 125 0 0 0 127 0 135 85 119 139 152 0 0 106 0 0 0 0
/
alg.
24433013 2446 3 oi3 24493013 24523013 2455 3 oi3 2458 3 oi3 2461 3 oi3 2464 3O i3 2467 3O i3 2470 3 oi3 1 24733013 24763013 24793013 2482 3O i3 3 2485 3O i3 24883013 2491 3O i3 2494 3 oi3 2497 3 oi3 25OO3013 2503 3 oi3 2506 3 oi3 2509 3 oi3 25123013 25153013 25I83013 25213013 25243013 25273013
2530soi3 25333013 25363013 25393013 25423013 9 25453013
2548soi3 25513013 25543013 25573013 2560 3 oi3 13 2563 3O i3 25663013 2569 3 oi3 25723013 25753013
0
5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 13 15 14 14 15 14 13 15 14 15 13 15 15 14 14 16 14 15 14 16 16 13 14 12 14 13 14 14 13 14 13 13 15 15 14 13 14 13 15 14 14 15 15 13 15
q 90 111 121 114 123 101 93 114 117 126 101 126 123 117 110 139 129 146 122 158 151 79 105 74 96 99 113 107 95 99 115 105 137 127 106 107 120 91 113 125 119 129 125 99 128
b 0 0 0 0 0 0 0 0 107 0 0 0 0 0 0 136 0 146 0 158 0 79 105 0 0 0 113 0 0 0 115 0 137 115 100 0 0 0 0 125 0 116 0 0 0
/
10
3
12 6
13
4. 5-DIMENSIONAL BASIS DATA FOR I 1 3 1 6 - 1 3 1 6 i 3 i 6 AND l 3 oi3-3013 3 oi3
alg.
0
25763013 2579 3 oi3 25823013 25853013 25883013 25913013 2594 3 oi3 25973013 2600 3 oi3 26033013 26O63013 2609 3 oi3 26I23013 26153013 26I83013 262I3013 2624 3 oi3 2627 3 oi3 2630 3 oi3 26333013 26363013 26393013 2642 3 oi3 2645 3 oi3 2648 3 oi3 2651 3 oi3 2654 3 oi3 26573013 2660 3 oi3 26633013 26663013 26693013 2672 3 O i3 26753013 2678 3 oi3 268I3013 2684 3 oi3 26873013 2690 3 oi3 26933013
5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
26963oi3 26993oi3 27023oi3 2705soi3 2708 3 oi3
c
14 16 14 15 14 16 16 15 16 15 16 17 13 13 15 13 15 14 15 14 15 11 13 13 12 12 14 14 13 13 15 12 13 12 14 14 13 13 15 13 14 13 15 15
q
109 138 131 148 125 161 154 137 147 157 170 183 87 98 114 94 114 109 117 115 127 63 80 79 75 82 102 98 93 89 114 78 93 77 98 98 97 93 117 103 118 98 127 123 14 119
b 0 137 0 148 0 161 147 127 147 157 170 183 0 0 0 0 0 109 117 0 115 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 73 117 0 0 0 127 117 0
/
alg.
25773013 1 258O3013 25833013 25863013 2589 3 oi3 2592 3 oi3
7 2595soi3 10 25983013 26OI3013 26043013 2607 3 oi3 2610 3 oi3 26133013 26I63013 26I93013 26223013 26253013 26283013 263I3013 2634 3 O i3 12 26373013 2640 3 oi3 2643 3 oi3 2646 3 oi3 2649 3 oi3 2652 3 O i3 26553013 26583013 266I3013 26643013 26673013 267O3013 26733013 26763013 2679 3 oi3 26823013 26853013 20 26883013 2691 3 oi3 26943013 2697 3 oi3
2700soi3 27033oi3 6 2706soi3 2709 3 oi3
a
c
5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
15 13 15 15 15 15 17 15 17 16 17 18 13 14 13 14 12 13 13 15 15 12 12 14 13 13 13 15 13 14 11 13 13 13 13 15 13 14 12 14 14 14 14 16 14
q 125 115 151 144 145 138 174 134 163 177 190 203 87 106 84 106 85 93 103 131 123 72 71 88 83 94 90 110 94 101 69 90 90 89 89 110 97 105 90 119 115 114 110 139 111
b / alg. a c q b f 118 7 25783013 5 15 122 0 0 258I3013 5 14 135 135 0 151 2584 3 O i3 5 14 128 0 25873013 5 16 164 164 145 25903013 5 15 141 134 7 0 2593 3 oi3 5 16 158 158 174 2596 3 oi3 5 14 121 108 13 125 9 2599 3 oi3 5 16 150 144 6 0 163 26O23013 5 14 137 0 177 2605 3 oi3 5 15 150 0 190 2608 3 oi3 5 16 163 0 203 26II3013 5 12 79 0 0 26143013 5 14 95 0 0 26I73013 5 14 106 0 0 262O3013 5 14 92 0 0 26233013 5 14 102 0 0 26263013 5 13 97 0 0 2629 3 oi3 5 14 105 0 0 26323013 5 14 119 0 0 26353013 5 14 111 5 16 136 3 139 0 26383013 5 12 0 71 0 2641 3 oi3 0 0 2644 3 O i3 5 13 80 0 0 2647 3 oi3 5 11 67 0 265O3013 5 14 91 91 0 0 26533013 5 13 90 0 0 26563013 5 14 102 0 0 26593013 5 12 81 0 0 26623013 5 14 106 0 0 26653013 5 14 102 0 0 26683013 5 12 81 0 0 267I3013 5 12 81 0 0 26743013 5 14 102 0 0 26773013 5 13 86 0 2680 3 oi3 5 14 101 101 0 0 26833013 5 12 85 0 0 26863013 5 14 109 105 2689 3 oi3 5 14 105 105 0 0 2692 3 oi3 5 13 106 0 0 26953013 5 13 102 0 0 2698 3 oi3 5 15 131 114 0 2701 3 oi3 5 14 111 0 2704 3 O i3 5 15 126 126 0 139 2707 3 oi3 5 13 103 0 0 27IO3013 5 15 127
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg. 27113013 27143013 27173013 27203013 27233013 2726 3 oi3 27293013 2732 3 oi3 27353013 27383013 2741 3 oi3 2744 3 oi3 27473013 27503013 27533013 27563013
27593oi3 27623oi3 27653013 27683013 277I3013 27743013 27773013
27803oi3 27833013 27863013
27893oi3 27923oi3 27953013
27983oi3 28013oi3 2804 3 O i3 28O73013 28103013 28133013 28I63013
28193oi3 28223013 28253013 28283013
28313oi3 28343oi3 28373013
28403oi3 28433oi3
a 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 14 16 13 14 13 13 15 15 13 13 15 14 15 13 15 15 14 14 16 15 16 13 16 16 12 13 13 14 13 13 15 14 15 13 15 14 16 12 14 13 15 13 15 15 14
q 115 139 90 105 97 102 131 127 106 102 127 111 130 106 134 130 134 126 159 139 158 112 160 152 78 93 86 101 99 99 127 111 119 112 144 120 152 87 112 99 124 100 124 124 124
alg. 0 c alg. 0 c q b f b f q b / 0 0 0 27123013 5 15 131 27133013 5 15 123 0 0 0 27153013 5 12 81 27I63013 5 13 93 0 0 0 27I83013 5 14 102 2719 3 oi3 5 13 93 0 0 0 27213013 5 14 102 27223013 5 15 114 0 0 0 27243013 5 14 109 27253013 5 15 121 5 14 14 5 0 0 118 0 115 27273013 27283013 5 14 114 5 0 0 0 15 130 27303oi3 27313013 0 0 0 27333013 5 16 143 27343013 5 12 90 0 0 0 27363013 5 13 99 27373013 5 14 115 0 0 27393013 5 14 118 118 2740 3 oi3 5 14 111 0 0 0 27423013 5 13 102 27433013 5 14 118 0 0 0 27453013 5 15 127 27463013 5 14 114 130 0 27483oi3 5 15 123 0 27493013 5 16 139 81 25 275I3013 5 14 122 122 27523013 5 14 118 118 134 27543013 5 14 118 86 32 27553013 5 15 134 134 130 0 27583013 5 13 114 27573013 5 16 146 146 134 2760 3 oi3 5 14 127 113 14 2761 3 oi3 5 15 147 147 0 27633013 5 15 146 146 2764 3 oi3 5 15 139 132 7 159 0 27663013 5 14 126 27673013 5 15 146 146 123 16 2769 3 oi3 5 16 159 159 0 2770 3O i3 5 15 138 144 5 16 158 171 5 151 17 7 171 27723013 27733013 0 0 27753013 5 14 128 27763013 5 15 144 144 160 0 0 27783013 5 14 120 2779 3 oi3 5 15 136 152 0 278I3013 5 17 168 168 27823013 5 11 69 0 0 27843oi3 5 12 81 0 27853013 5 13 90 0 0 0 27883013 5 12 77 27873013 5 14 102 0 0 0 2790 3 oi3 5 13 89 2791 3 oi3 5 14 98 101 0 0 27933013 5 15 110 27943013 5 12 87 0 0 0 2796 3 oi3 5 13 103 27973013 5 14 115 0 0 0 2799 3 oi3 5 14 111 2800 3 oi3 5 14 115 0 0 0 2802 3 oi3 5 13 95 2803 3 oi3 5 14 107 0 0 28O53013 5 15 123 122 1 2806 3 oi3 5 14 107 0 0 28O83013 5 15 123 2809 3 oi3 5 16 135 135 0 0 0 28II3013 5 14 128 28I23013 5 14 128 144 5 15 0 0 0 2814 3 oi3 2815 3O i3 5 16 160 132 4 5 15 0 136 5 136 15 136 28173013 28I83013 152 152 152 5 16 168 5 17 168 28203oi3 282I3013 0 0 0 28233013 5 13 100 2824 3O i3 5 13 99 0 0 28263013 5 14 111 28273013 5 15 124 119 5 0 0 0 28293013 5 14 112 2830 3 oi3 5 14 111 0 2832 3 oi3 5 15 123 123 2833 3O i3 5 16 136 136 0 0 0 28353013 5 14 112 28363013 5 14 112 0 0 0 28383013 5 14 112 2839 3O i3 5 15 124 0 28413oi3 5 16 136 133 3 2842 3 oi3 5 13 108 0 0 2845 3O i3 5 15 140 139 1 28443oi3 5 14 124 0
4. B-DIMBNSIONAL BASIS DATA FOR I 1 3 1 6 - 1 3 1 6 i 3 i 6 AND l 3 oi3-3O13 3 oi
alg. a c q 28463oi3 5 14 120 28493oi3 5 16 152 28523013 5 15 136 28553013 5 16 148 28583013 5 14 116 28613oi3 5 14 124 28643oi3 5 16 156 28673013 5 16 152 287O3013 5 15 156 28733013 5 16 168 2876 3 oi3 5 16 168 2879 3 oi3 5 17 180 28823013 5 13 106 28853013 5 13 102 28883013 5 15 130 2891 3 oi3 5 14 111 2894 3 O i3 5 15 127 2897 3 O i3 5 13 111 2900 3 oi3 5 15 143 2903 3 oi3 5 16 147 29O63013 5 14 131 29093013 5 15 147 29123013 5 15 140 29153013 5 16 156 29I83013 5 13 96 292I3013 5 15 120 29243oi3 5 14 124 29273013 5 14 120 29303013 5 16 152 29333013 5 15 136 29363oi3 5 16 148 29393013 5 13 111 29423oi3 5 15 143 29453013 5 15 140 2948 3 oi3 5 15 139 29513013 5 15 136 29543oi3 5 17 168 29573013 5 15 152 2960 3 oi3 5 16 172 29633013 5 15 148 2966 3 oi3 5 17 184 2969 3 oi3 5 17 180 29723013 5 15 147 29753013 5 14 139 29783oi3 5 16 175
6 0 152 0 0 0 0 153 149 156 168 168 180 0 0 130 0 0 102 143 147 0 147 0 0 0 0 115 0 148 136 148 0 143 136 0 130 168 149 172 148 184 180 147 0 175
/
3 3
9
9 4
4 6 3
alg. 0 c 28473oi3 5 15 285O3013 5 14 28533013 5 16 28563013 5 16 2859 3 oi3 5 15 2862 3 O i3 5 15 28653013 5 15 28683013 5 17 287I3013 5 15 28743013 5 17 28773013 5 16 288O3013 5 18 28833013 5 13 28863013 5 14 28893013 5 13 2892 3 oi3 5 15 2895 3 oi3 5 15 28983013 5 14 2901 3 oi3 5 15 2904 3 oi3 5 17 2907 3 oi3 5 15 29IO3013 5 16 2913 3 oi3 5 16 29I63013 5 17 29193013 5 14 2922 3 oi3 5 16 29253013 5 14 29283013 5 15 293l3oi3 5 14 29343013 5 16 29373013 5 16 29403013 5 14 29433013 5 14 29463013 5 16 2949 3 oi3 5 15 29523013 5 16 29553013 5 14 29583013 5 16 2961 3 oi3 5 16 29643013 5 16 2967 3 oi3 5 16 2970 3 oi3 5 18 29733013 5 16 29763oi3 5 15 29793013 5 15
q 136 120 152 148 128 140 136 168 152 188 164 200 102 118 99 127 123 131 135 167 147 163 156 172 108 132 124 136 120 152 148 127 124 156 139 152 136 172 168 168 164 200 163 159 152
b 0 0 151 148 0 0 0 165 0 188 0 200 0 118 0 0 0 131 132 167 0 163 0 0 0 132 0 127 117 152 148 0 114 156 139 146 133 172 165 168 164 200 163 159 145
/
alg.
2848 3 oi3 285I3013 1 2854 3O i3 28573013 2860 3 oi3 2863 3 oi3 28663013 3 2869 3 oi3 28723013 28753013 28783013 288I3013 2884 3 oi3 28873013 2890 3 oi3 28933013 2896 3 oi3 2899 3 oi3 3 2902 3 oi3 2905 3O i3 2908soi3 29113013 2914 3O i3 29173013
2920soi3 2923 3O i3 29263013 9 29293013 3 2932 3 oi3 29353013
2938soi3 2941 3O i3
10 29443013 29473013 29503013 6 29533013
3 2956soi3 29593oi3 3 29623oi3 29653013 2968 3 oi3 29713013 29743013 29773013 7 2980 3 oi3
0
5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
c 15 15 15 17 16 15 16 14 16 15 17 12 14 14 14 14 16 14 16 13 14 14 15 12 14 13 15 15 15 15 17 14 15 14 16 16 15 15 17 16 17 14 17 15 16
q 136 136 132 164 140 140 152 136 172 148 184 90 118 114 115 111 139 123 155 115 131 124 140 84 108 108 140 136 136 132 164 127 140 123 155 152 156 152 188 164 184 131 179 155 172
b 136 0 0 164 0 134 0 0 172 0 184 0 0 114 0 0 0 117 155 0 131 0 0 44 0 0 137 124 133 132 164 0 134 0 155 152 156 149 188 164 184 131 179 0 172
/
6
6
40
3 12 3
6
3
8. 4329 FINITE INTEGRAL RELATION ALGEBRAS
alg.
a
c
Q
2981 3 oi3 2984 3 oi3 29873013 2990 3 oi3 2993 3 oi3 2996 3 oi3 2999 3 oi3 3002 3 oi3 30053013 3008 3 oi3 30113013
5 5 5 5 5 5 5 5 5 5 5
16 17 14 16 17 18 17 18 18 19 18
168 191 132 164 180 196 204 220 220 236 236
6 / 7 191 132 164 180 196 204 220 220 236 236 161
alg.
a
c
Q
2982 3 O i3 29853013 29883013 29913013 2994 3 oi3 2997 3 oi3 3OOO3013 3003 3 oi3 3OO63013 3009 3 oi3 30123O13
5 5 5 5 5 5 5 5 5 5 5
17 17 15 16 16 15 16 16 17 16 19
188 184 148 164 164 164 180 180 196 196 256
b / alg. a c q b 188 0 2983 3 oi3 5 16 171 177 7 29863oi3 5 18 204 204 148 29893013 5 15 148 148 164 2992 3 oi3 5 16 164 164 164 29953013 5 17 180 180 164 2998 3 oi3 5 16 184 184 180 3OOI3013 5 17 200 200 180 3004 3 oi3 5 17 200 200 196 3007 3 oi3 5 18 216 216 196 3OIO3013 5 17 216 216 256 30133O13 5 20 276 276
f
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BIBLIOGRAPHY 223. Patrick Suppes, Axiomatic set theory, Dover Publications Inc., New York, 1972, Unabridged and corrected republication of the 1960 original with a new preface and a new section (8.4). 224. Gaisi Takeuti and Wilson M. Zaring, Axiomatic set theory, Springer-Verlag, New York, 1973, With a problem list by Paul E. Cohen, Graduate Texts in Mathematics, Vol. 8. 225. Alfred Tarski, Relation algebras, course notes by Steven R. Givant, 1 Jan 1970-14 May 1970. 228. , OR the calculus of relations, J. Symbolic Logic 6 (1941), 73-89. 227. , untitled, Manuscript on the calculus of relations, 1943, xv+269 pp. 228. , A remark on functionally free algebras, Ann. of Math. (2) 47 (1946), 163-165. 229. , A formalization of set theory without variables, J. Symbolic Logic 18 (1953), 189. 230. , Some metalogical results concerning the calculus of relations, J. Symbolic Logic 18 (1953), 188-189. 231. , An undecidable system of sentential calculus, J. Symbolic Logic 18 (1953), 189. 232. , Contributions to the theory of models. Ill, Nederl. Akad. Wetensch. Proc. Ser. A. 58 (1955), 56-64 = Indagationee Math. 17, 56-64 (1955). 233. , Equationally complete rings and relation algebras, Nederl. Akad. Wetensch, Proc. Ser. A. 50 = Indag. Math. 18 (1956), 39-46. 234. , Logic, Semantics, Metamathematics. Papers from 1923 to 1938, Oxford at the Clarendon Press, 1956, Translated by J. H. Woodger. 235. , A simplified formalization of predicate logic with identity, Arch. Math. Logik Grundlagenforech 7 (1965), 61-79. 236. , Equational logic and equational theories of algebras, Contributions to Math. Logic (Colloquium, Hannover, 1966), North-Holland, Amsterdam, 1968, pp. 275-288. 237. , Logic, Semantics, Metamathematics, second ed., Hackett Publishing Co., Indianapolis, IN, 1983, Papers from 1923 to 1938, Translated by J. H. Woodger, Edited and with an introduction by John Corcoran. 238. , Collected papers. Vol. 4, Birkhauser Verlag, Basel, 1986, 1958-1979, Edited by Steven R. Givant and Ralph N. McKenzie. 239. , What ore logical notions?, Hist. Philos. Logic 7 (1986), no. 2, 143-154, Edited by John Corcoran. 240. Alfred Tarski and Steven R. Givant, A formalization of set theory without variables, American Mathematical Society, Providence, RI, 1987. 241. Alfred Tarski and Robert L. Vaught, Arithmetical extensions of relational systems, Compositio Math 13 (1957), 81-102. 242. Jan Lukasiewicz, The shortest axiom of the implicational calculus of propositions, Proc. Roy. Irish Acad. Sect. A. 52 (1948), 25-33. 243. , Elements of mathematical logic, Translated from Polish by Olgierd Wojtasiewicz. International Series of Monographs on Pure and Applied Mathematics. Vol. 31, A Pergamon Press Book, 1964. 244. , Selected works, North-Holland Publishing Co., Amsterdam, 1970, Edited by L. Borkowski, Studies in Logic and the Foundations of Mathematics. 245. Johan F. A. K. van Benthem, Modal Correspondence Theory, Ph.D. thesis, University of Amsterdam, 1976. 248. , The logic of time, Reidel, 1983. 247. Jean van Heijenoort, From Frege to Gb'del. A source book in mathematical logic, 1879— 1931, Harvard University Press, Cambridge, Mass., 1967. 248. Robert L. Vaught, Model theory before 1945, Proceedings of the Tarski Symposium (Proc. Sympos. Pure Math., Vol. XXV, Univ. California, Berkeley, Calif., 1971) (Providence, R.I.), Amer. Math. Soc, 1974, pp. 153-172. 249. , Alfred Tarski's work in model theory, J. Symbolic Logic 51 (1986), no. 4, 869882. 250. , Errata: "Alfred Tarski's work in model theory", J. Symbolic Logic 52 (1987), no. 4, vii. 251. , Set theory, second ed., Birkhauser Boston Inc., Boston, MA, 1995, An introduction. 252. John von Neumann, Eine axiomatisierung der mengenlehre, Journal fur die reine und angewandte Mathematik 154 (1925), 219-240, correction ibid. 155, 128. 253. , uber eine widerspruchfreiheitsfrage in der axiomatischen mengenlehre, Journal fur die reine und angewandte Mathematik 180 (1929), 227-241.
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254. Heinrich Werner, Discriminator-algebras, Studien zur Algebra und ihre Anwendungen [Studies in Algebra and its Applications], vol. 6, Akademie-Verlag, Berlin, 1978, Algebraic representation and model theoretic properties. 255. Alfred North Whitehead and Bertrand Russell, Principia Mathematica, Volume I, Gambridge University Press, Cambridge, England, 1910, Second edition, 1925. 256. Ulf Wostner, Finite relation algebras, Notices of the American Mathematical Society 23 (1976), A-482. 257. , On equationally definable classes of partial ordering relations, Notices of the American Mathematical Society 23 (1976), A-643. 258. Ernst Zermelo, Beweis, dass jede menge wohlgeordnet werden kann, Math. Annalen 59 (1904), 514-516, in [247], Proof that every set can be well-ordered, 139-141. 259. , Neuer beweis fur die mb'glichkeit einer wohlordnung, Math. Annalen 65 (1908), 107-128, in [247], A new proof of the possibility of a well-ordering, 183-198. 260. , Untersuchungen iiber die grundlagen der mengelehre i, Math. Annalen 65 (1908), 261-281, in [247], Investigations in the foundations of set theory I, 199-215. 261. Max Zorn, A remark on method in transfinite algebra, Bulletin of the American Mathematical Society 41 (1935), 667-670.
Index
-F-labelling system, 508 incompatible, 265 _R-cone, 112 -R-image, 94 X-saturated, 408 a-variable equations, 136 e-relation, see also relation, epsilon n-hy-n matrix, 326 n-matrix, 326 w-additive, 245 w-sequences, 177 m-additive, 245 m-additive under z, 245 m-multiplicative, 245 ra-ary clone generated by, 132 n-associative, 371 n-diamond condition, 350 n-formula, 173 n-sentence, 173 ra-term, 173 1-cycle, 418, 459, 463-465, 467, 470 16-tuples, 86 2-cycle, 418, 459, 463-465, 468, 470 3-associative, 371 3-chain, 469 3-cycle, 418, 459, 463, 465, 467, 468, 470 4-associative, 371 absolutely freely n-generated algebra, 136 absolutely freely generated by, 133 additive, 243 agree, 180 agree up to, 330 (AI), 190 (All), 190 (AIII), 190 (AIV), 190 (AIX), 191 (AIX'), 191 (AIX"), 191 (AIX*), 191 algebra Boolean, 233, 294 complete, 267
regular-open, 257 commutative, 294 complete, 236 predicate, 169 similar, 122 symmetric, 294 term, 168 trivial, 22, 294 algebra of Boolean type, 122 algebra of group type, 122 algebra of monoid type, 122 algebra of relational type, 122 algebraic interpretation n-dimensional, 557 algebraic model, 559 algebraic satisfaction relation, 558 algebraically n-valid, 559 algebraically valid, 559 Allen, J. F., xiv, 362, 363 Allen-Hayes algebra, 363 Aim, J. F., xv Andreka, H., xv, 23, 424, 429, 434, 435, 465, 471, 472, 505, 506 Anellis, I. H., vii Aristotle, vii arrow tautology, 197 Arrow, K. J., x assignment, 136 associative law, xi, 32 AtFm+(£), 170 AtFm(£), 169 atom, 237, 296 diversity, 296 flexible, 459 identity, 296 atomic, 237 atomic algebra, viii, ix, xiii, 245, 247, 272, 274, 285-287, 324, 325, 331, 340, 343, 345, 346, 348-352, 354, 355, 360, 364366, 385, 400, 401, 403, 407, 408, 410, 414, 416, 417, 433, 457-459, 461, 470472, 483, 486, 488, 489, 497, 499, 512518, 522, 523, 557-559, 563, 564, 569, 572-574, 576
atomic formula, 169 automorphism, 460, 477 (AV), 191 (AVI), 191 (AVI'), 191 (AVI*), 193 (AVII), 191 (AVIII), 191 (AX), 191 (AX'), 191 Axiom of Choice, 38, 101 Axiom of Complementation, 42 Axiom of Converge, 52 Axiom of Kxtensionality, 39 Axiom of Infinity, 97, 100 Axiom of Intersection, 43 Axiom of Regularity, 102 Axiom of Relative Product, 49 Axiom of Singletons, 90 Axiom of the e-Relation, 56 Axiom of the Empty Set, 42 Axiom of Unordered Pairs, 47 axioms, 187 BA, 233, 236-239, 241-245, 247-253, 256258, 262, 267, 268, 270-275, 280, 282288, 291, 321, 366, 724 Backer, F., x, 418, 424 Badesa, C , vii base, 490 basis cylindric n-dimensional, 330 relational, xiii, 406, 422 n-dimensional, 330 5-dimensional, 422, 433 semantical, 350, 557, 559, 563, 564, 572, 576, 577 n-dimensional, 330 begins, 490 Berge, C , 469, 470 Berghammer, H., 83 Bernays, P., \riii, xi, 35, 36, 38, 85, 102, 198-200 Berry closure, 174, 212 Berry, G. D. W., 174 Beth, E. W-, 36 (BI), 192 (BII), 192 (Bill), 192 bisection, 67 bijecti-re class, 67 binary operation on, 121 binary relation, see also relation, binary binary relation on, 50, 90 binary relational language, 214 Binford, T. O., 362 Birkhoff, G., xiii, 137, 150, 231, 388 (BIV), 192 (BIV'), 192 (BIX), 192 Boole, G., vii, 1-3, 7
Boolean, 291 Boolean addition, 122 Boolean algebra complete, 267 regular-open, 257 Boolean algebra of subsets, 142, 290 Boolean algebra with operators, 286 Boolean combinations of equations, 15 Boolean dual, 252, 290 Boolean multiplication, 122 Boolean ordering, 100 Boolean part, 122, 286 Boolean reduct, 122, 286 Boolean relation algebra, 291 boundary, 256 bounded ordering, 100 Brady, C , vii, 2-4, 18, 20 Brink, C , xv, 2, 23, 323 Bruck, H. H., 30, 150, 467 Brunning, J., 2 Buehi, J. R., 267 (BV), 192 (BVI), 192 (BVII), 192 (BVIII), 192 (BX), 192 Borner, F., 23 canonical base for, 490 canonical base points, 490 canonical embedding algebra, 366 canonical permutations, 493 canonical relativized cylindric set algebra, 489, 494 cardinal, 102 cardinality, 102 Cartesian square, see also square, Cartesian Catalan numbers, 371 chain, 99 Chin, L. H., x, xiii, 8, 22, 23, 60, 294, 297308, 311-314, 316, 318-321, 369, 382, 384, 393, 394, 396, 397, 502 Church, A., 18, 192, 199 (CIV), 193 class, 35 antisymmetric, 99 asymmetric, 99 domain-reflexive, 98 linear, 99 proper, 35 range-reflexive, 98 reflexive, 98 universal, 42 Class Union Axiom, 92 clone generated by, 133 clopen, 283 closed, 256, 283 closure, 174 closure operator on, 256 coextensivity, 62 cofinite, 244 collapses, 495
725
color, 473 Comer, S. D., xv, 23, 389, 418, 423, 458, 470, 482 complement, 5, 42 complemented ordering, 100 complete, 100, 512 complete algebra, viii, ix, xiii, 29, 236, 242, 245, 247, 262-264, 267, 270-275, 280, 283, 284, 286, 288, 323-327, 330, 345, 348, 354, 355, 360, 364-366, 385, 400, 403, 407, 408, 410, 416, 457-459, 461, 471, 486, 488, 489, 497, 499, 512514, 516, 522-525, 558 complete Boolean algebra, 267 complete for arrow tautologies, 198 complete representation, 512 complete subalgebra, 512 completely cj-additive, 245 completely ro-additive, 245 completely m-additive under z, 245 completely m-multiplicative, 245 completely additive, 244 completely additive on, 274 completely multiplicative, 245 completely representable, 512 completion, 270, 286, 323 complex algebra, 292, 354 composition, 49 concepts, xiv condition (a), 267 congruence relation, 124 conjugate, 253 conjugated quasi-projections, 415 constant, 242 contains, 327 contracting, 256 converse, 5, 52, 327 cover, 471 (CV), 193 (CVI), 193 (CVII), 193 (CVIII), 194 cycle, 351, 417 diversity, 351 forbidden, 351 identity, 351 cycle law, 311 De Morgan, A., vii, x, xi, 1, 2, 4—8, 11, 12, 14, 20-23, 25, 45, 54, 238, 289, 309-311 denotation function, see also function, denotation dense, 237, 256 dense below, 265 dense in, 237 dense relation, see also relation, dense (DI), 191 diagonal condition, 328 diagonal property, 459 Diamond, A. H., 23 difference, 43, 234 symmetric, 43
(DII), 191 (Dili), 191 Dilworth, R. P., 100 direct product, 90, 128, 129 direct square, see also square, direct directly indecomposable, 129 discriminator term, 386 distributive ordering, 100 (DIV), 191 diversity element, 122 diversity relation, see also relation, diversity diversity relation on, 90 domain, 66, 90, 122 dual-normal, 242 Diintsch, I., 505, 506 (DV), 191 Eilenberg, S., 328 El Bachraoui, M., 380 element antisymmetric, 295 bifunctional, 295 difunctional, 295, 313 domain, 294 equivalence, 295 functional, 295 ideal, 294 left-ideal, 294 permutational, 295 range, 294 right-ideal, 294 subidentity, 296 symmetric, 295 symmetric-reflexive, 295 transitive, 295 elimination mapping, 527 embedding, 127, 243 empty, 41 ends, 490 epsilon relation, see also relation, epsilon equality relation, see also relation, equality equality symbol, 167 equational axiomatization for, 137 equational class, 137 equations, 136 equipollent, 187 equipollent in means of expression, 186 equipollent in means of proof, 186 equivalence relation, see also relation, equivalence equivalence relation algebra, see also relation algebra, equivalence, 142, 290 expanding, 256 extended formulas, 170 extends, 274 extensional class, 76, 117 F-labellings, 508 Feferman, A. B., viii, x Feferman, S., viii, x (FI), 193
726
field, 93 (Fill), 193 filter, 127, 241 proper, 127 filter generated by, 241 final index, 516 fine, 267 finished, 489 finite intersection property, 242 finitely based equational class, 137 (FIV), 193 flaw, 489 flexible, 459 flexible system of atoms, 488 f m n , 540 S"mn(2), 540 fm+(£), 540 fm+, 540 » m + 2 ) , 540 forbidden minor, 433 Fm+(£), 170 Fm(£), 170 formalism, 186 Formisano, A., 532 formula, 170 parameterized, 92 set-bounded, 39 free algebra over K, 140 free for, 175 free variables, 136, 173 Frege, G., vii, 3, 18, 193 Freyd, P. J-, 413 Frias, M. F., 322, 482 function, 66 denotation, 539 function from, 121 function on, 121 function symbols, 167 functional class, 66 functional part, 69, 394 (FV), 193 (FVI), 193 Gabbay, D. M., 323 generalization, 187 Givant, S. R., vii-x, xiii, xv, 15, 18, 21, 24, 25, 27-29, 32, 35, 38, 39, 43, 48, 60, 74, 76, 83, 85, 87, 98, 167, 174, 176, 177, 186, 187, 189-191, 193, 214-217, 243, 275, 280, 282, 285, 286, 295, 313, 357, 361, 383, 396, 398, 416, 485, 527532, 534-537, 542, 543, 547, 548, 550, 556, 566, 578, 580, 581 Gleason, A. M., 469, 470 Godel, K., viii, xi-xiii, 26, 32, 35-38, 85, 86, 90, 93, 100, 102, 192, 217, 230, 528, 530, 581 good,413 good substitution, 176 GRA, 292, 504, 505, 726 Graham, H, L., 150, 469 greatest lower iJ-bound, 99
Greenwood, R. E., 469, 470 Grelling, K., viii group, 292 group relation algebra, see also relation algebra, group, 292 groupoid, 122 Hall, Jr., M., 30, 292, 467 Halmos, P. R., xiv, 16, 102 Hayes, P. J., 363 height, 275 Henkin, L., xv, 94, 121, 129-131, 135, 137, 140, 192, 193, 215, 230, 233, 245, 248, 285, 286, 288, 331, 366, 382, 383, 388, 471, 494 (HI), 192 (HII), 192 (HIII), 192 (HIII'), 193 Hildebrand, C. A., v Hirsch, R., w , 30, 160, 247, 324, 331, 340, 341, 345, 357, 386, 400, 410, 420, 458, 468, 489, 497, 509, 517, 542 (HIV), 192 Hodges, W., xiv Hodkineon, I., xv, 30, 160, 247, 324, 331, 340, 341, 345, 357, 386, 400, 410, 420, 458, 468, 489, 497, 509, 517, 542 homomorphism, 125, 243 homomorphism on, 126 Houser, N., vii Huntington, E. V., vii, 19, 21, 233, 234, 258, 262, 289, 551 (HV), 192 (HV'), 193 (HVI), 192 (HVI'), 193 (HVII), 192 (HVII'), 193 (I), 19 ideal, 127, 241, 381 maximal, 128 Peircean, 158 proper, 127 relational, 152 proper, 152 ideal generated by, 241, 377, 382 idempotent, 256 identity partition, 473 identity element, 122 identity relation, see also relation, identity identity relation on, 90 (II), 19 (ill), 19 image, 95 inconsistent, 219 initial index, 516 injection, 67 injective class, 67 injective part, 69
integral, x, xiv, 31, 294, 317, 350, 355, 356, 358-360, 366, 367, 386, 389, 391, 392, 395, 418, 419, 421, 423, 424, 427429, 433-436, 454, 456, 459-461, 464, 465, 472, 473, 476, 480, 482-485, 504, 506, 583 interpretation, 177 algebraic n-dimensional, 557 intersection, 6, 43, 234, 327 interval algebra, 362 involutive, 256 IRRA, 504-506, 727 isomorphic to, 127 isomorphism, 243 isomorphism from, 127 isomorphism type, 423 (IV), 19 (IX), 19 (J), 30 Jech, T. J., 267 Jevons, W. S., 1 Jipsen, P., 386, 418, 419, 460, 470, 482 join-compact, 275 Jonsson, B., ix, x, xiii, xiv, 22-25, 30, 31, 144, 160, 231, 245-248, 253, 255, 266, 275, 286, 288, 292, 295, 300, 312, 317, 326, 351, 359, 365, 366, 380, 382-384, 386-388, 396, 414, 416, 423, 468, 476, 482, 483, 485, 499, 502, 504, 508 Kalbfleisch, J. G., 470 Kalish, D., 194 Kelley, J. L., 102 kernel, 151, 153 Koomen, J. A., 362 Koppelberg, S., 267, 270 Korselt, A., viii, 25, 531 Kramer, R. L., 288, 331, 418, 470 Kuratowski, K., xi, 48 Kwatinetz, M., 25, 531, 532 (L), 30 C, 189 £+, 189 £+, 189 £3, 189 £+, 189 £ „ , 189 £ x , 189 Lowenheim-Skolem-Tarski theorem, vii labelling, 489, 506 ra-ary, 507 finitary, 507 Ladkin, P. B., 335, 362 Lane, K., 536 Langford, C. H., 8, 18 language, 167 nice, 167 lattice of commuting equivalence elements, 502 lattice ordering, 100
least upper i?-bound, 99 length, 490 Lewis, C. I., vii, 8, 18 (LI), 192 (LII), 192 (LIII), 192 lines, 359 (LIV), 198 Cox, 189 logically implies, 179 logically valid, 179 loose color, 474 loose piece, 474 Lowenheim, L., vii, viii, xiii, xv, 25, 231, 531 lower i?-bound, 99 £s 3 , 189 £ s j , 189 Lukacs, E., 418, 419, 482 Lukasiewicz, J., 192, 193, 198, 199, 205, 208, 210 Cwx, 189 Lyndon algebra, 360 Lyndon, R. C , ix, x, xiii, xiv, 23, 25, 2831, 149, 150, 349, 351, 353, 358-360, 410, 418, 423, 459, 467, 468, 470, 472, 504, 508, 514-516 (M), 30 M(n>, 189 M(n)+, 189 M(n)x , 189 MA, 345, 727 MacLane, S., 328 MacNeille, H. M., xii, 102, 118, 273 Maddux, R. D., x, xv, 29, 31, 32, 68, 83, 143, 149, 160, 176, 235, 288, 293, 300, 314, 317, 318, 322, 325, 326, 328, 331, 332, 334, 335, 338, 345, 346, 348, 350, 354, 357, 362, 365-367, 369, 378-380, 382-384, 387-389, 393, 395, 397, 408, 410, 413, 414, 416, 418, 424, 429, 434, 435, 457-461, 465, 467, 470-472, 479482, 486, 488, 489, 497, 499, 502, 508, 512, 514, 516-519, 521-525, 537, 538, 541-543, 546, 553, 559, 563, 564, 572, 574, 576, 577 Mal'cev, A., vii, 231 Malik, J., 362 mapping elimination, 527 Martin, R. M., 2 matrix atom, 328 atomic, 328 basic, 328 closed, 328 forbidden, 399 identity, 328 path-consistent, 327 symmetric, 328 zero, 328
maximal element, 99 maximal filter, 128 maximal relational ideal, 152 McGune, W., 233 McKenzie, H. N., x, xiv, 30, 31, 118, 131, 137, 326, 360-362, 366, 410, 418, 423, 465, 482, 502, 504, 505, 530, 534 McKinsey, J. C. C , viii, x, xiii, 23, 32, 292, 294, 318, 355, 357, 358, 367, 384, 456, 464, 535 McNulty, G. F., 118, 131, 137, 361, 530, 534 meet, 234 meet-compact, 275 membership relation, see also relation , membership Mendelson, E., 35, 36, 102, 230 Merrill, D. D., vii, 2 middle index, 516 minimal element, 99 minimum element, 501 Mitchell, O. H., 14, 18 model, 179 model of, 179 modular lattice, 501 modus ponens, 19, 187 Monk's theorem, 468 Monk, J. D., x, xii-xv, 9, 30, 94, 102, 121, 128-131, 135, 137, 140, 150, 176, 177, 193, 233, 275, 280, 282, 285, 286, 324, 326, 334, 360, 366, 382, 383, 388, 410, 468, 469, 471, 473, 476, 494, 509 monochromatic, 473 monotonic, 242 monotonic on, 274 Montague, R., 194 Moore, G. H., vii, 18 multiplicative, 243 NA, xi, xiii, 31, 60, 203, 294, 296, 302, 306-309, 313-326, 329-331, 338, 340, 343, 345, 351, 352, 354, 355, 357, 358, 384-367, 369, 380-384, 387, 395, 398, 401, 413, 415, 417-419, 435, 436, 456, 458-462, 471, 476, 477, 481, 486, 487, 489, 502, 508, 517, 532-535, 538, 557, 560, 728 Nemeti, I., xv, 23, 416, 471, 472, 505, 506 Ng, K. C , x, 59 nonaseociative relation algebra, see also relation algebra, nonassociative nonprincipal ultraproduct, 130 nontrivial, 127 nonzero elements, 236 normal, 242 nowhere dense, 256 off-diagonal condition, 328 Ohlbach, H. J., 323 Omodeo, E. G., 532 one-to-one, 67 open, 256, 283 order, 467
order-reversing, 243 ordinal, 102 pair, 47, 296 ordered, 47 pair-dense, xiv, 501, 517, 518, 519, 521525
partial ordering, 99 partial ordering of, 99 partition, 469 (Pe), 198 Peano, G., vii Peirce's remarkable property, 14 Peirce'e tautology, 197 Peirce, B., 719 Peirce, C. S., vii, viii, x-xii, 1-25, 49, 51, 52, 54, 58, 59, 65, 66, 75, 107, 110112, 116, 197, 198, 308, 310, 369, 383, 384, 393, 394 Peircean part, 122 perfect extension, ix, 272, 288, 324 permutation-equivalent, 433 permutational, 504 persistent atom, 483 pieces, 473 Pigozzi, D., 131 point, 296 point-dense, xiv, 415, 517, 518, 522-525 pointer, 490 points, 359 Policriti, A., 532 polychromatic, 473 powereet, 98 Powerset Axiom, 98 PRA, 504-506, 728 predicate algebra, 169 predicate equality symbol, 167 predicates, 31, 168 predicative, 87, 92 preorder, 99 principal filter, 241 principal ideal, 241 product rule, 399 projective geometry, 359 proof, 188 proper class, see also class, proper proper relation algebra, see also relation algebra, proper, 290 QRA, ix, x, xiv, 83, 215, 383, 415, 578, 579, 728 QRA theorem, ix, x, xiv, 83, 215, 415, 578 quaternary relation, see also relation, quaternary quaternary relation on, 90 Quine closure, 174, 212 Quine, W. V. O-, 29, 40, 174, 190, 208210, 212, 215, 536, 537 quotient algebra, 125 Ri-Rio, 21, 289 RA, xi, xiii, xiv, 20, 23, 29, 31, 83, 289, 290-294, 313, 318-322, 324, 326, 340,
344-350, 355, 358-360, 365, 366, 380, 381, 383, 387, 393-398, 400, 403, 406408, 410, 411, 413-416, 420-424, 433, 456-459, 462-465, 467, 472, 479, 480, 482-485, 499-504, 512-519, 521-524, 532-534, 538, 550, 551, 553, 557, 558, 572, 574, 576, 577, 729 Ramsey theorem, 150 Ramsey's Theorem, 470 range, 66, 122 rank, 167, 516 RCA, 150, 729 rectangle, 295 reduced, 490 reduced product, 130 reduction, 490 reflexive, 295 regular, 256 regular subalgebra, 512 regular-open, 256 regular-open Boolean algebra, 257 relation binary, 4, 50 dense, 58 diversity, 13, 56 epsilon, 35, 56 equality, 35 equivalence, 60 identity, 13, 56 membership, 35 quaternary, 90 ternary, 90 unit, 50 universal, 13 relation algebra, 21, 289 equivalence, 24 group, x, 292 nonassociative, xi, 31, 293 pentagonal, 433 proper, 24, 143 quasi-projectional, 415 representable, 143 semiassociative, xi, 31, 293 square, 23, 24, 29, 142, 143, 149, 160, 164, 165, 178, 290, 356, 423, 522, 533, 534, 546, 557, 572 weakly associative, xi, 31, 293 relation algebra of dimension n, 345 relation algebra of subrelations, 142 relation defined by, 539 relation symbols, 31, 167 relational part, 50 relative addition, 8, 122 relative multiplication, 7, 8, 122 relative part, 122 relative product, 7, 49, 327 relative sum, 8, 49 relativization, 379 Replacement Axiom, 95 representable, viii—x, xii—xiv, 24, 25, 29, 30, 31, 83, 140, 143, 150, 160, 164,
166, 290-292, 324, 358-362, 389, 413416, 422-424, 427-429, 459, 460, 464, 465, 467, 468, 470-473, 476, 480-482, 484, 485, 504, 506, 508, 512, 514-516, 522, 524, 525, 533, 534, 538, 541, 542, 546, 579 representable relation algebra, 143, 290 representation, 143 complete, xiv, 143, 459, 465, 512, 514, 516, 521-523, 525 minimal, 424 square, 143, 409, 424, 425, 427-430, 432, 433, 463, 464, 465, 467, 470, 485 unique, 424 representation of a Boolean algebra, 271 rigid, 477 Riguet, J., 313 Robinson, J., 369 Robinson, R. M., 102 Rothschild, B. L., 150, 469 RRA, xii-xiv, 24, 30, 31, 83, 140, 143, 144, 148-150, 159, 160, 165, 166, 290, 292, 324, 326, 337, 358, 360, 361, 365, 380, 408-416, 420, 456, 458, 460, 462-464, 467, 468, 470, 473, 476, 481, 485-489, 504, 505, 508, 512, 515, 516, 532-534, 538, 542, 546, 550, 553, 557, 572, 574, 729 Rule for Changing Places, 8, 309 rule of inference, 187 rule of replacement, 187, 188 Russell, B., vii, 7, 8, 18, 49 Ryser, H. J., 30, 150, 467 SA, xi, xiii, xiv, 31, 293, 294, 306, 307, 314, 317, 318, 324, 326, 331, 340, 343, 345, 346, 348, 355, 357-359, 365-367, 369, 378-381, 383-390, 393-395, 397, 398, 400-403, 406-408, 410, 412, 456, 462-465, 467, 472, 486, 487, 497-499, 501-503, 517, 518, 522-525, 532-535, 538, 550, 551, 553, 556-560, 563, 564, 570-572, 574, 576, 577, 729 Scedrov, A., 413 Schmidt, G., xv, 83, 499 Schroder-Tarski Translation Mapping, 385 Schroder, F. W. K. E., vii, viii, xv, 1, 3, 12-14, 19, 20, 23-25, 51, 58, 59, 102, 122, 310, 385, 388, 401-403 section, 404 self-conjugate, 253 self-dual, 243 semantic equivalence relation, 179 semantically equivalent, 179 semiassociative law, xi, 33, 192, 293 semiassociative relation algebra, see also relation algebra, semiassociative semisimple, 33, 129 Sent x (£), 169 sentence, 20, 173 separative, 267 set, 35 set of binary relations on, 141
set union, 96 Set Union Axiom, 96 set-bounded formula, 85, 86 Sheffer, H. M., vii side left, 47 right, 47 Sikorski, R., xii, 235, 247, 267, 270, 486 similar algebra, 122 Simmons, R. G., 362 simple algebra, viii, ix, 22, 23, 29, 33, 127, 129, 143, 160, 245, 383-390, 401-403, 406-408, 421, 423, 424, 459, 482-485, 488, 489, 497-501, 504, 518, 519, 521524 singleton, 296 Skolem, T., vii, xiii, 231 spectrum, 424 Spencer, J. H., 150, 469 splittable, 472 splittable in, 472 splitting, 471 splitting along, 471 square, 295 Cartesian, 90 direct, 90 square relation algebra, see also relation algebra, square square relation algebra on, 142 squaring rule, 399 Stanton, R. G., 470 statements basic equality, 35 basic membership, 35 compound, 35 Stone, M. H., 29 Strohlein, T., xv, 83, 499 subalgebra, 123 subalgebra generated by, 123 subclass, 44 proper, 44 subdirect product, 129 subdirectly indecomposable, 129 subformalism, 186 subset, 44 subtractive, 243 subuniverse generated by, 123 successor, 97 suitable set of matrices, 490 sum rule, 399 superclass, 44 proper, 44 Suppes, P., 102 symbols, 168 symmetric class, 58 symmetric difference, 234 symmetric part, 58 symmetric relation generated by, 58 system of algebras, 129 (Ta), 198 tabular, xiv, 83, 413, 414, 416, 508 Takeuti, G., 267
Tarski, A., vii-xv, 8, 12-16, 18-33, 35, 3739, 43, 48, 50, 51, 54, 60, 74-76, 83, 85, 87, 94, 98, 121, 129-131, 135, 137, 140, 144, 150, 160, 166, 167, 174, 176, 177, 186, 187, 189-193, 198-200, 210212, 214-217, 231, 233, 243, 245-247, 253, 255, 266, 275, 285, 286, 288, 289, 292, 294, 295, 297-308, 310-314, 316321, 323, 326, 351, 357, 361, 365, 366, 369, 380, 382-388, 393, 394, 396-398, 401-403, 414-416, 423, 465, 468, 471, 485, 494, 499, 502, 504, 527-532, 534537, 540, 542, 543, 547, 548, 550, 556, 566, 578, 580, 581 tautology, 171 Taylor, I., 536 Taylor, W. F., 118, 131, 137, 530 Tm(£), 168 term algebra, 168 Tm n (£), 173 terms, 136, 168 ct-variable, 136 ternary relation, see also relation, ternary ternary relation on, 90 Theorem K, vii, 8, 22, 23, 54, 309 theory, 219 complete, 220 consistent, 219 tight color, 474 tight piece, 474 topological closure operator, 256 topological space, 264 topology, 264 trail, 490 transitive, 58 transitive relation, 58 triangle condition, 328 true in, 136 Tuza, Z., 460, 470 twin, 296 ultrafilter, 241 nonprincipal, 128 principal, 128 ultrafilter embedding, 366 ultrafilter on, 128 ultrafilter structure, 366 Ultrafilter Theorem, 242 ultraproduct, 130 unary algebra, 122 unary clone generated by, 132 unary operation on, 121 unary type, 122 union, 6, 92 binary, 43 unit element, 122 universal class, see also class, universal universal relation, see also relation, universal universally additive, 245 universally multiplicative, 245 universe, 122, 177 universe of discourse, 4
731
upper -R-bound, 09 (V), 19 valid in, 136 valuation, 171 van Benthem, J. F. A. K., 266, 362 van Heijenoort, J., vii, 25, 230 variables, 136, 167, 173 variety, 137 discriminator, 386 Vaught, R. L., vii, 102, 231 Venema, Y., 275, 280, 282, 285, 286 (VI), 19 Viana, J. P., xv videotape, 468 (VII), 10 (VIII), 19 von Neumann, J., viii, xi, 35, 102 WA, xi, xiii, 31, 203, 294, 306, 318, 324, 326, 331, 332, 334, 335, 338-343, 345347, 350, 355, 357, 358, 365-367, 369, 370, 380, 381, 384, 387, 411, 456, 462465, 467, 471, 486-489, 497, 499, 558, 731 weak associative law, xi, 293 weakly associative relation algebra, see also relation algebra, weakly associative well-ordered by, 99 Werner, H., 386 Whitehead, A. N., vii, 7, 8, 18, 49 witnesses, 221 Wostner, U., 418, 424, 435, 465, 531 (X), 19 (XI), 19 (XII), 19 (XIII), 19 (XIV), 19 (XV), 19 Zaring, W. M., 267 Zermelo, E., 101, 578 zero element, 122 zero rule, 399 zero-divisor, x, 31, 294, 317, 318, 355 Zierer, H., 83 Zorn, M., 102, 128, 159, 405
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