LECTURES ON COMPLEX ANALYTIC VARIETIES:
THE LOCAL PARAMETRIZATION THEOREM
BY
R. C. GUNNING
PRINCETON UNIVERSITY PRES...
8 downloads
555 Views
5MB Size
Report
This content was uploaded by our users and we assume good faith they have the permission to share this book. If you own the copyright to this book and it is wrongfully on our website, we offer a simple DMCA procedure to remove your content from our site. Start by pressing the button below!
Report copyright / DMCA form
LECTURES ON COMPLEX ANALYTIC VARIETIES:
THE LOCAL PARAMETRIZATION THEOREM
BY
R. C. GUNNING
PRINCETON UNIVERSITY PRESS AND THE
UNIVERSITY OF TOKYO PRESS
PRINCETON,
NEW JERSEY
1970
Copyright © 1970, by Princeton University Press All Rights Reserved L.C. Card: I.S.B.N.:
73-132628
0-691-08029-1
A.M.S. 1968:
3244
Published in Japan exclusively by the University of Tokyo Press; in other parts of the world by Princeton University Press
Printed in the United States of America
1.
PREFACE
In introductory courses on complex analytic varieties, it is customary to begin the local description of irreducible subvarieties by choosing a system of coordinates in the ambient space LP
such that the subvariety is in a particularly convenient posi-
tion, for example, such that the subvariety appears as a branched covering space of a coordinate hyperplane under the natural projection mapping.
zk+l
... = zn =
0
The existence of such coor-
dinate systems, together with a catalog of the elementary properties of analytic subvarieties in terms of these coordinate systems, comprise what may be called the local parametrization theorem for complex analytic subvarieties.
Once this has been established, it
is relatively easy to derive the standard local properties of analytic subvarieties, and the way is then clear to proceed to more advanced topics, either on the local or the global level. These lecture notes treat the local parametrization theorem, assuming some background knowledge of the general function theory of several complex variables.
They contain the mate-
rial common to the first parts of several courses of lectures on complex analytic varieties that I have given in the past few years.
They go further in various directions into the properties of complex analytic varieties than some recent texts on the subject (such as L. H$rmander, An Introduction to Complex Analysis in Several
ii.
Variables; or R. C. Gunning and H. Rossi, Analytic Functions of Several Complex Variables), and have a rather different point of view and emphasis than other texts (such as M. Herve, Several Complex Variables, Local Theory; R. Narasimhan, Introduction to the Theory of Analytic Spaces; or S. Abhyankar, Local Analytic Geometry) Of course, every author feels that his own organization of the material is in some ways superior to that currently available in the literature.
The first section is a survey of prerequisites from the general function theory of several complex variables.
The second
and third sections cover the local parametrization theorem for complex analytic subvarieties of the space of several complex variables,
and some of its immediate consequences.
The fourth section intro-
duces the notion of an analytic variety (also known as an analytic space) as an equivalence class of analytic subvarieties, abstracting those properties of analytic subvarieties that can be considered as being less dependent on the particular imbedding in the space of several complex variables; there seem to be definite didactical advantages to stressing this distinction between varieties and subvarieties.
The fifth and sixth sections cover those aspects of the
local parametrization theorem that remain meaningful for analytic varieties; the fifth section treats branched analytic coverings, which correspond to the projections of analytic subvarieties on coordinate hyperplanes, and the sixth section treats simple ana-
lytic mappings, which correspond to partial projections in the local parametrization theorem for complex analytic subvarieties. I should like to express my thanks here to the students who have attended the various courses on which these notes are based,
for all their helpful comments and suggestions, and to Elizabeth Epstein, for her customary beautiful job of typing.
A remark on the notation.
The usual mathematical notations are
used throughout, except that C is used to denote general set inclusion while C is used to denote proper inclusion (excluding equality).
There is no separate notation used to distinguish
equivalence classes from representatives of the equivalence classes,
in discussing varieties or germs of functions or sets; the additional notation is more burdensome and confusing than the systematic confusion of no notation.
iv.
CONTENTS
Page
§l. A background survey a. b.
§2.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
1
.
The local parametrization theorem for complex analytic .
.
8
Some applications of the local paranetrization theorem .
.
4G
a. b. c.
d.
a.
b. c.
d.
§4.
.
.
Some properties of analytic functions (1) Some properties of analytic sheaves (5)
subvarieties
§3.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
c.
d. e.
.
.
.
.
.
.
Elementary properties of analytic subvarities (8) Regular systems of coordinates for an ideal (12) Strictly regular systems of coordinates for a prime ideal: algebraic aspects (19) Strictly regular systems of coordinates for a prime ideal: geometric aspects (24)
Hilbert's zero theorem (4o) Coherence of the sheaf of ideals of an analytic subvariety (42) Criteria that a system of coordinates be regular for an ideal (48) Dimension of an analytic subvariety (52)
Analytic varieties and their local rings a. b.
.
.
.
.
.
.
.
.
.
.
62
Germs of analytic varieties (62) Analytic varieties and their structure sheaves (65) Some general properties of analytic varieties (69) Dimension of an analytic variety (So) Imbedding dimension of an analytic
variety (87) §5.
The local parametrization theorem for analytic varieties. . 97 a. b. c.
d.
Branched analytic coverings (97) Branch locus of a branched analytic covering (loo) Canonical equations for branched analytic coverings (112) Direct image of the structure sheaf under a branched analytic covering (117)
V.
Page §6.
Simple analytic mappings between complex analytic
varieties
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
a.
Simple analytic mappings (127) Relative and universal denominators (132) Direct image of the structure sheaf under a simple analytic mapping (138) Classification of simple analytic mappings (144) Normalization (154)
d. e.
Index of symbols .
.
.
.
b. c.
Index
.
.
.
.
.
.
.
.
. .
.
.
.
.
. .
. .
. .
.
. .
.
. .
. .
.
.
.
.
.
.
. .
.
.
.
.
.
.
.
. .
.
.
.
.
.
.
.
127
.
164 165
1.
§1.
A background survey
(a)
Some familiarity with the local properties of complex analytic
functions of several complex variables will be assumed from the beginning.
The reader acquainted with the material contained in Chapter I
(sections A through D) and Chapter II (sections A through D) of Gunning and Rossi, Analytic Functions of Several Complex Variables (Prentice-Hall, 1965), or in Chapter VI of HBrmander, An introduction to Complex Analysis in Several Variables (Van Nostrand, 1966), will certainly have an adequate background.
In order to establish nota-
tion, terminology, and references, a brief introductory review of this prerequisite material will be included here.
The ring of germs of holomorphic functions of variables at a point
no-a
is either understood or
This can be identified with the ring of convergent com-
plex power series
C[zl-all ...,zn-an)
the coordinate functions in e
.
, by viewing
The ring
n
a0
0 = (0,...,0) E C will also be denoted simply by when there is no danger of confusion. Points
complex
a = (all ...,an) c e will be denoted by
or by 9. for short when the dimension n irrelevant.
n
a e Cn
The rings
z1,...,zn
at the origin
n(9
n
as
O-a
or 6 , for various
are canonically isomorphic in the obvious manner.
Indeed, any nonsingular complex analytic homeomorphism from an open neighborhood of a point
Point b E Cn
a e
onto an open neighborhood of a
induces an isomorphism between the rings n&a
and
2.
the simplest such homeomorphism, which will be used for the n 0-b ; Thus for studying the
canonical isomorphism, is just translation.
local properties of analytic functions of several complex variables, it is generally sufficient to consider merely the ring
n
n
&0
An arbitrary complex analytic local homeomorphism preserving the origin can then be used for further simplification as needed. Recall that
n (Q is an integral domain; the product of two
non-zero elements of the ring n0
cannot be the zero element, the
germ of the function identically zero. quotient field
at the origin in
n92 (
,
.
n 0 has a well defined
Hence
the field of germs of meromorphic functions The ring
in the ring has a finite basis.
n 9 is also Noetherian; every ideal The units of the ring
elements of n0 having inverses in n0
Q
,
the
are precisely the germs
,
of functions which are not zero at the origin.
units form an ideal nVW in the ring n(L
n
,
Consequently the nonthe ideal of all germs
of functions which are zero at the origin; a Noetherian ring with this property is known as a local ring.
The ideal nVW of non-
units is clearly the unique maximal ideal of the ring residue class field
n
C of complex numbers.
n
(9
;
the
62 / VW is evidently isomorphic to the field Finally, the ring n ()
is a unique factori-
zation domain, an integral domain in which every non-unit can be written, uniquely up to the order of the factors and the units in the ring, as a finite product of irreducible elements; an irreducible element is one which cannot be written as a product of two non-units.
Two very useful tools in deriving these and other properties of the local rings
n
a are the Weierstrass preparation and division
Note that the ring n-1(-
theorems.
subring of
is canonically imbedded as the
n 8- consisting of germs of functions which are independent
of the last variable, corresponding to the imbedding 'zn-l'zn)
C(z1,
Between these two rings lies the ring n-10 [zn]
.
of polynomials in the variable n-1
m
CCz1,...,zn-1) C
zn with coefficients from the ring
The theorems of Weierstrass facilitate the natural induction .
step from n-1s
to
through the intermediate ring n-la [zn]
no
In more detail, an element
f e n0
if the germ f(0,...,0,zn)
is not identically zero, as the germ of
is said to be regular in
zn
a holomorphic function of the single complex variable
zn ; the
element
if the germ
f
is said to be regular in
f(O'...,0,zn)
has a zero of order
the complex variable
z
n
.
z
k
n
of order
k
at the origin in the plane of
Given any finite set of elements
there is a nonsingular linear change of coordinates in all of these elements regular in degree
k
in
zn
zn .
C'
f E i
n
6-
making
A Weierstrass polynomial of
is an element p E n-10 [zn]
of the form
k k-l p = zn + a z +...+ ak-1zn + ak 1 n
where the coefficients
a
i
e n-1Q
a Weierstrass polynomial of degree which is regular in
zn
of order
are non-units.
k k .
in
zn
It is evident that
is an-element of
(9
The Weierstrass preparation
theorem asserts that a Weierstrass polynomial of degree is the generic form of an element
n
k
in
f e n 0 which is regular in
z
n z
n
of order
k ,
of order
k
of degree
in the sense that whenever
f e n 61
there is a unique Weierstrass polynomial k
in
zn
such that
a Weierstrass polynomial of degree
q E
n
k
in
zn
a can be written uniquely in the form
n Ci
r e n-14 [zn]
and
p E
,
n
(3?
.
p E n-la[zn]
is
then any element
f = pq + r , where
is a polynomial in
than k ; moreover, if f c n-16L[zn]
zn
n-l a[zn]
f = up for some unit u e
The Weierstrass division theorem asserts that if
f E
is regular in
of degree less
zn
then necessarily q c n-lw [zr_] The Weierstrass theorems are not really limited in applica,
bility merely to the local rings; they can easily be extended to global situations, provided some care is taken with the domains of existence of the functions involved.
For any open set U C Cn
note the ring of functions holomorphic in
U .
a connected open neighborhood of the origin in be written as the product an open set
U = U' X U"
let
Suppose that U Cn
,
is
and that U
of an open set
U" C C , the complex plane of the variable
can
U' C CP-1 and zn
p E Q U
defines a Weierstrass polynomial in the local ring
then
has the form
p
de-
B--U
If
.
n
0
p = zn + aIzn 1 +...+ ak-lzn + ak
where the coefficients z' = (zl,...,zn-1) E U' has
ai e
Note that for each fixed point
the polynomial p(z,,...,zn-l,zn)
in
zn
k roots; assume that all of these roots are contained in the
open set
U"
.
Under these hypotheses, the extended Weierstrass
division theorem asserts that any function
f e 91 U
can be written
5 f = pq+ r , where
uniquely in the form is a polynomial in
zn
q e m U and
of degree less than k
.
r E (-U,[zn]
One rather immedi-
ate corollary of the extended Weierstrass division theorem is the following.
in C ,
Suppose that
and that
U
is an open neighborhood of the origin
fl,...,fk s 0 U
are functions whose germs at the
origin generate an ideal ,¢( C n&-0 ; then there is a subneighborhood
UO C U
of the origin in
Cn
such that any function
f e 61U
whose 0
germ at the origin is contained in the ideal SOt- can be written in
the form
f = glfl +...+ gkfk
for some functions
gi e au 0
(b)
The use of sheaves proves to be a very helpful notational
and organizational convenience in several complex variables.
This
is perhaps not really apparent at the outset, since notational complications are minimal and the interest is mostly in purely local phenomena.
Consequently, throughout most of the present lectures
sheaves will appear only incidentally as an alternative notation. Eventually, however, sheaves will be freely used; and some of the deeper semi-local properties of holomorphic functions, which are most conveniently stated in the language of sheaves, will play an important role.
The reader should thus have some familiarity with
analytic sheaves; an acquaintance with the material contained in
Chapter N (sections A through C) of Gunning and Rossi, Analytic
Ftntctf Several Complex Variables, or in section 7.1 of R rn nder, An Introduction to Complex Analysis in Several Variables, Will provide an adequate background.
Again a brief review of this
6.
material will be included here, primarily to establish notation. The sheaf of germs of holomorphic functions of variables will be denoted by
identification of the ring
U with the ring (-U point
n 0 , or merely by 9 when no confusion
For any open set
is likely to arise.
U C CC
of holomorphic functions in U ; and for any
there is a natural identification of the stalk
a E Cn
a
with the ring
is a sheaf of modules over the restriction
U C (
the sheaf of rings
n(Q
(n l9IU)r .
(n D IU) 6) ...E (n(9 IU)
An analytic sheaf I over
generated over
of germs of
n al'
of
U ; perhaps the simplest ex-
to the set
ample is the free analytic sheaf of rank
n19J U
n (Q a
n (¢a
An analytic sheaf over an open
holomorphic functions at that point.
sum
there is a natural
of sections of the sheaf a over
P(U, 6-)
of the sheaf 0 over the point
set
complex
n
U
over U , the direct
r
of r copies of the sheaf is said to be finitely
if there are finitely many sections of .1 over
U
U which generate the stalk
,a a
as an n Qua-module at each point
a e U , or equivalently, if there is an exact sequence of analytic sheaves of the form
(n 0IU)r> ) for some
r
.
;;,0
An important and often used semi-local property of
holomorphic functions of several complex variables is given by Oka`s theorem:
for any analytic sheaf homomorphism
over an open set
U C CP , the kernel of
q
cp:
(n Q IU)r .
(n
6 IU)s
is a finitely generated
analytic sheaf in an open neighborhood of each point of U .
An analytic sheaf sj over an open set be coherent if in some open neighborhood a e U
U
a
U C C is said to
C U
of each point
there is an exact sequence of analytic sheaves of the form
(nm IUa)r _ (no IU,)s -> (,f Iu,) for some
r, s
>0
It then follows from Oka's theorem that coherence
.
is preserved under many standard algebraic operations on sheaves;
for example, for any analytic sheaf homomorphism cp: (n9
IU)r
;;.
(n Q
IU)s
,
the kernel and image of the homomorphism
are coherent analytic sheaves, and for any exact sequence of analytic sheaves of the form
0
R- I
U -;;, 0,
if any two of the sheaves are coherent so is the third.
8.
The local parametrization theorem for analytic subvarieties
§2.
An analytic subvariety of an open set
(a)
U C CP
U which in some open neighborhood of each point of
U
is a subset of is the set of
common zeros of a finite number of functions defined and holomorphic in that neighborhood.
Note that an analytic subvariety of
necessarily a relatively closed subset of
U .
U
is
The subject of the
present lectures is the local nature of such analytic subvarieties
in the neighborhood of some fixed point of e , which for convenTo make this precise, con-
ience will be taken to be the origin. sider the set of pairs
hood of the origin in
Ua
.
Two such pairs
alent if there
(Va, Ua) , where
CP
and
(V1, Ul)
Va and
Ua
is an open neighbor-
is an analytic subvariety of (V2, U2)
s an open neighborhood
will be called equiv-
W C Ul if U2
of the origin
such that w fl Vl = W fl V2 ; it is readily seen that this is indeed
a proper equivalence relation.
An equivalence class of these pairs
is called the germ of an analytic subvariety at the origin in
L_n ;
and these equivalence classes are really the subject of the lectures. Any germ can be represented by an analytic subvariety
open neighborhood U
V of some
of the origin; but the only properties to be
considered here are those that are independent of the choice of representative subvariety of the germ.
In the notation and subse-
quent discussion there will be no systematic distinction between germs and representative varieties whenever there is no serious likelihood of confusion.
9 To each germ V of an analytic subvariety at the origin in C
there is canonically associated an ideal in the local ring
called the ideal of the subvariety id(V)
,
V
n o-O
at the origin and denoted by
defined as follows:
id(V) = (f c n(Q-0
l
an open set
there exist an analytic subvariety V of
analytic function such that
representing the germ V
U C G`n
and an
f a &U representing the germ f,
flV - 0 .)
It is clear that this is a well defined ideal in
other direction, to each ideal 4t c n0-0
n
SL 0
.
In the
there is canonically
associated a germ of an analytic subvariety at the origin in C called the locus of the ideal J )L and denoted by loc(i.) , defined as follows:
loc( (I(
) = germ represented by the analytic subvariety V - (z e UlfI(z) =...- fr(z) = 0) U C C' , where
fi e GL
U
U whose germs in n0 0
of the open set
are analytic functions in generate the ideal AZ.
.
It is clear that this is a well defined germ of an analytic subVariety at the origin in
da ; recall that any ideal
finitely generated, since the local ring nG-O
,DL C
no-0
is
is Noetherian.
These correspondences permit a very useful and interesting interplay to develop between the geometrical properties of germs of analytic subvarieties at the origin in perties of ideals in the local ring
Cu
n a0
and the algebraic pro-
10.
Several quite simple properties of these correspondences follow almost immediately from the preceding definitions; the proofs will be left as exercises for the reader.
If
of analytic subvarieties at the origin in
Gn
are ideals in the local ring n Q-0
,
V, V1, V2 ,
are germs
and lI., A1,
2
then:
(i) V1 C V2 =--> id V, J id V2 ;
l J locA2 ;
(ii) Ptl c ,0Z.2 =__> be (iii) V = loc id V ;
(iv) A C id loc,brL , but equality does not necessarily hold; V1 = V2 <==_> id V1 - id V2 .
(v)
and
V1 U V2
Note that
V1 fl V2
are also germs of analytic sub-
varieties at the origin in e , where the unions and intersections of germs are defined respectively as the germs of the unions and intersections of representative subvarieties.
V1 = loc '
l
and
V2 = be A2 , then
(vi) Vl fl V2
(vii) where
,(n
VI
Indeed, if
loc('&1 +A2)
U V2 - loc(, Z1 (2) = loch
fl 02)
1 + A2 is the ideal consisting of sums of elements from
the separate ideals, and
A2 is the ideal generated by pro-
,uc.l -
ducts of elements from the two ideals.
A germ V of an analytic subvariety at the origin in
LIP
is said to be reducible if it can be written V = V1 U V2 , where Vi C V are also germs of analytic subvarieties at the origin in Cn ; a germ which is not reducible is said to be irreducible.
It
11.
is easy to see that a germ V n &O
is a prime ideal in
.
is irreducible if and only if
id V
To a considerable extent the study of
germs of analytic subvarieties can be reduced to the study of irreducible germs, in view of the following observation. Any germ of an analytic subvariety at the origin
Theorem 1.
in e can be written uniquely as an irredundant union of finitely many irreducible germs of analytic subvarieties. Proof.
First suppose that there is a germ
V of an ana-
lytic subvariety which cannot be written as a finite union of irreducible germs.
Since
V
cannot itself then be irreducible, neces-
sarily V = V1 U V1 where
V1, Vi
eties and are properly contained in two germs, say
V1 ,
are germs of analytic subvariV ; and at least one of these
in turn cannot be written as a finite union of Repeating the argument, it follows that
irreducible germs.
V1 = V2 U V2 , where
V2, V2
and are properly contained in
are germs of analytic subvarieties V1 , and
a finite union of irreducible germs.
V2
cannot be written as
Proceeding in this way, there
results a strictly decreasing sequence of germs of analytic subVarieties
V J V1 I) V2 j) ... ; and consequently there also results
a strictly increasing sequence of ideals in the ring
nO 0
.
id V C id V1 C id V2 C .
This is impossible, since the ring
nO
O
is
Noetherian; and therefore every germ of an analytic subvariety can be written as a finite union of irreducible germs.
Suppose next
that a germ V of an analytic subvariety is written as a finite union of irreducible germs in two ways, say V = V1 U ... U V V' U ... U V1 1
.
It can of course be assumed that these are
=
12.
irredundant representations, in the sense that none of the germs can be omitted in these representations, or equivalently,
Vi, Vi that
V.
U
Vi
..
V'. Z U
and
V.
J
3/i
1
1
V'
Note that for any index i,
- Vi n v - (Vi n v1,) U...U (Vi n Vs) ; but since
ible, necessarily Vi - Vi n Vi(i) index
f(i)
.
and hence
for some index
g(i)
.
Thus
V.
Vi C Vi(i)
Similarly of course, for any index
Vi C Vg(i)
that and
.
J
for some
it follows
i
Vi
is irreduc-
Vi(i) C Vg(f(i))
Vg(i) c Vf(g(i)) ; since the two representations are irre-
Vi
c
dundant, it follows that
g(f(i )) = f(g(i)) = i
and
Vi = Vg(.)
The two representations thus merely differ in the order in which the terms are written, and the proof is thereby concluded.
When a germ V of an analytic subvariety at the origin in Cm
is written as an irredundant finite union of irreducible germs
V = V1 U...U Vr , these germs
V.
are called the irreducible com-
ponents or irreducible branches of the germ V
Considering only germs of analytic subvarieties at the origin
(b)
in
Cm
is of course merely a notational convenience; it is quite
evident that a simple translation extends the preceding results to any other point of
Cm
.
Actually of course all of the preceding
observations are clearly preserved under any complex analytic homeomorphism from an open neighborhood of the origin to an open neigh-
borhood of any other point in e , and in particular, under any complex analytic homeomorphism between two open neighborhoods of the origin in
Cm
.
The intrinsic properties of a germ of an
13
analytic subvariety at the origin in
are independent of the
Cn
choice of coordinates at the origin in
.
However it is often useful to choose coordinates at the Ln
origin in
which are conveniently positioned for studying a
particular germ of an analytic subvariety.
A set of coordinates
at the origin in e is said to be a regular system of
zl,...,zn
coordinates for an ideal A C na if for some integer
(i) k0 fl (ii)
j-1 in
The integer
k
=o;
dL
a [z.] zj
0 < k < n
n AZ contains a Weierstrass polynomial j = k+l,...,n .
for
is called the dimension of the ideal J?. with
respect to this system of coordinates.
Note that the imbedding
0 c n& depends on the coordinate system, viewing an element f E
.
as an element of
n(9
depending only on the first
j
coordinates.
For any ideal AC
Theorem 2.
system of coordinates at the origin in Proof.
at the origin in
CP
.
is a regular system of coordinates for A ,
with respect to which )OZ has dimension any nontrivial element
0 there is a regular
it is clear that any set of coordinates
If A(.- 0 CP
n
f
n
E41
.
n .
If A # 0 , select
After making a linear change of
coordinates at the origin in C if necessary, the function can be assumed to be regular in
fn
zn ; then from the Weierstrass
preparation theorem it follows that
fn =
un E n
14.
is a unit and
U
V. 1
and
V,
J/i
U
V!
ible, necessarily
that and
f(i)
.
- Vi fl Vf(i)
J
; but since
11 Vs)
and hence
for some index
g(i)
.
V.
V. C V.(i)
Similarly of course, for any index
Vg(i)
V!
V.
Note that for any index i,
V!
3/1
1
1
Vi == Vi fl V - (Vi fl v1-) U...U (v.1
index
z
can be omitted in these representations, or equivalently,
Vi, V!
that
is a Weierstrass polynomial in
[z ]
E
g
Thus
i
is irreducfor some
it follows
V. C Vf(.) C Vg(f(i))
c
V! C Vg(i) C VT(g(i)) ; since the two representations are irre-
dundant, it follows that
g(f(i )) = f(g(i)) = i
and
V! = Vg(i)
The two representations thus merely differ in the order in which the terms are written, and the proof is thereby concluded.
When a germ V of an analytic subvariety at the origin in is written as an irredundant finite union of irreducible germs V = V1 U...U Vz , these germs
V.
are called the irreducible com-
ponents or irreducible branches of the germ V .
(b)
Considering only germs of analytic subvarieties at the origin
in e is of course merely a notational convenience; it is quite evident that a simple translation extends the preceding results to any other point of
C'
.
Actually of course all of the preceding
observations are clearly preserved under any complex analytic homeomorphism from an open neighborhood of the origin to an open neigh-
borhood of any other point in e , and in particular, under any complex analytic homeomorphism between two open neighborhoods of
the origin in ( .
The intrinsic properties of a germ of an
15.
rrrko nnnAi+i nn +.ha+. P apt of nnnrdinntes.
z ..... z
he a
choice of coordinates at the origin in d . However it is often useful to choose coordinates at the
origin in e which are conveniently positioned for studying a particular germ of an analytic subvariety.
A set of coordinates
at the origin in e is said to be a regular system of
z1,...,zn
coordinates for an ideal A C (i)
(ii)
0 < k < n
k0 n ,lL = o j_1& [zj] n,OZ in
The integer
if for some integer
n(9-
k
j = k+l,...,n .
for
zj
contains a Weierstrass polynomial
is called the dimension of the ideal j?. with
respect to this system of coordinates.
Note that the imbedding
(t} c n & depends on the coordinate system, viewing an element
f E JQ
as an element of
depending only on the first
n(Q
J
coordinates.
Theorem 2.
For any ideal A(-- n6
system of coordinates at the origin in C Proof.
at the origin in
If
- 0
Cn
.
it is clear that any set of coordinates
is a regular system of coordinates for N c
with respect to which any nontrivial element
there is a regular
has dimension f
n
E,&
coordinates at the origin in
.
If ,OZ # 0 ,
select
After making a linear change of
.
if necessary, the function
Cp
can be assumed to be regular in
n
,
z
n
preparation theorem it follows that
fn
; then from the Weierstrass fn =
un E
n
a
16.
k
0 fl A = 0 , it is clear that
k
9 = kS
Altogether, apply-
.
ing the theorem of transitivity of integral extensions, is an integral algebraic extension of the
[zk+1,...,znI
k
n
subring
=
k
generated by the
k
Conversely, if the residue class ring
n
n-k
S
=
elements LV/,Q'(
has this form,
it follows readily that the coordinate system is regular for the
ideal JXL and that & has dimension
For since
of coordinates.
k
k
with respect to this system
necessarily k (9 n o = 0
k
is integral over k 0 = km
Further, since zj
for any value
j = k+l,...,n , there must exist a monic polynomial
such that p(z.) - 0
in
J
p j (z
f k( Q (z
i
n
,
or equivalently such that
fl ,(? c j-10 [ zj ] (I,&
]
pj(X) E kS [X]
Any such polynomial of
.
the smallest degree must necessarily be a Weierstrass polynomial; for otherwise
would be regular in
p.(zj)
of order less than
zj
its degree, and an application of the Weierstrass preparation theorem in the local ring
would yield a Weierstrass poly-
C(zl,...,zk,zj}
nomial of still smaller degree in If the coordinates
m [z
z1, ...,zn
coordinates for an ideal A C n(0
ideal 9 has dimension
k
k ,
]
.
.
form a regular system of
, with respect to which the
it follows as in the preceding para-
graph that there are Weierstrass polynomials k+l,...,n
l i ft ?
j
Pi E k 0 [z.]fli for
Choosing such polynomials of the smallest degree,
the resulting set of
n-k
germs will be called a first set of
canonical equations for the ideal A with respect to the given coordinate system.
Condition (ii) in the definition of a regular
17.
system of coordinates for an ideal can be replaced by the existence of a first set of canonical equations for the ideal with respect to the given coordinate system, often an easier condition to use.
Now to consider the geometrical significance of a set of coordinates
ideal ,OT C 0 ',pn
pk+l'
being a regular system of coordinates for an
z1,...,zn ,
select a first set of canonical equations
for the ideal with respect to the given coordinate
Choose an open neighborhood
system.
U'
that the coefficients of these polynomials out
U'
;
the functions
in the open subset
pj
are analytic through-
can then be viewed as analytic functions
pj
U' X
of the origin in d such
e -k
C C' , and these functions define an
analytic subvariety W = (z E U' X C2-kIpk+1(z) in that open set.
Since
r._
pn(z) = 0)
it is evident that any analytic
E ,{
subvariety representing the germ
subvariety W
...
local[ must be contained in the
in some open neighborhood of the origin, or equiva-
lently, as germs
loc A C W
.
The subvariety W
has a very simple
description, and this makes it possible to say some things about the germ
loc.OL
.
Theorem 3.
If
z1,...,zn
dinates for an ideal A C n Q
form a regular system of coor-
, with respect to which the ideal
has dimension
k , then there are arbitrarily small open product
neighborhoods
U = U' X U" c ek X Cn-k = C
ting analytic subvarieties
such that the mapping Mapping
U' X U" ---> U'
V C U
rr: V --> U'
of the origin admit-
representing the germ
!cc
induced by the natural projection
is a proper light, continuous mapping.
,a. (Recall that the mapping
7r
is said to be proper if
compact subset of V whenever light if
7r
germ
Consider any open neighborhood
loc .L
;
and assume that
WO
,
z'
and e U'
of the origin
U0
pk+l'..''pn
are analytic through-
V0 C WO where
and that
UO , -
U'
is sufficiently small that the
U0
first set of canonical equations out
is a compact subset of
K
is a
admitting an analytic subvariety VO C U0 representing the
CP
in
1(K)
is a discrete set of points for any point
1(z')
Proof.
7r
(z e UOlpk+l(z) _ ... = pn(z) = 0)
any product subncighborhood, then since strass polynomial in
zj
If U - U' X U" C U0
.
U1[z.)
p. c
is
is a Weier-
at the origin, the leading coefficient is
identically 1 while the remaining coefficients are analytic functions of
which vanish at the origin; these other coeffi-
a U'
z'
cients can than be made arbitrarily small by choosing enough.
In part_cular, choose
small
U'
sufficiently small that
U'
W C U' X U" , where
W
(z
( z ,zk+l,...,zn)Iz' e U '
and note that
= 0 for
V
1oc R in the neighborhood U. is a compact subset of
compact subset of
U'
;
n-k
of W and (K X c is proper.
)
v0 n u C WO n u- w, where
V
tive of the germ (K X e-k) fl W
, p . ( z ' , z .
)
and since
V
j = k+1,...,n);
is a representa-
It is clear that
whenever
U' X U"
K
is a
is a relatively closed subset
fl V = 7r1(K) , it follows that the mapping 7r
It is also clear that the mapping
tinuous, hence the theorem is proved.
7r
is light and con-
19.
It should be noted that the preceding proof really only used
pi s OD [zj]
the existence of the Weierstrass polynomials
fl AZ. for
j = k+l,...,n ; but since pj E kQ [z.] n,OZ [ (Q [zj] n,& for j = 1+l,...,n whenever k
replaced by
i
the same conclusion holds with
k < .e < n ,
Therefore the following is an immediate conse-
.
quence of the same reasoning. Corollary to Theorem 3. for any integer
P.
k < I < n , there are arbitrarily small open
,
product neighborhoods
U - U' X U" c
admitting analytic subvarieties such that the mapping mapping
(c)
Under the hypotheses of Theorem 3,
7T:
U' X U" > U'
d X
V C U
V -> U'
1
of the origin
= en
representing the germ locR ,
induced by the natural projection
is a proper, light, continuous mapping.
Turning next to the special case that the ideal A C n
a
is a prime ideal, a good deal more can be said both algebraically and geometrically.
In order to keep firmly in mind the restriction
that the ideal be prime, it will be denoted by 1/
throughout this
discussion.
Beginning with the algebraic considerations, for a prime
ideal
C
the residue class ring
n
gral domain, hence has a quotient field coordinates
zl,...,zn
ti
n0=
is an inte-
n
Since, when the
n
are a regular system of coordinates for the
ideal q with respect to which that ideal has dimension
was shown that
n
(jl
k
tV [z
k+1
k , it
,...,z ] , where the elements n
ti
n are algebraic over the ring
k
(j?
=
k
(V
,
then
20.
yti
necessarily the quotient field has the form ti
where
k
(Q
is algebraic over the field
Each element zj
-k
k[zk+l,...,zn1,
is the quotient field of the integral domain
=
k
ti
ti
k
9)1
hence is the root of an irreducible polynomial over the field
if the leading coefficient of this polynomial is taken to be 1 the polynomial is uniquely determined, and will be called the defining Now since the elements
equation for the element
zj
are
ti
actually integral over the ring
° k&
k
of the defining equation are elements of
L
ti
k
,
km
hence are elements of
,
k'1'
all the coefficients k2'7
N k
integral over
since k 67
kQl
is a
unique factorization domain so is integrally closed in its quotient (See van der Waerden, §101.)
field.
a monic polynomial
pj(zj) - 0
,
pj(X) E k 0 [X]
The defining equation is thus of minimal degree such that
p.(zj) s k & [zj] f k
or equivalently, such that
Consequently the defining equations of the elements
k+l,...,zn
are just the first set of canonical equations for the ideal 4 with respect to the given coordinate system; and from this observation
it is apparent that for a prime ideal 4 the first set of canonical equations is uniquely determined by the choice of the coordinate system.
It follows from the theorem of the primitive element that there are complex constants c +l`,+l +...- C Z
elemen ryy,
k+l' ...
such that the single
ck+l,...,cn
generates the entire field extension
, znJ over k
ti ti k
(See van der Waerdea,
n
k
§40.)
By making a suitable linear change of coordinates in the space
21.
-k
of the variables
zk+l'
.. 'Yzn ,
it can clearly be assumed that
itself generates the entire field extension.
zk+l
It is obvious
from the algebraic interpretation that the new coordinates will still regular system of coordinates for the ideal A/ C
be a
n
Ql
regular system of coordinates for a prime ideal Y C n (Q li,
additional property that nm
show that any prime ideal Al C n6'
member
The preceding remarks
has a strictly regular system of
ti
over
k lqq [zk+l]
n''L
with the
For any such system of coordinates, the field extension
ti
ti
a
will be called a strictly
=
regular system of coordinates for that ideal.
coordinates.
;
pk+l
is fully described by the single
(
k
of the first set of canonical equations for the ideal
and the ring extension n
k
3 [ k+l' ' ' '' zn ] is almost
fully described by that single canonical equation as well. this, recall that the discriminant
is the degree of the polynomial =
of the polynomial
is an element of the ring
pk+l E k & [`k+1]
the ring no
d
k
C9 [z
k+= '
pk+l e
'z n]
linear combination of the elements
To see
k (
,
and that if
any element of k 0 [zk+l] ,
can be written uniquely as a l/d,
zk+1r_l
with
ti
coefficients from the ring
k
CSt
.
(See van der Waerden, §101.
This is not really a fill description of the ring ti
n
ti
ti ti k
[zk+1'
ti " ',zn]
, since not all linear combinations of
these elements necessarily lie in the ring
f c n0
fi(x) E k 0 [X]
of degree strictly less than .
.)
n
for any element
gf(zk+1) e q-
r
Equivalently,
there is a unique polynomial r
such that
In particular, to each coordinate function
22.
zj
k+2 < j < n
for
gzj(X) e
k
61 [X]
there corresponds a pnique polynomial
of degree strictly less than
r
such that
qj = d-zj - qz (zk+l) e kS [zk+l'zj] n L
'
j
the
n-k-1 polynomials
qk+2,...,qn will be called the second set
of canonical equations for the ideal )V with respect to the given coordinate system.
These canonical equations are also uniquely
determined by the choice of the coordinate system; unlike the first set of canonical equations, the second set are only determined for
a strictly regular system of coordinates for a prime ideal 4 C n6L0 The two sets of canonical equations together generate an ideal
£ C nQ to
called the canonical ideal for the ideal JLP with respect
he given coordinate system; and the canonical equations
pk+l'qk+2, " .,qr
generate an ideal GI C n (.
called the restricted
canonical ideal for the ideal ,( with respect to the given coordinate system.
It is obvious that
1
C C C j
;
and although these
may be strict containments, the following result shows that these various ideals cannot really differ by very much. Theorem 4.
If
zl,...,zn
form a strictly regular system
of coordinates for a prime ideal A? C n(V the ideal has dimension
k , and if 4:
, with respect to which
and )C7,
are the canonical
and restricted canonical ideals for the ideal 4- with respect to these coordinates, then for some integers
da 4J c .c c
and
a,b,
db L C 'Cl
r,
23.
d e k0
where
pk+l
is the discriminant of the canonical equation
e k0 [zk+l] fl q . Since the canonical equations p. E k JT [z1 ]
Proof.
are Weierstrass polynomials of degrees
, repeated application of
rj
the Weierstrass division theorem shows that any element can be written as a polynomial in strictly less than
f E n (Q
k m [zk+l,...,znI , of degree
in the variable
r,
zj
, modulo the ideal
generated by the first set of canonical equations; for written as a multiple of
plus a polynomial in
pn
can then be written as a multiple of
rn-1 ,
and so on.
is equal to a polynomial in
positive integer
i
and any index
for large enough
a
the element
k & [zk+l]
dividing by
pk+l
qj
for any
,
k+2 < j < n , it follows that
can be written as a poly-
modulo the canonical ideal C'
and after
;
again, this final polynomial can be taken to
have degree strictly less than
rk+l
.
That is to say, if
sufficiently large, then for any element
f a
n(
of degree strictly less than
such that
If
da-f - pz ESC
.
f E L
it follows that
Well, since 4 C Al ; but then necessarily pf = 0 , is the degree of the polynomial of least degree in e C"
.
This shows that
a
C e
a
is
there exists a
Polynomial pf E k 0 [zk+1]
80 that
Since
k (Q [zk+l]
modulo a multiple of the second canonical equation
nomial in
of
n-l (9 [zn]
plus a polynomial in
pn-1
of degree strictly less than
the expression
can be
f
rn , each coefficient in this polynomial
degree strictly less than
n-2 (Q [zn-1]
fl
rk+l
pf
since
as
rk+l
k (2 [zk+l] fl( .
Now if in the
24.
preceding argument the element of the polynomial ring
is from the beginning an element
f
the initial application k 6 [zk+l,...,zn] ,
of the Weierstrass division theorem is not needed; that is to say, for any element
there exist an integer
f e k(Y
and a polynomial pf E k(9 [zk+l] pf E
such that
rk+l
of degree strictly less than As before then, whenever
.
1
[zk+l,...,znI n lo., there is an integer
f E k (
b
b
such that
Applying this in particular to the canonical equations
E
pk+2' ..',pn ,
it follows that
d
b
and the proof is
thereby concluded.
As a matter of minor interest, it might be noted that in n E (r-1) and the preceding proof one can take a = i=k+2
b _ max (rk+2'
... '
1
,-n
The geometric significance of a set of coordinates
(d)
zl,...)zn
being a strictly regular system of coordinates for a
prime ideal Y C no follows now from a comparison of the germ loc 9 with the germs
loc Z and
defined by the canonical
loc
equations for the ideal with respect to the given coordinate system.
Suppose that the ideal IV has dimension
coordinate system.
Let
-p
k+!'
...,pn
and
k with respect to this
qk+2, ..., qn be the
first and second sets of canonical equations for the ideal and d E k 01
germs
be the discriminant of the polynomial
pk+l ; and select
f1,...,fr c n a which generate the ideal.
Let
U
be an
open neighborhood of the origin sufficiently small that all of these
25.
germs are represented by analytic functions in
U ;
it is convenient
to take this neighborhood in the form of a product domain
U = U' x U" x Ufu c
ck x e
-k-l
X
=
L1
.
The subset
V = (z c Ulf1(z) _...= fr(z) = 0)
is then an analytic subvariety of the open set loc
the germ
U which represents
Since the canonical equations are actually poly-
.
/
nomials in the last
n-k
functions in all of
U' X
coordinates, they are actually analytic i1-k ;
the subsets
W ° (z e U' X 1-klpk+].(z)
pn(z) = qk+2(z) _...= qn(z)= 0)
and
W1 = (z e U' X &-klpk+l(z)
qk+2(z) =...= qn(z)-0)
are then analytic subvaricties of the open set represent the germs
locZ- and
lee t-
l
Li1-K
U' X
which Since the
respectively.
first canonical equations are all Weierstrass polynomials, it follows as in the proof of Theorem 3 that small that
U'
can be chosen sufficiently
W C U ; the conclusions of tha':. ;theorem then hold for
the subvariety W
,
so that the mapping from W
tc
induced by
U'
the natural projection is a proper, light, continuous mapping. Finally the discrin4nant
only depends on the first
d
so defines an analytic subvariety D = (z' e U'Id(z') = 0)
Of the open subset
U' C
-
,
variables,
26.
The relations between the ideal ,l
given in Theorem 4 can be expressed
and k'1
canonical ideals k'
and its associated
in terms of the chosen generators for these various ideals as follows.
hlj, h!., al j, alj, bi, bij
There exist germs
1
in n0
such that r
pi -
E j-1
hijfj
(i = k+l,...,n)
,
r
E
q.
1
daf.1
j =1
(i - k+2,...,n)
h".f. 10 j
n
n =
E
j=k+l
a! .1.). +
1j i
E
j=k+2
a'l'q. 1j
(i = 1,...,r)
,
n
dbpi = bipk+l +
E bijgj j k+2
Suppose that the neighborhood U
,
(i = k+2,...,n)
is also chosen sufficiently small
that these additional germs are represented by analytic functions in U ,
and the preceding relations hold throughout
U
It is then
.
immediately evident that V C W C Wl ;
and indeed that
Vfl((U'-D)XU"XU'") - (Wn((U'-D)XU"XU"') =W1fl((U'-D) XU" XU"') or equivalently, that these three subvarieties coincide outside of
the closed subset D X U" X U"' C U' X U" X 'j") =U Theorem 5.
Let
z.,...,zn
form a strictly regular system
of coordinates for the prime ideal (Q C n m the ideal has dimension
.
, with respect to which
k ; and consider the first canonical equatico
27.
[zk+l] n 4 , a Weierstrass polynomial with discriminant
pk+l c k d 6 k 6
.
There exist arbitrarily small connected open product
U = U' X U" X UC e X
neighborhoods
origin, and analytic subvarieties
loc 4
,
and
C1
of the
k 1 - Cn
X fC
V C U , representing the germ
((z',z") e U' X U"lpk+l(z',z,,) = 0) Cu' X U"
V0
with the following properties: (i)
U' X U" X U'" -> U' X U"
The natural projection mapping
induces a proper, light, continuous mapping 7T: V - V0
with image
all of V0 ; and Lhe natural projection mapping U' X U" -> U' turn induces a proper, light, continuous mapping image all of (ii)
U'
7T0: VO -4 U' with
.
Introducing the analytic subvarieties
D = (z' e U' I d (z ') = 0), the restriction restriction
in
r, = v n (D X U" X U"'),
71V-B: V-B --> V0-B0
B0=V
0
n( D X U")
is a homeomorphism, and the
7TOIV0-B0: VO-B0 - U'-D
is a finite-sheeted covering
projection.
Remarks.
For the definitions and properties of covering
spaces see for instance E. H. Spanier, Algebraic Topology (McGrawKill, 1966).
The subvarieties
B C V
and
B0 C V0
along which
the projections may fail to be covering mappings will be called the
a'itical loci of the subvarieties
V
and
respect to the given coordinate system. itt this
VO
respectively, with
The configuration described
theorem can perhaps most easily be kept in mind by referring
to the following diagram:
,
28.
CV CU'XU"XU"' Cdxc xi-k-l= Cp
V-B
117r
(homeomorphism)
CVO CU' X U"
VO - BO
(finite covering) J,7T0!V-B0
I'S'O
C
X
+
_
1( projection)
Cu' Cu'
U' - D
Cc
There are arbitrarily small connected open product
Proof.
neighborhoods
(projection)
in which the constructions describe;;
U = U' X U" X U"'
in the paragraphs preceding the statement of the theorem can be carried out; and the desired results then follow directly from the
and Wl
obvious properties of the subvarieties W lows from Theorem 3 that the mappings
7r
and
.
It first fol-
are proper, light, 'WO
and continuous; for this, it is only necessary that the neighborhood U'
be chosen sufficiently small that W C U
canonical equation
pk+l
Conversely, for any point
Next, since the first
is one of the equations describing the
V , it is clear that
subvariety
.
for any point
7r(z) E V0
(z',z") E V0-B0
,
since
z e V
d(z') / 0
it is
clear from the form of the second canonical equations that the relations
qk+2(:;',z",zk+2) =...= gn(z',z",zn) - 0
coordinates
z"'- (zk+2,...,zn)
z = (z',z",z7") c W1 7r(z) = (z',z")
;
variety
7r
V-B
7rJV-B: V-B - V0 - B0
for which is therefore
V-B
onto
V0-B0 , hence a homeomorphism.
is proper, the image
7r(V)
is evidently the full sub-
a one-to-one mapping from Since
of the unique point
IT ((U'-D) X c1 X C
the mapping
determine the
V0
.
Finally note that the subvariety
V0 C U' X U"
can
29.
VO = ((z',z") E U' X Clpk+l(z,z") = 0)
be defined as fixed point has
r
a'
E U'-D , the polynomial equation
distinct roots
;
so for each
pk+l(a',z") = 0
all lying in
U" , where
is the degree of the Weierstrass polynomial pk+1 .
r
Applying the
Weierstrass preparation theorem (or equivalently the implicit function theorem) to the germs defined by the function local rings hood
k+l6'(a',z"
(i)
gl(z'),...,gr(z')
+]_IZ'
there are
a'
such that
gi(a') = z(ti)
analytic functions
r
and that
is the union of the
VO n (Ua, x U") = 7rr1(Ua,)
((ZZ") E
E U',, z" = g (Z'))
r
disjoint sets
for
i
a
Each of these sets is clearly mapped homeomorphically onto under the natural projection from
the restriction
7T0J
V0-B0: V0 - B0
7ro
is all of
U' X U"
to
U'
;
U`, a
and consequently
-> U' -D is an r-sheeted covering
Since it is again clear that the
projection in the usual sense. image of
in the
), it follows that in some open neighbor-
of the point
Ua, C U'
pk+l
, the proof is thereby concluded.
U'
There are several remarks about the preceding theorem and its proof which perhaps should be made here. that
B0
First, it is clear
is really the branch locus of the mapping
in the customary sense.
For since
Weierstrass polynomial equation lii the discr iminant locus
the polynomial in
z"
D
is defined by the single
V0
pk+l(z',z") = 0 , the Doints
z'
are precisely the points for which
has fewer than
following result is immediate.
7T0: V0 -> U'
r
distinct roots.
Thus the
30.
With the hypotheses and notation
Corollary 1 to Theorem 5.
of Theorem 5, the set
is the point set closure in
V0
the r-sheeted covering space z'
e U'-D
over
V0-B0
U' X U"
U'-D ; and as a point
approaches a point of the discriminant locus
of the points
D ,
in the covering space lying over
(7101(z'))
of
some z'
approach coincidence.
Actually, since all of the points point
z'
(7TO (z'))
approach the origin in
approaches the origin in
note that the composition
V0-B0
.
U'
.
However in this case the set
may approach coincidence as
in the topological
not approach coincidence, and
lying over a point
approaches a point of
z'
D , the points of
the discriminant locus
as an
is not necessarily
B
sense; for although some of the points of V0 e U'-D
V-B
homeomorphic to the covering
U'-D
the br. ench locus: cf the mapping 7 07T: V -> U'
z'
as the
U
Now in addition to this,
clearly exhibits
7T07T
r-sheeted covering space of space
is a Weierstrass polynomial,
pk+l(z',z")
V
lying over
z'
need
V may remain an r-sheeted covering The proof that
V
space over some of the points of
D
point set closure of
is somewhat more involved, and
V-B
in
U
.
Again note that all of the
will be taken up separately shortly.
approach the origin in U" X U"'
points of
(7f
point
approaches the origin in
z'
is the
U'
as the
.
Second, it was noted in the proof that in some open sueneighborhood
U'1 C U'-D
of any point
a'
there are
e U'-D
complex analytic functions which parametrize the
r
r
sheets of the
31.
covering space
7T1 0 (Ua,)
over
U3,
;
these
joint complex analytic subvarieties of equations
z" - gi(z') = 0
r
sheets are the dis-
Ue, X U"
defined by the
for the various values
i = 1,...,r
Actually it is clear that these sheets are k-dimensional complex analytic submanifolds of
Ua, X U" ; for introducing new complex
analytic coordinates in some open neighborhood of any point of Ua, X U"
defined by
w,
- zl,...,wk = zk, wk+l
Lk+l - gi(zl,...)zk
the subvariety is locally just the coordinate hyperplane
wk+1 = 0
(Assuming that the reader is familiar with the notions of differentiable manifolds and submanifolds, it suffices to remark that complex analytic manifolds and submanifolds are the obvious analogues; the only point of possible difficulty which must be kept
in mind is that a k-dimensional complex analytic manifold or sabmanifold is a 2k-dimensional topological manifold or sifomanifold.)
Furthermore, since the second canonical equations exhibit the last n-k-1
coordinates of a point
of the first the
r
k.+1
coordinates
z e V-B
as complex analytic functions
(z',z") c V0-B0
it is evident that
,
sheets of the covering space v 17r0(Ua,)
k-dimensional complex analytic submanifolds of
are likewise
U', X U" X U" a
metrized by some complex analytic maps
para-
G.: Ua, -> Ua, X U" X U"`
Thus there results the following assertion. Corollary 2 to Theorem 5. of Theorem 5, told of
V0-B0
(U'-D) X U"
8ubmanifold of
With the hypotheses and notation
is a k-dimensional complex analytic submaniand
V-B
is a k-dimensional complex analytic
(U'-D) X U" X U"'
.
32.
Finally, there is no loss of generality in assuming that the U
open set
where
is actually a complete product domain U = U1 X...X Un, is an open neighborhood of the origin in the plane of the
U.
complex variable
U' = Ul X...X Uk ,
zi ; thus
U"'- Uk+2 X...X Un
For any index
.
U" = Uk+l , and
1 < I < n
the natural projection
U1 X... X Un - Ul X... X U.9 induces a mapping
by restriction; thus in the previous notation,
7r2:
V - Ul X... X UI
7r = Irk+l
and 7r07r
-
Irk
As was already noted after the proof of Theorem 3, for any index k < I < n
the mapping
from V into
is a proper, light, continuous mapping
7r,
U1 X...X Ule
.
It is indeed clear that the following
also holds, as an immediate consequence of the parametrization noted in deriving Corollary 2.
Corollary 3 to Theorem 5.
of Theorem 5 the domain U any index
k+1 < .£ < n
from V-B
onto its image
7ri(V-B)
If in addition to the hypotheses
is a complete product domain, then for
the restriction 7r2(V-B)
in U1 x...x U2 ; and this image
is a complex analytic submanifold of
(U'-D) X Uk+1 X...X iix
U'-D under the natural
which is an r-sheeted covering space over
projection
is a homeomorphism
7r1IV-B
(U'-D) X Uk+l X...X U, - U'-D .
There still remains the critical locus in more detail.
to be considered
The canonical equations do not suffice to describe
this subvariety fully, since W n (D X U" X U"')
B
.
B
can be a proper subset of
However for many purposes a sufficiently com-
plete description of the critical locus continuation of the preceding results.
B
is given by the following.
33
Theorem 5.
(continued)
Suppose that
V
is an irreducible
germ of a proper analytic subvariety at the origin in
U. = id V C n Q
consider the prime ideal
C
n ,
and
Then with the same
notation as in the first part of the theorem it further follows that: (iii)
The subvariety V
is the point set closure of V-B
in U U.
Proof.
Denoting the point set closure of V-B
it is clear that merely to show that for then since
V-B C V .
and
Now to each analytic function
z' F U'-D
there are
f E B U
associate a polynomial.
For any point z' under
T0T: V-B -> U'-D ; label these points
in some order, recalling from the discussion of
analytic functions of .
is an irreducible germ at
distinct points of V lying over
r
Corollary 2 that the mappings
Of U'-D
V
in the following manner.
the covering projection GI(z'),...,Gr(z')
To prove the theorem it suffices
in some neighborhood of the origin.
the origin, necessarily V = V-B
U,(X1
U by
is itself an analytic subvariety of U
V-B
V - B U (V-B)
Pf = pf(z';X) E
in
z'
G i.(z')
can be chosen to be complex
in some open neighborhood of any point
The exaression n
pf(z';X) =
ii
(X -f(G.(z')))
i=1
is a polynomial of degree
r
in the variable X , with the elemen-
tart' symmetric functions of the values
f(Gi(z')), i - 1,...,r , as
coefficients; so it is evident that these coefficients are well defined complex analytic functions in all of
U'-D
.
For any compact
34.
subset K C U' , the inverse image 7r of
U
since both mappings
the values
f(Gi(z'))
7r
and
is a compact subset
are proper; consequently
7r0
are uniformly bounded in K fl (U'-D) , as
are the elementary symmetric functions of these values.
It follows
from the generalized Riemann removable singularities theorem that the coefficients of the polynomial in all of
U'
so that
,
pf
pf E 6 U,[X]
extend to analytic functions .
This polynomial has the
properties that its degree is the number of sheets in the covering
projection
7r07r: V-B -> U'-D , and that for each point
the roots of the polynomial equation pf(z';X) = 0 the
r
values
function
X = f(G.(z'))
pf(z';f(z))
vanishes on
V-B
V
i = 1,...,r
for
z'
c U`-D
are precisely The composite
.
is then an analytic function in 6 U which
and hence on V-B
Introduce the subset
.
= (z e Ulpf(z';f(z)) = 0
This is an analytic subvariety of
U ;
for all
f s 0 U]
for it follows from the
corollary to the extended Weierstrass division theorem noted in §1(a) that a finite number of the functions define the subset
V
pf(z';-f(z))
serve to
in some open neighborhood of any point of U.
V D V-B ; and the proof will be concluded by
It is clear that -x-
showing that
for which
V C V-B .
a / V-B
.
Consider any point
,
a'
under the light proper mapping
and all are distinct from the point
analytic function
e U
There are only finitely many points
e V-B C V lying over 7r0I: V --- U`
a =
f e (V U
such that
f(a) # f(b1)
a
.
for
Choose an k
35.
and consider further the polynomial then necessarily Gi(a')
s - r
pf(a';f(a)) jL 0 , so that a'
values
r
V
a
a U'-D
the polynomial equation
a' X D
are just the points
a' E D then select a
If
.
X = f(bk) ; hence
converging to
pf(aj;X) = 0
a'
The roots of
.
are just the
values
r
and these approach the roots of the polynomial equation
f(Gi(a!))
pf(a';X) = 0
as a approaches
polynomial equation values
If
.
The roots of the polynomial equation
are precisely the
sequence of points
bk
and the points
in some order.
pf(a';X) = 0
pf(z';X) a (QU,[XJ
pf(a';X) = 0 approaching
f(Gij(a!))
a'
Xi
;
so for any root X
of the
there will be some sequence of .
Since the mapping
TrCF
is
proper, after passing to a subsequence if necessary the points will converge to some limiting value, which must necessarily be one of the points of the index
k
bk ; and hence
xe = bk
Again pf(a',f(a)) / 0 , so that
.
suffices to verify that
for that value
V
a
.
This
V C V-B , and the proof is thereby con-
cluded.
Again there are some remarks about the proof of this final part of the theorem which should be made here.
Note that the essen-
tial element of the proof was the observation that lytic subvariety of
U ;
exhibiting
V-B
V-B
is an analytic submanifold of
, and that the mapping
natural projection
is an ana-
and that the proof of this assertion really
Used only the conditions that (U'-D) X U" X Gm
-_B_
U' X U" X U" --> U'
as a covering space of
V-B --> U'
induced by the
is a light, proper mapping U'-D .
(This result is
36.
typical of a class of extension theorems for complex analytic subvarieties, theorems providing sufficient conditions for an analytic subvariety
- D X U" X U"
V-B C (U' X U" X U"'
sure to an analytic subvariety of
U' X U" X U"'.
best left to a later, more general discussion.)
to extend by cloThis aspect is Now on the one
hand, this argument can also be applied to each connected component of the set
That is to say, if
V-B .
V-B = W1 U...U Ws
are the connected components, then each set
Wk
where Wk
satisfies the con-
ditions under which this argument goes through; there are of course only finitely many connected components, since each must be a covering space of the connected open set
component Wk
in
U'-D .
The closure Wk of the
is an analytic subvariety of U ; and it is
U
evident that this subvariety contains the origin. subvariety
V
at the origin is hence the union of the germs of
these subvarieties 1
s
.
V
Wk ; but since
With the hypotheses and notation V-B
of Theorem 5 and its continuation,
On the other hand, when U U = U1 X...X Un
.£
is irreducible, necessarily
The following is therefore an immediate consequence. Corollary 4 to Theorem 5.
tion
The germ of the
7r2(V-B)
= k+l,...,n .
is a connected point set.
is a complete product domain
this argument can also be applied to each projec-
of the set
V-B
into the factor
The point set closure
analytic subvariety of
U1 X... X U.,
is continuous,
J7ri (V)
Try V-B
is closed and hence
;
7r2(V-B)
for i
and since
7rj V-B C 7ri(V)
.
U1 X...X U1
,
for
is therefore an
k+l,... , n . Since 7rI
is proper,
7r2
7rg(V)
The following result is
37.
therefore a _urther consequence. Corollary 5 to Theorem 5.
If in addition to the hypotheses
of Theorem 5 and its continuation the domain U
is a complete pro-
duct domain, then for any index k+l < I < n the image an analytic subvariety of U1 X...X U.8
is
7rr(V)
.
Note that ai'ter an arbitrary nonsingular linear change of coordinates in
Cn
involving only the variables
total projection 7: V -> 7rk(V) = U' C Ck
zk+
the
,
h ..,zn
is unchanged; hence the
restriction of this projection to the inverse image of the subset
U'-D
remains an r-sheeted unbranched covering of of each point
e U'-D
U'-D
In some
.
there will be
open neighborhood
U',
analytic mappings
Gi: U', --> e-k which parametrize the
a'
of this covering; and the partial projections k+l < .B < n
r
sheets
r
for
7r,,(V) C CC
are parametrized by the appropriate sets of components
of these mappings.
When not all the components of the mappings
GI
are considered, it is possible that the images of different mappings Ga.
After
either coincide completely or intersect nontrivially. D*
choosing a larger analytic subvariety D C
if necessary,
C U'
it can be assumed that the images of different mappings
Gi
are
*
either disjoint or coincident in U'-D only some of the components.
7r,e(V) C CE
are also unbr nc
, even when considering
Thus the par-_ial projections
d
sibly coverings with fewer than
of U'-D*
D
r
sheets.
then complex analytic submanifolds of
,
although pos-
These projections are
(U'-D*) X & -k
,
and as be-
fore, their closures are complex analytic subvarieties in a neigh-
38.
borhood of the origin in the image space.
Consequently, even for
coordinates which form a regular but not necessarily strictly regu-
id V Cn 4
lar system of coordinates for the ideal projections
wi(V)
,
the partial
are analytic subvarieties of open subsets in CE
.
This can be summarized as follows. Corollary 6 to Theorem 5.
If
is an irreducible germ of
V
a proper analytic subvariety at the origin in
en
,
and if
z1,...,zn
form a regular (but not necessarily strictly regular) system of
coordinates for the prime ideal 4 = id V with respect to which k+l < £ < n
the ideal has dimension k , then for any index partial projection
of
7rI(V)
V
the
is an irreducible germ of a proper
analytic subvariety at the origin in
.
pf(z';X) E ( U,[XJ
Finally recall that the monic polynomial
constructed during the proof of the last part of the theorem has the property that
pf(z';f(z)) = 0
z - (z',z",z"') e V-B = V .
for any point
Considering the germs of these various
functions at the origin and passing to the residue class ring ti
n
modulo the prime ideal I
n
determines an element
pf(f) - 0
in r
(jl
element over
k,
[X) = kB [X]
Pf(X) E k
e n
k
C
;
and further,
Thus the polynomial pf(X) is the
= n6ILI
polynomial exhibiting
id V , this polynomial
-
n
ON as an integral algebraic
This observation may help to
clarify the geometrical significance of the earlier algebraic constructions, or the algebraical significance of these later geometric constructions.
39
Theorem 5 in its entirety, together with its various Corollaries, provides a very useful local picture of the complex analytic
subvariety defined by a prime ideal 4 C n(9
;
this picture will be
referred to as the local parametrization theorem for germs of analytic subvarieties.
The next step is to derive some properties of
germs of analytic subvarieties following readily from the local parametrization theorem.
4O.
Some applications of the local pa'rametrization theorem.
§3.
One rather direct application of the l-ocal parametrization
theorem is to the completion of the list given in §2(a) of elementary
relations between germs of analytic subvarieties at the origin in
n C
and ideals in the local ring n6 . It was noted there that for any ideal 9 C 6.- there is a containment relation ,t C id loc (JZ ; the question when this is really an equality was left open. Theorem 6. L
= id loc
C n(-
it follows that
.
'd'
It is of course only necessary to show that
Proof. id loc A
For any prime ideal
C 4
Choose a strictly regular system of coordinates
.
z_,.... zn
for the ideal
dimension
k ;
(
with respect to which the ideal has
and introduce the canonical equations for the ideal,
For any element
and the other notation as in §2.
f c n
6
,
use of
the canonical equations and repeated application of the Weierstrass division theorem as in the proof of Theorem L show that there is a polynomial r
k+1
pf c k
[zk+l]
of degree strictly less than the degree
of the canonical equation
daf - pf e polynomial
for some integer pf
a
k+l .
E k(Q [z_K+1]
If
,
such that
f c id loc V
,
vanishes on the projection
this polynomial actually
+
V0
of the subvariety
V
in the space
as described in the local parametrization theorem.
each point
z'
then the
also vanishes on the analytic subvariety V =
in Cn ; indeed, since p,1 E Ck+1
p
E U'- D
there are
rk+l points
New for
(z',z +i) e V0 - BO
lying over
z'
under the covering projection
since the polynomial
pf(z',zk+l)
Vo-Bo -> U'-D ; and
has degree strictly less than
(rk+l) but vanishes at all these points, it is necessarily the zero
prime and
pf = 0 , so that
Thus
polynomial.
it follows that
d
id loc
that
daf e
; but since * is
f c ( .
This therefore shows
and concludes the proof.
It should be noted that the proof of this result only required the use of the first part of Theorem 5.
The proof of the
final part of Theorem 5 required the additional hypothesis that the
prime ideal f be the ideal of an irreducible germ of a subvariety at the origin in e ; however, in view of Theorem 6, any prime ideal is such an ideal, and this additional hypothesis is therefore automatically satisfied.
prime ideal Y
That is, all of Theorem 5 holds for an arbitrary
n
Now the treatment of the analogue of Theorem 6 for an arbi-
trary ideal A C n
.
follows quite easily from the preceding result
for the special case of a prime ideal, upon using a simple bit of additional algebraic machinery.
Recall from the Lasker-Noether
decomposition theorem that any ideal QC
in the ioetherian ring
n
C-
can be written as the intersection of a finite number of primary ideals.
,(f(
n
fQ(
(See van der Waerden, §87.)
The radical of an ideal
Q is the set _ {f E n(g fr E ,Q( for some integer r > 0 depending or. f
, and AZ C PAZ . clearly U,OZ is also an ideal in n The radical of a primary ideal is a prime ideal; and when an ideal ,07, is written
42.
as an intersection ,QL - 4l n ... n r of primary ideals, its radical is the intersection
J' fl
Theorem 6 (continued).
that
N,0(
= id loc ,QZ
-
.1rAF1 n
... n
r of prime ideals.
For any ideal ( t
it follows
.
If 4_C n e9- is a primary ideal, its radical 'f* is a prime ideal, and it is evident that loc loc.. ; it then Proof.
follows from the first part of Theorem 6
4.
that id loc 4 = id loc l,¢ -
For any ideal ,(Jj, C n (Y written as an intersection of primary
ideals 4 - 11 n ... n 1. , note that and
id loc A - id loc
served,
id loc j 1-
thereby concluded.
=
Ti
n ... n id. loc
1n ... n f-fr -
'i
loc j = loc *1 U...U loc, r °[rr
; hence, as just oband the proof is
0
This result is usually called the iiilbert zero theorem (i;il-
bertsche Nullstellensatz).
Another way of stating it is that if
f e nO vanishes on loc A. for any ideal JQ C n(Q for some integer
r > 0
.
,
then
As a corollary, the ideals A
fT
n
CIL
e ,d[ for
which A = id b e47. can be characterized purely algebraically as
the radical ideals, those ideals A such that 0 = Nr/Z .
(b)
A slightly subtler application of the local parametrization
theorem leads to a proof of the coherence of the sheaf of' ideals of an analytic subvariety.
This result can be stated quite simply with-
out using sheaves, as follows; but the proof seems to require Oka`s theorem or something of comparable depth, so sheaves will appear in the proof in order to effect some simplification.
1+3 .
Suppose that V
Theorem 7.
is an analytic subvariety of an
open neighborhood U of the origin in
Ln
at the origin is irreducible; and that functions in
id V C no o
id V C n 6
Then if U
.
at any point
e n o a
for the ideal
ideal has dimension
k ;
id 'V C
no o
at that point.
with respect to which that
and introduce the canonical equations for
Assume that the neigh-
the ideal, and the other notation as in §2.
borhood U
generate the ideal
a e U
Again choose a strictly regular system of coordinates
Proof.
zl,...,zn
is sufficiently small, the germs of the
of the germ of the subvariety V
a
are analytic
fljl".;fr e nN U
U , such that their germs at the origin generate
fl,...,f
functions
, such that the germ of V
is chosen sufficiently small that the canonical equations U
are .anal tic Uhtoughout
and arc in the ideal in n(U generated
by the functions
f1,...,fr ; and that the local parametrization
theorem holds in
U .
For any point
the local ring
a e U
ndf a
is of course isomorphic to the local ring
ne o
can be effected by the change of variable
wi - zi-ai ; elements of
ti
n0
n
0
will be written either as
o
g(z)
and this isomorphism
or as
to indi-
g(w)
cate in which local ring they are to be considered as lying. clear that for o.
j
at the point
- k+l,...,n a
the germ of the canonical equation
is regular in the local coordinate
that germ is a nontrivial monic polynomial in
k
&- [w.] c
applying the Weierstrass preparation theorem write
where p3(w) e
pi(w) e n
o
k
&o[w
is a unit.
It is
,
since
; hence
pj(w)=
is a Weierstrass polynomial in It is also clear that for
wj
j
w.
and
k+2,...,n
44.
the germ of the canonical equation
pk+l(z)
n
and
Q'(w) e
Note that since
.
are units, the elements
qk+2(w),...,gn(w)
pk+l(w),...,pn(w),
nm a
can be
a
is as usual the germ of the aiscriminant of the poly-
d(w) c k(Q o
nomial
at the point
where
qi(w) =
written
qj
all lie in the ideal in
generated by the germs of the functions
o
fl,...,fr .
g(w) e n 67 o , use of the polynomials
For any element
qk+2(w),...,gn(w)
pk+l(w)'
and repeated application of the
Weierstrass division theorem as in the proof of Theorem 4 show that there is a polynomial
than the degree of the polynomial integer
n
a
s
n
,
such that for some
generated by the germs of the functions
o
a ,
pk+1(w)
is contained in the ideal in
pg(w)
,
fl,... If
vanishes on the germ of the subvariety
g(w)
If
point
of degree strictly less
pg(w) s k(9 o[Wk+l]
so does the polynomial
?:g(w)
V
at the
; but one cannot conclude
from this, as one did in the corresponding case in the proof of Theorem 6, that the polynomial
pg(w)
problem is that under the projection V o
C e- -41
the point
the same image
vanishes identically.
71: V - V
0
in the critical locus
entire subvariety
from V C Cn
a c V need not be the only point of
7(a) = (a',a") c V C Ck X C when B C V ; the equation
a
while the polynomial p (w)
onto
V having
is contained
p i1(w) = 0
a neighborhood of the point
Vo
The
defines the
(a',a") e Vo
need only vanish on that part of V0
g
which is the image of a neighborhood of the point
mapping
IT
.
a e V under the
This can of course only happen when the covering space
45.
U'-D
over
Vo-Bo
is not connected near the point
7f: V-B - Vo-Bo
restricting the covering projections
U'-D
?o: Vo-Bo
hood of
e U'
a'
,
(a',a") E V0 ; and
to the inverse images of a small open neighborsome local components of
local components of V-B
near the point
will arise from
Vo-Bo
a e V , while others will
arise from local components of
V-B near the other points of
mapping under
(a',a") E V
to the point
7r
V
As noted previously
.
0
in corresponding situations, the closure of each connected component of the local covering
V0-B0
near the point
will be an
(a',a")
analytic subvariety of an open neighborhood of that point; and it follows readily that the polynomial a product
Pk+l(w)
pk+l(w).pk+1(w) , where
is the defining equation for that part of V arising as the image of a neighborhood of
Pk+l(w) E k& o[wk+l]
near the point
0
a
in
is contained in the ideal fl,...,fr
the functions
.
n
a
(a',a")
The remaining
V .
is of course a unit in the local ring
term Pk+l(w) pk+l(w)
can be factored into
pk+l(w)
n(Qa
,
so that
generated by the germs of
Yet another application of the Weier-
strass division theorem shows that
pg(w)
pg(w) = 0
where the polynomial p(w) Ee o[wk+l] k
than the degree of the polynomial pg(w)
pk+l(w)
has degree strictly less .
Now if
vanish on the germ of the subvariety V
does follow as usual that
at the point
a ,
fl,...Ifr
na
n
at the point
generated by
o a
.
(Note that
can really be bounded independently of the choice
the exponent
s
of the point
a .)
it
pg(w) = 0 ; and therefore the product
is contained in the ideal in the germs of the functions
and hence
g(w)
46.
At each point
a E U
generate an ideal JT
c n0
the germs of 'the functions
fl, .. .,fT,
and it is clear that the set of these
a ,
ideals form a coherent sheaf of ideals A over the open set the germ of the function
U ;
also generates an ideal N'a c
ds
n 6a
and again the set of these ideals form a coherent sheaf of ideals over the open set
The intersection A
U .
flaA
of two coherent
sheaves of ideals is also a coherent sheaf of ideals, as a consequence of Oka's theorem; hence, perhaps after shrinking the neigh-
borhood U , there will exist a finite number of analytic functions hl'
" .,ht
E n(L
functions generate the ideal for each point
a c U ,
,O
h. E M o
hence such that
hi
E
0a
it follows that this function can be written
while
s
h. = E, d g .,f. 1
1j
n0 o
J
hi e (
is prime, by hypothesis;
NC0 , necessarily
ds
is to say, there will exist germs
gij E
n
o
h' E PC)
such that
That
hi = Ejgijfj
Upon restricting the neighborhood
J
still. further if necessary, it can be assumed that the functions are analytic throughout
gij
U ,
holds in that entire neighborhood.
sider a germ
g e id V C
the preceding paragraph, d
Since
A A4a c n(3a
At the origin the ideal ,cl(o = id V C
U
the germs of these
h. = dsh! /for some analytic function
as a product
so since
a E U
such that at each point
U
s
g E A fl
asg
=
Eikihi
A9
n
0 d
s
Now to conclude the proof, con-
at some point
Therefore there are germs
n(Q a
As noted in
a c U .
g E Pa ; hence of course
= ZijdSkigijfj ;
possible since
and that the last equation above
k. E
n®
and dividing through by
such that a
ds
,
is an integral domain, it follows that
as is
47.
g = Eijkigijf.
Therefore
6 IQa .
C id V
and since clearly
id V C %
at each point
a
it follows that
,
id V - ,U(.a
a E U ; ,
thereby
completing the proof of the desired result.
It should be observed that the conclusions of Theorem 7 carry over immediately to not necessarily irreducible analytic subvarieties; for if in some open set
and there are analytic functions
can be written V = V U V" f"
which generate the ideals of
each point of If
V
U ,
respectively at each
fi. f generate the ideal of V at
is any analytic subvariety of an open set
if
the trivial ideal
U C C
,
a e U there can be associated the ideal
- id V C &
a
'-"a
V
n a
this associated ideal is of course The set of all these ideals form
an analytic subshcaf of the sheaf
nS
over the set U , which will
and called the sheaf of ideals of the analytic
be dented by subvariety V .
V"
f
so that the obvious induction can be carried out.
then to each point
A
and
V'
U , then the products
point of
the analytic subvariety V
U
As Theorem 7 and the remarks in the last paragraph
show, this is a finitely generated subsheaf of the sheaf must be a coherent analytic sheaf over the set
U
.
nS
,
hence
That is to say,
an immediate consequence of Theorem 7 is the following: Corollary to Theorem 7.
of an open set U C en , analytic subsheaf of
n
V
If
is any analytic subvariety
its sheaf of ideals
9 over
U
.
;7(V)
a coherent
48.
It is perhaps worthwhile summarizing some convenient criteria
(c)
that a system of coordinates be regular for an ideal, so that the local paremetrization theorem can be applied to the locus of that ideal.
Theorem 8(a).
Suppose that A is an ideal in
n
6-
and
,
that V is an analytic subvariety of an open neighborhood of the origin in
representing the germ
Cn
lee . .
Then the following
three conditions are equivalent: (i)
(ii)
n-1
0 [zn] fl BL contains a Weierstrass polynomial in
zn
there are arbitrarily small open product neighborhoods
U = U' x U" C CP-l X C of the origin in the mapping jection
such that
induced by the natural pro-
7T: V fl u - U'
U' X U" - U'
CF1
is a proper, light, continuous
mapping; (iii)
the germ of the subvariety v fl (zlzl
... = zn-1 - 0)
at the origin is just the origin itself, or equivalently, the origin is an isolated point of this intersection.
Proof.
It follows easily as in the proof of Theorem 3 that
condition (i) implies condition (ii). set
v fl (zlzI = ... - zn_l = 0)
Assuming condition (ii), the
is just the inverse image of the
origin under the light proper mapping
7T
,
hence is a finite set of
points including the origin; so that condition (ii) implies condition (iii).
Assuming condition (iii), note that the function
on the analytic subvariety V fl (zlzI = ... = zn-1 = 0)
zn
vanishes
in some open
49.
neighborhood of the origin in zn = f + g1zl +...+ gn-lzn-1
germs
f e ,07 , gl' .. '' gn-1
Cn ; hence by the Hilbert zero theorem,
for some positive integer E
61
.
The element
r
f e A is thus
clearly regular in
zn ;
a unit multiple of
f will be a Weierstrass polynomial in
n-lj [zn1 (1J
and some
so by the Weierstrass preparation theorem
, hence condition (iii) implies condition (i).
That
suffices to conclude the proof. Theorem 8(b).
Suppose that ,(Q
is a prime ideal in
!!''
and that
V
is an analytic subvariety of an open neighborhood of the
origin in & representing the germ
loc
.
Then the following
three conditions are equivalent: (i)
after a change of coordinates involving only the variables
zV...,zk , these coordinates form a regular system of coordinates for the ideal It with respect to which the ideal has dimension at most k ; (ii)
there are arbitrarily small open product neighborhoods
U = U' X U" c ck X e-k of the origin in e such that the mapping
7r: V n u ----> U'
jection mapping
induced by the natural pro-
U' X U" -> U'
is a proper, light, con-
tinuous mapping; (iii)
the germ of the subvariety V 1) {zjz1 = ... = zk = 0)
at
the origin is just the origin itself, or equivalently, the origin is an isolated point of this intersection.
50.
Proof.
It follows as in the Corollary to Theorem 3 that
condition (i) implies condition (ii). set
Assuming condition (ii), the
is just the inverse image of the
V n (zlz1 = ... = zk = 0)
origin under the light proper mapping
7r
, hence is a finite set of
points including the origin; so that condition (ii) implies condition (iii).
Assuming condition (iii), note that the germ of the subvariety at the origin is just the origin itself;
V n (zlzl = ... = zn-1 = 0)
hence from Theorem 8(a) it follows that n-l0 [zn] n * contains a Weierstrass polynomial in
zn
.
This implies that
zn
is part of a
regular system of coordinates for the ideal * , with respect to which the ideal has dimension at most coordinates
z1,...,zn-1
n-l , although of course the
might have to be changed.
At any rate,
the local parametrizaion l.:heorem (in particular Corollary 6 to 1
Theorem 5) shows that the natural projection e-1 X C ---> induces a light proper mapping from V
onto an analytic subvariety
n-1 of an open neighborhood of the origin in of the subvariety
Now the germ
Vn-1 n (zlzl = ... = zn-2 = 0)
necessarily just the origin itself, provided that argument can be repeated with the subvariety
Vn-1
at the origin also k < n-2 , so the
in place of V
The obvious induction shows then that condition (iii) implies condition (i), and the proof is thereby concluded. It is evident that, when the three equivalent conditions of Theorem 8(b) hold, the coordinates
z1,...,zn
form a regular system
of coordinates for the ideal Y with respect to which that ideal has dimension exactly equal to
k
provided that either (i)
k
6 n'-
0
51.
the image of V under the natural projection to
or (ii)
of
U'
is all
U`
With this remark it is apparent that Theorem 8(b) contains
.
the converse of Theorem 3, at least for prime ideals. Theorem 8(c).
Suppose that
is a prime ideal in If
that V
n
is an analytic subvariety of an open neighborhood of the
origin in
CU
loc 4 , and that
representing the germ
z1,...,zn
form a regular system of coordinates for the ideal 9 with respect to which the ideal has dimension
k
.
Then
zl,...,zn
strictly regular system of coordinates for the ideal
form a
if and only
if for sufficiently small open product neighborhoods +l
U = U' X U"
V n u -> 7rk_h1(V) n U'
U' X U"
U'
of the origin in
X Cr-'-'
,
the napping
induced by the natural projection mapping
is a one-to-one mapping from a dense open subset of
V n u onto a dense open subset of the partial projection of Proof.
Cn
If
V
z1,...,zn
into
7r',+1 (V) n U' , where
Irk+l(V)
is
C]c+l
do form a strictly regular system of
coordinates for the ideal I , the desired result is an immediate consequence of Theorem 5.
For the converse direction, recall from
Corollary 6 to Theorem 5 that the partial projection of +l
loc 1/ into
is an irreducible germ of a proper analytic subvariety at the
origin in e+1 , and that in a suitable open neighborhood of the origin the natural projection mapping from e to C exhibits dense open subsets of both V
and
Irk+,(V)
as covering spaces of
the complement of an analytic subvariety of an open neighborhood of the origin in
Ck ; the hypotheses further imply that these are
52.
covering spaces of the same number
r
of sheets.
of the last part of Theorem 5, every element n m of the residue class ring
field r
over the subfield
field of degree at most
the element zk+l E n'})l
;
k
k r
over
over
less than
r ; but since
k
k m
ti
is of degree at most n
m .
is an extension
If the degree of
is less than r
k
k
there must be a monic polynomial pk+l
f of the quotient
n(Q/,(
so that
As in the proof
vanishes on the partial projection
pk+l
'k+l(V) , that set must be a covering of fewer than , which is impossible.
Thus
generates the field extension
of degree
E k S I Z k+l] (1'Y
zk+l
n
is of degree over
sheets over
r
r , hence ;
k
k7;1
and the
given coordinate system is strictly regular for the ideal IV
,
as
desired. In the definition of a regular system of coordinates for an
(d)
ideal
,
C
n (.
,
the notion of the dimension of the ideal with
respect to that system of coordinates was introduced; in general this dimension depends both on the ideal and on the choice of the coordinate system.
However, if there is a regular system of coor-
dinates for a prime ideal 9 C n& with respect to which the ideal has dimension
k ,
it follows from the local parametrization theorem
that a dense open subset of a sufficiently small neighborhood of the origin in any analytic subvariety represent=ing the germ
lee * , is
a k-dimensional complex analytic manifold; so it is clear that for a prime ideal, this dimension is independent of the choice of the coordinate system.
Thus it is possible to speak simply of the dimension
53.
of a prime ideal Al C n ®
, denoting this by dim 1(
.
For an irre-
ducible germ V of an analytic subvariety, the dimension of the germ V will be defined as the dimension of the ideal
denoted by dim V .
id V , and will be
For an arbitrary germ V of an analytic sub-
variety, written as the union of its irreducible components
V = UiVi ,
the dimension of the germ V will be defined by dim V = maxi dim Vi of course this does not necessarily coincide with the dimension of
in V with respect to all regular systems of coordinates
the ideal
for that ideal.
The germ
V Vill be called pure dimensional if
for all the components
dim V = dim Vi
V.
.
Several properties of the dimension follow quite readily from the local parametrization theorem, and will be gathered together in the following theorem. Theorem 9(a).
If
V
varieties at the origin in
and W
are germs of analytic sub-
such that
V
is irreducible and
dim W< dim V.
W C V , then Proof.
For the proof it can of course be assumed that W
is irreducible.
Choose a strictly regular system of coordinates for
the prime ideal
id V C no
dimension
k ;
since
, with respect to which that ideal has
id V C id W , it is clear that these coordi-
nates can also be taken to be a regular system of coordinates for the prime ideal
sion < k
.
id W , with respect to which that ideal has dimen-
Suppose that actually
dim W = dim V = k
.
Then, by the
local parametrization theorem, under the natural projection mapping
representative subvarieties for both V and W
in some open neigh-
borhood of the origin in
Cn
appear as finite-sheeted branched
covering spaces of an open neighborhood the unbranched part
V-B
of the covering
C
of the origin in
IJ'
V
;
is a k-dimensional
complex analytic manifold, and an open subset of any open neighborhood of the origin in this manifold is necessarily contained in the
subset W .
Now any analytic function
in this neighborhood of
-
the origin in e , representing a germ
f e id W , restricts to an
analytic function on the complex manifold V-B , which vanishes in an open subset of that manifold; and since irreducible subvariety
f e in V .
id W c id V , which is impossible since dim W < dim V ,
Theorem 9(b).
variety
z1,...,zn
V fl (zlz,
This implies that id V C id W ;
and therefore
as desired.
The germ V
origin in e has dimension coordinates
is connected for an
V , this function vanishes identically on
V-B , hence represents a germ
necessarily
V-B
< k
of an analytic subvaricty at the if and only if for some system of
centered at the origin the gerri of the subzl` = 0)
at the origin is just the origin
itself. Proof.
This is an immediate consequence of Theorem 8(b).
Theorem 9(c).
the origin in
The germ V of an analytic subvariety at
is of pure dimension
n-1
if and only if
id V
is a principal ideal. Proof.
First suppose that
analytic subvariety at the origin in
V
is an irreducible germ of an GP , of dimension
n-l ; and
choose a strictly regular coordinate system for the prime ideal
id V
55.
In this case there is but a single canonical polynomial, the irre-
ducible Weierstrass polynomial pn ; so the canonical ideal C
is
the prime principal ideal generated by that Weierstrass polynomial.
Since C
is a prime ideal, it follows immediately from Theorem 4 id V , and hence
that
More generally, if
desired.
sion
is also a principal ideal, as
id V
V
is an arbitrary germ of pure dimen-
n-1 , then writing this germ as the union of its irreducible
components
V = V1 U...U V
hence as above, each ideal by some element
each germ
,
Since
ring, it is evident that
f1 ... fr E n
V
Conversely, suppose that
subvaricty at the origin in
f e n (Q
factorization ring, this element fl ... f
f
(
fi E n
h c id Vi =
zn
.
n
;
is a unique
and then
since the ideals nf. V.
it can be assumed that
Cn
zn
for some nonzero element
pendent of
@
Considering any one component
strass polynomial in
n 62
Since
.
are the irreducible components of the germ V
choice of coordinates in
is the principal
id V
fr,) , where Vi= inc nm C.
V = loc(n Q f) - lcc(n (Q f1) U...U
an element
.
can be written as a product
of irreducible elements
are prime ideals.
is the principal
is the germ of an analytic
such that
Gn
ideal generated by some element
f
is a unique factorization
n67
id V - id V1 fl... fl id Vr
ideal generated by the element
n-1
is a principal ideal, generated
id Vi
fi E
is of dimension
V.
,
after a suitable f.
i
is a Weier-
If
dim V. < n-1 , there is necessarily
fi
independent of
g E n (Q
the product
However, for any point
z'
zn ; that is to say, h = g fi
is inde-
= (z1,...,zn-1)
suffi
56.
ciently near the origin such that value of
z
r.
h(z') # 0
,
there will be some
in the region of analyticity of representatives of all fi(zl,...,zn) = 0 ; so this is clearly impos-
these germs such that
dim V. = n-l
sible, showing that Theorem 9(d).
the origin in
The germ V
is of dimension
CP
and concluding the proof.
of an analytic subvariety at 0
if and only if
consists
V
of the origin itself; this is the only germ that can be represented by a compact analytic subvariety of an open neighborhood of the origin in
Cn
.
The first part is an immediate consequence of the
Proof.
For the second part, it suffices to
local parametrization theorem.
show that if V
is a connected complex analytic subvariety of an
open subset U C Cr' , the restriction to in
U
of any analytic function
cannot attain its maximum modulus unless it is constant on V;
V
for if
functions in
eF'
,
arc necessarily constant on
of an analytic function
V
and in particular the coordinate
U ,
consists of a single point.
p c V ;
U , then
is a compact connected analytic subvariety of
all functions analytic in
that
V
f
V ,
and hence
V
Suppose then that the restriction to V in
U
attains its maximum at a point
it can of course be assumed that
p
is the origin in
is an irreducible germ at the origin, and that
V
is
represented as an r-sheeted branched covering of an open neighborhood of the origin in To the function pf.(z';X) e k& [X]
f
Ck
,
as in the local parametrization theorem.
there is associated a monic polynomial such that
pf(z';f(z)) = 0 whenever
z =(z',z") e v .
57.
The values of the coefficients of this polynomial at any point z'
E
e sufficiently near the origin are the elementary symmetric
functions of the values taken on by the function
points z - (z',zJ) E V lying over the point complex analytic functions of
z'
.
at the
f z'
and these are
;
However, since
maximum at the single point lying over
z'
r
f
attains its
it follows easily
= 0 ,
from the usual maximum modulus theorem that these coefficients must indeed be constant; but then the function stant on the subvariety
V
f
must itself be con-
'as desired.
Before continuing with further parts of the theorem, it is convenient to demonstrate the following useful auxiliary result. Semicontinuity Lemma.
Suppose that
fi(z;t),...,fr(z;t)
are continuous t;neticns in an open subset U' X U" C d X Cm , and are analytic in t E U"
let
z e U'
for each fixed
t c U"
;
and for each fixed
be the germ at the origin of the analytic sub-
V(t)
{z e U'If,(z;t) _ ... = fr(z;t) = 0) , the origin being a
variety point of
U'
.
Then for any fixed
dim V(t) < dim V(to) function
dim V(t)
whenever
t
to E U"
it follows that
is sufficiently near
to
.
(The
is thus an upper semicontinuo.zs function of
t
in U" .) Proof.
if
dim V(to) = k ,
it is a consequence of Theorem
9(b) that for a suitable system of coordinates in
U'
the origin
is an isolated pc nt of the subvariety V(to) (1 (z E U' I zl consequently for some positive numbers ZIfi(0,. "'0,z
8,E
it follows that
...,zn;to)I > e > 0 whenever ,
z = 0) ,
max
k+l<j
8
.
58.
By continuity then, Elfi(O,...,O,zk+l,...,zn;t)l >_ 2> 0 whenever
1Z.1 - 5
i
l
for all points U
for
0-k
is thus disjoint from the boundary of the polydisc
centered at the origin in
5
The subvariety of
fi(0,...)0,zk+l,...,zn;t) = 0
defined by the equations
i - 1,...,r
of radius
to .
sufficiently near
t
ax< n
Cn-k
;
so the component of
that subvariety contained in the interior of the polydisc is necessarily compact, hence is of dimension to say,
V(t) fl (z e U'lz,
0
... = zk - 0)
That is
by Theorem 9(d).
is either empty or has
the origin as an isolated point, so that by Theorem 9(b) again dim V(t) < k , as desired.
If V is the germ at the origin in
Theorem 9(e).
an analytic subvariety of pure dimension
k , and if
of
Cn
f e n
Q1
is a
non-unit which does not vanish identically on any irreducible com-
ponent of V , then the germ at the origin of the subvariety W = V n {zlf(z) = 0) Proof.
is of pure dimension
k-1
.
Of course it suffices to prove this theorem for the
special case that
V
is an irreducible germ.
Since
f
id V ,
it
-follows that W C V , and hence by Theorem 9(a) that dim W < dim V -= k
.
Let
fl,...,fr
be analytic functions in an
open neighborhood of the origin defining a subvariety representing
the germ V ; and for any point consider the germ W(t) {zlfl(z+t) =
...
t C V sufficiently near the origin,
at the origin of the analytic subvariety
fr(z+t) = f(z) = 0)
.
Note that this germ is
59.
analytically equivalent to the germ at the point {zlf1(z)
t e V
...
-
of the subvariety
- fr(z) = f(z-t) = 0) = V fl (zlf(z-t) = 0)
is any point at which V
manifold, then since Theorem 9(e) that
;
so if
is a k-dimensional complex analytic
vanishes at that point it follows from
f(z-t)
dim W(t) = k-1
since there are points
V
t
t e V
Note also that
.
W(0) = W ; and
arbitrarily near the origin at which
is a k-dimensional complex analytic manifold, it follows from the
semicontinuity lemma that at least true that
k-1 = dim W(t) < dim W .
If W
dim W = k-1..
Therefore it is
is irreducible, it is then
If W
necessarily of pure dimension
k-1
as the union W = W1 U...U Ws
of its irreducible components, and
let
k. = dim W.
such that ai
W.
For each component Wi
select a point
a. e W..
ai , W.
for
j # i
.
Near the point
ai e V of
is irreducible and is defined by the vanishing of the
Wi
single analytic function
sarily k
is reducible, write it.
is a k.-dimensional complex analytic manifold near
and such that
course
.
.
f ;
so by what has just been proved, neces-
= k-1 , and the desired result is thereby demonstrated.
,
1
Some comments should perhaps be made at this point about the preceding theorem.
First, if V
is an analytic subvariety in
an open neighborhood of the origin, and if
V
is irreducible at the
origin, it is not necessarily irreducible at all points near the origin; for example, the subvariety
V C C'
V - ((zl,z2,z3, s
is readily seen to be irreducible
1z2
-
z2z3 = 0)
defined by
at the origin, but to be reducible at any point (0,0,z3) for However,
V
z3 J
is at :!east pure dimensional at all points sufficiently
near the origin; for if V
is irreducible and of dimension
k
at
0.
6o.
the origin, a dense open subset of an open neighborhood of the origin V
in
is a k-dimensional complex analytic manifold.
This observa-
tion was used in the proof of Theorem 9(e), as the reader will no doubt have observed.
Second, if
V
is a complex analytic manifold,
then the converse to Theorem 9(e) also holds; indeed, this is really just Theorem 9(c).
However, for a general analytic subvariety
V C Cn , the converse to Theorem 9(e) does not necessarily hold; that is to say, if
V
is of pure dimension
an analytic subvariety of pure dimension sarily true that w = V fl (zlf(z) = 0) f
.
k
and if W C V
is
k-1 , it is not neces-
for some analytic function
This is a point to which further discussion will later be given.
Third, by iterating Theorem 9(e) in the obvious manner, it follows readily that whenever
open neighborhood U
are analytic functions in an
f1,...,fr_-k
of the origin in C , the subvariety has dimension at least k at
V = (z e Ulfl(z) _ ... = fn-k(z) = 0) each of its points.
Again however, as might be expected in view of
the preceding comments, the converse assertion does not necessarily hold; a subvariety of pure dimension
k
in
Cn
cannot necessarily
be defined as the set of common zeros of precisely
n-k
analytic
functions, even locally. Theorem 9(f).
If
V1, V2
are germs at the origin in
of analytic subvarieties of pure dimensions
kl, k2 , respectively,
then for any component W of the intersection that
dim W > kl + k2 - n .
V1 n V2
it follows
Proof.
Let
fi,...,fr,gl,.
be analytic functions in
,gs
an open neighborhood of the origin such that the subvarieties
V1 = (zlf1(z) = ...
=
represent the germs
r
=°
V1, V2
) ,
and
V2 = (zlg1(z) - ... -g s (Z) = 0)
respectively.
For any point
sufficiently near the origin consider the germ W(t)
t E Vl
at the origin
of the analytic subvariety (zlfl(z+t) = ... = fr(z+t) = gl(z) _ ... = gs(z) = 0)
this is just the intersection of the germ
with the translation
V2
to the origin of the germ of the subvariety V1 If
t e V1
is any point at which
analytic manifold, then the submanifold
V1
at the point
is a k1-dimensional complex
V1
can be defined by the vanishing of LP
that for the subset
W(t) ` V2
dim W(t) > k2 - (n-k1)
t a V1.
dim W(t) > kl + k2 -n ; for at such a point
dinate functions in
coor-
n-k1
hence it follows readily from Theorem 9(e)
,
defined by these functions necessarily
Note further that
.
since there are points V1
Note that
.
w(o) = V1 n V` ;
and
arbitrarily near the origin at which
t E V1
is a k1-dimensional manifold, it follows from the semicontinuity
lemma that
dim V1 > dim W(t) > kl + k2 - n
If
.
Vl n V2
ducible, the desired result has been demonstrated.
If
reducible, write it as the union W - WI U ... U Wm ible components, and let select a point
a.
e W.
analytic manifold near
Near the point
a.
&i - dim W.
such that ai
Of course
W.
V1 fl V2
is
of its irreduc-
For each component Wi
.
is a 2.-dimensional complex.
and such that
so by what has just been proved, is thus proved.
W.
is irre-
ai
W.
for
is irreducible and
W.
j
i
.
= V1 fl V2
Bi > kl + kk -n , and the theorem
62.
§4. (a)
Analytic varieties and their local rings In the discussion of the local parametrization theorem,
interest was centered on the form of an analytic subvariety in terms of a particular, conveniently chosen system of coordinates in the ambient space
(
.
In the applications of the local parametri-
zation theorem discussed in the last section, however, the role of a particular coordinate system was irrelevant, except as a tool in the derivation of the desired properties.
For these and many other
properties interest really lies in an equivalence class of germs of analytic subvarieties, where two germs
V1, V2
of analytic sub-
varieties at the origin in e are called equivalent germs of V
analytic subvarieties if there are represcntatiJe subvarieties V2
in open neighborhoods
analytic homeomorphism
U1, U2
and an
of toe origin in
o: Ul - U2
such that
V2
gP(V1)
.
It
is obvious that this is indeed an equivalence relation in the technical sense.
There will generally be no attempt made to distinguish
between germs of analytic subvarieties and equivalence classes of germs of analytic subvarieties; it is usually completely clear from context which is meant.
It should be noted that an equivalence class of germs of analytic subvarieties depends quite essentially on the particular imbeddings of the subvarieties in the ambient space
CP
.
Thus the
n
germ of a k-dimensional analytic submanifold of
C 1
of a k-dimensional analytic submanifold of
are inequivalent
germs of analytic subvarieties whenever
C 2
and the germ
nl / n2 , even though
63.
they are equivalent germs of complex analytic manifolds; and again, if
is the germ of an analytic subvariety at the origin in
V
then
V
Cn
,
can also be viewed as the germ of an analytic subvariety at
the origin in
Cn+l
through the canonical imbedding
en C e+1
but these are inequivalent germs of analytic subvarieties.
It is
thus evident that there is a point to introducing a further, weaker equivalence relation among germs of analytic subvarieties, in order to investigate those properties of analytic subvarieties which are to some extent independent of the imbeddings of these subvarieties in their ambient complex number spaces.
For this purpose, consider two germs subvarieties at the origin in spaces a continuous mapping "1 from the germ
V1, V2
C 1, Cr2 , respectively.
V1
into the germ V2
germ at the origin of a continuous mapping here
V1
and
U1, U2
hoods
V2
of the origin in the spaces
qr*: V2 - V2
is meant
q: V1 - V2 , where
C 1, C
The two germs
V1, V2
logically equivalent if there are continuous mappings
*: V2 -> V1
By
are analytic subvarieties in some open neighbor-
representing the given germs.
and
of analytic
such that the compositions
respectively,
are topo-
p: V1 - V2
if(p: V1 - VI
and
are the identity maps; this is of course equivalent
to the condition that the two germs have topclogically hormcmorphic representative subvarieties in some open neighborhoods of the origin.
A continuous mapping
T: V1 - > V2
analytic mapping from the germ VI
is said to be an
into the germ V2
if a repre-
sentative mapping on analytic subvarieties extends to an analytic
64.
mapping of a neighborhood of the origin in
of the origin in
C
;
n C l
into a neighborhood
that is to say, the mapping
V1 -> V2
cp:
is analytic if in terms of some representative subvarieties VV V2 in open neighborhoods
U1, U2
of the origin in the spaces C 1, C
respectively, there is an analytic mapping
OjV1 = q
0: U1 . U2
such that
Note that the critical matter is that there exists some
.
extension of
Cp
to an analytic mapping, but not what the particular
extension is; so two analytic mappings are identified when they
yield the same continuous mapping from V1
into
V2 , regardless
of what the extensions of these mappings are in the ambient complex number spaces.
The two germs
Vi, V2
are said to determine
equivalent germs of analytic varieties if there are analytic map-
pings
qp:
V1 - V2
*Cp: VI --> V1
and
such that the compositions cp4f :
V2 -4 V2 are the identity maps.
It is
clear that this is an equivalence relation in the technical sense; an equivalence class is called the germ of an analytic variety. Note that equivalent subvarieties in this sense are topologically equivalent spaces; so that underlying any germ of an analytic variety is a well defined germ of a topological space. Note further however that a germ of an analytic variety cannot be viewed as being imbedded in a complex number space
Cn
,
although
of course a representative analytic subvariety is always so imbedded; different representatives of the same variety may be imbedded in quite different complex number spaces.
65.
The germ of an analytic variety can be viewed as the germ
(b)
of a topological space with an additional structure imposed; and one way of describing this additional structure is through the analytic functions on the variety.
Consider first an analytic subvariety V of an open subset
U C
;
and to each point
Pa= id V C n6a
.
a e V
associate the ideal
The residue class ring
which was
considered in some detail earlier, will now be denoted by
V
and will be called the ring of germs of holomorphic functions on the
subvariety V
at the point
a
.
The terminology is suggested by
the following outlook on this residue class ring.
For any germ
f e n&a select a representative analytic function neighborhood of the point
a
function to the subvariety V
in e ;
in an open
f
the restriction of this
is a continuous complex-valued
function in an open neighborhood of the point
on the set
a
and the germ of this restricted function at the point
depends only on the original germ
f e n0
a
.
V
clearly
a
It is apparent that
this restriction mapping is a well-defined homomorphism from the ring
nS a
into the ring of germs of continuous complex-valued
functions on the set
V
at the point
a
,
and that the kernel of
this homomorphism is the ideal A a ; hence the residue class ring
A can be identified with a subring of the ring of germs of continuous complex-valued functions on the set
V
at the point
a
and the germs so arising can be considered to be the germs of holo-
morphic functions on the subvariety V
at the point
a
.
66.
V 6a for all points
The set of rings
to form a sheaf of rings over
can be taken
a e V
V which will be denoted by
V
a
and called the sheaf of germs of holomorphic functions on the sub-
variety V .
Note that this sheaf can be viewed as a subsheaf of
rings in the sheaf of germs of continuous complex-valued functions
V
on the set r(W,V 6 )
For any relatively open subset W C V
.
of sections of the sheaf
V&
the ring
over w will also be
denoted by V 6W and will be called the ring of holomorphic func-
tions in the subset W
f e 1'(W,V6 )
V
6
of the subvariety
V .
Any section
can of course be viewed as a continuous complex-
W
valued function on the set W ; and a continuous complex-valued function
f
on the set W belongs to the ring r(W,V6 )
if and only if
is_ocally the restriction to
function in the ambient space
CP
V(9 W
V of an analytic
It should be emphasized that
.
it is not required that there should exist an analytic function
in an open neighborhood of W
in
. n
such that
only required that this should be true locally. restriction homomorphism
n
(Q
a
_
n 0 a ; hence
module over the ring
of modules over the sheaf of rings of course when viewed in this light to the subvariety as before
7(V) `
V n
V
& Iu
at the origin in spaces cp:
FIW = f ; it is
Note that the
Vd
as a al
can be viewed as a sheaf
Q1
n C9 IV
on the set
v
Actually
.
V m _s just the restriction
of the analytic sheaf
(n 6 ILT)/ q (V)
, where
is the sheaf of ideals of the subvariety V.
Now consider two germs
continuous mapping
V as exhibits
F
C
, C
V1, V2
of analytic subvarieties
respectively.
If there is a
V1 - V2 , then for each germ
f
of a
67.
continuous complex-valued function on
the composition
V2
f,T
a well-defined germ of a continuous complex-valued function on thus
induces a homomorphism
cp
Q1
into the ring of germs of
V2
continuous complex-valued functions on
V
V,
from the ring of germs of con-
cp
tinuous complex-valued functions on
maps the ring
is
V,
p
In particular,
.
into the ring of germs of continuous complex-
2
valued functions on Theorem 10.
V,
.
A continuous mapping
V-1 - V2
cp:
between
two germs of analytic subvarieties is analytic if and only if
Cp*(y,(9 )cVe1
2
Proof.
borhoods
Select analytic subvarieties Vv V2
of open neigh-
of the origin, representing the given germs of
U1, Lit
!p: V1 - V`
analytic subvarieties, and a continuous mapping
representing the given germ of a continuous mapping.
If
p
is
analytic then, perhaps after shrinking the neighborhoods, there is a complex analytic mapping Now a germ
f e `1(q-
0: U. - U2
such that
0IVI = cp
can be represented by the restriction
.
FIV2
2
for some analytic function
F
in
borhoods if necessary; the germ
sented by the restriction
U2 , again shrinking the neigh-
-
r
2
2
subvar_ety
in
T'2
?*
F°OIV1 , and hence
(f) c
V
6
-
1
6
Conversely sappose that C (_r S ) W-1 ..
can then be repre-
q) (f) = f,p
The coordinates
V1
-restrict to complex_ anslyt.i:c _1anctions on to x
and the compositions
analytic functions on the subvariety
V,
(w, IV
)
- w .° T
are then
near the origin; hence,
68.
after shrinking the neighborhoods if necessary, there will exist analytic functions These functions
F.
in
F1,...,F
U1
such that
F.!V1 = wj°(
can be used as the coordinate functions defin-
0: U1 - U2 , and it is evident
ing a complex analytic mapping from their construction that
OIVl = (P ; the mapping
cp
is thus an
analytic mapping, and the proof is thereby completed. A germ of an analytic subvariety determines a germs of a topological space; and this space further possesses a distinguished subring of the ring of germs of continuous complex-valued functions, namely the ring of germs of holomorphic functions on the subvariety. It is an immediate consequence of Theorem 10 that two germs
Vl, V2
of analytic subvarieties determine equivalent germs of varieties if and only if there is a topological homeomorphism inducing an isomorphism
T
a
V2
T
(P
V1
cp:
--> V2
between the rings of
germs of analytic functions on the two subvarieties.
V 0 on an analytic subvariety V
V1
Thus the ring
is the complete invariant deter-
mining equivalence as varieties; and consequently the germ of an analytic variety can also be defined as an equivalence class of germs of topological spaces endowed with distinguished subrings of the rings of germs of continuous complex-valued functions, equivalence being topological homeomorphism and the induced mapping of functions, such that the class contains the germs of an analytic subvariety with its ring of germs of holomorphic functions.
With this observation in mind, it is an easy matter to introduce the global extension of the germ of an analytic variety.
69.
An analytic variety is a Hausdorff topological space endowed with a
distinguished subsheaf V Q of the sheaf of germs of continuous complex-valued functions on
germ of V
V , such that at each point
together with the stalk V m The sheaf
lytic variety.
a c V the
is the germ of an ana-
a
V © will be called the sheaf of germs
of holomorphic functions on the analytic variety
V ; or alterna-
tively, the sheaf V m will be called the structure sheaf of the analytic variety, since it provides a complete description of the structure of the variety.
The sections of the structure sheaf V
over a relatively open subset W C V
will. be denoted by VCTW
will be called holomorphic functions in the subset W
and
of the
analytic variety V ; these are of course continuous complexv,_lucd functions on the subset W .
It should be noted that a
sufficiently small open neighborhood of any point on an analytic variety can be represented by an analytic subvariety of an open subset of some complex number space; but the entire variety may not be representable by an analytic subvariety.
(c)
Some of the elementary properties of analytic varieties are
quite easily established.
V , the ring
V
0a
At any point
a
on an analytic variety
of germs of holomorphic functions can be repre-
sented as the residue class ring
n
Q
or alternatively, recalling the discussion of the local parametrization theorem, as an integral algebraic extension of the ring for some integer
0 < k < n .
It follows immediately that
V
(Sla
k
70.
is a Noetherian ring.
The units of the ring
V
are those germs
C9
a
of analytic functions which are non-zero at the point
quently the non-units form the ideal V1Wa C V(y-
Va
is thus a local ring, with maximal ideal
the residue class field field
V
Since elements of
C .
a
The
.
V VM/
;
and
is clearly the complex number
10W a V
conse-
;
consisting of
all germs of analytic functions vanishing at the point ring
a
Q can be viewed as germs of con-
tinuous complex-valued functions, it is apparent that Via contains no nilpotent elements; that is to say, no power of an element f e V (
a
is the zero element unless
f
is itself the zero element.
The germ V of an analytic variety is said to be reducible if it can be written V = VI U V2
when
V. C V
are also germs of
analytic varieties; and a germ which is not radueib le irreducible.
An analytic variety
irreducible at a point at the point
a
V
said to be
is said to be reducible or
a c V according as the germ of that variety
is reducible or irreducible.
Note that the germ
of an analytic variety is irreducible precisely when the germ of any representative subvariety is irreducible; it then follows from
Theorem 1. that the germ of any analytic variety can be written uniquely as an irredundant union of finitely many irreducible germs
of analytic varieties. Note that the germ V of an analytic variety is irreducible if and only if the ring V is an integral domain; for considering a representative subvariety
,QZ =
id V C n 0
,
the residue class ring
domain precisely when
n
V with ideal
(Q 1, Q is an integral
is a prime ideal, and as noted earlier,
71.
A = id V
is prime precisely when the germ of the subvariety It should be pointed out that, even when
irreducible.
V
is
V S- is an
integral domain, it is not necessarily a unique factorization domain; further discussion of this point will be deferred to a later portion of these notes.
An analytic subvariety of an analytic variety V
is a sub-
V
set of V which in some open neighborhood of each point of
is
the set of common zeros of a finite number of holomorphic functions
in that subset of V ; and as usual, there is correspondingly defined the germ of an analytic subvariety of the germ of the
variety V
If W
at any point.
then whenever an open subset of
subvariety of an open set U
the part of W
is an analytic subvariety of V V
is represented as an analytic
in some complex number space
contained in that subset of
V
,
is represented as
another analytic subvariety of U , contained in natural correspondence associating to each germ
LIT,
V . Td
There is a
of an analytic
subvariety of the germ V of an analytic variety an ideal
id WC V 0 , just as in the case of germs of analytic subvarieties at a point in
1
;
and there is further a natural correspondence
associating to, each ideal A C V (2 a germ _oc .& of an analytic subvariety of the germ
of an analytic variety.
V
These corre-
spondences satisfy the quite obvious relations listed on page -0 for the case that
V = C
.
Less obvious but still quite easy
the assertion that the Hilbert zero theorem holds for ideals in the
ring
V (9
.
12.
For any germ
Theorem 11.
V
of an analytic variety and
any ideal i?C Vm it follows that id be (JZ
.IQL
Represent the germ V by the germ V of an analytic
Proof.
subvariety at the origin in
V
-
,
and let ' - id V C n
(g
then
;
is the image of the natural ring homomorphism
p: n n o
lg u
ry
the ideal IV C n Q will be denoted by
-
V
,
and the kernel of this homomorphism is n
For clarity, the locus of an ideal in
.
lecn ,
a
and the locus of an ideal in V a will
be denoted by locV ; and correspondingly, the ideal of a subvariety in
will be denoted by
Cn
V will be denoted by
be elements of
n
generate the ideal A in
V
fl,...,fr'gl'...,gs
p-1(9 )
Introducing the ideal
idV .
f1, ... , f r be elements of
g1,...,gs
and the ideal of a subvariety in
note first that
in the ring -16
idn ,
- locn Nf.'
locV
n&
LQ
,
' and
geoe? = tir_g the ideal.
whose images
.
For let-
.
p(g1)''.''p(gs)
it is evident that
A' ; now a point
generate the ideal
in a
z
sufficiently small neighborhood of the origin in e lies in the
and
gl(z) _ ... _ gs(z) = 0
°'(z; -
...
fr(z) = gl(z)
,
--
rt,
1ccV
analytic subvariety representing
loci
p(h) c idV W
for an element h e
Hilbert zero theorem in
idV locV
locn 4
note further that
Cn
= p(idn locn QZ '
n ,
)
and thus when
... = gs(z) = 0
4T = lock
h e id
z e V
hence precisely when
in the analytic subvariety representing
hence precisely when
precisely when
W
.
n
Ql
.
lies
z
Letting
id- ?.T = p(idn
w)
;
T
for
precisely when hIW - 0
Therefore, applying the usual
it follows that
p(f0 ' )
.OZ , as desired.
73.
A point in an analytic variety point of the variety
V
V
if the germ of
is said to be a regular
V
at that point is equiva-
lent to the germ of the complex number space
of some dimension
k ; the set of all regular points form the regular locus of
which will be dnoted by 7t(V)
.
It is clear that X(V)
V is a
complex analytic manifold, although it is neither necessarily connected nor necessarily pure dimensional; and it is clear that W '(V) is an open subset of the variety
V .
A variety V
such that
V = k(V) will be called a regular analytic variety; evidently a regular analytic variety is just a complex analytic manifold itself. The complement
V - `j (V)
of the regular locus of
the singular locus of the variety
a point in j(V)
is called
and will be denoted by ,I (V)
is said to be a singular point of the variety
If the analytic variety V V
V ,
V
V
is represented by an analytic subvaricty
of an open subset U C CP , then the regular points of the
variety V
are precisely those points at which the representative
subvariety
V C U
is a complex analytic submanifold.
For on the
one hand it is completely obvious that any point of the subvariety V C U
at which
V
is a complex analytic submanifold of U
necessarily a regular point of the variety
V .
is
On the other hand,
in the neighborhood of any regular point of the analytic variety
there are for the representative analytic subvariety V C U complex analytic mappings that
:
C'
then the mapping
C` C:
q):
Ck
> V C U
and
*: V
local such
is the identity mapping near the origin; but
Ck - U
is necessarily of rank
k
near the
origin, and hence its image, the subvariety V C U , is locally a
74.
complex analytic submanifold
of
U .
This thus provides an
equivalent way of describing the regular locus of the variety
V
which is useful in deriving such results as the following. Theorem 12.
singular locus j (V)
V the
For any complex analytic variety
is a proper analytic subvariety of V .
Since the result is really local in character, it
Proof.
V of an open
suffices to consider a representative subvariety
neighborhood U of the origin in d ; and by the preceding remarks, at which V
it suffices to show that the set of points of V
not an analytic submanifold of U
variety of V .
If the variety
form a proper analytic sub-
V
is reducible at the origin, so it
can be written as a union of subvarieties is small enough, then clearly
is
V = VI U V2
provided U
(V) _ ,J(Vl) U J(V2) U (V1 11 V2)
'
hence it suffices to prove the desired result when the subvariety V
In this case,
is irreducible at the origin.
dimension
k
V
is of pure
at each point; and from the local parametrization
theorem it follows that F ,(v)
is a connected, k-dimensional,
complex analytic manifold forming a dense open subset of the analytic subvariety
V .
Now from Theorem 7 it follows that whenever U
sufficiently small, there are holomorphic functions
f1, ..
'tr
is
in
U which generate the ideal in V ` nAa at each point a e V It is then easy to see that
(V)
is the subset of
V
consisting
of those points at which the rank of the Jacobian matrix of the functions
f1,...,zr
is strictly less than n-k .
For on the one
hand, if the rank of this Jacobian matrix at some point
a e V
is
75
m
m of the functions
m > n-k , there are
and
zeros form an analytic submanifold of dimension this submanifold contains that
point
a
it necessarily coincides with
On the other hand, if
.
manifold at a point
&. ''gn-k
n-m < k ; and since V ,
so
is a k-dimensional analytic submanifold at the
V
and
- n-k
is
V ,
whose common
fi
V
is a k-dimensional analytic subn-k
a e V , there are
analytic functions
such that in a neighborhood of
the subvariety V
a
is
the set of common zeros of these functions, and that the rank of the Jacobian matrix of these functions at the point
it follows that they can be written in the form some analytic functions
n-k
.
The singular locus
described by the vanishing of all
.u coons
J(V)
na for
fl . .
.
.
.
.
...
is also
is then the subset of
(n-k) X (n-k)
of the Jacobian matrix of the functions quently lJ (v)
r gi = dIl h..f.
E 0- , and hence it is apparent that
h.
The rank of the J .`lcohi n matrix of the at least
n-k
id VC
are contained in the ideal
gi
but since the functions
is just
a
V
subdeterminants
fl,...,fr , and conse-
V
is an analytic subvariety of
as desired.
To conclude this catalog of elementary properties of analytic varieties, it should be observed that the machinery of analytic sheaves can be carried over quite readily to analytic
varieties. if V is an analytic variety grit'-_ structure sheaf V
an analytic sheaf over
sheaf of rings analytic sheaves
V0 V
.
(32
is a sheaf of modules over the
V
Again the easiest examples are the free 7a, -
-
V
(9
=
V
m
, ;
and an analytic sheaf
which is the i?omomorphic image of a free analytic sheaf is called
76.
a finitely generated analytic sheaf.
The critical matter for apply-
ing the machinery of analytic sheaves is of course Oka's theorem, which does extend quite easily to this case as follows. For any analytic sheaf homomorphism
Theorem 13.
q
over an analytic variety V , the kernel of
4P: V 6 r --> V & s
is a finitely generated analytic sheaf in an open neighborhood of
any point of V . Proof.
Since the desired result is local in character, it
suffices to consider an analytic subvariety hood
U
of an open neighbor-
V
of the origin in & , representing a neighborhood of some Letting
sheaf of ideals of the subvariety
V C U , both P (V)
precisely the sheaf
U .
and the
are coherent analytic
residue class sheaf V 0 = (n0lu )/2 (V) sheaves over the open set
be the
(V) C na IU
fixed point on the given variety.
V HIV
Note that the restriction
is
VCQ , considered merely as a sheaf of rings.
The sheaf homomorphism
p: V a r
V0
sented by a matrix whose coefficients
can as usual be repre-
s
mid
are holomorphic
functions on the subvariety V ; and if the neighborhood U
is
chosen sufficiently small, there will exist holomorphic'funetions M..
in U
such that
M.. IV = mi.
a homomorphism of analytic sheaves
The matrix
.
0:
(n Q.IU)r
(Mid) (n
determines IU)s
;
and
since this homomorphism evidently takes the submodule (V)r C (n 0IU)1
into the submodule
(V)s C (n(j)IU)s
duces on the quotient sheaves a homomorphism ?: V
,
it in-
m r ___>
V
( s
77.
ti
Note that the restriction
phism
cp
.
Now since
01V
ti
is precisely the original homomor-
is a coherent analytic sheaf in U, the
V 61
ti kernel of the homomorphism
is also a coherent analytic sheaf in
0
U ; and therefore, after shrinking the neighborhood
there will exist a sheaf homomorphism
U
if necessary,
such that the following is
`Y
an exact sequence of analytic sheaves in U
:
ti
r t > VCjI V0
(n@ IU)q Note that the homomorphism
7 = TT0 where `Y: V m q
V
is the natural mapping (n®IU)q ___> V
`Yo
r
can be factored into a product
''
;
and since
T0
is surjective there results the
further exact sequence of analytic sheaves in
v q
"'r
`Y
U :
ti
s
V
V
and
q
Restricting the latter exact sequence to
VO-
V yields an exact
sequence of analytic sheaves over the variety V
of the form
V
so that the kernel of
T
is locally finitely generated over
V
B
and the proof is thereby concluded. An analytic sheaf ,cQ
over an analytic variety V
to be coherent if in some open neighborhood Wa
is said
of each point
there is an exact sequence of analytic sheaves over
a e V
V of the form
78.
(Vm for some
r, s
> (V0 IWa)s
IWa)r
>0,
(J IWa)
It then follows from Oka's theorem, as in the case
.
of sheaves over open subsets of e , that coherence is preserved under the usual algebraic operations on sheaves.
When the variety variety of an open set
V
is represented as an analytic sub-
U C C1 , there have then been introduced
two separate notions of coherence, one for sheaves of modules over the sheaf of rings
in U
n(2
and another for sheaves of modules
V m over
over the sheaf of rings
V ;
and perhaps ap few words of
comparison are in order here.
On the one hand, if
sheaf in the open set
and if the ideal 2 (V) C
U pC
tr-":ia=_y on the nodule y( the restriction J IV
sheaf of rigs V 0 V
.
ea h ' oioi;
fo
a =V,
I
is an analytic
can be viewed as a sheaf of modules over the
,
that is, as an analytic sheaf on the variety
sheaf on the variety V .
For suppose there is an exact sequence
(Q-modules over
r
U , then
is a coherent analytic
it is easy to see that the restriction j IV
U
of the form
y am (r0
J;; 0
Ios
.
Considering any _ oint
a e V , since by _ssuo tion the ideal
acts trivially on
,
(V)3) q):
s VLla
0 a
-- p a ,Q
acts
QLa
then of ccuLrse
If in addition I is a coherent analytic sheaf in
of sheaves of
n
:)
it follows readily that
and hence that
induces a homcmorphism
with image the full module
if
ry(f)
0
79.
for some element
f e
V
iDs
,
a
then
representing the residue class some element
'J'
,
is the residue class of
*: Va r --> ,41"
it follows that C e nQla
F = T(G)
for
be the mapping
where
f = Vc(g)
V
g e Vm a
of the form
r V V67s
0
IV
is a coherent analytic sheaf over
so d IV
F e no
Thus there results an exact
.
sequence of analytic sheaves over
V,
and so necessarily
f ,
G c n(P a ; letting
naturally induced by
for any element
cD(F) = 0
V ,
as desired.
other hand, if I is an analytic sheaf over the variety
On the
V , it can
of course be viewed as a sheaf of modules over the sheaf of rings n m IV
.
Introduce over the open set U
the sheaf I with stalks
defined by
J a L
a
,
viewed as an no a-module, for a e V
0, for
a e U-V ,
and with topology defined by taking as sections over an open subset
W C U
the sections of J
This is called the trivial. extension of the sheaf
over W - W fl V . '9
to the open set
sheaf over
U
over W fl V extended by the zero section
U c cn , and is readily seen to be an analytic
In particular, for the sheaf
.
V 0 itself the
trivial extension is clearly the coherent analytic sheaf
Vm
= (n IU)/ 2 (V) over the open set
homomorphism
:
U
.
Note that for any
o between analytic sheaves over the sub-
variety V , there is an obvious induced homomorphism
t:
k---> J
a
8o.
between the trivial extensions of these sheaves over the open set U ; and that whenever
P>4
>
is an exact sequence of analytic sheaves over the subvariety V , the induced homomorphisms between the trivial extensions of these various sheaves form the exact sequence
of analytic sheaves over the open set
U
.
It is an immediate conp
sequence of these remarks that for any coherent analytic sheaf
over the subvariety V , the trivial extension analytic sheaf over the open set the sheaf extension
(d)
is coherent over
V
is coherent over
Suppose that
Vl
and
U ;
'2
.'indeed, since
is a coherent
j IV - J
if and only if its trivial
U .
V2
are irreducible germs of
analytic subvarietes which determine equivalent germs of analytic varieties; it is then clear that considering analytic subvarieties Vl, V2 (V2)
representing these germs, the regular loci k ('Vl)
and
are coma ex analytic manifolds of the same dimension, and
consequently that
the dimension of an
dim V] = dim V2
.
Thus it is possible to define
reducible germ of an analytic variety to be
the dimension of any representative analytic subvariety.
Having
done so, the obvious elementary properties of dimension carry over to analytic varieties almost immediately.
For an arbitrary germ V
of an analytic variety, written as the union of its irreducible components
V = U. V. , the dimension of the germ V will be defined
by dim V = maxi dim V.
so again the dimension of V
;
dimension of any representative subvariety. called pure dimensional if components
V.
of V .
dim v = dim Vi
is just the
The germ V will be for all the irreducible
The dimension of an analytic variety at a
point will be defined to be the dimension of the germ of the variety at that point; and the dimension of the analytic variety as a whole
will be defined to be the maximum dimension of the variety at all of its points.
An analytic variety will be said to be pure dimen-
sional if its germs at all points are pure dimensional and of a constant dimension, which must of course be the dimension of the analytic variety as a whole.
Note that an analytic subvariety of
any analytic variety can be viewed as an analytic variety itself, so has a well defined dimension.
pure dimension
k ,
For an analytic variety V
it is clear that the regular locus X (V)
of is
a k-dimensional complex analytic manifold, and is a dense open sub-
set of V , although not necessarily a connected subset; and that the singular locus ,( (V)
is an analytic subvariety with
dim ) (V) < k , although not necessarily a pure dimensional subvariety.
Recalling the results of §3(d), note that if
irreducible germ of an analytic variety and W C V
V
is an
is the germ of
an analytic subvariety of V , then necessarily dim W < dim V Furthermore, if
V
is the germ of an analytic variety of pure
82.
dimension
k
and
is a non-unit which does not vanish
f e V QZ
identically on any component of V , then the germ of the subvariety {z e V,f(z) = 0}
is of pure dimension
k-1.
However, as will be
.
seen later, the converse assertion does not necessarily hold; a
subvariety of V
of pure dimension
k-l
cannot necessarily be
described as the locus of zeros of a single function in
V
62
It is clearly of some interest to characterize the dimension
of the germ V of an analytic variety directly in terms of the local ring V 62
;
it is indeed possible to do so quite simply, by means
of the following purely algebraic concepts.
m
,
For an arbitrary ring
the depth of a prime ideal Y C & is defined to be the largest
integer
d
such that there exist prime ideals
,L/
i
C S for which
'V =4.C the depth of the ideal non-negative integer or
will be denoted by depth,( , and is a In a complementary fashion, the height
.
of a prime ideal A C Q is defined to be the largest integer
11i C I for which
such that there exist prime ideals
'V = Yo DJ/l D the height of the ideal //
2 D
...
D7' h
will be denoted by height,( ,
also a non-negative integer or
-
h
and is
It should be emphasized that
.
all these containments are proper containments, and that all the
prime ideals considered are properly contained in the ring aNote that a prime ideal has depth
0
.
if and only if it is a maxi-
mal ideal; and note further that when the ring 0 is an integral.
83
domain, the zero ideal is a prime ideal, and is the unique prime ideal of height
0
.
For a prime ideal It C ns
Theorem 14(a).
irreducible germ V = loc 1/
in e ,
determining an
of an analytic subvariety at the origin
it follows that depth
dim V
height /i
Remark.
- n - dim V .
The difference n-dim V
appears quite frequently,
and as a convenient abbreviation it will be called the codimension
of the germ of subvariety V C C and will be denoted by codim V ; thus the last conclusion of the theorem is that height 1 - codim V Proof.
As a prelimin-ry observation, note that if
W' r W
are any irreducible germs of analytic subvaricties at the origin in tP
dim Wr < dim W-1 , then there exists an irreducible
such that
germ W"
of analytic subvariety such that
f e id W' - id W C n &
this, select any element id W C id W'
;
To see
, noting that
and consider the germ of analytic subvariety
W0 - [z e Wjf(z) = 0]
,
noting that
that for some irreducible component sarily
W' C W" C W .
W' C W0 C W . W"
It is clear
of the germ Wo , neces-
W' C W" C W ; but it follows from Theorem 9(e) that
dim W" = dim W-l > dim W'
,
and hence that
W' C W" C W
.
Turning now to the proof of the theorem itself, let k = dim V , d
depth I ,
and
h = height if
.
It follows
immediately from the observation made in the preceding paragraph
84+.
that there are irreducible germs
the origin in e such that V0 C V1 C ... C Vk-1 C
The ideals Yi - id Vi C )V,
D
Yl
D
of analytic subvarieties at
V.
dim Vi = i
and that
V C Vk+l C Vk+2
n
C
... C Vn-1 C n
are then proper prime ideals for which
... DYk-l DyDYk+i
D
g+2 D ... D -n-1
Dtin'
and consequently it is clear that
depth * > k
and
height 4 > n-k
On the other hand, there must exist some prime ideals
"
and I I. C n a such that
4'hC...C 4'1C*C*" C...C'V"d; and the irreducible germs W, = be
and V". = loc 49-",
analytic subvarieties at the origin in
are then such that
V'h D ... J V'l D v D v"l D ... D v"d
of
.
Since the dimensions of any two consecutive subvariety germs in this chain differ by at least 1, as a consequence of Theorem 9(a), it follows readily that
n > dim V'h > k{h
and
0 < dim V"d < d i m
d,
or equivalently that
height 4 < n-k
and
depth / < ?.:
Comparing these two sets of inequalities yields the desired result.
85.
It is of course a trivial consequence of this theorem that
depth's
+ height I = n
for any prime ideal I C n8l
Several
.
other consequences follow almost immediately from previously established properties of dimension, and should perhaps be mentioned in
The locus of the zero ideal is all of
passing.
Cn , hence is an
n-dimensional analytic subvariety; so that depth 0 = n and height 0 _ 0 .
The locus of the maximal ideal
nWV C
n 0 is just the origin in
a 0-dimensional analytic subvariety; so that depth height
C a
and
0
Theorem 9(c) asserts that a prime ideal
- n
n
is a principal ideal precisely when dim lock - n-l; so
that a prime ideal J C n3 is principal if and only if height or equivalently if and only if depth (. - n-l
n
3
It follows from r
ele-
- is generated by
r
elements then height
< r , or
equivalently depth ,(.{? > n-r Theorem 1L(b).
For an irreducible germ V
of an analytic
variety
height VW/ = dim V VIM/
is the maximal ideal of the local ring
Proof.
the germ V
V
Represent the germ
-
n
V
V
of an analytic variety by
of an analytic subvariety at the origin in
id V C r(-
let
= 1,
then necessarily dim loc A > n-r ; so that if a prime
ments of n(9 ideal A C
.
is generated by
Theorem 9(f) that when the prime ideal
where
Cn,
;
thus
J
is a prime ideal in
Note that for any prime ideal l/ i
n
[9
C
,
,
and
and
n o for
86.
which
the residue class ideal
A
is a prime ideal in V Q
q_ /l/ C V &
it is evident that there thus arises a
;
one-to-one correspondence between the set of those prime ideals in containing
n d
and the set of all prime ideals in
1/.
nQ
is the depth of the prime ideal k[ in
ideals Ai C n m
such that
= AV-
o
C
6Q
If
.
there are prime
,
C
V
...
C Id ;
and
it is evident that 41 d = nV , the maximal ideal of the local ring
n(Q
Passing to the residue class ring
.
V
VVW
- nUw
d
N
m of the form
,
N
...
1 C
C .LLd - V WV
On the other hand, if
maximal ideal VVW in
V
Writing
;
is the height of the
...
] I.,A
h
f
o D
D
V
I for some prime ideals ,
...
D
and since
h=
;
,
there results
and consequently h < depth height VV -
dim V - depth 4 by Theorem 1-(a), the desired
result has been established.
The Yrull dimension of a ring Q is defined to be the largest integer
V 67
is an
0 , the zero ideal of
The two inequalities just established show that depth q ;
C
and since
and noting that I/ h = 4L / 1/_ a chain of prime ideals in n of the form C n SC
and consequently
, there are prime ideals
kf- i
VVW
h
integral domain it is evident that
V
and noting
,
there results a chain of prime ideals in
N C
d < height V V1 .
such that
Cf1
N
N that
V
k
Ji C & such that
for which there exist
k+l prime ideals
87.
YoC 91CY2C...C7k; and it is denoted by Krull dim (Q.
.
For a local ring (}
mal ideal W , it is clear that Krull dim 0 = height W/
with maxi;
for the
longest chain of prime ideals of the above form evidently must end
with the maximal ideal, Y k = W .
For an integral domain
C4 the
zero ideal is a prime ideal, and it is clear that Krull dim 0 _ depth 0 ; for the longest chain of prime ideals of the above form
evidently must begin with the zero ideal, , o - 0 integral domain
.
For the local
V 0 of an irreducible germ V of an analytic
variety, then, Krull dim V m = height VIM! = depth 0 ;
and the
last theorem can be restated as the equality dim V = Krull dim VCP
for any irreducible germ V
Any germ
(e)
V
of an analytic variety.
of an analytic variety can be represented by a
germ of an analytic subvariety at the origin in the complex number space CU
of some dimension n; the smallest dimension
n
for which such a
representation is possible will be called the imbedding dimension of and will be denoted by
the analytic variety V , is of course clear that
imbed dim V > dim V
imbed dim V .
for any germ V of
a complex analytic variety; and it is also clear that = dim V
if and only if
V
a complex analytic manifold.
It
imbed dim V =
is the germ of a regular analytic variety,
The imbedding dimension can be con-
siderably larger than the dimension for some varieties, though;
88.
indeed, the imbedding dimension cannot be bounded by any function of the dimension, even for irreducible analytic varieties.
It is of
evident interest to characterize the imbedding dimension of a germ
of an analytic variety V
in terms of other properties of V , in
V 9 of the variety.
particular in terms of the local ring
Such a
characterization is quite easy, in purely algebraic terms; but it is convenient first to establish the following useful auxiliary result.
Nakayama's Lemma.
Let 0- be an arbitrary local ring with
If M and
maximal ideal W .
such that the quotient module
N C M
are modules over the ring
is finitely generated and
M/N
M = N + VW M , then necessarily N = M
Passing to the quotient module
Proof.
L
clearly suffices to show that if
over the ring 6 such that If
.
L = 14/n ,
is a finitely generated module
L = WV L , then necessarily
L # 0 , choose a minimal set of generators
module
L ; thus the elements
X1, ...,Xr
X1,...,Xr
of the
Since
.
m. e w such that
r Xr =
L
L = 0
but no
L
generate
proper subset of these elements serve to generate
L = WV L , there must exist elements
it
r-1
E m.X. i=1
mr e VW then
,
hence such that
(1-mr)-Xr =
7-
m.X.
;
but if
i=1
(1-m-)
,
W , so that
(1-mr)
is invertible in the
r-l
ring (9
and
Xl,...,Xr-i
Xr =
E mi(1-m
serve to generate the module
tradiction, the proof' is concluded.
That then shows that L ;
and with this con-
89.
Properly speaking, Nakayama's Lemma is rather more
Remark.
general than the result just established; but since the more general result will not be required at present, the preceding misettribution will be used for terminological convenience.
case of the lemma, if ,Dt
such that
V1t .,OL
4
are two ideals in the ring
and ,
Note that as a special
then necessarily
Z-= , L
The imbedding dimension of a germ V of an
Theorem 15.
analytic variety is the minimal number of generators of the maximal
ideal VVW of the local ring V (j! Proof.
origin in
LIn
Select a germ V of an analytic subvariety at the , representing the given germ of an analytic variety.
On the one hand, note that the coordinate functions &1
generate the maximal ideal r.W C n LQ
classes
,
zl,...,zn
in
hence that the residue
in V a generate the maximal ideal V VV' C V &.;
zl,...,zn
it is consequently obvious that the minimal number of generators of the maximal ideal
V WJ C V & is less than or equal to the imbed-
ding dimension of
V .
On the other hand, suppose that
are analytic functions at the origin in classes
`,,...,f
in
V
n
such that the residue
are a set of generators of the maximal
ideal VVW C V @
,
tors of the ideal
V VW .
df1(0),...,dfm(0"
are necessarily linearly independent vectors in
e
.
and that
m
is the minimal number of genera-
Note that the differentials
(Otherwise, after relabeling these functions if necessary,
there exist complex constants
ci
such that
f1= c2 f2 +...+ cm fm + r
90.
for some function r s n(1 with
nWV2
r E
classes
Letting & C
.
f2,...,fn
,
V
Ul +
1M1 =
V
fl
0 , or equivalently, with
and recalling that fl,f2,...,fm
generate the ideal VVW C V CQ
that
-
be the ideal generated by the residue
V
in V !Q
dr(O)
it follows from the above equality
,
= OZ +
r C A+ VWJ2 c V W ;
V
from Nakayama's Lemma it follows that
f2..., m generate the ideal m
that
V1Ml
.
V Wt!
, so that actually
This contradicts the hypothesis
is the minimal number of generators of the ideal
hence serves to complete the proof of the assertion.) fl,...,fm in
.
V
W C
V
S
can then be taken as part of a set of coordinate functions
Now for any other coordinate function
the residue class
zi
J To
wm = zm,
,
i =
VVV
for some analytic functions
since 1 = fl,...,zm = f generate
wl = zl,...,
zi
zl = fl,...,
is contained in the maxima]. idea]
gilzI + ... g zm
hence zi
V\MI
wi = zi - gilzl
-
.
.
g.. cn
The functions
.. - g. zm
(i = m+l,...,n)
are also coordinate functions in a neighborhood of the origin in
and by construction, the residue class wi = 0 lently, the coordinate function w i = m+l,...,n
.
Thus
i
in
V
,
or equiva-
vanishes identically on V , for
V c ((w1,...,wn) E C 1wM+I = ... = wn = 0)
so that imbed dim V < m .
,
The theorem is thereby proved.
The proof of the preceding theorem suggests various other
expressions for the imbedding dimension of a germ V of an analytic variety.
,
The functions
C0 ; so there is no loss of generality in setting
zm = f
hence
First, in terms of the maximal ideal VVW itself, consider
91.
V W 2 c VVW as modules over the ring
the ideals
duce the quotient module 2
f.( V Vd /VVw
)
VVYJ /VVW 2
V
(
Since clearly
= 0 for any f e VVW
it follows that VWflVVW
can be viewed as a module over the residue class ring but since
V
2
0 /V WV
VOIVW,( is just the complex number field, this is equiv-
alent to viewing sion
and intro-
,
VW /VMN 2
dimC VVW
as a complex vector space. The dimen-
lVW 2
of this vector space is of course finite,
since the original ideal VVW is necessarily finitely generated.
Corollary 1 to Theorem 15.
For any germ V of an analytic
variety,
imbed dim V - dime VVW Proof.
If imbed dim V = n
/Vwv
there are
2 n
fl,...Ifn e VVW which generate the maximal ideal
functions Vw
,
as a con-
sequence of Theorem 15; the images of these functions in the quotient module
VVW
2
then generate that module as well, so that
dime VW/ V Mr 2 < n = imbed dim V . dime
V1W /VVW 2 = m there are
On the other hand if
m functions
911
...,gm e V W such
that the images of these functions in the quotient module generate that module.
These functions
generate an ideal All. C VVW
+ VW 2 ,(i'L = V WV ,
= VVM/
;
gl,...,gm
V VW / V
W2
consequently
, which evidently has the property that
but, from Nakayama's lemma it follows that
hence that V VW has m generators. Referring to
Theorem 15 again, necessarily imbed dim V < m = dime and that suffices to conclude the proof.
V M /
W2
92.
The imbedding dimension of an analytic variety can also be expressed in terms of the ideal of a representative analytic subvariety.
Corollary 2 to Theorem 15.
Let
V
be the germ of an
analytic subvariety at the origin in L , and let be generators for the ideal spanned by the vectors
id V C n
(Q
.
df_(0),...,dfm(0)
f1,...Ifm e n
If the subspace of is of dimension
r
CP ,
then
V of an analytic variety represented by the given
for the germ
germ of a subvariety it follows that
imbed dim V
Viewing the ideal Ol = id V C
Proof.
meximal _dcals n W! Cn 0 ring
n
n-r
end
V
1M CV 0
n
C2
as well as the
as mod'-,,-- es over the
the following is an exact sequence of n 0-modules:
nMA/ -- VWV - 0
0
The submodule
.
is mapped onto the submodule VJ2
rWV 2 C nVA(
VW
hence there results the following exact sequence of quotient modules over the ring
n
m
.
,&+nw 2 0
n
VAI
r1Mj
2
VW r_
V 2
0
.
V
It is clear that any element f e nW/ C n 0 acts as the zero element on each of these
n
-modules, so that this last sequence can
indeed be viewed as an exact sequence of modules over the residue
93.
n(D /nW
class ring
nQ
spaces since
VVd /V VWnflV
Wif
,
WV
hence as an exact sequence of complex vector ',,
C .
The vector space structure of
is of course the same as that obtained by viewing
2
W 2
as a module over the ring V &
it follows that M/ dime nW/ /n
,
so from Corollary 1
dime VWd /VWJ 2 = imbed dim V ; and since
2 = n , the exact sequence of vector spaces leads to
the identity
imbed dimV=n - dime n
W
Now the mapping which associates to any function ferential
df(O) s Cn
precisely nW 2 n
f e nw" its dif-
is obviously a linear mapping with kernel
hence this mapping can be used tc identify
;
nw 2 with the complex vector space
Cn
.
The subspace
( ,( + WV 2 )/ 1Ml d
c- nW / n
fl,...,f
so under this identification it becomes the sub-
n
space of
n
e
'
is generated by the functions
spanned by the vectors
a complex vector space of dimension imbed din, V = n-r
A germ
V
,
dfl(0),...,dfm(0) , hence is r
.
Consequently
as asserted.
of an analytic subvariety at the origin in
will be called a neat germ of a subvariety if imbed dim V = n
for
the germ V of an analytic variety represented by that germ of subvariety; occasionally, as a convenient if not wholly accurate terminology, a neat germ of a subvariety will be called a neat imbedding of the germ of an analytic subvariety it represents.
neat imbedding is neat in the sense that it represents the given
A
94.
analytic variety as a subvariety of the ambient complex number space of least possible dimension, hence with no waste or excess.
It fol-
lows immediately from Corollary 2 to Theorem 35 that neat germs of subvarieties can be characterized in the following manner.
A germ V
Corollary 3 to Theorem 15.
variety at the origin in for all elements
cn
of an analytic sub-
is neat if and only if
f e id V C a
df(O) = 0
.
Neat germs of subvarieties form a very convenient class of subvarieties for a number of reasons, such as the following.
Corollary 4 to Theorem 15.
Two neat germs
analytic subvaricties at the origin in
CP
of
V, V'
determine equivalent
germs of analytic varieties if and only if they are equivalent germs of analytic subvarieties.
Proof.
Of course if
V
and
V'
determine equivalent
germs of analytic subvarieties they determine equivalent germs of analytic varieties.
Conversely, suppose that
V
and
deter-
V'
mine equivalent germs of analytic varieties, so that for some representative subvarieties there are analytic mappings
and
q): V -> V'
*: V -> V such that the compositions *0(p: V -> V
9°*: V - V'
are the identity mappings; and let
extensions of the analytic mappings
p
and
Cn , write
and
T
be
i , respectively, to
some open neighborhoods of the origin in C . coordinates in
I
and
In terms of the
(fl(z),..,fn(z))
95.
for some holomorphic functions
fi(z)
.
Since the mapping
the identity on the subvariety V , necessarily for any point
(z1,...,zn) e V
,
and therefore
T°I
is
fi(z1,...,zn) = zi fi(z)-zi c id V C
n
0-'
consequently, from Corollary 3 to Theorem 15 it follows that the differential of the function
3fi(0)/azi = b
equivalently, that
S
.
fi(z) -z
This shows that the composition
i
is zero at the origin, or
for the usual Kronecker symbol ?°(D
is a complex analytic
homeomorphism in some open neighborhood of the origin in of course the mapping
0
(P
,
must itself be a complex analytic homeo-
morphism in some open neighborhood of the origin; this mapping then exhibits
V
and
V'
varieties at the origin in
so
0
as equivalent germs of analytic subCP
,
and the proof is thereby concluded.
Note that as a consequence of Corollary 4, a germ of an analytic variety can be represented by a unique neat germ of an analytic subvaricty; for any two neat germs of analytic subvaricties representing the same germ of an analytic variety are necessarily equivalent germs of subvarieties.
The previous considerations extend in part to arbitrary local rings; no attempt will be made here to carry out such extensions in general, but a few remarks should be made in view of some later applications.
ring (9
The imbedding dimension of an arbitrary local
can be defined to be the minimal number of generators of
the maximal ideal 1h of that local ring; for the local ring of a germ of an analytic variety this agrees with the geometrical definition of the imbedding dimension, as a consequence of Theorem 15.
96.
The proof of Corollary 1 to Theorem 15 is purely algebraic, so that
in general the imbedding dimension of a local ring Q coincides with the dimension of the vector space 1M/I MW2 over the residue
class field & /VW sion of a local ring
.
It is true in general that the Krull dimen(0
is less than or equal to the imbedding
dimension, although there is something to prove here for an arbitrary local ring; a local ring is called a regular local ring if its Krull dimension is ecual to its imbedding dimension.
ring V CQ
of a germ V of an analytic variety is thus a regular
local ring if and only if V variety.
The local
is a germ of a regular analytic
97.
The local parametrization theorem for analytic varieties
§5.
V
If
(a)
the origin in
is the germ of an irreducible analytic subvariety at Gil
,
and if the coordinates in e are suitably chosen,
the natural projection mapping
mapping 7: V --> C
Ln - Ck
induces a complex analytic
having the various properties listed in the
local parametrization theorem.
This type of mapping is a useful too!
in studying the local properties of complex analytic subvarieties, and can be adapted to be equally useful as a tool in studying the local properties of complex analytic varieties.
Indeed, in many
ways the local parametrization theorem expressed in terms of complex analytic varieties is easier to use than the version for complex analytic subvarieties discussed in Section 2.
To begin the discussion, consider two germs complex analytic varieties.
A continuous mapping
V1, V2
of
q: V1 T V2
is
of course just a continuous mapping between the underlying germs of topological spaces, and determines continuous mappings between any two germs of complex analytic subvarieties representing the given germs of varieties; note that if any one of these latter mappings between germs of subvarieties is analytic, then all the mappings are analytic; and the mapping will be called an analytic mapping between the given germ c_"' analyt c varieties.
Of course
10, a continuous mamr ing
is snol-. ti c if and only if
(P
(T_ G) C f2
r
V_
5/2
recalling Theorem
.or the induced maps-rr< of functions.
For the
j
global analogue, ccns_der two complex analytic varieties
A continuous mapping
P: V1 ----> V2
V1, V2
is just a continuous mapping
98.
between the underlying topological spaces; and such a mapping will be called an analytic mapping if it induces an analytic mapping be-
tween the germs of analytic varieties at each point of Vi equivalently, if
cp (V2(9
q)(p) ) c
V1QZp
for each point
(p: V - Ck
In particular, a continuous mapping
or
p e V1 .
is analytic pre-
cisely when the coordinate functions of the mapping
morphic functions on V .
,
qp
are holo-
The special analytic mappings which
arise in the local parametrization theorem can be described as in the following definition.
A branched analytic covering
T: V
U
is a proper, light,
analytic mapping from a complex analytic variety V onto an open subset D C U
U C e , ouch that there exists a complex analytic subvariety is dense in
for which V - T-1(D)
V
and the restriction
T: V - V-1 (D) > U-D is a complex analytic covering projection.
The last condition means
that for a sufficiently small open neighborhood point
z E U-D , the inverse image
7T1(Uz)
Uz C U-D
of any
consists of a number
of components such that the restriction of v to each ccmponent is a complex analytic equivalence between that component and
U
z
;
con-
1
sequently V - 7-l (D) is a complex analytic manifold of pure, dimenand since it is dense in V , necessarily the variety V
itself of _.are dimension
k
.
The subset B = 7T (D) C V will
be called the critical locus of the branched analytic covering; it
99.
is clear that
B
is a complex analytic subvariety of
J (V) C B where J (V)
V
and that
is the singular locus of the variety V
That branched analytic coverings behave very much like ordinary covering projections is indicated by the following useful auxiliary result.
Localization Lemma.
Let
T: V -> U be a branched analytic
covering; and selecting a point
where
pi
z E U , let
are distinct points of
small open neighborhoods 7r1(Uz)
consists of
pi E Vi
for each index
UZ
of the point
i ;
the sets
V.
1
U such that
in
z
connected components
s
- (p1,...)ps)
Then there are arbitrarily
V .
with
V1,...,VG
so arising form a basis
V._
for the open neighborhoods of the point
and for any such sel,
T1'-l(z)
pi
in the topology of V
is also
the _est_^icCion T: V. --> U 1 z
branched analytic covering. Proof.
the points
p.
1
Selecting any disjoint open neighborhoods in
sufficiently
V ,
V1
note first that T 1(Uz) c U. Vi
open neighborhood
U
of
in
z
for any (For
U .
otherwise there would exist a sequence of points
of
c V such that q.
the image points the points
T(q.)
T(q.)
converge to
together with
z
z
but
U. VI
qj
Since
.
form a compact subset in
U
and since the riapning v is proper, a subsequence of the points q.
must converge to a limit point
one of the points
pi , since
q E V ; and clearly
v(q) = lir! T(q,)
-
z
must be
q
But this is
.
J
impossible, since
y
U. Vi .)
boyhood Uz , let
V
be a connected component of
Now choosing a connected such neigh-
1 7r
(U
z
)
in
V
100.
V C V!
then
for one of the neighborhoods
that v(V ) = UZ Jr
V
.
V
(For since
- V
V!
Note further
.
fl B - V
is dense
it (V-B)
and is a covering space of the connected set
U - U z
it is evident at least that a point
z0 c Uz - 7r(V*)
set closure of points
qi E V
7r(V*)
7r(V
= a.
.
qo E r (z0) n
zo ,
V'
1 =
V .
Select a sequence
.
and a sequence of points is
7r
must converge to a limit
qj
C 7r l(Uz) n V7 ; but this evidently implies
that qo e V , which is impossible since Consequently V
Uz
Again, since the mapping
proper, a subsequence of the points
point
in
)
converging to
7r(qi )
If there were
) D Uz - Uz (l D .
it would necessarily lie in the point
,
of the set
z. E 7r(V )
such that
7r(V
n D , z
7r(go)
Z0 /
7r(V*) . )
must be an open neighborhood of the point
That the restriction
7r: V - UZ
pi
in
is a branched analytic
covering is quite apparent, and the proof is thereby concluded.
As a first consequence of the localization lemma, note that for a branched analytic covering
7r: V --> U
trarily small open neighborhoods of any point restriction of the mapping
7r
there are arbi-
p c V
such that the
exhibits each neighborhood as a
branched analytic covering; therefore the germ of a branched analyti covering is a well defined notion, and it is possible to speak of a germ of an analytic variety as being represented as a germ of a branched analytic covering.
assuming that the point the mapping
7r
,
p
There is no loss of generality in _s mapped onto the origin in
e'
under
and this normalization of the local version of a
101.
branched analytic covering will always be chosen.
The mapping
can then be described directly in terms of the germ V by its
71-
k
coordinate functions, which under the normalization adopted will be
k elements of the maximal ideal VVW C the germ V ; any set of k
of a germ V
of the local ring of
V
elements of the maximal ideal VVW
of an analytic variety of pure dimension
k , which
arise as the coordinate functions of the germ of a branched analytic
covering, will be called a system of parameters for the germ V . The basic elementary existence and characterization result for branched analytic coverings is the following. Theorem 16.
pure dimension
k
such that a point 1 71
(7r(p)) c V
,
and
V
If
(a)
is a complex analytic variety of
7r: V -- k is a complex analytic mapping
p e V
is an isolated point of the subvariety
then the restriction of the mapping
open neighborhood of the point p
(b)
r
to some
is a branched analytic covering.
If V is the germ of a complex analytic variety of
pure dimension
, then a set of
k
elements of the maximal ideal.
a form a system of parameters for the germ V V W1 C V only if they generate an ideal
( c)
V LQ
For any germ 7r: V -> U C (r
covering, the gene V
subvariety V
such that VVW - 'i. k
of a branched analytic
can be represented by a complex analytic
of an open neighborhood of the origin in
that the coordinates in for the ideal
A1Z C
if and
id V C n m
C n
CP
such
are a regular system of coordinates
and the mapping
77-
is induced by the
102.
natural projection mapping c ---> e .
If V
Proof.
k,
dimension that
and
7r
m
7r: V
7r(p) = 0 e e
variety
is a complex analytic variety of pure
then
,
is a complex analytic mapping such
c
p
is an isolated point of the sub-
I(v(p) C V precisely when the coordinate functions of
the mapping
generate an ideal
7T
4Z C
V (3
such that loe ,Ot = p
P
and by the Hilbert zero theorem, this is in turn equivalent to the
condition that N.U1
id -P =VVIA/ CV(9p .
-
Therefore parts (a)
and (b) are really equivalent, and for their proof it is only necessary to show that any set of
germs
1,
fl,...,fk
in V & P
generating an ideal UCH VQp with be ,01 = p is a system of parameters for the germ
V .
Suppose therefore that those germs
a.'e irepresenLed by ar.aly tic functions analytic subvariety
V
'.i
.. , f1
.
of an open neighborhood
in C , where the subvariety
V
on a _,ompl ex of the origin
U
represents the given germ of a
variety; and suppose that the set of common zeros of these functions consists of the origin a-one, the origin being the r,oint p
the neighborhood U
If
.
is sufficiently small, the irreducible com-
ponents of the germ V will be represented by separate analytic
subvarieties of U restrictions to
and the functions
of analytic =unction
V
terms of ` he coordinates z, ;
analytic marring
J
into C'
-rom U
n
;
f,,...,f,,
,
7
this is
.. , Z
in
will be the
F1,...,F1 C
in
U
In
.
introdu:;e the complex
,S(F_(Z),...,Fk(z),z1,...,z
from
clearly a complex analytic homeomorphism
onto a complex analytic submanifold of
Ck
X U C Cp ,
103.
hence the image of the subvariety
subvariety V
X U
1
analytic variety as
fl,...,fk k
V .
V
U
is a complex analytic
representing the same germ of a complex For this representative, the functions
are the restrictions to the subvariety
coordinates
wl.....,wk
by assumption V
1
in the ambient space
fl (wlwl = ... = wk = 0)
V1
of the first
Ck+n .
Now since
consists of the origin
alone, it follows from Theorem 8(b) that the coordinates
wl,...,wn
form a regular system of coordinates for the prime ideals in
k+n GL
corresponding to the various irreducible components of the germ of V1
at the origin; hence from the local parametrization theorem it
ei n _, Ck
further follows that the natural projection each irreducible component of
exhibits
as a branched analytic covering
V
Ck
of some open neighborhood of the origin in
.
This projection
is the analytic mapping defined by the given analytic functions fi,...,fk ,
and the entire subvariety is then represented as a
branched analytic covering of an open neighborhood of the origin in Ck
by this mapping; therefore
f1,...,fk
form a system of para-
meters far the analytic variety V , as desired.
Actually, part (c)
has been proved at the same tirae, so that the entire proof is concluded.
One special case of this theorem is perhaps worth discussing separately.
neighborhood
Any n V
origin determine
functions which are holomorphic in an open
of the origin in
Cn
an analytic mapping
and which vanish at the
T: V
e ; and this map-
ping is a branched analytic covering at the origin in
V
if and
only if the origin is an isolated point of the subvariety of common zeros of these
n
functions.
For
n = l
,
the set of zeros of a
non-constant analytic function is always isolated, so that any nonconstant function of one complex variable defines a branched analytic covering.
This is of course a very familiar result; and it
is further familiar that the standard form of a branched analytic covering, in some sense, is the mapping
z T zr
An immediate
.
corollary is that any non-constant analytic function of a single complex variable determines an open mapping.
For
n > 1 , the
situation is rather more complicated, and branched analytic coverings are but a special type of non-trivial analytic mapping.
Al-
though it follows immediately from the localization lemma that a branched analytic covering is an open mapping, there are nont:civial mappings which are not open, even though their images have non-empty interiors.
mapping
The sirmlest example is probably the analytic
(zl' `2) --- (`11 "lzP) ; the image of this mapping is the
complement of .:he set
((zl'z
)
2
e
Iz1 - 0, z2 # 0) , hence the
mapping is evidently not open. (b)
If T: V -7 U
Js a branched analyic covering, the
t_mac=Jirit
i;
to the
mite-S _eted e
is :ie ewv
of the critical
_
_n
` oDDin
the nu lbe_,
th_ crof ti:_ branched ana_'r'---- covo' ?or a
t
'i ,
fcllceis _ro the iocaliz at-on
lemma that tf_ere S_'C arbitrarily small open neighborhoods
Vp
of
1.05.
p
in
V
such that the restriction of the mapping
also a branched analytic covering.
to
7r
Vp
is
Since the orders of these local
branched analytic coverings can only decrease as the neighborhoods Vp
shrinks to .he point
p ,
it is evident that the order is the
same for all sufficiently small such neighborhoods; this common order will be called the branching order of the mapping
71'
point
7r: V - U
p ,
and will be denoted by
o(p)
is a branched analytic covering of order
point subset that
and letting pi,...,pr
z E U
7r 1(z) C V
r ,
then selecting any
be the distinct points of the
it follows again from the localization lenma
,
o(pi) = r
Ei
Note that if
.
at the
A useful convention is to list a point
.
p E 7r 1(z)
a total of
sisting of
r
o(p)
times; then Y-1 (z)
elements for each point
are not necessarily distinct points of For any point
p
z E U , but the elements V .
outside the critical lo.-us
branched analytic covering
7r: V --> U ,
,
B
of a
it Is of course clear that
c(p) = 1 ; however there may very well be points
locus for which o(p) = 1
is a set con-
p
in the critical
since not all the points of
7r
1(7r(p)
need necessarily have the same branching ord r, even when the cr tical locus is chosen to be as small as -possible.
There is th -
some point to introducing the subset E = {p c'11 of ") > 1)
hi h will be ca cove-:rins
7:
.
e . the bra =C1? I-Cus G.. y `_7
; _ oin is in
.;
anche
analyti
e branch locus .. _11 be called
branch points olf than branched analytic covering.
1o6.
Theorem 17.
covering T: V --> U
variety V .
The branch locus' B
of a branched analytic
0
is an analytic subvariety of the analytic
The intersection of the germs of the branch loci, for
all representations of the germ V of an analytic variety as a branched analytic covering, is precisely the singular locus J (V)
of the germ V . Proof.
The entire theorem is really of a local nature.
Hence it can be assumed that the variety V complex analytic subvariety V
is represented by a
of an open subset
U C e ,
that as in Theorem 7 there are holomorphic functions
U
which generate the ideal
id V C n&
f1 ...,fm
at each point
a
and
in
a e U
;
and further, it can be assumed that there are holomorphic functions
in U
g_,...,gk
*
whose restrictions to the subvariety V
coordinate functions for the mapping v . a E U
the differentials
and
dfi(a)
arc the
Note that at any point
dg .(a)
can be viewed as
J
vectors in
B
0
CP
.
The first step in the proof is then to show that
- (a E V C U*Irank(df1(a),...,dfm(a), dg1(a),...,dgk(a)) < n)
To do this, consider a point equal to
n .
at which the above rank is
In an open neighborhood of that point
of the functions
_"1, ..g1, ...,gk
dinate functions in all of the functions all of the functions gi,...,gk
a e V
;
.
a
,
some
n
can be taken as local coor-
clearly these
n
functions must inc_ude
g1 , since the set of common zeros of
f1,...,fm
and any
k-1
of 4he functions
is an analytic subvariety of positive dimension and not
1.07.
It follows immediately that
just a point.
manifold of dimension that the functions
o(a) = 1
is a complex analytic.
g1,...,gk, .
are a regular system of parameters
a c V at which
Next consider a point
a
in
V and an open subset
morphism is described by n U
such that
,
Ua C
The inverse homieo-
-
h1,...,hn
continuous functions
Ua - Ua n D , hence by the Riemann Ua , so
removable singularities theorem are holomorphic throughout Va
that
by
Thus a can be
is actually a regular analytic variety.
defined by the vanishing of fly..., fn
and
in
for any point w e Ua ; these
(h1(w),...,.h(w))e Va
functions are holomorphic in
of the
Va
then a topological homeomorphism between a neighborhood point
is
g1,-..,g;_
The mapping defined by the functions
-
a , and
in a neighborhood of the point
k
o(p) = 1
there, so that
V
n-k
of the functions
f,...,fm , say
rank(df1(a),-..,dfnK(a)) = n-k
.
Moreover,
on the k-dimensional manifold defined by the vanishing of the func-
tions
fl,...,fn-k ,
the mapping defined by the functions
gl,...,g_
is a complex analytic homeomorphism; and from this it is easy to see that
rank(df1(a),...,dfn_,(a), dg1(a),...,dg (a)) = n Having established this preliminary result, it is obvious
that
B
is an analytic subvariety of
those points of V
at which all the
V ;
n X n
B,
for
consists of
determinants formed
from the matrix of holomorphic functions (df1(z),...,dfm(z), dg l(z),...,dgk(z))
are zero.
Now consider
the germ of the subvariety V at the origin in U c cn , and assume as usual that the system of parameters
s ,...,gk
take the
origin in
also vanish at the origin in
Cn
for a suitably small
Ic1 ..I < e
gl,.,gk on V
the set of common zeros of the functions
,
and
It follows immediately from the
.
semicontinuity lemma, that, whenever s > 0
U
which axe holomorphic in
g (z) = gi(z) + I. cijzj
tions
For any complex constant
.
1 < j _ n , consider also the func-
1 < i < k,
c =
matrix
C
to the origin in
Cf
has the origin as an isolated point; consequently, applying the functions
I e.I < s
Theorem 16, whenever
a system of parameters for the germ V as germs at the origin in
Cf
of an analytic variety.
j (V) C Bo , where
,
also form
gc,...,g
If
is the
B0
branch locus of the branched analytic covering defined by the system of parameters
g1,...,g,
select a point
,
passing through the origin but not lying in the
component of
BC
singular set
J (V)
Then it follows as in Theorem 12 that
.
rank(df1(a),...,dfI'll (a)) = n-k
Note though that
.
for the constant vector
dg (a) = dgi(a) + c.
qucntly the-e exist constants
Ici .
I
< e
a
ci - (c..)
such that
does not lie in the branch locus
This shows that
.
Bs-
0
of the branched g,,...,gk
analy is covering defined by the system of parameters and therefore necessarily If
(V) C B
c
,
iI B
o
system of parameters
that
B.
0
fl ]3c i 0
Bc n B
S-,
,
L B0
C B`
as germs at the origin in
the process can be repeated, yielding a
,...,b_
Pcs
0
c
conse-
;
j
(a), dg,(a),...,dg (a)) = n the point
lying in some
a
r - 1 BV
0
with branch locus
B
0
as germs at the origin in
such
Lp
109.
Since the ring V Q is Noetherian this Process must terminate after
a finite number of repetitions, and then
j (V) = Bo A Bo' fl Bo
n ....
which suffices to complete the proof. It follows from the proof of the preceding theorem, or more
V
generally from the Noctherian property of the ring
together
with the statement of the preceding theorem, that the singular locus (V)
can be written as the intersection of finitely many branch
loci, in the representations of the germ
V
of an analytic variety
as a branched analytic covering in various ways.
Iturthermore, for
as a branched analytic
any particular representation of the germ V
covering, j (V) C Bo [ B ; and these can be proper containment
Indeed, a complex analytic manifold V
relations.
can be rebre-
sentecd as a in:'asuchod analytic covcrin^; vit}'. a non-trivial branch locus.
On the other hand, whenever
p e R(V)
.
x:
e V-B
0
then necessarily
A system of parameters for the germ of the analytic
p c V will be called a regular system of
variety V at a point parameters if
o(r) - 1
in the branched analytic covering they
define, or equivalently, if the germ of a branched analytic covering they define has an empty branch locus; the point be a regular point of the variety
V .
p
must then
Note that a regular system
of parameters for the germ V of an analytic. variety actually form a set of coordinates on the manifold
full maximal ideal V VW as its radical.
V
V , hence they generate the
V rather than just an idea.': having Conversely of course, whenever a system
110.
of parameters generate the full maximal ideal V WV C V QZ imbed dim V = dim V , so that
V
,
then
is locally a manifold; and the
system of parameters form local coordinates, hence are a regular system of parameters.
Thus a system of parameters is regular if and
only if they generate the full maximal ideal; and a local ring
V
admits a regular system of parameters if and only if' the germ V of analytic variety is regular.
Branch points of two quite different kinds can occur in a branched analytic covering
iT: V -- U
.
p E Bo
A point
will be
called an essential branch point if there exist arbitrarily small open neighborhoods that
Vp
of the point
p
is a connected set.
VP - Vp fl 30
in the variety
V such
The remaining points of
Bo
will be called the accidental branch points; thus for all sufficiently small open neighborhoods in a variety components.
V ,
the set
Note that if
Vp
of an accidental branch point
Vp - V f1 Bo p E K(V) fl Bo
has at least two connected then
p
is necessarily
an essential branch poinlt; for any sufficiently small connected open
neighborhood
Vp
of the point
p
is a connected complex analytic
manifold, so the complement of the analytic subvariety is necessarily ,connected.
Vr A Bo C p
This observation can be rephrased upon
application of e o_em 17, in an apcarently more con--using manner, the assertion that these branch points of a branched analytic covering which cease
be bran Ch points in some other representa-
tions o-' the variety as a branched analytic covering are necessarily
essential branch points; this is really not confusing, if it is
3l1.
remarked that the property that a branch point be essential is really a property of the branched analytic covering and is not intrinsic to the complex analytic variety so represented. V
ety
in some neighborhood of the point
variety of an open subset of covering
7T: V -- U
LJ1
Representing the vari-
p e V by an analytic sub-
such that the branched analytic
is induced by the natural projection mapping
as in the local parametrization theorem, it follows from
Cn ---, do
Corollary 4 to Theorem 5 that the separate components of Vp - Vp fl B
,
for sufficiently small connected open neighborhoods
of the point
Vp
p
in V , correspond to separate irreducible com-
ponents of the germ of the variety V
at the point
p
.
Thus the
accidental branch points of the branched analytic covering, which necessarily lie in the singular locus
J (V)
,
of the variety
V ,
are precisely those points at which the germ of the variety is irreducible.
If the variety V
is irreducible at each point, then all
the branch points in any representation of V as a branched analytic covering are essential branch points.
It would be natural to attempt
to pull apart all the accidental branch points, to obtain an analytic variety more primitive than the original variety, such that the original variety arises by imbedding that more primitive variety in such a manner that some accidental intersections arise; but this cannot be done :oo brutally, since accidental branch points may have a limit point which is an essential branch point.
For example, the
analytic sub-Variety V C & defined by the single equation z3
-
z2z1 = 0
is exhibited as a branched analytic covering of
LP2
112.
under the natural projection mapping locus is the subvariety zl # 0
for
(z1,0,0)
the points
(0,2 2,0)
Co -> C2 , and the branch
Bo = ((z1,z2,z3) E Vlzlz2 = 0)
; the points
are accidental branch points of V , while for all
As noted earlier, the germ V
z2
are essential branch points of V.
is irreducible at the origin in
but not at any point of the form
(21,0,0)
for
z1 # 0
C3
.
The canonical equations for a prime ideal )VC n6
played
a fundamental role in the derivation of the local parametrization theorem; and it might be anticipated that their analogues for branched analytic coverings would have a comparable use.
In this latter case,
though, the geometric properties can be taken to some extent as being given; but the analogues of the canonical equations provide useful tools in deriving further algebraic and analytic properties.
The
advantage of this reversal in point of view is that a comparison of the discussion here with that in §2 may perhaps clarify the earlier considerations, by exhibiting more explicitly the analytic structure underlying the previous almost purely algebraic constructions.
First, as a preliminary observation, if
7T: V --> U
is a
branchedi analytic c- vering and h is a __olomorphic function en al _ of U C 9', then the composition li (h) = h°7T is a holomorphic
=z_Lncti ,n or all of V ; and this
clearly a`
'_somorpr:i
from the
wing
kQiJ
jr11(V
is
ng of hr=omorphic _urictionc n
int. the rI-ng of holemorphic f'unctione on V , since the image is all of
li
.
It is convenient to identii
the ring
k (9U
with
113.
its isomorphic image
7F (k(4 U)
,
as a subring of
V
6)
V
; and with
this convention, the characteristic properties of the canonical equations can be summarized as follows.
Theorem 18.
ing of order
r
be a branched analytic cover-
7f: V -> U
Let
U C e .
over an open subset
For any analytic function
(a)
unique ionic polynomial
f e V QV there exists a
pf(X) e &[XI of degree
r
such that
pf(f) = 0 on V
If
(b)
the discriminant
is an analytic function on V such that
g E V 6) V
of the polynomial
dg e k11 U
pg(X) E k0 U[XI
not identically zero, then for any analytic function there exists a unique polynomial such that
on
Proof.
(a)
of
g
(X) e
k 0 U[X)
V
62V
of degree
r-1
V .
The polynomial pQ(X)
is constructed exactly
as in the proof of the continuation of Theorem 5. z E U
f e
is
For any point
let V (z) = (p1(z),...,pr(z)) c V , where a point is re-
peated according to its branching order so that there are always precisely
r
points of this set but they axe not necessarily al-
ways distinct points; it is evident that the only possible such
polynomial p f(X) must be
r pf(z,X) =
II
i=l
(X -f(p.(z)))
and it is only necessary to show that the coefficients of this poly-
nomial are analytic functions in U .
Note that these coefficients
114-
are the elementary symmetric functions of the values
f(pi(z))
,
hence are independent of the order in which the points of the set Tr-1(z)
are written.
Now it follows quite trivially from the local-
ization lemma that the coefficients are continuous functions of since the function
f
is itself continuous on V . z0 e U
an open neighborhood of any point
z ,
Furthermore, in
outside of the image
D
of the critical locus, the branched analytic covering is an r-sheeted analytic covering in the ordinary sense; hence in that neighborhood it is possible so to label the points of the set pi(z)
U
is a complex analytic mapping from a neighborhood of
into
z0
in
Thus the coefficients are clearly analytic functions
V .
U-D , and since they are continuous in U
in
that each
7T1(z)
it follows from the
Riemann removable singalarities theorem that they are analytic throughout (b)
U , as desired.
Consider next an analytic function
that the discriminant
dg e
is not identically zero in
of the polynomial
k U U
g e V aV
such
pg(X) E k 0U(X]
Retaining the notation adopted in
.
the first part of the proof, recall that the discriminant is given
by
d (z) = g
jg(p.(z)) - g(p.(z))] ; thus the condition on the
IT
J
1
11J
discriminant is equivalent to the condition that the g(pi(z)),
i =
,...,r
,
a. E k U
f e V
V
)
d
9
1
such that
E a.(z)-g(p(z))J , 1 J
J=o
z e U.
the Droblen is to
r-1 (
values
are distinct for at least one point
Now for any other analytic function find analytic functions
r
115.
for any point
z
E U ; for then the polynomial
r-1 gf,g(z,X) _ has the desired properties.
viewed as a system of a.(z)
r
Note that the equations (*) can be
linear equations in the
r
unknown values
z E U ; hence by Cramer's rule
at any fixed point
,
E aj(z)XJ
j=0
g(pi(z))2,...,g(pi(z))r-l]
aj
g(pi(z)),
= det[1,g(pi(z)),
...,g(pi(z))r-lj,
...,g(pi(z)j-l,d9(z)f(pi(z1,g(pi(z))j+1,
where in both determinants the entries in row
i are as indicated.
The determinant appearing in the left hand side of the last equation
is the van der Monde determinant n , and it is well known that A2 = dF(z)
is the discrim_inant of the polynomial
pg(X)
at the
J
point
z
.
If
dg(z) / 0
,
then factoring that term from the deter-
minant on the right hand side of the last equation and. dividing by
A on both sides produces the explicit formula
...,g(pi(z)r-1]
aj(z) =
Note that both determinants on the right hand side change sign upon interchanging any two rows; the product is thus invariant under the simultaneous change of any pair of rows in the two factors, hence is really independent of the order in which the points of the set r-1 (z)
are labelled.
Again it follows trivially from the locali-
zation lemma that the functions
aj(z)
defined above are continuous
116.
in all of
U , and they axe analytic in
functions
pi(z)
U-D
since locally the
can be chosen to be analytic mappings; so by the
Riemann removable singularities theorem the functions analytic throughout
aj(z)
U , and the proof is thereby concluded.
If V is the germ at the origin in
C"
of an irreducible
k-dimensional analytic subvariety, and if the coordinates in
are chosen to be strictly regular for the ideal
CP
z1,...zn
id V C no,
e induces a branched analytic
then the natural projection e covering
are
The restrictions to the subvariety
'rr: V - U .
the coordinate functions
zk+l'
are complex analytic func-
..,zr,
lions on V , and the polynomials
V of
pz (X) e kQ U[XI
of Theorem 18(a)
J
lead to the first set of canonical equations
pj = rz (z.)
for the
J
ideal
id V C n0 ; and letting
canonical equation qz_,z J
(X) E
k+l
k
1 o
canonical equations
=p
p,`
d E k0 be the discriminant of the ,
the rolynomials
k+1.
of Theorem 18(b) lead to the second set of qj =
qz
(z,+l) j yz
id V C
n
(9
.
for the ideal
k+l
It is in this sense that Theorem 18 can be considered
as extending the canonical equations of analytic subvarieties to branched analytic coverings.
The canonical equations were only
established for prime ideals in §2; but clearly Theorem 78 can be used to derive the canonical equations for an arbitrary pure-
dimensional ideal in the ring no
Note that the condition that the discriminant p ? (X) e k m U[X3
of the polynomial
dg e k(
U
not be identically zero is
b
equivalent to the condition that the values for at least one point theorem.
points
be distinct
z e U , as remarked in the proof of the
Actually of course these values are distinct for all for which
z e U
dg(z) # 0 ; so in this sense, the condi-
tion is that the values of the function
generally separate the
g
7r: V - U
sheets of the branched analytic covering
(d)
g(p.(z))
.
As noted before, if 7r: V --> U is a branched analytic
covering and
f
is a holomorphic function on the subset
U C d ,
* then the composition
7r (f) = fa7r
is a holomorphic function on the
variety V ; and the mapping v . kOU -> VOV so defined clearly an isomorphism from the ring of holomorphic functions on U into the ring of holomorphic functions on
V .
For any point
p e V , the localization lemria, shows that there are arbitrarily
small open neighborhoods of the point
such that the restrictions
p
of r to these neighborhoods are also branched analytic coverings; and hence there results the natural local isomorphism 7r
: k0V(_ ) -> TTQIp
over the subring
.
.
5T(U)
The ring
V
7r*(k d 7r(p) )
can be viewed as a module
c
V
T
p
indeed, it follows
readily from the local paramctrization theorem that
V
mT
is a
finitely generate,. integral algebraic extension over this subring. Actually somewhat more can be shown; viewing the rings
118.
ti
(ko7r(p)) as forming a subsheaf of rings of the sheaf
k(9V(p) -
of rings A over the variety V , the sheaf V (S? is locally a finitely generated sheaf of modules over this subsheaf of rings 7r (U& ) c V m .
This is rather reminiscent of the coherence con-
ditions discussed earlier, but is in a sense somewhat topsy-turvy; it is more natural to consider locally finitely generated sheaves of modules over either the structure sheaf U CO of
or the structure
U
V(9 of V , whereas here the structure sheaf V 0 is viewed
sheaf
as a locally finitely generated sheaf of modules over a new sheaf of
rings 7r (U0 )
over V .
This can be reversed, to yield a more
convenient way of looking at the same situation, by considering the
direct image 7r,(Vm ) of the sheaf of rings inverse image
V(g
, rather than the It is perhaps
of the sheaf of rings
7r (U
clearer to discuss the relevant sheaf construction somewhat more generally at first, and then to specialize to the case of present interest.
Suppose therefore that between two topological spaces
7r: V --> U
V and
is a continuous mapping
U', and that J is a sheaf
of rings (or of groups, etc.) over the space
V .
To each open set
Ua of a basis for the open sets in the topology of U
the ring Ra = P(7f 1(TJa), j )
It is clear that whenever U. C Up
the natural restriction mapping of a section of to the subset
p pa13 :
P >
whenever
7T -'(U) C 7r(U)
I
over
.
Thus
7f l(UP)
induces a homomorphism
Ra ; and that these homomorphisms satisfy
Ua C TJp C U,,
associate
{Ucx, R
pafpP7, = p(Y7
a, pip} is a presheaf of
119.
U ; the associated sheaf will be called the direct image
rings over
under the mapping
of the sheaf 7r*(j)
.
7r , and will be denoted by
It is obvious that the presheaf just constructed is a
complete presheaf, so that the natural homomorphism
a T f(Ua,7r*(j
is an isomorphism; that is to say,
))
r(Ua,7r*(J) N F(7 (Ua),
under the obvious canonical isomorphism.
)
Now for a branched analytic covering 7: V --> U , the direct image
7r*(V(9)
is a sheaf of rings over the open subset
U c ck .
There is moreover a natural isomorphism from U 6 into
7r*(V0 *
for to any section
7r
fa e F(Ua,UCQ )
(fa) = fa 7r c F(7r (Ua)IV0)
presheaf of sections of direct image sheaf
to define a homomorphism from the
into the presheaf used to define the
U
7r*(VQ?)
,
,
and observe Unat this clearly yields
an isomorphism from the sheaf
U L into the sheaf
this isomorphism, the sheaf v*(V (Q)
modules over the sheaf of rings sheaf over the open subset
Theorem 19(a).
associate the section
Under
can be viewed as a sheaf of
U (9 , that is to say, as an analytic
U C
For any branched analytic covering
7r: V T U , the direct image sheaf 7r*(VS) is locally a finitely generated analytic sheaf over U Proof.
.
As a consequence of Theorem 16, an open neighbor-
hood of any point on the analytic variety
V
can be represented by
an antic subvariety V of an open neighborhood of the origin in Cp
,
such that the mapping
7r
is induced by the natural projection
120.
mapping 0 - Ck
as in the local parametrization theorem.
It
suffices to prove the theorem for just this piece of the branched
V over any point of U
analytic covering; for the part of
can be
written as a disjoint union of such pieces, by the localization lemma, and clearly the direct image sheaf is the direct sum of the direct images of each separate component. branched analytic covering is of order V
hV
If this piece of the
r ,
consider the monomials
V
k+l ,
zn E r(V,V92)
0 < v1+l,...,Vn < r-1 , where as
for
...
before the analytic functions z
are the restrictions to the subJ
variety V of the coordinate functions
by E r(V,V
zj
in
Cn
The sections
induce sections HV E r(u,7r,(V&)) ; and the proof
)
will be concluded by showing that these sections
sheaf
.
HV
generate the
as a sheaf of modules over the sheaf of rings
7r.*(V&)
For any point
a e U
let
1r
(a) _ {p,,...,p5) C V , where
axe distinct points; and applying the localization lemma, choose
pj
an open neighborhood U
of the point
a
such that
c V a -
V--'(u
SL
has
connected components
s
restriction
o(p )
.
Since the poin=mss
V".
.
pj e V.
and the
D.
are distinct and 7r(=:) = a , there J
such that the function
g - c,_+! z; 1 +...+ cnzn
takes distinct values at distinct cci_nts
indeed, if the neighborhood
the function
for which
a
are constants
;
V1, ... ,Vs
is a branched analytic covering of order
7r: V. -> U J
Pi
U(9
g
U.
is chosen sufficiently small,
takes distinct values on the separate components
Now for each component
V.
there exists by Theorem 18 a monic
121.
polynomial
e ka U
pg'j(9) = 0
on the component
pg,j(X)
normal
of degree
[X]
V.
V.
for any fixed point
z' _ (z,,...,zk) a U a
the separate components of
7T-1(Ua)
Note that the restriction
g
takes distinct values on
it further follows that the
,
analytic subvariety V-1 (U ) = U Vi a of degree
and is nowhere zero on
V.
for
i / j
germs
F E 7f*(V6)
fi E V &
,
; recalling
a
F
is evi-
represented by holo-
pi
on the various components
fi
V.
of
)T
for a sufficiently small open neighborhood Ua of the point The function of
g.
f i/ It
Vj
.
1
morphic functions
to the
o(pj) , which vanishes identically on
the definition of the direct image sheaf, the element s
i #j.
for
is thus a polynomial in
Now consider an arbitrary element
dently described by
V.
of the function pg'j(g)
g.
are
at the points of V-1 (Z ')
is nowhere zero on the components
function pg'.(g)
zk+1,. " ,zn
g
and since the function
,
such that
; since the roots of the poly-
precisely the values of the function lying in
o(p.)
a
is analytic on V
i
1(Ua)
a
.
in an open neighborhood
pi ; consequently, as in the local parametrization theorem, this
function on
can be written as a polynomial
V.
fi E kQa[ k+l' ., n] of degree at most o(pi) - 1 in each variable. Then
f*i
lI
g- e J
j/'-
most
o(n_)- 1 +
with the function
k a [ k+l' ... , i o(pj) = r-1
j#i
fi
k
]
is a :polynomial of degree at
in each variable, which agrees
on the component
V.
and vanishes on the
122.
components
for
V.
j / i
;
and consequently F = E fi
i
i
expressed as a linear combination of the elements cients in
k(Q a ,
II
is
g.
j/i
J
Hv with coeffi-
thus concluding the proof of the theorem.
The construction in the proof of the preceding theorem shows
that when the analytic variety V
is represented by an analytic sub-
variety V of an open neighborhood of the origin in d , such that the natural projection
d'
e exhibits
V
as a branched ana-
lytic covering of an open neighborhood U of the origin in e , there is an exact sequence of analytic sheaves over U of the form
0-> V'( --->U&R>TP*(V(q)-;> 0; here
U (9R
U6 1 C U ^-1
can be identified with the subsheaf
(9[zk+l,...,zn]
consisting of polynomials of degree at most
in each variable, so that
7r.(V0 )
R = rn-k , and the mapping onto
can be identified with the restriction of these polynomials
to the analytic subvariety V C U X .-k .
Consequently the kernel
x can be identified with the subsheaf x C U OR
C Um [zk+1,
.
' "zn
consisting of those polynomials vanishing on the analytic subvariety V C U X Cn-k
More accurately, for any point
.
consists of those polynomials in
most
a[zk+l,...'zn]
UCQ
of degree at
in each variable which vanish at all points of the sub-
r-1
variety V C U X Cn-l'
neighborhood J
n=k+l it is 0) = cR 7r. ( V
a c U the stalk x ,_
U
a
lying over some sufficiently small open
of the point
a
in U
.
In the special case that
easy to see that X = 0 , and consequently that .
To see this, note that any polynomial
123.
f E k& a[zk+l]
of degree at most
r-l , which vanishes on the
analytic subvariety V fl (Ua X Cl) a , must have
of the point
r
for some open neighborhood
Ua
distinct zeros over a dense open
subset of Ua , and hence clearly vanishes identically.
This is of
sufficient interest to merit restating explicitly, as follows.
Corollary 1 to Theorem 19.
analytic covering of order
If
is a branched
induced by the natural projection
r
when the variety V
mapping
U
7r: V
is represented by an
analytic subvariety of an open neighborhood of the origin in then the direct image sheaf
7P.(VCV )
is a free sheaf of rank
(:k+1
r
.
In the case of a more general branched analytic covering,
the direct image sheaf
7r*(
V
(9)
is not necessarily a free analytic
sheaf, even locally; however it is always a coherent analytic sheaf.
This amounts to the assertion that the kernel sheaf H in the exact sequence above is locally finitely generated; but actually it is easier to establish that result somewhat more indirectly. Theorem 19(b).
For any branched analytic covering
n': V -41- U , the direct image sheaf T*(V(D )
is a coherent ana-
J.,ytic sheaf over U . Proof.
As in the proof of the first part of the theorem,
it suffices to consider only a branched analytic covering
7: V ---> U
induced by the natural projection mapping
Li, .-
C
When the variety V is represented by a complex analytic subvariety of an open neighborhood of the origin in
C?
.
There is no
124.
loss of generality in assuming that the coordinates in chosen that the coordinate the covering.
maps the subvariety
Cn ---> a
subvariety V0
-->
V
onto an analytic
of an open neighborhood of the origin in e+l p: V --> V
inducing an analytic mapping +l
generally separates the sheets of
As in the local parametrization theorem, the partial k+1
projection
zk+l
are so
Cn
.
The further projection
then induces a branched analytic covering
v: V
0
---> U
and the original branched analytic covering is the composition 7r = op
Introduce the auxiliary subsheaf of rings
.
,H L V (Q
on
the analytic variety
V, defined as having as stalk at any point
p e V the subring
p = k07r(p1k+l] c
,61
V
ap
,
where
zk+l is the
restriction of the coordinate function zk+l to the analytic subvariety
V
and
7 (kO p)) C
image
is as usual identif'ed with its isomorphic
m
k 7(P) V
of the polynomial pz
Op
.
Letting d e kL' U be the discriminant
(X) E k0 U[X]
k+l
of Theorem 18(a), and noting
that this discriminant is not zero since the function
zk+1
gener-
ally separates the sheets of the branched analytic covering 7r: V -> U , it follows immediately from Theorem 18(b) that d V 19 p
C
sheaves,
7r*(d
V(D
7r*(VS )
p d
V
p E V ; consequently, in terms of
at each point
0 CJ C V 0 .
d 7r*(V(9)
7r*(V®) ; and therefore
7r*(d . V0) c 7r .(J )
to show that T*(,a)
Note further that clearly
.
To complete the proof, it suffices
is a free analytic sheaf; for then
Tr*(V L
is exhibited as a subsheaf of a free analytic sheaf, and since
125
it*(V d)
is locally a finitely generated analytic sheaf as a conse-
quence of Theorem 19(a), necessarily
71-*(V (0)
is a coherent analytic
sheaf . Now note first that the direct image sheaf p*(,) = V 0
of a point
V0q
For selecting any open neighborhood
q e Vo ,
it
follows from the definitions of the direct image sheaf and of the
sheaf a that
P(Voq,P*() ))
r(P-1(V0q),I ) = 1'(P-1(V0q),UC [k+1]);
and since sections of the sheaf
zk+2,. .,zn , it is further evident that
coordinates 1(Voq,
n,
[zn/
10 rk+1]) = r(Voq, U
r(P
B
passing to the germs at the point
P*(.Q
a
are independent of the
[zk+l]
U
= UQ()1zk+l]
a (P*( ) )
V
0
q
.
Consequently, upon
k+l]) q ,
.
it follows that
Then
0*(V m ) ; and since
c*(V (D )
is a free
0
analytic sheaf as a consequence of Corollary 1 to Theorem =9, it follows that
7r*(j)
is also a free analytic sheaf, and the proof
is thereby concluded.
Although the direct image sheaf
7r*(.
)
is not neces-
sarily a few analytic sheaf, it perhaps should be pointed cut that the proof of the preceding part of the theorem did provide some slightly more detailed information than merely that the direct
ire sheaf 7r*(VS )
is coherent; for the essential step in the
proof was to show that locally the sheaf 7r*(V0) as a subsheaf of a free analytic sheaf.
could be imbedded
Thus the following asser-
tion is an immediate consequence of the proof of the theorem.
126.
Corollary 2 to Theorem 19.
analytic covering of order
r ,
If
7f: V --> U
is a branched
then the direct image sheaf
7r.,(V0 )
is locally an analytic subsheaf of a free analytic sheaf of rank r.
127.
§6.
(a)
Simple analytic mappings between complex analytic varieties.
The partial projection mappings appearing in the local para-
metrization theorem have not so far been considered in any detail, although one example of their usefulness was provided in the course of the proof of Theorem 19.
Actually these mappings play a very use-
ful role in the study of the local properties of complex analytic varieties.
Analytic equivalence is really too strict an equivalence
relation to be used from the beginning in attempting an explicit classification of the singularities of complex analytic varieties;
it is natural to try to develop a sequence of progressively stricter equivalence relations culminating in analytic equivalence, so that at each stage a more reasonable classification is possible; and the partial projection mappings are of some relevance to this prog-ram.
The present section will be devoted to a discussion of these partial projection mappings for complex analytic varieties.
It is first use-
ful to characterize this class of mappings somewhat more intrinsically.
p: V1 - V between two complex
A simple analytic mapping analytic varieties
VI
and
V
is a proper, light, analytic mapping
such that there exist analytic subvarieties which
V,-A1
and
the restriction
V-A
are dense in
p: VI-A1 - V-A
and
VI
Note that the image
for
contains the dense open subset
must be a closed subset of V
and A C V for
V respectively and
is an equivalence of analytic
varieties. p(V1)
Al C V1
p(V1)
is necessarily all of
V-A C V
since the mapping
Most of the applications the varieties
V1
and
p
and
V
p(V1)
is proper.
V are both pure
In
128.
dimensional; of course it is clear that whenever one of the two varieties is pure dimensional, the other variety is also pure dimensional and of the same dimension.
That these mappings are at least closely
related to the partial projection mappings in the local parametrization theorem is indicated by the following easy observation. Suppose that
Theorem 20.
is an analytic map-
p: V1 --> V
ping between two pure dimensional complex analytic varieties.
If
p
is a simple analytic mapping, then there exists an open neighborhood Vq
of any point
q
of
V
such that the varieties
Vq
and
V1q = p-1(Vq)
can be represented by branched analytic coverings
7T1: V1q
and
U
T: Vq --4 U of the same order with
Conversely, if there is an open neighborhood
in
V
such chat th varieties
Vq
and
sented by branched analytic coverings of the same order with
7T1 = Tp ,
`v'l q
7r1 = 71-p
of the point
Vq
- - -1 (Vq
can be repre-
1
T1: Vlq ---4 U
q
and
then the restriction
T: Vq
p: V7q -> VG
is a simple analytic mapping. Proof.
representation in
V
If
p
is a simple analytic mapping, select any
7T: Vq ---> U
of an open neighborhood of a point
as a branched analytic covering.
T = Tp: V1q -4 U
q
The analytic mapping
is then a light mapping, so by Theorem to it is
a branched analytic covering provided that q is sufficiently small; and clearly the branched analytic coverings
and
7T:
T1: V10 - U
Vq - U are of the same order. Conversely, if
7rl = 7Tp
for some branched analytic coverings Tl: Vl0 -> U and 7r: Vq --> is of the same order, it is clear that the mapping
P
is both light
129.
and proper.
Bi C V1q
Let
and
B C Vq
be the critical loci of
these branched analytic coverings, and introduce the analytic sub-
variety D = 7r1(B1) U 7i'(B) C U ; then Vlq - 7Fll(D) and are dense open subsets of the varieties
and are exhibited by
7r1
covering manifolds of
and
7T
V1q
and
Vq
Vq - v-1 (D) respectively,
as equivalent complex analytic
U-D , so that the restriction
p: Vlq - 7r11(D) - Vq - 7f 1(D) is an analytic equivalence of varieties.
Thus the restriction
p: Vlq
Vq
is a simple analytic
mapping, and the proof is thereby concluded. Corollary to Theorem 20.
p1: V1 - V and
If
p2: V2 - V1
are simple analytic mappings between pure dimensional complex analytic varieties, then the composition
p P
I 2
:
V2 --- V
is also a simple
analytic mapping. Proof.
If
p1: V1 - V
is a simple analytic mapping, then
locally at least there is a branched analytic covering of order
r
such that the composition
analytic covering of order the composition ing of order
r
.
7rplp2: V2 --> U
r , so that
p1p2
71p1: V1 - U
7: V - U is a branched
Then, as in the proof of Theorem 20,
is also a branched analytic coveris a simple analytic mapping as
desired.
It should be observed that a simple analytic mapping
P: V1 -> V
is superficially almost the same thing as a branched
analytic covering of order 1, except of course that the range space
V is not necessarily just an open subset of the complex number space. $owever, there is really quite a considerable difference between
130.
these two concepts; for instance, a branched analytic covering of order 1 is necessarily a complex analytic equivalence, whereas the partial projection mappings in the local parametrization theorem are examples of simple analytic mappings which are not necessarily analytic equivalences.
Indeed, a simple analytic mapping
is not
p
even necessarily a one-to-one mapping. To see how this can happen, select any point in Theorem 20 choose an open neighborhood that there are branched analytic coverings 7T:
of
Vq
q E V , and as
7r1: Vlq > U
Vq -> U of the same order with Vlq = pI(Vq ) and
If the neighborhood
q = 7f 1(7T(q))
V
in
q
such
and
7f1 = 71p
is chosen sufficiently small then
Vq
it 7f11(7T'(q)) = p-l(q) _ (pl)...,ps) C Vlq ;
.
and
applying the localization lemma, it can be assumed that consists of
7r11(U) = p-1(Vq)
such that
pi E Vii)
connected components
s
and the restriction
a branched analytic covering.
If
B1 C V1q
71'1:
V.qW,...,
Vii) --> U
and
B C Vq
is also
are the
critical loci of these branched analytic coverings, then D = 7r1(B1) U ir(B)
is an analytic subvariety of
U-D both
complement
in the usual sense.
'T1
and
7T
U ;
and over the
are analytic covering projection:
Recall from the local rarametrization theorem
that if the neighborhood
Vq
is connected and sufficiently small,
then the point set closures of the connected components c_
TT (U-D) C V1. and of 'T 1(U-D) Viq
and
V
q
Vq
are ana rtic subvarieivies o
^esrecti-,rely, representing the irreducible component:
of the germs of these varieties at the various points Now if
s > 1
,
it is clear that
7!'i-(U-D)
p1,...,pv,c
has at least a connected
].31.
components corresponding to the sequently that
V
7r
components of
s
also has at least
1(U-D)
connected components, so
s
is necessarily reducible at the point of the variety
Vii)
component
q
Moreover the
.
containing the point
Vlq
evidently mapped analytically by
; and con-
7r11(U)
pi
is
to an analytic subvariety
p
V('-) C Vq , such that the restriction
p:
Vii)
a simple analytic mapping; and the varieties
Vq1) Vq1)
is itself
clearly contain
no common irreducible components, so that the decomposition
V
= Ui V91)
is some grouping of the irreducible components of
Vq
q q
at the point
.
Thus geometrically, if
than one point, then nents of
V
is reducible at
at the distinct points of
V1
separate component varieties of V Note that if and if
V C V q -
restriction
p :
p: V1 --> V
p-1(e) q
contains more
and the separate compo-
p-1(q)
are mapped to
.
is a simple analytic mapping,
is an open neighborhood of a point P
(Vq)
VQ
q c V , then the
is also a simple analytic mapping.
Thus it is possible to introduce the notion of the germ of a simple analytic mapping
p: V1 --> V over the germ V of a complex ana-
lytic variety, observing that
V1
may necessarily consist of a
finite number of germs of complex analytic varieties.
132.
point p1:
pl E V1
there is a natural ring homomorphism
--
V p(p
is a simple analytic mapping, then for each
P: VI --> V
If
(b)
It is quite easy to see that this homomor-
p1
V 1
)
phism is an isomorphism into the ring
V
precisely when
(9
Pi
1
p-1(p(p1)) = p1
contains points other than
p-1(p(pl))
For if
.
p1 , the observations made in the preceding paragraphs show that the image under
p
of the germ of the variety
at the point
VI
the germ of a proper analytic subvariety V C V variety
V
f s V QP(pl)
V1
at the point
V16 Pi 1
of the germ of the
which vanishes identically on the subvariety V C V p1(f) = f°p = 0
at t (^
in
V
&
On the other hand,
.
p
1
then the image under
p1 = p-1(p(pl))
vas riety
is
p(pl) ; and selecting a non trivial germ
at the point
it is clear that if
p1
1
of the germ of the
p
is the entire germ of the variety
point p]
p(p1) , and consequently
Now selecting a point
is an isomorphism into
p]
q e V and letting
P-1(q) _ (p ,..,ps) C V , the homomorphisms 1 1
p
i
:
V
q
vi pi
can be considered as determining a single ring homomorphism
P
Vl@
->
q
V
ps
into the direct sum of the various rings
V
0-p
; and this homo-
morphism is clearly an isomorphism into that direct sum ring. Note that when
a proper subring of
s > 1
V
Q
1
p (f) = (fl,...,fs) E
@
Pi 1
V & 1
the image
...
V
V1 1
tD ...
p1
d)
B
p (V(}q) PS
V1 & n -s
;
is necessarily
for if f e V&q and , then
V
133.
fi(pi) = f(pi(pi)) = f(q)
i
.
Even when
is easy to see that
p (V(Qq) =
V1
C
if and only if the mapping p
is an analytic equivalence between the germ of the variety and the germ of the variety
V at
q = p(p)
p
at p
V1
In any case, though,
.
cannot really be too small, in a sense that can
p*( V(La)
the image
s = 1 ,
may be a proper subring; indeed, in this case it
p (V 61q)
the image
is independent of
be made precise through the following discussion.
A relative denominator for the simple analytic mapping
p: V1 -k V
at a point
q e V
d e V 6-
is an element
P*(d)-(V1 (9p1 (D
...
such that
mP ) C P*(Vcq)
37 V
1 p-1(q) = (pl,...,ps)
where as before
relative denominator is an element for any germs
fE
V
f
e
i
V1
Q).
,
pi
e V1 ; that is to say, a
d e V
with the property that
i = l,...,s , there exists a germ
such that p1(d) fi = pi (f) e
c
q
Note that the zero element of
V
6q
Vl
pl ,
for i = 1, ...,s
is a relative denominator, al-
though of course in a rather trivial sense; but at least the set of relative denominators is not empty.
It is clear that the set of all
relative denominators for the mapping ring
V 0q
;
form an ideal in the local
p
this ideal will be called the ideal of relative denomi-
nators for the simple analytic mapping
be denoted by
9,(P)q
p
at the point
q ,
Note further that when "g-(p)q = V
and will
&
,
so
that in particular the constant function 1 is a relative denominator, then
p*(
V&q)
V1
(Q
p1
@
... ®V (Q 1
ps
; but this means that p-1(q) -F
is a single point of V1 , and that the mapping
p: V1 --> V
is an
analytic equivalence between the germ of the variety the germ of the variety
V
at
of the definition, an element
a
,
d e
as noted above.
V
q
VI
Again the zero element of
V Oq
p
and
As an extension
will be called a universal
denominator if it is a relative denominator at the point germ of a simple analytic mapping
at
p: V1 ---> V
q
at the point
for any q e V .
is a universal denominator, and the
set of all universal denominators form an ideal in the local ring (Q q ; .
this ideal will be called the ideal of universal denominators
for the variety
V at the point
q , and will be denoted by
1-9-q
That there are in fact non trivial universal denominators is a conscquence of the following result.
There exists a holomorphic function
Theorem 21.
d
in an
open neighborhood of any point of a p:;_rc; diricnsional complex analyt,i:: variety, such that
is a universal denominator but not a zero
d
divisor at each point of that neighborhood. Proof.
such that W
ing.
and that there exists a holomorphic function
r
which separates the sheets of this branched analytic cover-
The polynomial
r W () e
9
discriminant anccion
of the given point
can be represented by a branched analytic covering of order
7r: W --3 U
g E W QW
Choose an open neighborhood W
k TU[X]
of Theorem 18(a) then has a
dg E k(S L which is not identically zero; and the
is holomorphic on W
d - 7r (dg) e W 1 W
divisor at any point of W that this function
d
.
and is not a zero
The proof will be completed by showing
is a universal denominator at each point of W
135.
p: VI - Wq
Consider therefore a simple analytic mapping of some point
over an open neighborhood Wq
localization lemma the neighborhood Wq
can be so chosen that the
j.ng, although perhaps of order less than function
to the neighborhood Wq
g
pg(X) E k& (W )[X]
polynomial
By the
is also a branched analytic cover-
7r: Wq --> 7f(Wq) c U
restriction
in W .
q
r
.
The restriction of the
still separates sheets, and the
associated to this restricted
q
branched analytic covering as in Theorem 18(a) is evidently a factor
of the full polynomial pg(X) ; hence the discriminant
d' F- k(9
77-(W q)
is a factor of the discriminant
of the polynomial pg(X)
d E k070
so that
d = d'-d"
for some holomorphic function
q)
d" E
Note that
k 07.r(W
7fp :
V1 - 7r(Wq )
is also a branched
q
analytic covering, that the induced function p*(g)
E
V
pp*(g)(X) E
separates sheets, and that the polynomial
a 1
V
a7.so 1
k @7r(W )[X] q
associated to this function as in Theorem 18(a) also has the discriminant
d'
.
p-1(q) = (p3_,-,pr} C V1 ,
If
that the neighborhood s
components
is chosen such that
Wq
VP ,...,V 1
with Ps
it can be assumed
p1(Wq)
consists of
pi E V ; and given any elements i
a-_ter shrinking the neighborhood Wq
if necessary
fi E Vl nl these germs will be represented by holomorphic functions various components
18(b) that
on the
These functions together form a single
V pi
holomorphic function
f. i
f
on
p-1(Wq) ; and it fc=lows from Theorem
can be expressed as a polynomial in
coefficients in k& r(W
)
q
, hence that d' f E p*(W (Q q)
p *(g) .
with
Therefore
136.
E P (W (9q)
so that
,
the simple analytic mapping
p
d
is a relative denominator for
at the point
q
,
and the proof is
thereby concluded.
The terms relative denominator and universal denominator are suggested by the interpretation of these concepts by means of meromorphic functions.
variety
V&q
Recall that at a point
q
of a complex analytic
V at which that variety is irreducible, the local ring
is an integral domain; and the elements of the field of quo-
tients
V
?'Yt
q
of this integral domain are defined to be the germs
of meromorphic functions on the variety V at the point point
q
at which the variety is reducible, the local ring
q
At a
.
V
62 q
is not an integral domain; but it is still possible to introduce of the local ring
the total quotient ring q
\r2
elements of V "lq
V(Qc
,
and the
are defined to be the germs of meromorphic func-
tions on the v-,x iety
V at the point
q
.
To recall this construc-
tion, in case it should not be familiar, introduce the ideal
Vq
C V62q
cons:istirig of all zero divisors it the local ring
the total quotient ring
f/g
where
Vk
is the ring of all formal quotients
q
f c V Vq and g c V Sq -
with the usual defini-
tions of equivalence and of the ring operations. is naturally imbedded in formal quotients
f/l
.
V`
C
V
is irreducible at
Vh q
V
q
as the subring consisting of all
those formal quotients f/g for which f A
when
The ring
q
The units of the ring
is a field precisely when
V
V `C
;
consist of
hence
V
Lq
0 , or equivalently, precisely
q
137.
Now for any simple analytic mapping p1 e V1
points at
pl:
Vl q*
-
V
q = p(p1) e V , consider the ring homomorphism
m
1
pl(g) e
then
and
p: V1 --k V and any
Note that if
g e V 9 q
is not a zero divisor,
1
V
is not a zero divisor either; for
(Q
1
a zero divisor only when
can only happen when
at the point
V1
V mq
is a zero divisor in
*
j
M,
q
---> V rr4 U 1
g
Thus the homomorphism per:
V
V
p' 1
,ps) C V , then the various homomorphisms
p-l(q) = (p1,
pi' V r'
q , hence when
induces a ring homomorphism
V 0 p 1 1
p1 , and that
vanishes on one of the irreducible compo-
g
nents of the analytic variety V at the point
If
is
vanishes on one of the irreducible
pl(g)
components of the analytic variety
p1: V Q 9
pi(g)
p1
can be considered as determining a single
D
ring homomo_ phism
e
...
pl
1
ps
V1
into the direct sum of the various rings
V1
pi
.
As in the case
of holomorphic functions, it is clear that this mapping is always an isomorphism into the direct sum ring; but for the case of meromorphic functions, the existence of a relative denominator which is net a zero divisor implies that this isomorphism is ontc the full direct sum ring, hence that
V!r1q
tinder the isomorphism inator
P
d 6 A9(p)q C V O q
ti VI)IJ
.
p1
...
V ps
To see this, select any relative denom-
which is not a zero divisor in the ring
138.
V
(Vq
and consider any meromorphic functions fi/gi e
'
i = 1,...,s
Since
.
mcrphic functions and
is a relative denominator, there exist holo-
d
f
and
pi(g) =
divisor in
for
V 0q
in
g
such that
evidently
i
V (Pq , and the meromorphic function
the property that
pi(f/g) = fi/g.
for
there will at least exist a meromorphic function pi(f/g) = fir
for
g
is not a zero
f/g e V
'Pt q
has
i= 1,...,s , as desired.
In particular, given any holomorphic functions
that
pi(f) =
fi 6 V ( PC VlrcP i 1 i f/g 6 V 'l q
such
i= 1,...,s ; and indeed, it can always be
assumed that the denominator
g
of this meromorphic function is
any assigned relative denominator a zero divisor in the ring V Q)q
g e AY(p)q C V((!q
which is not
.
As in the case of branched analytic coverings, so also in
(c)
the case of simple analytic mappings is it more convenient to consider direct images rather than inverse images.
If
is a simple analytic mapping, the direct image sheaf
p: V1 - V p*(V a)
is
1
evidently a well defined sheaf of modules over the sheaf of rings
V
Q)
on the analytic variety
variety and
V
V ,
thus an analytic sheaf over the
In a similar manner, introducing the sheaves
V .
V;'(
of germs of meromorphic functions on the analytic vari-
1
eties
V and
VI
respectively, which are clearly analytic sheaves
on their respective varieties, the direct image sheaf
p*(V ?.?
1
is also an analytic sheaf over the variety
V .
Recalling the
139.
p-1 (q) _ {pl,...,ps} C V11
definition of the direct image sheaf, if for a point
q e V
it is clear that
p*(V
a n d that
V
)q
1
.....
p
1
`T " p
1
p p
V
p
1
1
ar, noted earlier, it follows that it is possible to identify the
with the sheaf
p*(V
direct image sheaf
over the variety
V'"(
A
1
is canonically
p*(V M )
V ; that is to say, ,he direct image sheaf
1
isomorphic to the sheaf
VjIrL
V GL C V
Since
itself.
it fol1
1
canonically isomorphic to an analytic subsheaf of the sheaf germs of meromorphic functions on
germs
fi
e
V
0 pi
1 VYIt of
To be quite explicit, an
V .
is described in the usual way by a set of
F e p*( Q ) q
element
is
p*(V
lows that under this isomorphism the direct image sheaf
for
i= 1,...,s
;
there is, however, a unique
1
meromorphic function i= 1,...,s ,
f/g t
and the element
morphic function.
pi(f/g) = fi
such that
V
for
q
F will be identified with this mero-
Thus the elements of the stalk
p*(.
(
)q
will
1
be identified with the set of those merom_orphic functions fig e V'1?
q
such that pi(? /g)
e V Q7
1 that the denominator
g
pi
for
i =1,...,s ; note
can be taken to be any preassigned rela-
tive denominator fps the simp-e analytic mapping that
g
p ,
provided only
is not a zero divisor.
Theorem 22-
Suppose that p: V1 -> V is a simple analytic
Mapping between two pure dimensional complex analytic varieties. (a)
The direct image sheaf
p*(V (Q 1
)
is a coherent
].k0.
analytic sheaf over the variety V
locally isomorphic to a sheaf
of ideals in the structure sheaf V(9
The sheaf J-(p)
(b)
.
of ideals of relative denominators
is also a coherent analytic sheaf over the variety V Proof.
(a)
.
Since the theorem is local in character, there
is no loss of generality in considering merely an arbitrarily small
open neighborhood of some point of the variety V .
Thus as a con-
sequence of Theorem 21 it can be assumed that there is a holomorphic function
V which is a relative denominator at each point
on
d
but is nowhere a zero divisor.
The direct image sheaf
p*(V 1
can be identified with an analytic subsheaf of the sheaf V 711 germs of meromcrphic functions over
of p*(V (V ) 1
`V
of
V , and indeed, the elements
can all be tai en to have th
common denomi-
nator d e V q at any point q c V ; thus ti p'(V1m ) d-p,,( 1(Q ) c V (9 , so that p*(V1(Q ) is isomorphic to a sheaf of ideals over the variety V . ence ot. the sheaf
p*(V 12
)
To demonstrate the coher-
it then suffices merely to show that
1
that sheaf is locally finitely generated.
As consequences of
Theorem 20 and Theorem 19(a), it can further be assumed that there are branched analytic coverings
-hich
7r1 = lip
sheaf over U .
and
7r1: V1 - U
7r: V --> U and
,f1*(V () is a finitely generated analytic
1
Choosing functions hV c i (V1,V m ) = P(U,7r1*(V (L)) 1
which represent generators of the sheaf
7r1*(V (j2)
1 as an analytic
1
sheaf over
for
U , the proof of this portion of the theorem will be
141.
completed by showing that these functions hV E P(Vl,V Q ) N r(V,p*(V ®)) 1 1
represent generators of the sheaf
as an analytic sheaf over
p*(V ( )
q c V let
For any point
V .
1
p-1(q) _ (pl, ..., ps} C V, and Now an element
7r,-17r(q)
_ (pl, ...,psips+l' ...,pt} C V1
is represented by germs
F c p*(V (Q }q
fi
E V
1
1
p. i
i= 1,...,s ; and these germs together with the zero germs
for
for
0 E V & p 1
i= s+l,...,t
represent in turn an element
i
)7.(q)
F E V1*(V
Since the. functions
.
of the analytic sheaf such that
7r1*(V (9 )
= EV gVhV ; but then
hV
represent generators
, there exist germs
fi
= 2'V
gV e UCO 7r(q)
7r] (gV)hV C
V
&p 1
i
for
so that F = £V 7r (gV)hV E p*(V O ) q , and the desired 1 result is thereby demonstrated.
Again as a consequence of Theorem 21 it can be assumed
(b)
that there is a holomorphic function
d
on V which is a relative
denominator at each point but is nowhere a zero divisor, since the The direct
second part of the theorem is also local in character. image sheaf
p*(V
of the sheaf
1 VI'q
-)
can be identified with an analytic subsheaf
of germs of mcromorphic functions on
V ,
and
d-p*(V (q ) is a sheaf of ideals on V . Note that a p*(V Q1 ) 1 1 germ g e V 0 q is a relative denominator for the simple analytic
mapping
p
at a point q c V precisely when
(It is evident from the definition that a germ tive denominator precisely when
p*(V((! 1
with a submodule of V'M q
(9 )qC g c V(Qq
)q c VG q .
Thus if
g
,
is a rela-
identifying
is a relative
142.
denominator, then
©-q ; and conversely if
B )q C 1
ib not a zero divisor ne:es-
d
dg-p*(V Q )q C 1
o )q C V 0q, and hence g is a relative denominator.)
sarily Thus
N (P)q = {g e
64 )q C 1
and since both
d-p*(V 0 )
are coherent sheaves of
and
1
ideals over
it follows that
V ,
of ideals over
V
is also a coherent sheaf
9-(P)
(Although this last step is a standard argument,
.
an additional few words might prove helpful to the beginner. B-) 1
sheaf
is a coherent sheaf' of ideals by the first part
of the theorem; so select finitely many functions
by E P(V,V 6-)
which generate that sheaf of ideals at each point of
ing
V
if necessary.
1'he residue class sheaf
course a coherent analytic sheaf also. c9(p)
The
V , restrict-
,r I/d-V&
is of
The above formula shows that
is the kernel of the analytic sheaf homomorphism
p: V(Y T (DV ( V O/d - V (9) which associates to an element
f e V q the residue classes of
the elements h V f in VO/d-V (9 , hence 5-(P)
is a coherent sheaf
of ideals as desired.) For a simple analytic mapping
Akp)o C V&q subvariety
a point
loc ,i3'(p)q
p: V1 -- V , the ideal
q e V determines the germ of an analytic
of the variety
V
at that point.
Actually,
since 9'(p) is a coherent sheaf of ideals, there is a well defined analytic subvariety
loc ,J (p) (C V
such that at any point
q e V
14}.
the germ of the subvariety
loc (p)q ; for in
is just
loc A9(P)
an open neighborhood of any point of the variety
V there are
finitely many holomorphic functions which generate the ideal
,(P)q C V
6q
at each point
q
of that neighborhood, hence the
set of common zeros of those functions is the subvariety in that neighborhood.
hence at a point image
Recall that at a point
q c V - Joe n¢(p)
q c V for which N (P)q = V 6- q , the inverse
is a single point of
p -!(q)
loc n9' p)
V1
and the analytic mapping p
is an analytic equivalence between the germ of the variety p 1 (q)
a point
and the germ of the variety
V
q e loc n¢(p) , the mapping
equivalence.
p
at the point
V1
at
q ; while at
cannot be an analytic
This can be summarized as follows.
Corollary 1 to Theorem 22.
For a simple analytic mapping
p: V1 -> V between two pure dimensional complex analytic varieties, the set of points of
V
at which the mapping
p
is not an
analytic equivalence is precisely the analytic subvariety
locn7'(p)CV V. At a regular point
P: V1 - V
q E V
a simple analytic mapping
is of course precisely the same thing as a branched
analytic covering of order 1, hence is an analytic equivalence; so
as a consequence of the preceding corollary CV) C V - :! oc r- (p) This can be restated more conveniently as follows. Corollary 2 to Theorem 22.
For a simple analytic mapping
p: V1 - V between two pure dimensional complex analytic varies,
-L44.
be A (P) C J (V) , where as usual the variety
i (v)
is the singular locus of
V .
Applying the Hilbert zero theorem, it follows from Corellary 2 that at any point
q E V ,
1 e(p)q = id be S (P)q D id I(V)q Consequently any germ
f E id J (V)q C V
the radical of the ideal 4 (p)q C V d)q germ p
q
must be contained in
so that a power of the
,
is a relative denominator for the simple analytic mapping
f
at the point
q e V .
This observation is also worth restating
explicitly as follows.
For a simple analytic mapping
Corollary 3 to Theorem 22.
p: V1 - V between two pure dimensional complex analytic varieties, some power singular locus
nator for
(d)
image
p
fV
of any germ
j (V) C V
f e V &q -which vanishes on the
at the point
at the point
q
q
.
p: VI -> V , the direct
Under a simple analytic mapping
p*(V 61 ) at a point
fied with a submodule of the
is a relative denomi-
a
E V has been canonically identi-
V mq -module
functions on the variety
V rnq
of germs of
V at the point
q
.
This
direct image module completely characterizes the germ of the simp=.e analytic mapping at the point
from the following theorem.
q
,
as can be seen readily
145.
Theorem 23.
If
p1: V1 - V and
---> V are germs
p2: V2
of simple analytic mappings over the pure dimensional complex ana-
V at a point
lytic space
q E V , and if
p2*(V 6) )q C pl*(V (¢)q,
2
1
then there is a germ of a complex analytic mapping such that
p2F - pl
Proof.
open neighborhood of the point
and
V2
C
V
variety
V1
are holomorphic
w,l v2
2 on the variety
f1
p2*(wj IV2)q = p1*(fj ) q
.
V1 ,
after q
if
These functions
define a complex analytic mapping F into
hence
;
1
to a still smaller neighborhood of the point
necessary, such that fII...,fn2
are the coor-
p2*(wi IV2)q E P2*(V m )q ( pl*(V (Q )q
there are holomorphic functions restricting
If wl,...,wn2
.
C 2 , the restrictions
dinate functions in functions on
it can be assumed that
q ,
is represented by a complex analytic subvari-
V2
of an open subset of
V2
V to a sufficiently small
p2: V2 - V are simple analytic mappings, and
p1: V1 --k V and
ety
V2
'
Restricting the variety
that the variety
F: V1
from the analytic
C 2 ; and the proof will be concluded by showing
that this is the desired mapping.
Recall that there is a complex
analytic subvariety A C V such that the restrictions
pi: V1-A1 - V-A
and
p2: V2-A2 -> V-A
are complex analytic
equivalences between dense open subsets of the varieties
where
Al - pl1(A)
and
A2 = P2 '(A)
.
V, V1, V2,
By construction, the
restriction of the mapping
F
the analytic homeomorphism
p21p1: V1-A1 -> V2-A2 ; hence by con-
tinuity,
F
to the subset
Vi-A1
itself is a complex analytic mapping
coincides with
F: V1 - V2
146.
such that
p2F- p1 , and that completes the proof.
An immediate consequence of this theorem is then the desired result. Corollary to Theorem 23.
If
pi: V, --> V and
p2: V2 -_> V
are germs of simple analytic mappings over the pure dimensional
V at a point
complex analytic variety Pl*(V
q _ V , and if V1
)q = p2*(V & )q , then the germ of
l
lytically equivalent to the germ of of an analytic mapping
F: V1 - V2
V2
p21(q)
at
such that
Since these direct image modules
ize the germs of simple analytic mappings
at
p1(q)
under the germ
,
p2F = p1
p*(V (V )q 1
p: V1 --4 V , for the
it suffices to determine which submodules of
q
arise as direct images
of p*(V (Q )q C 1 borhood of
q
,
Vg
p*(V ())q
.
.
do character-
V at a
classification of all the simple analytic mappings over point
is ana-
V
N can
It is evident that the elements
are bounded meromorphic functions in a neigh-
at least at those points at which their values are
well defined; and it will be demonstrated that every bounded mero-
morphic function in VA q
is in the direct image
p*(V (,Q )q
for
1
some simple analytic mapping
p: V1 -- V
in a neighborhood of c.
It is first necessary to establish a few further properties of meromorphic functions on an analytic varriety.
On a complex analytic manifold, all bounded meromorphic functions are of course holomorphic; indeed, rather more generally,
it follows from the Riemann removable singularities theorem that
147,
all bounded holomorphic functions on the complement of a proper analytic subvariety of a connected analytic manifold extend uiLcely to holomorphic functions on the entire manifold.
This is not the
case for an arbitrary complex analytic variety, though; but at least the following does hold. Removable Singularities Lemma.
(a).
Let W be a proper
analytic subvarioty of a pure dimensional complex analytic variety V , and let
f
be a bounded holomorphic function in the intersec-
tion of an open neighborhood of the point plement tion
V-W
f c
.
V'lq
such that
Then
f
q
in
represents the germ of a meromorphic func-
; and there is a monic polynomial
pf(f) = 0
V with the com-
in V
pf(X) c VCQq[X]
.
q
Proof.
Since the desired result is of a local character,
there is no loss of generality in supposing that the variety represented as a branched analytic covering
Tr: V ---> U
.
V
is
The
usual Riemann removable singularities theorem shows that the function
f
extends to a holomorphic function on the complex manifold can be assumed to be
R (V) C V ; thus the given function
f
bounded and holomorphic at least on
V-D , where
critical locus of the branched analytic covering.
B C V
is the
Now turning to
the proof of Theorem 18, observe that in that proof it is really sufficient merely that the function on
f
be bounded and holomorphic
V-B ; for the coefficients of the various polynomials con-
structed in the proof of that theorem are then bounded and holomorphic in
U-D , where
D = r(B)
is a proper analytic subvariety
148.
U C e , and hence by the usual Riemann removable
of the domain
singularities theorem once again they extend uniquely to holomor-
phic functions in U
With this observation made, the lemma is
.
then an immediate consequence of Theorem 18.
This lemma can also be described in the following more convenient terms.
A weakly holomorphic function in an open subset
U of a complex analytic variety
V
is a function which is defined
and holomorphic in u n (V) , and is bounded in the intersection of an open neighborhood of any point of U with the regular locus `R(V) ; note that this local boundedness condition is non trivial
only at points of the singular locus j (V) morphic functions in by
U
V &U ; note that
U C R (V) a point
.
.
The weakly holo-
clearly form a ring, which will be denoted
V aU c
V O_U ,
with equality at least when
The ring of germs of weakly holomorphic functions at
q E V will be denoted by
V9
; an element
f e V Lq
of
course need not be represented by a function which is well defined at the point
Vq
q
if
form a sheaf
q e d (V) V
for any open subset
.
The collection of all the rings
- over the variety V ;
and
P(U, Vm)
Note that any bounded holomorphic
U C V .
function on the complement of a proper analytic subvariety of a connected analytic variety phic function in
V
is automatically a weakly holomor-
V .
Now for any germ
f E Aq of a weakly holomorphic func-
tion on the pure dimensional analytic variety
V at the point
q E V , it follows from the removable singularities lemma that
VCJ,
149.
f E V "t q and that f is integral over the subring f/g E V'l q
Conversely, if
V Lq
C Aq
V
a C V /'` q
is integral over the subring
, then a representative function
f/g
is bounded and
holomorphic in the complement of the analytic subvariety represent-
ing be V (9 q g hence
f/g e v&q
in an open neighborhood of the point
q ; and
Thus the removable singularities lemma can be
.
restated as follows. -Removable Singularities Lemma (b).
q
of a
V(Lq
of
For any point
pure dimensional complex analytic variety V , the ring
germs of weakly holomorphic functions is precisely the integral V &q
closure of the ring
in its total quotient ring
With these preliminary observations and definitions out of the way, the result now of interest can be stated as follows.
A germ
Theorem 24.
at a point
q
f e V rn q
of a meromorphic function
of a pure dimensional analytic variety V
tained in the direct image
p*(
V
(Q )
is con-
under some germ of a simple
1
analytic mapping
If f c
Proof. f E p. (V CO ) q
p: V1 --> V
Va
if and only if
f c V6-q
.
is a meromorphic function such that
under a simple analytic mapping p: V1 ---> Vq over
1 an open neighborhood
Vq
of the point
an open neighborhood of the point versely, consider a germ Vq
of the point
lytic covering
Ti:
q
f E V(Qq
q , then
q , and hence .
f
is bounded in
f E V(Qq
.
Con-
Choose an open neighborhood
which can be represented as a branched anaVq -31- U
over an open domain U C C
.
If this
150.
neighborhood is chosen sufficiently small, the variety represented by a complex analytic subvariety U X U' C Ck X Cn-k = Cn , with the point origin, such that the mapping
w
corresponding to the
q
can be represented by a
f
on the variety
f
of an open subset
V9
is induced by the natural pro-
jection U X U' --> U ; and the germ weakly holomorphic function
can be
Vq
Vq
The removable
.
singularities lemma implies that there is a monic polynomial pf(X) e V (0q[X] borhood
such that pf(f) - 0
q
.
If the neigh-
pf(X) c V e
Vq
[X]
such that
pf(f) = 0
Vq ; and moreover, there will. exist a manic polynomial
Pf(X) E
n
(D
U XU
(X3
f - h/g
such that
for some germs
The removable
Pf(X)IVq = pf(X)
also implies that f c
sinbaaariLies
sor.
V
is chosen sufficiently small, this polynomial can be
Vq
represented by a polynomial on
in
where
g,h E V m q
Again, if the neighborhood
Vc
V g
9
, hence that
is not a zero divi-
is chosen sufficiently small,
these germs can be represented by holomorphic functions on
and moreover, there will exist holomcrphic functions such that
GIVq = g
and
HIVq = h
.
G,H E
Vq ;
n
aU XtJ'
Now consider the complex
analytic variety
V0= {(z1,..., zn+,) EUXU' XC{(zl,...,zr_) E Vq;Pf(zn+l) Note that the intersection just the point
V.
n+l-H_0).
fl {(zl,...,zn)Iz1 = ... = z = 0)
q = (0,...,0) F en , hence the intersection
VO fl
finitely many points
zk = 0) (0,...,0,zn+1)
consists at most of the
for which
zn+1
is one of
is
151.
the roots of the polynomial equation from Theorem 9(b) that neighborhood
Vq
dim V0 < k = dim Vq , after shrinking the
the analytic subvariety C U XU'
.
The natural projection map-
further if necessary.
ping U X U' X C- U XU I
V
Pf(zn+l) = 0 ; thus it follows
induces a complex analytic mapping p from V0 C U X U' X C onto the analytic variety
Since this projection mapping even induces a proper
q
light mapping from the subvariety c U X U' X CIPf(zn+l)
that the restriction V0
p
-
onto
0)
U X U'
it follows
,
of this mapping to the closed subvariety Introducing the complex analytic
is also proper and light.
subvarieties
AO = ((zl,...,zn+l) e V0IG(z1,...,zn) = 0) Aq = ((zl,...,zn)
note that
Vq-Aq
e VgJG(zl,...,zn) = 0)
identi::ally on any component of
The function
Vq-Aq , and
pf,(f) = 0
GIVq
g
and hence does not vanish
Vq
Vq
,
Vq , since
is a dense open subset of
is not a zero divisor at any point of
holomorphic on
and
f = h/g
at all points of
is
Vq-Aq
consequently the mapping which associates to any point (Z1,...,zn) E Vq-Aq
the point
is an analytic marring
(zl,...,zn,f(zl,..Izd) e U X U' X C
F: Vq-Aq - V0-A0
.
This mapping F
clearly one-to-one, and has as its image the entire variety since for any point
(z1,...,zn+l) c VO-A0
is
VO-AO
necessarily
Zn+l = H(zl, ..,zn)/G(z1,...,zn) = f(z1,...,zn) ; and-the composition P"F: Vq-Aq
Vq-Aq
is the identity mapping, so that the restric-
152.
tion
p: VO-AO
Vq-Aq
is an equivalence of complex analytic
This is almost enough to show that
varieties.
p: V0 -> Vq
is a
simple analytic mapping, except that it has not been verified that VO-AO
is a dense open subset of
not necessarily true.
Thus it is necessary further to introduce
the analytic subvariety components of
V0
V0 ; but the latter assertion is
V1 C V0 C U X U' X C
of pure dimension
k
consisting of those
on which the function
G
does not vanish identically, and the subvariety
A
1
= ((zl,...Izn+1) E V1IG(z1,...,zn) = 0)
The restriction of
p
light, analytic mapping
to the subvariety p: V1 --> Vq
.
.
is still a proper,
V1 C V0
Clearly
V1-A1 C V0-A0 ;
and since the variety
V0-AO
is of pure dimension
neighborhood of each point, necessarily indeed
V1-A1 = V0-A0
V0-A0 C V1-A1 , so that
p: V1-A1 -> Vq-Aq
and the restriction
hence an equivalence of complex analytic varieties. V1-A1
is evidently a dense open subset of
p: V1 -> Vq
V1 ,
is a simple analytic mapping.
constructed that p (f) = zn+llV1 r
(9V
V1
in an open
k
is
In this case
so that
This mapping was so
,
and hence
f E p*(V
)Q;
and that suffices to conclude ,he proof of the theorem. The first consequences of this theorem are some simple additional properties of the weakly holomorphic functions on a complex analytic variety.
153.
Corollary 1 to Theorem 24.
If
d c V aq
is a universal
denominator an a pure dimensional complex analytic variety V ,
then
C V(D A
Proof.
Given any germ
f E V 0q
,
it follows from Theorem
p: Vi -> V
24 that there exists a germ of a simple analytic mapping f c p*(V
such that
; hence
)q
d-f c V (V q , recalling the defi-
nition of a universal denominator.
On a pure dimensional complex
Corollary 2 to Theorem 24.
analytic variety V, V (Qq
of V'M
V Q q-submodule
is a finitely generated
.
Proof'.
Selecting a universal denominator
d c
V
which
61
q
is not a zero divisor, and recalling the conclusion of Corollary 1,
note that as V 0 a -modules ti C
V(9 q
that is to say,
V
q
c
V
0 q is isomorphic to the ideal hence is necessarily finitely generated.
d-
V
V
c
q
C
V
One approach to the classification of simple analytic mapPings over a pure dimensional complex analytic variety then follows from this next corollary and the corollary to Theorem 23. Corollary 3 to Theorem 24.
On a pure dimensional complex
analytic variety V , the submodules from germs of simple analytic mappings the submodules of
V Q+q
of the form
germs of weakly holomorphic functions
p*(V (Q )r; C V '' f q
p: V, - V V (Vq[fl,...,frI f1,...,fr
arising
are precisely for some
in VSq .
1)4.
Proof.
If
P: V1 --> V
is the germ of a simple analytic
mapping, it follows from Theorem 24 that
of V Q
p*(V
is a submodule
)q
this submodule is necessarily finitely generated, as a
;
9
consequence of Corollary 2 to Theorem 24, and if module generators, then clearly
f1,...,fz
are
p*(V m ) q = V m q[fl,...,fr] 1
Conversely, consider a submodule V(Qq[fl,...,fr] C
V
0q
It
.
follows from Theorem 24 that there exists a simple analytic mapping
p1: V1 --> V such that
f1 c pl*(V Q) 1
from the proof of that theorem that
)
q
indeed, it is evident
;
ti
pl*(V m )q
V
1
simple analytic mapping
(The
Qq[fl]
p1: V1 - V arises from a partial pro-
jection mapping, as in the local parametrization theorem; the function
fl
appears as the restriction of the coordinate
and there is a mc:_r_c nclyncmial in variety
V1 ,
f2...,fr the variety
in the ideal of the
zll+1
so the argument is as on page 15.)
induce weakly analytic functions V1
.
At each point of
be repeated, using now the function analytic mapping
The functions
p1(f2),...,p1(f
pI (q) C V1 p1(f2)
;
on
the argument can
there results a simple
p2: V2 -> V1 , and the composite
is a simple analytic mapping such that
zn+1
(P1P2)*(V 2
plp2: V2 --> V )q
V
q[fl'f2]
The iteration of this argument then yields the proof of the desired
result .
(c)
There is another, more geometrical approach to the classi-
fication of germs of simple analytic mappings
pure dimensional complex analytic variety
V
p: V1 --> V over a at the point
q e V
155.
Since the ring Va q
of germs of weakly holomorphic functions is a
finitely generated V(Qq-module by Corollary 2 to Theorem 24, it follows from Corollary 3 to Theorem 24 that there exists a germ of a simple analytic mapping
p: V ---> V at the point
q e V such that
q = Vm q ; and it follows from the corollary to Theorem 23
p*(^
that this simple analytic mapping is uniquely determined up to analytic equivalence.
The simple analytic mapping
p: V -> V will
be called the normalization of the germ of the complex analytic variety
V at the point
the point p: V
q
V
q c V .
The germ of the variety V at
will be said to be normal if this normalization is an equivalence of analytic varieties; thus the germ of
the pure dimensional variety
V at the point
q
is normal precisely
when Vmq = Vmq , that is, when every g rm of a weakly holomorphic function is holomorphic.
The normal germs are just those germs of
complex analytic varieties for which the Riemann removable singularities theorem holds in the same form as for complex manifolds.
More algebraically, it follows from the Removable Singularities Lemma (b) that the germ of a pure dimensional complex analytic vari-
ety V at a point
q
is normal if and only if its local ring
is integrally closed in its total quotient ring. if
p: V T V is the normalization of the germ
V(9 q
It is clear that V ,
then V
is
itself a normal analytic variety; for the simple analytic mapping P
induces an isomorphism between the rings of weakly holomorphic
functions on V and on V .
156.
The normalization
p: V -> V is in a very natural sense
the maximal simple analytic mapping over the pure dimensional variety
V at the point
q E V
.
For if
p1: V1 --> V
is any germ of
V at the point
a simple analytic mapping over the variety
then of course pi*(V C )a C VQq = p .(V-( )a
;
q e V
it follows from
1 Theorem 23 that there exists a complex analytic mapping such that
p1F = p
analytic mapping.
over the variety
,
and it is clear that
F
F: V -_> V1
is itself even a simple
Consequently all the simple analytic mappings
V at the point
q
are necessarily factors of
the normalization mapping; a geometrical approach to determining all the simple analytic mappings consists in finding the normalization and then examining the possible factorizations of the normal-
ization. The r ,'clam is still a non tri z al one in most concrete cases, but can be considered as somewhat better understood than before.
No attempt will be made here to discuss this classification
in further detail; but to round off the discussion, a few general properties of the normalization and of normal analytic varieties will be considered briefly. It is evident that a normal germ of an analytic variety is
irreducible; for if a germ V of an analytic variety is reducible,
then l (V)
has at least two connected components, and the func-
tion which is identically
0
on one component and identially 1 on
the other cempcnents is weakly holomorohic but clearly not helomorphic.
Thus the normalization
p: V - V
involves at least the
splitting apart of the separate components of the germ V ;
the
15Y.
connectdd components of the germ V
correspond to the irreducible
Actually somewhat more can be said,
components of the germ V . and will shortly be said.
Considering the normalization
p: V --> V of a pure dimen-
sional germ of analytic variety, represented as a simple analytic mapping
p: V -k V between two complex analytic varieties, there
are analytic sub,rarieies tion
A C V and A C V such that the restric-
p: V-A - V-A is an equivalence of complex analytic varie-
ties; consequently there is a well defined analytic mapping cp:
V-A -. V-A which is inverse to the mapping
V
Assuming that
p: V-A - V-A
is represented by a complex analytic subvariety
V of an open subset of
,
the component functions of the map-
ping
M,
are evidently weakly holomorphic fanctions on
thus
(p
can be viewed as a weakly analytic mapping
which is inverse to the mapping
ping p
.
p: V ---> V .
V ; and
(p: V - V
Of course the map-
is not necessarily a well defined mapping outside of the
regular locus
''(V) C V ; but in some cases it can be defined
everywhere on
V , as can be seen by use of the following auxiliary
result.
Irmma.
If
f
plex analytic variety q e V , then
f
is a weakly holomor-phic function on a com-
V and if
V
is irreducible at a point
extends uniquely to a continuous function on
X (V) U q C V . Proof.
If
f
is weakly holomorphic near
q , then by the
Removable Singularities Lemma there is a monic polynomial
158.
pf(X) E V 0V [X]
in an open neighborhood
of
Vq
in
q
V
such
q
on R (V)
pf(f) = 0
that
equation
pf(X) = 0
If the distinct roots of the
.
at the point
are
q
X1, ...,Xr , and if
are arbitrary disjoint open neighborhoods of these sepa-
U1,...,Ur
rate points in
C , then the roots of the equation
lie in the union Vq
fl Vq
U1 U ... U Ur
at all points of
pf(X) = 0 will Vq
provided that
is chosen sufficiently small; for as is familiar, the roots of
a monic polynomial are continuous functions of its coefficients. If
V
is irreducible at the point
be so chosen that function
f
in
Vq
can
is connected; the values of the
Vq fl R (V) Vq fl k(V)
q , the neighborhood
must therefore be contained in a single
neighborhood Ui , and defining
f(q) = Xi
continuous extension of the function
f
to
clearly yields the unique (V
A
(V)) U q
.
q
That suffices to conclude the proof.
Now if the analytic variety
V
is irreducible at every
point, it follows from the preceding lemma that any weakly holomor-
phic function on V automatically extends to a continuous function on the entire point set
V .
defined continuous mapping
In this case, then, there is a well cp: V ---> V which is weakly analytic
and is inverse to the normalization; so the variety V and its normalization are then homeomorphic as topological spaces, differing only in that
V has more holomorphic functions than has
in the obvious sense.
V
Of course, similar assertions hold for any
simple analytic mn,_ping p1: V1
V , since as noted any such
mapping is a factor of the normalization mapping
P: V - V .
159.
Even though no attempt will be made here to discuss normalization and normality in detail, one specific property really must in all conscience be mentioned, namely, that the set of points at at which a pure dimensional complex analytic variety is not normal form a proper analytic subvariety.
This has a number of rather For instance, this pro-
striking consequences and reformulations.
perty is really equivalent, modulo results just established, to the property that the set of points at which a pure dimensional complex analytic variety is normal form an open set.
tion holds, then in the normalization at a point
V ,
q
the variety
If this latter condi-
p: V --> V
of the variety V
V will be normal at all points,
after restricting V to an open neighborhood of the point q
if
necessary, and it then follows from Corollary 1 to Theorem 22 that the variety
V
is normal outside of a proper analytic subvariety;
the converse is of course quite trivial.
Another equivalent pro-
perty is that the sheaf of germs of weakly holomorphic functions on a pure dimensional complex analytic variety is a coherent analytic sheaf.
If this last condition holds, then the sheaf of germs of
universal denominators has stalks d q = {f e V& g If. V m g c so is a coherent sheaf of ideals over
V
V
®q
as in the argument at the
end of the proof of Theorem 22(b); and the set of points at which
the variety V
is not normal is the locus of the sheaf of ideals
, hence is a proper analytic subvariety of
V .
Conversely,
assuming that the property holds as originally stated, then in a neighborhood of any point of the variety
V
the sheaf
V
of
16o.
weakly analytic functions coincides with the direct image sheaf
p( B)
V
, hence
of Theorem 22(a).
is a coherent analytic sheaf as a consequence
Yet another equivalent property is that the sheaf
of germs of universal denominators is a coherent analytic sheaf. F`r if this last condition holds, the set of points of the analytic variety
V
at which the variety is not normal, which is the locus
of the sheaf of 'deals nQ
,
is a proper analytic subvariety of
V
conversely, assuming that the property holds as originally stated,
the sheaf 4 of universal
in a neighborhood of any point of V denominators coincides with the sheaf
,gy(p)
of relative denomi-
nators for the normalization, and hence is a coherent analytic sheaf as a consequence of Theorem 22(b).
Finally, note that as a
consequence of this property a pure dimensional complex analytic variety which is normal at a point
q
is normal and hence irreduc-
ible at all points in an open neighborhood of normalization
q ; hence in the
p: V --> V , the reducible branches of the variety
V are separated a
all points.
It was noted earlier that
V may
be irreducible at a limit of points at which it is reducible, so that this splitt'ng into irreducible branches is rather non trivial.
The restriction co pure dimensional complex analytic varieties is not essential, but is merely a consequence of the fact that the present discussion of simple analytic mappings was limited to the case of pure dimensional complex analytic varieties for the sake of convenience.
Noting that any complex analytic variety can be writ-
;en as a union of pure dimensional components, and that the natural
161.
normalization of the entire variety is the disjoint union of the normalizations of these separate components, the extension of the discussion to analytic varieties which are not necessarily pure dimensional is quite obvious.
A beautifully simple and direct proof of this property, due to Grauert and Remmert, is as follows. Theorem 25.
The set of point's at which a pure dimensional
complex analytic variety is normal form an open subset.
Since the theorem is of a local character, there is
Proof.
no loss of generality in restricting attention to an open subset of the variety for which there exists a holomorphic function such that
V
d
is a universal denominator but not a zero divisor at
d
Introduce the analytic subvariety
each point of V . W = {z e Vld(z) - 0)
;
and let Pt be the sheaf of ideals of this
analytic subvariety, so that A is a coherent sheaf of ideals in the structure sheaf
.
( ,(Lz, LIZ )
aTrz = Hom
Az
V0
For each point
z
e. V the set
of module homomorphisms from the ideal
V6 z into itself is a well defined module over the local ring
V mz ; and the set of all of these modules form a coherent analytic sheaf
aU- over the analytic variety V .
(The proof of this asser-
tion is straightforward, and will be left to the reader.) that to any germ
morphism
X.
c
g e V (Oz
Note
there is naturally associated the homo-
defined by ?. (f)
this then establishes an inclusion
gf for any f c R_ z
V z' , which evidently
162.
corresponds to a sheaf inclusion
V
any elements X e Zz and
f e ,U(.z C V
zero divisor, the quotient
.(f)/f
meromorphic function at the point 0z , the product ment g E ,QZz c V
Note further that for
(Q C
for which f is not a
`
is a well defined germ of a z
; and that for any other ele-
g'(%(f)/f) _ X(fg)/f = x(g) E IAz C V(Qz
,
homomorphism.
A(f)/f
The meromorphic function
(?(f)/f). ,OZz c &z
perty that
over the subring tion.
V
&z C V
since
is a module
thus has the pro-
and consequently must be integral
,
hence a weakly hollomorphic func-
z
It is apparent that the resulting germ
independent of the choice of the germ
f e
results a natural inclusion Z_ c V(QZ
R-z
X(f)/f C V (Qz ,
hence that there
The resulting inclusion TT(Q [ -c
.
is
corresponding to a sheaf
z
inclusion Z-c V (Q
.
V
is
8
clearly the natural inclusion of the holomorphic functions into the weakly holomorphic functions.
To conclude the proof, it is only
necessary to show that the variety
precisely when
V
S
z
= olr,
V
is normal at a point
z e V
for if V is normal at a point
;
q r V,
so that V®q = M q , that from the coherence of the sheaves
and
Zr'
it follows that
neighborhood of
hoed of
q
q
,
V B z
hence that
d'z for all points V
V
of an open
z
is normal in an open neighbor-
.
Now if
V
so that necessarily
is normal at a point z c V , then V&z V 0z =
Conversely, suppose that °
net normal at the point
z c V, so that
V0
z
C
V 3z
.
V"Sz V
$Y the
is
163.
Hilbert zero theorem, Nfor some power point V
z
z
V ; and since PV
, necessarily
S _'d , hence N` C Vz d
= id W = d
is a universal denominator at the
V Qz C V m
z
Choose the least integer .
for which the latter containment holds, noting that
z-1.V0z thus NLz V'"z c V0z but Z V & z , so that weakly holomorphic function g c'& (9z for which Note that for any germ
gr
E
Pz-1
V6z
z
f c U(._
9-f E
z.
such that X /
g / VS' .
it follows that
gf
and since
Z _z
g
is everywhere bounded,
necessarily vanishes on W , hence
Thus multiplication by V (Qz
there is a
c u`z Vmz c V(Oz ; actually, since f van-
ishes on the subvariety w C V the analytic function
V > 1
)
so that
g
is a homomorphism k E
V
z
earlier, that suffices to conclude the proof.
As noted
.,
164.
INDEX OF SYMBOLS
Page
1
n
vm
65
a7
148
nWJ
2
VW/
70
n r, r
2
V)),
136
v
(p)
(
119
133 134
oO
105
,laz.
41
(v)
47
(v)
73
(v)
73
id V
dimq
9
53
dim v imbed dim V
80
8'i
165.
INDEX
Analytic subvariety, Analytic variety,
8, 71
69
Branched analytic covering, ---- , branch points of,
---- , order of,
Branch points, ---- ,
98
105
104
29, 105
accidental or essential,
110
Canonical equations for an ideal, first set, ---
,
second set,
Canonical ideal, ----
,
22 22
restricted,
22
Codimension of a subvariety,
83
Coordinate system for an ideal, regular, ---
,
strictly regular,
Critical locus, ----
21
for a branched analytic covering,
.universal,
133
82
Dimension, of an ideal (with respect to a system of coordinates), of a prime ideal,
3, 81 Direct image of a sheaf,
regular
13
53
---- , of a germ of subvariety, ---- , of a germ of variety, 80
----
98
134
Depth of a prime ideal,
---- ,
13
27
Denominator, relative, ---- ,
16
53
pure,
119
Cerm of an analytic subvariety.
---- of all analytic variety, Height of a prime ideal,
8.
64
82
Hilbert's zero theorem (Nullstellensatz),
42
166.
Imbedding dimension, of an analytic variety, ---- , of a local ring, Krull dimension,
95
86
Localization lemma,
99
Mapping, between germs of subvarieties, ---- , between germs of varieties, Meromoriahic function,
Nakayama's lemma,
63
9'i
2, 136
88
Neat germ of analytic subvariety,
93
imbedding of a germ of variety,
----
87
Normal analytic variety, Normalization,
155
Oka's theorem,
6, 76
Regular analytic variety,
93
155
73
----
local ring,
----
point of a variety,
----
system of coordinates for an ideal,
----
system of parameters for a germ of variety,
96 73
Sheaf, analytic, ----
,
57
6, 75
coherent analytic,
7, 77
----
of germs of holomorphic functions,
----
of ideals of a subvariety,
----
,
66, 69
47
69
structure,
Simple analytic mapping, ---- , germ of,
127
131
Singular point of a variety,
73
Strictly regular system of coordinates for an ideal, Subvariety,
109
147, 149
Removable singularities lemma, Semicontinuity lemma,
13
8, 71
System of parameters for a germ of variety,
101
21
16
Total quotient ring, Variety,
136
69
Weakly holomorphic function,
148
Weierstrass division theorem, ----
polynomial,
----
preparation theorem,
3
4
4