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with center at the origin and by using the Riemann mapping function z =
(Z)| < —*• and so, we can expect that the convergence of the expansion (3.11) will be faster than that of the original one (3.1). By this idea, Takahasi-Mori-Sugihara (see the references J = 1,2,3 if
7 0 < + o o , ni = 0,Ni,
t = 2,3;
(156)
"3,"2
vj{L)=
iff , j = 1,2,3 if
'3vj2(x1)=0(l), if
IL <+oo,
m=0,Nu
Xl^0+,j
= 1,2,3,
* = 2,3;
= +oo, Hi = 0, Ni, i = 2,3;
7Q
(157)
(158)
i3
Vj2(xi) = 0(1), X! -> L - , j = 1,2,3, if iz = +co, rii = 0, JVj, i = 2,3;
(159)
"3,"2
Zim / i ^ / i ^ X i ^ x i ) 3
Nk
Jun+ A . ^ ^ ^ ^ X i - A . E £ ^<S/fc2S+(<5jt3 + l ) n 2 + l fc=2 s=rifc + l
>,i5t;3S+(<5fc2 + l ) n 3 + l t —1 tfc flo ft. 0 .s fc
^k2n3+Sk3S,6k2S+Sk3ni U,-
Ni LSi2S+(5i3 + l)n2 + l,(Si2
+ l)n3+6i3S+l,-lnLi
ft"1 6,
fljlA/J + <%(<^'2 + Sj3)ll «i2n 3 +6i3«,4i2S+*i3n2 U «3l«+«j2+«j3
S=Ui + l
)
"3,"2
= V°,
n
3,n2
J = 1,2,3, if J 0 < + o o , ni=0,Ni,
t = 2,3;
Km /£ a WJ 3 X y (a;i) = Vf, J = 1,2,3,
x\—+L
if
7L<
+oo, n$ = 0, Ni, i = 2,3;
(160)
(161)
238 "3,712
where
713,7*2
713,712
7*3,712
,7*2
are given constants,
f
7*3,7*2
I™ := J h22n2~1(T)h32n3-1(T)dT,
e = const > 0.
L-e
The boundary value problems (BVPs) (151), (152), (156), (157); (151), (152), (156), (161); (151), (152), (157), (160); (151), (152), (156), (159); (151), (152), (157), (158) are uniquely solvable (here we do not take care to make precise the appropriate classes of solutions). The problem (151), (152), (158), (159) is solvable up to the rigid-body motion. If in a neighbourhood of a cusped end stresses are bounded then at the above end all moments of the stress vector will be equal to zero. Non-zero stress vector moments given at a cusped bar end mean that this end in the three-dimensional case is loaded by a concentrated surface force, and concentrated moments of the corresponding order. In the dynamical case we have to add to the boundary conditions (156)(161) the initial conditions (154) since hi{x\) > 0, i = 2,3, for t = 0, x\ G ]0, L[, and, therefore, the system (151), (152) is not degenerate for such (xi,t). The (0,0) and (1,0) approximations have been considered in Sections 2.3 and 2.4, respectively. 2.3
(0,0)
Approximation
In the (0,0) approximation the system (151), (152) will have the form ( / i 2 M , , i ( i i , t ) ) , i +°Yj = XJlph2h3dVj^t\ 00 t) hi{x\)hz{x{)
°.°
W-(T,
j = 1,2,3,
°'° X? \ + 2fi
°'°
(162)
°'° X? \i
Let us consider the static case of (162). Obviously, X\
T
dr
/
r°>°
Xl
• f
dr
M^/^WM*M+4' „.o
„o
To
(I63)
239 x° = const e]0, L[,
cPa = const, a = 1,2, j = 1,2,3.
Let further t>j(0)=y>S
if
«,-(£) = ¥#
%°<+co,
if
/L<+OO,
j = 1,2,3,
(164)
j = 1,2,3,
(165)
^•(ari) = 0(1),
^i^0+
if I 0 = + o o , j = l , 2 , 3 ,
(166)
w,-(x1)=0(l),
n - L -
if 7 L = +oo, j = 1,2,3,
(167)
X y ( 0 ) = A . - ^ / i s ^ i U ^ o = V-,0 if ^o < +oo,
j = 1,2,3,
(168)
X y ( L ) = Xjhihsvj,!^^ = ipf if 4 < +oo, y!-. V^. %, ipf, j = 1,2,3, are given constants.
j = 1,2,3,
(169)
0,0
0,0
0,0
Let Yj G L([0,L]), and if IQ = +oo (II = +oo), let it be such that the iterated integral in (163) is bounded by x\ —> 0+ (L-). If - — — is locally summable in ]0,L[, then from (163) it follows that /i2 • A3
for regular solutions (VJ G C 2 (]0,L[)) only the following problems are wellposed: (162), (164), (165) (VJ G C([0,Z,])); (162), (166), (165) («,- G C(]0,L])); (162), (164), (167) (VJ G C([0,i[)); (162), (166), (166) (VJ is bounded); (162), (164), (169) (Vj G C([0,L[), /i2/i3«,M G C(]0,L]); (162), (168), (165) (Vj G C(]0, L}), /i2^3Uj,i € C([0, L[); the mixed problems when on the one end of the bar for some displacement components the Dirichlet and for others either the Neumann or (166), (167) type conditions are given but on the other end for first components either the Neumann or the Dirichlet or (166), (167) type conditions and for the second components the Dirichlet conditions (the Neumann and (166), (167) type conditions are not admissible) are given, are well-posed. In the case (162), (166), (167) we have got the solution up to the rigidbody translation {c\ = 0, c\, j = 1,2,3, are arbitrary). It should be so since in this case the bar under consideration as a three-dimensional body is loaded 0,0
only by surface forces (which are included in Yj) acting on the lateral surfaces of the bar. All other BVPs have unique solutions and constants c£, a = 1,2, j = 1,2,3, can explicitly be calculated.
240
Remark 2.3.1 Let 2hi(x1) = hl0x^L(L - xi)5i,
hl0 = const > 0, «*, 5i = const > 0, i = 2,3.
Then we can give transparent geometric interpretation of setting of above BVPs. To IQ(IL) < +oo there corresponds K2 + K3 < I (82 + 53 < 1), and to IO(IL) = +00 there corresponds K2 + K3 > 1 (82 + 53 > 1). If at least one of the bar profiles and projections has a sharp cusp (see the definition in 4 ) , i.e., K2 + K3 > 1 (82 + 83 > 1), then at this end the components of the displacement vector can not be given. If both the profile and projection have blunt cusps (see the definition in 4 ) and K2 + K3 > 1 (62 + 53 > 1), then the same is true but for K2 + K3 < 1 (62 + S3 < 1) the above components can be given. If
— has nonsummable singularities in ]0, L[ then only arbitrary three /12 • /13
(but one for any fixed j) out of six conditions of (164), (165) can be given (in particular, it contains cases when either only (164) or only (165) can be given). If 2hi := h°x"\
h°, a{ = const > 0, i = 2, 3,
(170)
equations (162) are of the type of (1) for which the conditions (8), (20), (36) are fulfilled since in case of (162) the coefficients a, = 0,i = 1,2,3 in (1), where h := /12/13 and (170) holds. Hence, Theorems 1.1.1 and 1.1.2 are valid for (162). Therefore, the edge x\ = 0 of the bar can be fixed only if a = 012 + ct3 < 1.
More precisely, without loss of generality we can assume L = l, °
j>j(x1)=0,
v>5 = 0, ^ = 0 , 7 = 1,2,3.
Then, if 0,0
YjZWl
or Z, 2ih _i,
there exist unique strong generalized solutions Vj(xi,t)&W+
or L2,h, j = 1,2,3,
of the initial boundary value problems (162), (170), (154) when N2 = iV3 = 0, (164), (165) and (162), (170), (154) when N2 = NZ = 0, (166), (165).
241
2.4
(1,0)
Approximation
Let us consider a symmetric (2/tj = 0, % = 2,3) bar in (1,0) approximation. In view of (151), (152), the corresponding complete system of equations has the following form: ~2°'°
0,0
(A + 2n){h2h3°vhl),1
+3A(/i 2 /i 3 u 0 3),i + i i ° = P^hs-^-,
021'0
1,0 1
X
0
v(h2hl v3A)A-3(\+2iJ,)h2h3 v3-\h2h3 vhl+hsX$
(171)
dt2
= ph2h3—^, 2 ' dt
0, oo ° d2°v°2 p.(h2h3 v 2 ,i),i + X% = ph2h3 ,
(172)
(173) a21'0
10
tf\?-.\ . ^2.hA3 . 1v^ .2 x y 0 _= ph , ,2hi—^-, ,,^3^A*(^2fci * 2,i),i. _- Q 3ph + .h.3X% at2
(174)
0
0,0
g2
^
p.(h2h3 v 34)4 + 3p(h2h3 v i),i + X% = ph2h3—^-, 1,0
(175) Q2^°
(A+2^)(/i 2 /ii 1 A,i),i-At/i2/i3 0 t' 0 3,i-3/i/i2/i3 1 w 1 + /13X? = ph2h33-Qp-,
(176)
In the static case, BVPs for equation (173) have been solved in Section 2.3. Therefore, for this equation, e.g., the Dirichlet problem is well-posed only 0,0
0,0
if Jo < 00, II < 00. For the same reason for (174) the Dirichlet problem is 1,0
i,o
correct only if Jo < 00, II < 00 (see also 15 , 3 4 ) . Hence the approximate value of . . lo,o . . 3a;3i,o . . 102(3:1,0:2, ar3) w - v 2{x1) + - 7 - v 2(2:1) 1,0
,„„„•. (177) 1,0
can be preassigned at the ends of the bar only if Jo < +00, II < +00. Systems (175), (176) and (171), (172) can be correspondingly reduced to the following systems 10 00 _ _ 3fj, v ! = -n v 3,1 - h2 1(x1)h^1(x1)
I 7°'° / X${x1)dx1
V?
I - C\
,
/
C\ = const, x® e]0,L[,
242 0,0
,0,0
(A + 2/j,)(h2hl v X + 2/j,
t^
3,H),II
1,0
= 3X3° + 3(ft3-X-i),i
h2h\ h^hz1 jxl{xr)dXl
-
h^h^G
J,n and 10 00 3Xv3 = -(A+2/x) v i.i-h^ixi^in)
/ f°'° / X^{xl)dx1
0,0
(A + 2n)fi(h2hiv0,0liU),n ( h2h\
- 12(A + p)p(h2h3 v
,'o,o \ X^(x!)dxi
x
h2-\hl
\ - C2 \ , C2 = const,
hl)A
\
\
1
- C2 (ft^AJ )
1
An (A+^ X o + _ ^ x o + S A ^ X i A + 2/i A + 2/x The advantages of these systems consist in the following: the second equations +12
involve only one unknown function and after their solution (see ? ) , v \ and 1,0
v 3 can be readily calculated from the first equations. Now, let us come back to the dynamical case. The system (171), (172) was considered in Section 1.2. Literally in an analogous way can be considered the mixed problem for the system (175), (176). Introducing the notation
=
0,0
1,0
«V«i
0,0
,
F:=
1,0
Xl h3X$
this system can be rewritten in the folllowing form Lu = (Aut)t - (Bux)x
(178)
+ (Ciu)x + C2ux + C3u = F,
where 'ph2h3 0
0 \ ph-ihl)'
5
( ph2h3 0 \ 0 (A + 2n)h2Ki33
>
243
Ci =
3p,h2h3 0
0
C2
r =(° ° 1
°\
3 ^h2h3 OJ' V° 3/i/i 2 /i 3 ;' For the system (178) in the domain JD we consider the mixed problem under initial and boundary value conditions du(x, 0) (179) u{x,0) = 0, = 0, 0 < z < l , dt
0,0
1,0 "1
(180) 0. r . (•>2+ "3) r.„ Below the spaces J5, E*, W+, W+, W_, W l , are the same as for the problem (84)-(86) and in an analogous way we can introduce the notion of the strong generalized solution u of the problem (178)- (180) in W+ and L2^. The folllowing theorem is correct. Theorem 2.4.1 Let the conditions (83), (107), (108) be fulfilled and let either pa > p*, where p* = p*(\,p1,a2,a3,htj,T) be sufficiently large positive number, or let T be sufficiently small, i.e., T < 7b(A,/z,0:2,^3, /i*). Then for any F S Wl there exists a unique strong generalized solution u of the problem (178)-(180) in L^^h for which the estimate 0,
v3
3
c u
< \\F\\W.
u
2,h
holds. If F £ L2,h-1 C Wl, this solution will be also a strong generalized solution of the problem (178)-(180) in W+. Now, under the condition (83) let us consider the split system (173), (174). Assuming v ••
0,0
/ 0,0
1,0
,F=
1,0 \
[X$, h3X$
for the system (173), (174)
in D, we consider the folllowing mixed problem «(a;,0)=0,
dV 0)
^' at
=0,
0
(181)
and 0,0
= 0
v2 r»„
1,0
v2
0.
(182)
r.(«2+3<,3)
There holds Theorem 2.4.2 Let the conditions (83), (107) be fulfilled. Then for any F € Wl there exists a unique strong generalized solution v of the problem (181), (182) in L2,h for which the estimate c\\v\\r
< \\F\ w
244
holds. If F G L2,h~1 C W^, this solution is also a strong generalized solution of the problem (173), (174), (181), (182) in W+. Now, let us consider all the above systems (171)-(176) together as the one system for U = (Ui,U2,u3;v1,V2,v3),
(
Ui = Vi,
0,0
0,0
0,0
1,0
Wj = Uj, 1,0
4=
1,2,3,
1,0 \
X
l, X2 , X3 ; /l3Xj , / l 3 ^ 2 > ^3-^3 J
in the domain D under homogeneous initial boundary value conditions dU( 0) 1,0 g'
0,0I7(x,0) = 0, V i = 0,
vi
r,„
=0,= 0,0
(183) (184)
In this case for the vector-function U the spaces E, E* are introduced in a similar way as. Let W^Wjf;) be a weighted Hilbert space obtained by closure of the space E(E*) under the norm
IMIw+(w., = (hih^ul +
J D
+ pul + uDdD i=i 3
J h2hsY,[vi+Pvit + vl]dDD
i=1
By W- {Wt) we denote the space with the negative norm constructed by L2(D) and W+(W$). Combining the above-obtained results, we conclude Theorem 2.4.3 Let the conditions (83), (107), (108) be fulfilled and either po > p*, where p* — p*(\,p,, 0:2,0:3, ftj,T) is a sufficiently large positive number, orT is sufficiently small, i.e. T < Tb(A,/i, a2,a3,hj). Then for any Fo G Wl there exists a unique strong generalized solution U of the problem (171)-(176), (183), (184) in L2ih for which the estimate c\\U\\L, holds.
<\\F0\\W.
245
IfFo G 1/2 h^1 C W*_ this solution is also a strong generalized solution of this problem in W+. Remark 2.4.1 Let us note that if in the condition (83), the number 7 > max(l,2(3), then the riquirement in conditions of Theorems 1.2.1-1.2.4 Po > P* or T < To can be removed and only the assumptions (83), (107), and (108) can be left. Remark 2.4.2 Repeating Remark 1.2.7 in connection with the last problem, we note once more that according to the embedding theorems the boundary value condition (184) is fulfilled in the following sense. The solution /o,o o,o o,o i,o i,o i,o \ , , , U = I v i, v 2 , v 3 ; v i, v 2, v 3 I G W+ takes zero boundary values in the sense of the trace operation. Remark 2.4.3 Replacing in (177) the index 2 by j,j = 1,2,3, we obtain the approximate expression for the components Wj of the displacement vector. Summing up the above results, we conclude: the displacement vector w := {w\ ,W2,u>3) takes zero boundary value on To in the sense of the trace operation only if (X2 + 3«3 < 1. Thus, the cusped edge x\ — 0 of the bar can be fixed in the (1.0) approximation only if a.2 + 3oj3 < 1 while the same edge can be fixed in the (0.0) approximation only if a.2 + a^ < 1. References 1. Vekua, I. N., On a Way of calculating prismatic shells. Proceedings of A. Razmadze Institute of Mathematics of Georgian Academy of Sciences, 21 (1955), 191-259. (Russian) 2. Vekua, I. N., The theory of thin shallow shells of variable thickness. Proceedings of A. Razmadze Institute of Mathematics of Georgian Academy of Sciences, 30 (1965), 5-103. (Russian) 3. Vekua, I. N., Shell theory: General methods of construction. Pitman Advanced Publishing Program, Boston-London-Melbourne 1985. 4. Jaiani, G. V., Elastic bodies with non-smooth boundaries-cusped plates and shells. ZAMM, 76 (1996) Suppl. 2, 117-120. 5. Babuska, I., Li, L., Hierarchic modelling of plates. Computers and Structures, 40 (1991), 419-430. 6. Gordeziani, D. G., To the exactness of one variant of the theory of thin shells. Soviet. Math. Dokl., 215 (1974) 4, 751-754. 7. Guliaev, V., Baganov, V., Lizunov, P., Nonclassic theory of shells. Vischa Shkola, Lviv 1978. (Russian) 8. Khoma, I., The generalized theory of anisotropic shells. Naukova Dumka, Kiev 1986. (Russian)
246
9. Khvoles, A. R., The general representation for solutions of equilibrium equations of prismatic shell with variable thickness. Seminar of the Institute of Applied Mathematics of Tbilisi State University, Annot. of Reports, 5 (1971), 19-21. (Russian) 10. Meunargia, T. V., On nonlinear and nonshallow shells. Bulletin of TICMI, 2 (1998) 46-49. (electronic version: http://www.viam.hepi.edu.ge/others/TICMI) 11. Schwab, C , A-posteriori modelling error estimation for hierarchik plate models. Numerische Mathematik, 74 (1996), 221-259. 12. Vashakmadze, T. S., The theory of anisotropic plates. Kluwer Academic Publishers, Dordrecht-London-Boston 1999. 13. Zhgenti, V. S., To investigation of stress state of isotropic thick-walled shells of nonhomogeneous structure. Applied Mechanics, 27 (1991) 5, 3744. 14. Jaiani, G., On a Mathematical Model of a Bar with a Variable Rectangular Cros-section. Preprint 98/21, Institute fiir Mathematik, Universitat Potsdam, Potsdam 1998. 15. Kiguradze, I. T., Initial and boundary value Problems for the systems of ordinary differential equations. V. 1. Linear Theory. "Mezniereba", Tbilisi 1997. (see also, Itogi Nauki i Tekhniki, Seria Sovremennje Problemi Matematiki, Noveishje Dostizhenia, V. 30, Moskva 1987, 1-202.) (both in Russian) 16. Ladyzhenskaya, O. A., Boundary value problems of mathematical physics. "Nauka" Press, Moscow 1973. (Russian) 17. Jaiani, G., On a model of a bar with variable thikness. Bulletin of TICMI, v.2 (1998), 36-40. 18. Jaiani G. V., Boundary value problems in (1,0) approximation of a mathematical model of bars. Bulletin of TICMI, v.3 (1997), 7-11. (electronic version: http://www. viam.hepi.edu.ge/others/TICMI) 19. Jaiani G. V., Relation of a mathematical model of bars to the threedimensional theory of elasticity. Workshop in partial differential Equations, University of Potsdam, pp. 15 and 16, 1999. 20. Krasnov M. L., Mixed boundary value problems for degenerate linear hyperbolic differential equations of the second order. Matem. sb., 49(91), 1959, 29-84. (Russian) 21. Baranovskii F. T., A mixed problem for a degenerate hyperbolic equation. Izu. Vyssh. Uch. Zaved., Matematica, 3(16), 1960, 30-42. (Russian)
247
22. Briukhanov V. A., On a mixed problem for a hyperbolic equation degenerating on apart of the domain boundary. Different. Uravnenia, V.8, Nl, 1972, 3-6.(Russian) 23. Vragov V. N., A mixed problem for a class of hyperbolic- parabolic equations of the second order. Different. Uravnenia, V.12, Nl, 1976, 24-31. (Russian) 24. Vragov, V. N., Boundary value problems for nondassical equations of mathematical physics. Novosibirsk: 1983, (Russian) 25. Taniguchi M., Mixed problem for weakly hyperbolic equations of second order with degenerate Neumann boundary condition. Funkc. ekvacioj, 1984, 27, N3, 331-366. 26. Berezanskii, Yu. M., Expansion in proper functions of self-conjugate operators. Naukova Dumka, Kiev, 1965. (Russian) 27. Liashko, I. I., Didenko, V. P., Zitrizkii, O. E., Noise filtration. Naukova Dumka, Kiev. 1979. (Russian) 28. Vishik M. I., Boundary value problems for elliptic differential equations degenerating on a part of the domain boundary. Uspekh. Mat. Nauk, 9, 1(59), 1954, 138-143. (Russian) 29. Vishik M. I., Boundary value problems for elliptic equations degenerating on the domain boundary. Matem. Zb., 35(77), 3, 1954, 513-568. (Russian) 30. Smirnov M. M., Degenerating elliptic and hyperbolic equations, Nauka, Moskva, 1966. (Russian) 31. Fichtengolz G. M., Course of differential and integral calculus. V.l, Nauka, Moskva, 1969. (Russian) 32. Mikhlin S. G., Course of mathematic physics. Nauka, Moskva. 1968. (Russian) 33. Jaiani G. V., The first boundary value problem of cusped prismatic shell theory in zero approximation of Vekua theory. Proceedings of I.Vekua Institute of Applied Mathematics, 29 (1988), 5-38. (Russian, Georgian and English summaries) 34. Jaiani G. V., Bending of an orthotropic cusped plate. Universitat Potsdam, Institut fur Mathematik, Preprint 98/23, 1998, 1-30.
248
VANISHING VISCOSITY LIMIT OF T H E I N C O M P R E S S I B L E NAVIER-STOKES EQUATION (ABSTRACT) K. ASANO Kyoto University, Yoshida College, Inst, of Mathematics Yoshida Nihonmatsucho, Kyoto 606-8501, Japan E-mail: [email protected] We consider the incompressible Navier-Stokes equation in the domain Q C R3 with the boundary S = 9 0 : dtu + u •
VM
— uAu + Vp = 0,
V • u = 0, -yu = u | 0 = 0, u |t=o= wo, V • wo = 0,7U0 = 0, 2
where v = e £ (0,1] is the viscosity coefficient. We assume that S is an analytic surface. The solution u = u(e, t, x) is expected to satisfy the property: u(e, t, x) —> u°(t, x)
as
e —> 0,
if x is away from S. Here M° is the solution of the incompressible Euler equation with the same initial data u°, satisfying the slip boundary condition. In the case Q, = R\ with S = R2, we can prove that u(e, t, x) has the asymptotic form: u = u°(t,x) +eu1(t,x)
+
e2u2(e,t,x)
+u°(t, x) + eu1(e, t, x) + e2u2(e, t, x), p = p°(t,x) + ep1{t,x) +
e2p2{e,t,x)
+ep°(i,x) + e 2 p 1 (e,* ) x) + eV(<:,*1:E)-
249
Here 'u{(e,t,x',x3/e)\ u^(e,i,a;',X3/e) eu3(e,x',x3/e) J
,
x' =
{xi,x2).
From this asymptotic form, we can prove the desired result. We also discuss the stationary problem in the exterior of the ball. The first boundary layer has some interesting properties.
C H A P T E R 3:
PARTIAL COMPLEX DIFFERENTIAL EQUATIONS IN THE PLANE
253
B O U N D A R Y VALUE P R O B L E M S FOR A CLASS OF N O N R E G U L A R ELLIPTIC EQUATIONS N. E. TOVMASYAN State Engineering University of Armenia, 105 Terian Str., Yerevan, 375009, Armenia, E-mail: [email protected] In this paper we consider some boundary value problems for a class of nonregular elliptic equations. These problems we reduce to second kind Fredholm integral equations and calculate their indices
1
Introduction
Let r be a simple closed sufficiently smooth contour, surrounding a bounded simply connected domain D and let D be the closed domain P U T . Without loss of generality we will assume that 0 & D. The positive direction on T is leaving the domain D on the left. Consider the first order differential operators Lj (j = l,...,n) given by d
x
d
(1)
where / is the identity operator, while Xj and a.j (j = 1 , . . . ,n) are complex constants satisfying ImXj
> 0,
j = 1 , . . . , m,
Im Xj < 0, AjT^Afc,
(2)
j = m + 1 , . . . , n, j ^ k,
j,k =
l,...,n.
(3) (4)
For definiteness we will assume that m>n — m. Consider the following boundary value problem: find a n-times continously differentiable solution u(z) z £ D of the equation L\ • • • Lnu(z)
= 0,
z € D,
(5)
satisfying the conditions dm-1u(z) Re Q kQ m-l~k y x Im
dm-1u(z) dykdx m—X~k
fk(z), fm+k(z),
z e l \ fe = 0 , l , . . . , m - l , zGT,
k = 0, l , . . . , n - m - l ,
(6) (7)
254
where the operators Lj (j = 1, ...,ra) are defined by (1) and fk(z) (k = 0 , 1 , . . . , n — 1) are given functions defined on I\ Notice that for m = n we have only the conditions (6). It follows from (2) and (3) that the equation (5) is elliptic. Moreover, if m = n — m, then the equation (5) is regular elliptic, otherwise (5) is nonregular elliptic. For fk(z) = 0 (k = 0 , 1 , . . . , n - 1) the problem (5) - (7) is called homogeneous. We will say that a function u{z) belongs to the class H(D) if it satisfies a Holder condition in the closed domain D. Similarly we define the class H(T) on the contour I\ We will assume that the functions fk(z) (k = 0 , 1 , . . . , n — 1) and their derivatives d3fk{z) dgj
,
, _ k = 0,...,n-l,
,
. , j =
, l,...,n-m-l,
belong to the class H(F), where s is the arc length of the point z £ I\ We look for a solution of problem (5) - (7) in the class of functions, which together with their derivatives up to order n — 1 belong to the class H{D). In the special case where Reafc = 0 (k = 1 , . . . , n — 1) the problem (5) - (7) in the half-plane was considered in [1]. Notice also that for a/t = 0 (k = 1, . . . , n — 1) some Dirichlet type problems for equation (5) in the simply connected domains have been considered in 2 - 4 , where these problems are reduced to normal-type singular integral equations. The purpose of the present article is to reduce the problem (5) - (7) as well as some more general boundary value problems to second kind Fredholm integral equations and to calculate their indices. Recall that the index of problem (5) - (7) is the difference ko — k'0, where k'0 is the number of linearly independent conditions that are necessary and sufficient for solvability of problem (5) - (7), while ko is the number of linearly independent solutions of the corresponding homogeneous problem. Here the linear independence means over the field of real numbers. We prove that the index of problem (5) - (7) is equal to n(2m — n). 2
The general solution of equation (5) and some auxiliary results
Let D and V be as in section 1 and let A be a constant such that ImA ^ 0. Denote by D\ the image of the domain D under the mapping £ = x + Xy {<; = Z + iri€Dx,z = x + iy£D). Definition 2.1 We say that a function
such that u can be represented in the form T1(z,z,t,Co)!P(t)dt+ )f(Qd( 0, C = £ + in, z = x + iy, p2 = £2 + n2. The system integral equation (1) has solution in the class functions Uj(z) G C(D+), j = 1,2, having zero order 7 > a — 1 in I\ The kernels of system (1) have on T a weak singularity for a < 1, a singularity for a — 1 and a super-singularity for a > 1. Therefore the system (1) is called a system of complex integral equations with weak fixed singularity of kernels on the boundary T, when a < 1, a system of complex integral equations with fixed singular kernels on T, when a = 1 and a system of complex integral equation with fixed super-singular kernels on T, when a > 1. In this paper the system (1) is investigated in dependence of the roots of the characteristic equation A(A) = dxdy ~jij< dxdy JG dxdy JG = I < —-, (p > dxdy + JG * ] 8z2 4 Substituting these expressions into (3.6) and taking into account (3.13) it is easy to see that (3.12) is a solution of (3.6). Now consider the case when (1 — 2a(z))2 — 16b(z) ^ 0 in C + . In this case the roots k\(z), k2{z) of the equation k2+(2a(z) — l)k+4b(z) = 0 are obviously different, k\{z) ^ k2(z) in C + . Let Re k^ — max(Re kitOQ,He k2t00), where kjoo = hm kj{z). We assume that the functions • dtdx = 0. {z))dxdydt = 0 Jc (z,t)\2)dxdydt f r, du / 3 {xo), =
u(z) = (p(z)+
r2(z,z,z0,T)cp*(T)dT
Jzi
JCi
with ZQ, 21, CO, CI € T> arbitrary fixed points. Here (p* denotes the conjugate function to ip and the resolvents Ti and T 2 can be determined from T1(z,C,t,T)
= W1(z,C,t,T)
+
r 2 (*,<,t,T) = Wl(3,C, t,T)
iW2(z,C,t,T) -iW2(z,Ct,T)
where W\ and W2 are two-parametric solutions of Dw = 0 which satisfy the following conditions Wi | C = T =
-C(Z,T),
W2
|C=T=
-ic(z,r).
For particular equations the corresponding resolvents were determined by K.W. Bauer 2 and K. Nusser 7 . Starting with this result we can give the following integral representation for the solutions of (4).
271
Theorem 2 For every solution w of (4) defined and analytic in the domain T> there exist functions
-z k
w{z) = Y,V Vk(z)+
n—1
T1(z,z,t,Ca)Y^Vk
/ Zl
fc=0
fe=0
+ f r 2 ( z , z, z0, T) J2 Vk
(13)
fc=n
Conversely for all functions Pk(z) holomorphic in T> the expression in (13) represents a solution of (4)For a pseudo-analytic function u there exists the following generalized Cauchy integral formula (cf. I.N. Vekua 1 0 ). Let Q be a finite, multiplyconnected domain bounded by a finite number of rectificable closed curves. Let C denote the boundary of Q and ZQ = XQ 4- iyo be a fixed point inside Q . Then the value of u in ZQ is given by u z
( o) = y~-• /
(u{z)U(z,z0)dz-u(z)V(z,z0)dz)
with the kernels U(z,z0) = Ui(z,z0) V(z,z0) =V1{z,z0) Ui{z,z0)
=
U2(Z,ZQ)
(14)
-V2(z,z0)
r1(z0,^,z,z)\og((z
- z0)(z
-z^))
z — zo +
{^i(zo,zo,z,z)-T1{t,z^,z,z))Jza
+ / Jzo
Vi(z,z 0 ) f* +
t-ZQ ~, l
/
~ z0
ri(£,zti,z,z)c(£,z5)d£
Jzn
-r*2{zE,z,z,z)log{{z-z0){z-z^)) _ _ (T^(Z0,Z0,Z,Z)-V^{T,Z0,Z,Z))
JTE
+ /
=z /
Ai(z,z,z0,v)dr] Jo
—
r - Z0 T2{r],zo,z,z)c*(r),zo)dri
rzo
U2{z,z0)=
dr
+
272
+
drj
Jo rZQ
+
rZQ
dV
Jo
r1(z0,zE,C,v)Ai(z,z,^r))d^
Jo
r1(z0,z0-,t,r])A*2(z,z,r],Z)dZ
Jo
rzo
V2{z,zo)=j
Al{z,z,z$,£)d£
Jo rZQ
rZQ
d
+
€
Jo
r*1(z0-,z0,T),t)A?i(z,z,n,t)dr) Jo
rzo
pzo d
+
£
Jo
mzo,z0,V^)Ai(z,z,^,ri)dr] Jo
where the functions At(z, C, z0, Co), i = 1,2, are the analytic continuations of the functions . . . dUi(z,z0) A1{z,z0) = ~ \-c(zo, z0)Vi(z, z0) azo dVi{z,z0) A2{z,z0) = — ^ z z — +c(z0,z0)U1(z,z0) (which are analytic in the real variables x,y,XQ,y$) into the complex plane. They are analytic functions of z, C, .zo, Co- The resolvents Ti, T2 are defined as above. The kernels U, V depend on the coefficient c of the Bers-Vekua equation only and do not depend on the domain considered. With this we can give the following representation for a solution of (4) which is a generalized Cauchy integral formula for a poly-pseudo-analytic function. T h e o r e m 3 Let C denote the boundary of a (multiply-connected) domain Q. Then (*°) = i E ( ^ + ^
/
( i f J2
Ti7f(2 + ^
({-~(z -1)'
+
[Dk+lw(z)]
U(z,z0)dz
z)l[Dk+lw(z)}v(z,zo)dz
1=0
gives the value of a solution w of (4) in zo G Q if for w and the expressions Dkw, k — 1 , . . . , n — 1, the values are prescibed on the contour C. The kernels U, V are given by (14).
273
L. Bers 6 introduced a generating pair of a pseudo-analytic function in the following way: The pair (F, G) of particular solutions of (3) is called generating pair if the following conditions are satisfied: • $s[F{z) • G(z)} > 0 in the domain D, • Fz,Fz,Gz,Gz
exist and are Holder continuous in V.
Then Bers showed that for every pseudo-analytic function v there exist two real-valued functions $(x,y),'$>(x,y) such that v can be represented in the form v = $F + VG. The functions $ and ^ are determined uniquely by vG-vG =rrz, FG-FG'
$ = ^ s
vF-vF FG- FG
T
*
Starting from these results we can use for the pseudo-analytic functions vk in the representation of a poly-pseudo-analytic function w according to Theorem 1 the form vk = $ fc F + * fc G , k = 0 , . . . , n - 1 with suitable real-valued functions Qk,tyk,k n—1
= 0,...,n
— 1. This leads to
n— 1
w^Ys^^kF + YsV^kG. k=0
(15)
fc=0
Now the functions
vkG-vkG FG-FG
=
'
k
vkF-vkF FG-FG'
K
'
To determine the functions v^ from the poly-pseudo-analytic function w one can use the relation (12). Thus we have the following Theorem 4 Let (F, G) be a generating pair of (3) in the sense of L. Bers. Then for every poly-pseudo-analytic function w there exist real-valued functions $£, tyk, k = 0 , . . . , n — 1, such that for w the representation (15) holds. The functions $k, $k are given by the relations (16) whereas vk can be calculated from w using (12).
274
4
Differential operators for the solutions
Differential operators have been introduced successfully by K.W. Bauer 3 for the representation of solutions of partial differential equations. The author 5 proved a necessary and sufficient condition on the coefficient c in equation (3) under which such operators exist, which give all the solutions v of (3) by means of a holomorphic function / in the form
v = Y,aj(z,z)g-f(z)
+£
j=0
b^z^—fiz)
=: Kmf + K*m_J,
mGN.
j=0
The coefficients a,j and bj can be calculated from the factor c in a simple way. Now we use for the solution w of (4) in the representation (10) for the pseudoanalytic functions Vk the expressions Vk = Kmfk + K^_1fk,fk holomorphic in T>, k = 0 , . . . , n — 1. We get n-l fc=0 which can be rearranged to the form m
TO—1
w = yjaj(-z,2)(5 J M+ \ J bj(z,z)5:>u j=o j=o where u denotes the polyanalytic function u = Y^l=o Vkfk and S is a differential operator defined as Su :— uz — w2 with 8^+lu = S^u), 5° := u. This result means that in the case of the existence of differential operators Km and K^n_1 of Bauer-type for the differential equation (3) the poly-pseudoanalytic functions can be calculated from the polyanalytic functions by means of differential operators. References 1. M.B. Balk, Polyanalytic Functions, Akademie Verlag, Berlin, 1991. 2. K.W. Bauer, Bestimmung und Anwendung von Vekua-Resolventen, Monatsh. Math. 85 (1977), 89 - 97. 3. K.W. Bauer and St. Ruscheweyh, Differential Operators for Partial Differential Equations and Function Theoretic Applicatons, Lecture Notes in Math., 791 (1980). 4. P. Berglez, Characterization of certain differential operators in the representation of pseudo-analytic functions, Rend. 1st. Mat. Univ. Trieste 14 (1982), 2 7 - 3 1 .
275
5. P. Berglez, Differentialoperatoren bei partiellen Differentialgleichungen, Ann. Mat. Pura Appl., 143 (1986), 155-185. 6. L. Bers, Theory of Pseudo-Analytic Functions, New York University, 1953. 7. K. Nusser, Uber die Darstellung von pseudoanalytischen Funktionen, Diplomarbeit, Graz, 1994. 8. D. Pascali, The structure of n-th generalized analytic functions, in: G. Anger (ed.): Elliptische Differentialgleichungen, Vol. 2, Akademie Verlag, Berlin, 1971, 197 - 201. 9. I. N. Vekua, Verallgemeinerte analytische Funktionen, Akademie Verlag, Berlin, 1963. 10. I. N. Vekua, New Methods for Solving Elliptic Equations, North Holland Publ., Amsterdam, 1967.
276 THE BAUER-PESCHL EQUATION — DERIVATION A N D SOLUTION OF A PARTIAL DIFFERENTIAL EQUATION B Y LAPLACE'S M E T H O D
K. W. TOMANTSCHGER Department of Mathematics A, Graz University of Technology Steyrergasse 30, 8010 Graz, Austria E-mail: tomanQweyl. math, tu-graz. ac. at The present paper is concerned with the Bauer-Peschl equation (1 ±zQ2wz(
+ Xw = 0.
The problem, for which A-values the solutions of the equation can be represented by differential operators, can be solved by the method of Laplace. Assuming the solution in form of a differential operator w(z,0
= A0(zX)X(z)
+ Ai(z,OX'(z)
+---An{z,C)X(n){z),
X{z) being arbitrary holomorphic functions, we obtain an overdetermined system of partial differential equations for the functions Aj(z,Cj. Since the coefficients Aj(z, £) are polynomials in zC,/{\ ± z ( ) , the solution is a double sum. This is quite another kind of representation of the solution as we know it from K. W. Bauer, who solved the equation in a completely other way.
1
Introduction
In this paper we shall derive a general solution of the equation (1 + ezC,fwzi:
+ \w
= 0,
AeC,
e = ±l
(1)
with differential operators. During the past two decades, this elliptic resp. formal-hyperbolic differential equation has often been referred to as the Bauer-Peschl equation. 1966 introduced K.W. Bauer the differential operators with this equation ( 1 ). K.W. Bauer had derived the following solution for A = en(n + 1), n e IN, .
.
- A (2n - u)\
(-e)"- 1 '
/^
„ dv
n_v
dv
\
^o = EA(^i (1 + e , 0 n-,(c" j?f(*) + *" or9(0), f(z), g(() beeing arbitrary holomorphic functions. But when K. W. Bauer started to solve equation (1) he didn't know that special differential equations possess solutions, which can be represented by arbitrary holomorphic functions and a finite number of their derivatives. So his solving way was
277
completely another one than we use it for calculating differential operators today. In this paper Gi and Gi are simply connected domains of the complex z resp. £ plane; z £ Gi, ( £ Gi. G\ and G2 is assumed to be such that ez( y^ — 1 in Gi x Gi- We look for a general solution of (1), represented by two arbitrary holomorphic functions X(z) and Y(() and a finite number of their derivatives, that is,
w(zX) = 52M*X)—£J- + '£Di(z,0—j£l. 3=0
j=0
^
Aj(zX) and Dj(zX) are determinate coefficients and have to be calculated. Since not every partial differential equation possesses such a kind of solution, it is clear, that we first determine all these constants A, for which such solutions exist. This can be made by the method of Laplace a (see 5 , pp.68). In Chapter 2 this method is sketched shortly. Applying it on the Bauer-Peschl equation we obtain A = e n (n + 1 ) , n e IN. In Chapter 3 we set Y = 0, i.e., we take the part of the solution with X(z) and its derivatives. Inserting this integral into the equation (1) with A = e n ( n + 1), and using the fact that the functions X, X', X", • • • , X^n+1^ are independent, we get an overdetermined system of n + 2 equations for n + 1 coefficients Ao, • • • , An (see (25) - (28)). Only if the last equation is identically fulfilled for the already calculated coefficient Ao, the equation possesses an integral in such a form (see (28)). In our case the last equation will be satisfied, because we already have used the method of Laplace. There we demanded that the invariant hn must be equal zero. We treat our system (25) - (28) with n = 1,2, 3. That means, that we look for solutions which go till to the first, to the second and to the third derivative of X(z). Looking at the three calculated solutions we see, that we need a double sum for representing our general integral (see (44)). Applying the symmetry of equation (1) in z and £, we easily obtain the coefficient Dj. Remark 1 Equation (1) is of importance, for instance in the case A = — n(n+l), e = —1. This Bauer-Peschl equation is closely related to several basic equations which are of mathematical and physical importance ( x , 2 ). It is related to the twodimensional wave equation WX1X1 + WX2X2 = WX3X3 a T h i s method given by Laplace 1777 was developed and extended by Darboux. Today it is upon his exposition that the present account of the method is based.
278
from which it results by separation of variables and suitable projection. It may also be obtained from the ultrahyperbolic equation WXlXl + WX2X2 = WX3X3 + WX4X4 as well as from the parabolic equation WXlXl + WX2X2 = WX3X3 + WXi . 2
Laplace's method
The differential equation (E) :
wzC + a(z, ()wz + b(z, C)wc + c(z, ()w = 0 ,
w = w(z, Q , (2)
can always be written d (dw
\
+aw
d-z{-dC
)
, fdw + b
\ +aw
{-OC
,
..
hw
)=
{3)
'
where h = az + ah — c. If h = 0, equation (3) reduces to a linear equation uz + bu = 0, where we have taken u = w^ + aw as an auxiliary unknown. The general integral of this first order equation leads us to an intermediate integral of equation (2) dw - _ fbdz — + aw = Ye J where Y is an arbitrary function of £. Integrating this differential equation, we obtain the general solution of equation (2) w
-fadi
X(z)+ [Y{()efad<:-fbdzdt
,
X{z) being an arbitrary function. We see that this integral is of the form w = aX(z) + JpY(C)dC,
(4)
a, 0 beeing determinate functions of z and (. If h
T£
0, we set dw wi = — +aw.
... (5)
279 Substituting this into (3), eliminating w from the resulting equation and inserting w into (5) yields (Ei) :
witZ{ + aiwi
(6)
where ai = a- (log h)^,
bi = b,
a = c - az + b^ — b (log h)^ .
If we would know ioi, we could calculate w, because from (3) and (5) we get W
=
u>i,z + bwi —h •
It is clear that the integration of equation (2) and of equation (6) constitutes two equivalent problems. Making the substitution Wi = wz + bw
(7)
and defining k — &£ + ab — c, we obtain equation WiX + aWi = kw .
(8)
If k = 0, the general integral of (2) resp. (8) can be represented in a formula analogous to formula (4), which would be derived from it by permuting z and £, X and Y. Providing k ^ 0, equations (7) and (8) will lead by elimination of w to the new equation, analogous to (6). Remark 2 The two expressions h and k are called the invariants of equation (2), because h and k don't change if we make a change of the unknown function such that w = M(z, ()w for any function M.
Denoting the invariants of (6) by hi and ki, an easy calculation shows hi = aiyZ + aibi — ci = 2h — k — (log h)z^ , ki = &i,£ + ai&i — c\ = h .
280
k\ cannot be zero since we have supposed h ^ 0. But it may happen that h\ is zero without either of the invariants h and k vanishes. If this is so, the general solution of equation (6) can be derived. According to formula (4) we obtain w = A0X(z)
+ A1X'(z)
+ f BY(()d(
,
(9)
A 0 , Ai, B being definite functions of z and (, and X(z), Y(£) being arbitrary functions. If we set Y — 0, the solution (9) consists of an arbitrary function X(z) and of its first derivative. The repeated application of Laplace's method will lead to a sequence of equations (E), (E1), (E2), . . . . We also get a sequence of h, hi, h2, •••, and k, k\, k2, • • •, for which generally holds hn = 2hn_i - kn-i - (log/i n _i) z C , kn = hn-i.
(10) (11)
If we know the invariants and the nth transformation wn we can write down the dependent variable w(z,(). For the transformation holds wm+i = wm£ + amwm .
(12)
Then equation {Em), already written as a first order equation with the invariant hm, becomes hmwm
= ium+i,a +bwm+i.
(13)
Consequently, fbdz WmeJ
1
d /
=
h^d-z rm+ieJ
fbdz\
)'
and therefore _d d__ d ( Jbdz\ (14) hdz hidz hn-idz \ ) If we come, after n successive transformations, to an equation En for which the invariant hn = a n , 2 + anb — cn = 0, this equation is integrable. Going back step by step, we can derive from it the general integral of the equations (En-i), {En-2), • • •, up to equation (E). Inserting wm+i from (12) into (13) and solving the resulting equation for m = n and with hn = 0 , we have wJbdz
=
wn = a{X + I YfidQ)
with
281
X(z) and y(C) are arbitrary holomorphic functions, cx(z,() and (3(z,() are determinate functions. Now, according to (14) the relation between w and wn is Jbdz me
3 d hdz h\dz
d hn-\dz
°* (x(z) + JY(()e-td(
(15)
and therefore, effecting the differential operations, we have the value of w expressed in the form w =
(16)
A0 X + jY(3dc\+AAx' + jYpzdC +.-- + An\x^ + J t-d(^ where Ao, A\, ••• , An are determinate functions of z and ^. X^' represents the j t h derivative of X with respect to its argument z. Since the functions X and Y are arbitrary, (15) is a general solution. Taking Y(£) = 0, we get the specialised integral (particular solution) w = A0(z, C) X(z) + Ar(z, Q X'(z) • • + An(z, 0 I w ( z ) ,
(17)
so that an integral exists of an arbitrary function X(z) and of a finite number of its derivatives. The assumption for the existence of such a solution is that one of the invariants vanishes in the succession of equations, which are constructed by repeated transformations of Laplace. 2.1
The invariants of the Bauer-Peschl equation
Let us apply this method to the Bauer-Peschl equation (1). We ask for which coefficient resp. for which constants A our differential equation W +
(l+Xez(rW
«
= 0
'
e = ±1
'
possesses an integral of the form (17). In our case we have a = 0,
6 = 0,
c = — (1 +
and therefore -A h = k = -c = (1 + £ZC) 2 '
—J, ezQ2
282
Eliminating A;„_i from (10) by (11), we get the recursion relation ft„ — 2/i„_i - hn-2 - (log/i„_i)^,
h0 =
ft,
n > 2.
(18)
Starting with n = 1, we use the recursion (10) und set k$ = k. Then h
2e 1
(1+£*C)
_ 2
- A + 2e
~~ (1 + ^ C ) 2 '
In the next place, we take n = 2 in (18). This yields h2
2e 4 /, , £ 2 = hi + (/i! - ft) + 7;—• TvT = fti + (1 + szQ (1 +ff^C) 2
- A + 6e (1 + e z < ) 2 '
Making one step more, we obtain from (18) with n = 3 , ,
2e , 6e - r 2, = ft2 + (1 + £zC) (1 + e ^ C ) 2
"3 = "2 + (ft2 - ftl) + 7-—
- A + 12e (1 + ezC)2'
Consequently, ,
,
hn = « n - l + (1 +
2ne ezC,f
and -A + £ n(n + l) (1+ezC)2 ' That means, that the invariant ft„ only can vanish at any stage of the successive transformations, if the constant A is an integer of the form A = en(n
+ 1),
(20)
where n is a positive integer. Only in this case the solutions of the BauerPeschl equation can be represented by an arbitrary function X(z) and its first n derivatives X'(z), • • • , X ' " ' ( 4 Remark 3 Similarly, as we have constructed the solution (17), we can get a solution of the form w = D0(z,QY(0
+ D1(z,C)Y'(C)
+ ••• + Dm{zX)Y^m\Q,
(21)
where Y(() is an arbitrary holomorphic function and Do, D\, • • • , Dm are determinate functions. Here we used the transformation (7).
283
Lemma (1) When the differential equation (2) WZQ + a(z,()wz
+ b(z,C)w<; + c(z,C)w = 0
possesses an integral in the form w = A0X{z) + --- + resp.
AnX^{z)
w = D0Y(Q + ••• + DmY^
((),
then the transformation w^ + aw = w\
resp.
wz + bw = W±
was effected. X and Y are arbitrary holomorphic functions. (2) Let us suppose that both sets of transformations are finite in the sense that, in each set, only a finite number of operations is needed to produce a vanishing invariant. Then the general integral of equation (2) is
w j=0
j=0
After we have determined the invariants, we use formula (15) for getting the solution of our differential equation. Taking Y = 0 and inserting 6 = 0 yields d
d
hdz
h\dz
d
hn-\dz
,- J an dCX(z)
(22)
Now we have two possibilities. The first possibility is to calculate an and to substitute it into formula (22). By effecting the differential operations, we obtain the solution of the form (17). The second way is to substitute the solution (17) with unknown coefficients AQ(Z, £),• • •, An(z,() into our differential equation (1) with A = en(n + 1). Since the functions X(z), X'(z), X"(z), • • • , are linear independent, the equation is only satisfied, if the factors of X^n>(z), n = 0,1,2, • • •, are equal zero. In this way we get a system of differential equations for the coefficients.
284
3
Calculation of the solution of the Bauer-Peschl equation by a system
Now we want to determine the solution (17) in G\ x G2 of the differential equation enln 4- 1) = 0, £ = (l + ezC)2W The integral is represented by a differential operator WzC+
, > ±1
(23)
"
fc=0
where X{z) is an arbitrary holomorphic function. Then by directly substituting (24) into (23) we obtain the recursive system X(n+1)(*) = ^ X(n)(z).
= 0
(25)
a ^ n - i _ e n ( n + l)
X<*)(z): _2^± = p^ oC
X(z):
^
.
ozo(
+
+
l^±A^
k = n-1,.,1
(1 + e z Q
(27)
^±AAO=0.
(28)
azaC (1 + ezQY Since this system contains n + 2 equations but only n + 1 undetermined functions Ak, the system is overdetermined. So the last equation must be satisfied. In our case this surely will be done, because Laplace's method guarantees us the existence of a solution in form of a differential operator (24) of the partial differential equation (23). Taking the case where h\ = 0, e.g. n = 1, then a solution of the form w = A0(z,C)X(z)
+
A1(z,0X'(z)
exists. Integrating relation (25) and (26) with n = 1, we have 2
A\ = Ai(z)
arbitr.
and
A0 = —7— AAz). v y v ; z{\ + ezQ Inserting AQ into (28) with n = l w e get by comparison of coefficients the two equations " 1 " : -zA[ + 2Ai = 0 ,
285
C : -z2A[
+ 2zA± = 0.
A\ = z2 represents a particular solution of these two dependent equations. Hence AQ = 2z(l + ez()~ . The equations (27) drop in our case. We thus have Proposition 1 In G\ x G2 the differential equation 2e Wz +
<
(1 +
szCy
w = 0
possesses the particular solution 2z w = , "~ , X + z2X'. 1 + ezC,
(29) '
v
In our next step the invariant h2 vanishes. That means that n = 2. But let us ask, what happens, if we don't set n = 2 in equations (26), (27) and (28). Will we get more solutions or not? Now the integral possesses the form w = A0(z,()X(z)
+ A1(z,C)X'(z)
+
A2(z,C)X"(z).
For this solution the system (25) — (28) reduces to A A 1 \ i-x. A2 = A2(z) arbitr.,
.
/ .
en(n
+ 1) . \
1
V
sn(n + 1) ^ A2 (1 + ezC)
A
AltC =
C + " 0
.
/
en(n
+ 1) ,
(1 +
ezQ
From the first equation we obtain n(n + 1) A
i
= —FT
. , .
,
TTA2Z.
. 30
w K z{\ + ezQ ' By inserting this into the second equation, we get by integration with respect to C
A0 = -n(n + l) z(l + ezQ
, 2
en(n
+
l)(s
Z*{1+EZQ2
+
2zQ
n2 (n + if 2z2(l+£zC)
286
Substituting this into the last equation and making comparison of coefficients, we get • l V ^ -
j B
( „
+
l ) . ^
+
n(„+.)(=fiLtii+2)M,-M»)
C : z2A'2' - [2 + n{n + l)]zA'2 + 3 n ( n + l)A2 = 0, C2 : z2A'2' - 4zA'2 + 6A2 = 0.
(33) (34)
The Euler-Cauchy equation (34) possesses the solutions A2 = z2 and A2 = z3. By substituting A2 = z2 into (32) and (33), we see that these equations are only fulfilled for the positive integer n = 1. Now we can calculate the two other coefficients. With (31) and (30) we get A0 = 0 and Ai = 2z(l + ez £ ) _ 1 . Proposition 2 In G% x G2 the differential equation ezQ2
(1 + possesses the particular solution
2z X' + z2X". 1 +ez(
(35)
But this is quite the same result (29) as we had before. We only have to introduce a new arbitrary holomorphic function X\{z) = X'{z). Now we consider the case A2 = z3. Substuting this in equation (33), we see that it is identically satisfied for all n. Giving A2 = z3 in (32), we get the relation [n(n + 1) - 2][n(n + 1) - 6] = 0, which implies the positive integers n = 1 and n = 2. From (31) and (30) we have with A2 = z3, n = 1 and n = 2 -2-2
2z2
,
A0 = — 7, M 1 + ez(' . . 6z(l-ez() . and A0 = —±- r f , Al = (1 + ezQ2
1 + ez( 6z2 -— 1 + ezC,
Now we can say: Proposition 3 In G\ x G2 the differential equation (1 +
ezQ2
respectively.
287
possesses the particular solution w = - r ^ — . X
+ J^—JX*
1 + ezC,
+ z3X".
(36)
1 + e^C
Proposition 4 In G\ x Gi the differential equation (1 + e^C) possesses the particular solution
w
= w^Ax
+
(1 + ezQ1
rf~rx'+ z*x"- (3?)
1 4- ezC,
Starting with a solution of the form w = A0(z,()X(z)
+ A1(z,QX'(z)
+ A2(z,()X"(z)
+
A3(z,OX'"(z),
we obtain in a similar way the following results: Proposition 5 In G\ x Gi the differential equation 2e ezQ2
(1 + possesses the particular solution 97
1 +
ez(
X' + z2X".
(38)
This corresponds to (29) and (35). Proposition 6 In G\ x Gi the differential equation 2e (1 +
ezQ2
possesses the particular solution 2z „, 2z2 X' + 2 ,X" 1 + ezC, 1 + ezC, Defining X\(z) = X'(z),
we have Proposition 3.
+ Z*X'" •
(39)
288
Proposition 7 In G\ x G2 the differential equation 6e 'JzC
(1 +
ez()2
w = 0
possesses the particular solution p ^ O x > (1 + ezQ2 Defining X\{z) = X'(z),
+
- ^ - X » 1 + ez(
+ Z*X»>.
(40) v
we have Proposition 4.
Proposition 8 In G\ x G2 the differential equation (1 + e^C) possesses the particular solution A-72
A-7
w =
?73
= ^ — X' + X" + z4X'" . 1 + ezC, 1 + ezC,
.X 1 + ezC,
(41)
Proposition 9 In G\ x G2 the differential equation Wzd + 7 — (1 + possesses the particular solution w
12z(l - ezQ = -W-^X (1 + ezC)2
jr^w ezQ2
1 - ,, l 2 £ Z \22 X' (1 + ez() "
+
= 0
r^-rX" ' 1 + ez(
+ ,4X'".
(42)
Proposition 10 In Gi x G2 the differential equation (1 +
ezQ2
possesses the particular solution A2\ 2 4 z ( l - 3 e < + zV 2C )
(i+^o
3
y
+,
1 0 ,22 / o _ n 0 , r t 12z (3-2ezQ
(i+^o
2
v
, ,
+
- | Q „ 33
12*
m^cx
y
„ ,
4 +zX
• (43)
289
Taking the integrals of Proposition 1, 4 and 10, we see that they also can be written in the following form £z(
w = 2z I 1
w =
2z2e
3ezC 1 + ezC 6ez( s 1 + £Z(
w = Gz [ 1 24z\l +I2zz
3
+12z d
1 -
(1 + szCy l0z2C2 s 2 + (1 + EZ()
1 + e^C £ZC
l +
z2X',
X +
1 + ezC,
X + 6z2
1 -
ez( X' + z33Xv-n 1 + ezC
$£ZA3^3 C
X +
(1 + £^C) 3
' (1 + e ^ O 2
\ X" + zAX'". ez(J
Now the building law can be seen easily. Therefore we set n—k
n
w(z,0
,
= ^>fc+1 k=0
v
j=0
-ezQ V 4- ezC,
X^k\z
(44)
where £?£,., are constant coefficients which have to be determined. Inserting solution (44) into the differential equation (23), all factors of the independent functions X^k\ k = n + 1, n, • • •, 0, must vanish. This implies the system n—k
Y^(-eyjBkJ((k
+ j + l)
J=0
C
C
I ) -(1 + £2C)^' +2 (1 + ezCy+1 T - C wJ +" *'
+
n-fc+1
E (-e^B*-u(1 + n—k
+ en(n
+ 1) ^ ( _ e ) J " B f c j .
i?n+i,-i = 0 ,
(45)
ezC)i+i
^•+i ^
(1 +
ezQi+2
0,
A; = n + 1, • • •, 1,0.
Starting with k = n + 1 we get 0 • Bni0 = 0. This coefficient cannot be calculated because its factor is j = 0. From our solutions (29), (37) and (43)
290
we can assume that Bn,a = 1, because it is the constant factor of the highest derivative of X{z) multiplied by zn+1. Remark 4 If it would hold Bn$ ^ 1, we could devide the solution (44) by the constant Bnfi for obtaining the term 1 • zn+1X^n\ The three integrals of Proposition 1, 4 and 10 also allow us the conjecture £n-i,o = -Bn-i,i- This relation can be proved by writing the factor of X^n~^ in the following form: const. zn
ez( 1+ezC
= const. zn
Bn-1,0 + Bn-\\— 1+C 1 + ezC Taking (45) with k = n and deviding the resulting equation by (—ez)/(l + ezQ2 we have the relation Bn-i,i
- n(n + l)Bnio
= 0,
which implies J 5 „ _ u = B n _i, 0 = n ( n + 1).
(46)
In our next step we set in (45) k = n — 1. Furthermore, we make a comparison of coefficients with respect to (e J 'z- 7 ^ J_1 )/(l + ez(y+1 for j = 1,2. The two resulting equations are - B n _ 2 , i + n(n + l)B n _i,o - (n + l ) B „ - i , i = 0 and
2B n _ 2 ,2 + [2 - n (n + l)]Bn-hl
= 0.
Applying the results before we have Bn-2,i
= ( n - l ) n ( n + l)2 ,
Bn-2,2 = \ (n - 1) n (n + 1) (n + 2).
(47) (48)
Entirely in the same way as before, (45) yields for k = n — 2 - n B „ _ 2 , i +n(n
+ 1) B„_2,o - # n _ 3 , i = 0,
[2 - n ( n + l)]B„-2,i + 2(n + l ) B n _ 2 > 2 + 2 5 n _ 3 , 2 = 0, [ 6 - n ( n + l p n - 2 , 2 + 3B„-3,3-0.
(49) (50) (51)
291 Using (47) and (48), we deduce from equation (50) and (51) that Bn-3,2 = \ (n - 2) (n - 1) n (n + l ) 2 (n + 2),
(52)
B„-3,3 = ^ ( n - 2)(n - l ) n ( n + 1) (n + 2) (n + 3).
(53)
Bn-3,i cannot be calculated with equation (49) because £?n_2,o is undetermined. We don't get an equation for a coefficient JB/^o because in the recursion equation (45) it possesses the factor j = 0. First we consider the coefficients (48), (53) and -B n -i,i in (46). Writing them with faculties, we obtain n_1,1
(n + 1)! ~~ 1! (n - 1)! '
(n + 2)! " 2! (n - 2)! '
n 2,2
"
n
(n + 3)! ~ 3 ' 3 " 3! (n - 3)!
which implies n p p
" '
_ (n + j»)l " p! (n - p)\ •
We next turn to the coefficients Bn-\fi senting them with faculties, we have
B
-'<° = 0 ! ( ^ T ) ! ( " +
X)
•
, (
j
in (46), then (47) and (52). Repre-
B
-"
' i!^TT25! <" + !) •
Now we see, that
B
—- = ^w^i ( n + 1)'
(55)
Looking to (54) and (55), let us suppose that -Bn_PiP_2 possesses the form (n + p - 2)! S p p 2 (56) - ' - ~ (p-2)!(n-p)! C with the unknown constant C, which holds for all p = 2,3, • • •, n. Putting (56) with p = 2 into (49), we see that C=
|n(n+l).
292
This can be seen as a binomial coefficient. Furthermore, we write the factor 1 of the fraction in (54) and the factor n + 1 of the fraction in (55) as binomial coefficients n + 1\
(n + 1 resp
o j
-
v i
Taking the relations (54), (55) and (56) with binomial coefficients, we obtain the conjecture
In our next step we make the index transformation k = n — p and j = p — s resp. p = n — k and s = n — k — j . Now the coefficient (57) becomes
B
" = ^^JiF(kl+j 11)> °- fc - n ' ° ^ » - * -
(58)
Inserting (58) into (45), we see that this equation is identically satisfied, which proves the correctness of our relation. According to (44) and (58) we can say: T h e o r e m 1 J n f t x G2 the Bauer-Peschl equation (23) en (n+1) zC + 7T~, 7v2
w
(1 +
w
=
„ °'
ezQ1
possesses the particular solution f v r)i(n+j)\(
n + 1 \
n—k
n
mT
n e JN0 ,
w(zX) =fc=0 5>* +1
z^j (59)
the function X{z) beeing arbitrary holomorphic. Since we treat a self adjoint differential equation, it holds for the invariants h = k. So it easily can be shown, that for the integrals (17) and (21) holds m = n. The symmetry of z and £ in (23) implies Dj(z, C) = Aj((, z), 0 < j < n (see Lemma). Now we can say: T h e o r e m 2 In G\ x G2 the Bauer-Peschl equation (23) en (n+1) < + 77~i 7vi w (1 + ezC) 2
w
n =
°>
_T n e JN 0 ,
293 possesses the particular solution n fc=0
n—k
^
}
y(fc)( C ) t
j\k\
\k + j + l)(l
+ e zC)i (60)
the function Y(() being an arbitrary holomorphic function. Theorem 3 The general solution of (23) is obtained by adding the integrals (59) and (60). This easily can be seen, because the sum includes two arbitrary functions (see also Lemma, (2)). It should be mentioned once more, that G\ and Gi are simply connected domains of the complex z resp. £ plane. Furthermore, G\ and G-z are assumed to be such that 1 + ez( does not vanish in G i x G2. Remark 5 Taking the solutions of Proposition 1, 6 and 8, we obtain another building law. It yields a solution for the differential equation (1 +
EZQ2
References 1. K. W. Bauer, Uber die Losungen der elliptischen Differentialgleichung (1 ± zz)2 + Xw = 0, Journal f. d. reine u. angewandte Mathematik, 221, Teil I, 48 - 84; Teil II, 176 - 196 (1966). 2. K. W. Bauer, Uber eine der Differentialgleichung (1 ± zz)2 ±n(n+l)w = 0 zugeordnete Funktionentheorie, Bonn. Math. Schr., 23 (1956). 3. K. W. Bauer, St. Ruscheweyh, Differential Operators for Partial Differential Equations and Function Theoretic Applications, Lecture Notes in Mathematics, 791, Springer-Verlag, Berlin • Heidelberg • New York (1980). 4. R. P. Gilbert, Constructive Methods for Elliptic Equations, Lecture Notes in Mathematics, 365, Springer-Verlag, Berlin • Heidelberg • New York (1974). 5. M. Kracht, E. Kreyszig, Methods of Complex Analysis in Partial Differential Equations with Applications. A Wiley-Interscience Publication, New York • Chichester • Brinsbane • Toronto • Singapore (1988).
294 KOMPLEXE DIFFERENZENGLEICHUNGEN M. CANAK Poljoprivredni fokultet (Landwirtschaftliche Fakulf'at), Katedra za matematiku Nemanjina 6, 11000 Zemun, Beograd, Yugoslavia
1
Einfuhrung
Definition 1.1 Es sei eine komplexe Gleichung der Form z = g(z)
(1.1)
gegeben, wobei g{z) eine beliebige analytische Funktion ist. Die Gleichung (1) kann eine geschlossene oder nichtgeschlossene Kontur, wie auch eine Menge isolierter Punkte bestimmen. Im weiteren werden wir die Menge der Punkte in der komplexen Ebene, die durch die Gleichung der Form (1.1) bestimmnt sind, eine K - Kontur nennen. Eine grosse Zahl fur die Praxis wichtiger Konturen (Gerade, Kreis usw.) lasst sich in der Form (1-1) darstellen. In seiner Arbeit x hat der Verfasser eine Abbildung ag(z) der Menge der stetigen komplexen Funktionen w = w(z, z) auf die Menge der analytischen Funktionen auf folgende Art und Weise eingefuhrt: Definition 1.2 Es sei g{z) eine analytische Funktion und w = w(z,z) eine stetige, komplexe Funktion, die eine konvergente Potenzentwicklung nach z und z besitzt. Dann ist die zusammengesetzte Funktion w(z, g(z)) analytisch und wir bezeichnen sic mit ag^w. Der geometrische Sinn dieses Operators ist folgender: Wenn z = g(z) die Gleichung einer geschlossenen Kontur ist, so besitzen die Funktionen w — w(z, z) und ag(z)W den gleichen Randwert auf dieser Kontur. Darstellung der Kontur in der Form z = g(z) und die Anwendung der Abbildung ag^ stellen die Hauptidee fur die sogenannte KRK - Methode (KRK = Komplexe Representation der Kontur) dar. Diese Methode hat der Verfasser in der Arbeit 2 eingefuhrt und niitzte dieselbe in der Theorie der verallgemeinerten analytischen Funktionen und Randwertaufgaben. Definition 1.3 Es seien LQ : z = go{z), L\ : z = gi(z), • • •, Ln : z = gn(z) die gegebenen Konturen, die die Gebiete Go, Gi, • • • ,Gn begrenzen, und es sei Go C Gi C • • • C G„. In seiner Arbeit 3 hat der Verfasser zuerst die
295 sogenannten areoldren V? - Differenzen a9lW-agoW=q/igogi) 91
aa„w gn -
-go
aa,._,w -V (gn-i,
gn-i
^(gl,g2)-^(fl0,gl) gi
fr(gl,g2,---
*(go,gi,g2)
-go
* ( g n - l , g n ) ~ fr(gn-2,gn-l) 9n - gn-2
,9n) - ^ ( g Q . g l , - - - , g n - l )
gn - g o
gn)
_ ,T, , , x — * \gn-2>gn-l,gn,)
, T ,,„
„
„
/, 9x U-4)
„ x
= W v g O , g l , ' •• i g n - l , g n )
Auf Grund dieser Differenzen konstruierte er weiterhin folgende Funktionenfolge
go-z ^o,g,)-m9o) 9i-
=
z
: ^(gQ,--- , g n ) - ^ ( z , g Q , - - - ,gn-l)
(i.3) lTf,_
x
gn-^
Diese Differenzen spielen in der Interpolationstheorie der nichtanalytischen, komplexen Funktionen eine wichtige Rolle. Die Gleichungen in denen, neben den unbekannten komplexen Funktionen auch ihre Differenzen der Form (1.3) fiir das System von Konturen z = gi(z), (i = 0 , 1 , . . . , n) erscheinen, nennen wir weiterhin komplexe, areolare * Differenzengleichungen. Es herscht eine starke Analogie bei der Form und Struktur der allgemeinen Losungen von der komplexen Differential - und Differenzengleichungen (siehe
296 3
). So enthalt die allgemeine Losung der komplexen Differenzengleichung erster Ordnung eine beliebige analytische Funktion und die allgemeine Losung der komplexen Differenzengleichung n-ter Ordnung enthalt n beliebigen, analytischen Funktionen. 2
Einige lineare komplexe Differenzengleichungen
In seiner Arbeit 3 hat der Verfasser einige lineare, komplexe Differenzengleichungen gelost. Dabei hat er folgende Satze bewiesen. Satz 2.1 Es sei die Gleichung einer einfachen, glatten, geschlossenen oder nichtgeschlossenen Kontur L : z = g(z) gegeben und es sei Vgw(z,z)
= V(z,g) =
-2——. 9 z
Es seien weiterhin a{z, z) und b(z, z) gegebene, stetige, komplexe Funktionen. Die allgemeine Losung der linearen, nichthomogenen Differenzengleichung $>w = a(z,z)w + b(z,z)
(2.1)
wird durch die folgende Formel v
;
V
l + (g-z)-a(z,z)
'
gegeben, wobei £(z) eine beliebige analytische Funktion ist. Satz 2.2 Es seien LQ : z = go(z), L\ : z = gi(z), • • • Ln : z = gn{z) die gegebenen Konturen, die die Gebieten GQ,GI, • • • ,Gn begrenzen, und es sei Go C G\ C • • • C Gn. Die allgemeine Losung der komplexen Polydifferenzengleichung y(z,9o,9i,---
,9n-i,gn)=0
(2.3)
wird durch die Formel w(z, z) = (z- g0){z - g{) • • • (z - gn-i)
(2.4) z
^ ( ~ 9o)
gegeben, wobei
297 Differenzengleichung n-ter Ordnung ist eine Gleichung der Form *(£,So, ••• ,9n-i) + ai(z)^(z,g0,--,gn-2) + a2{z)^{z,g0r-,g„-3) H \r an-2(z)$(z,go,gi) + a n _i(2:)*(z,g 0 ) + an(z)w = 0 (2.5) wobei ai(z),a2(z), • • • ,an(z) gegebene, analytische Funktionen sind. Das Auflosen dieser Gleichung ist ahnlich wie das Auflosen der entsprechenden komplexen Differentialgleichung. J. Keckic 4 untersuchte die komplexe Gleichung der Form Dnw + ai(z)Dn~1w
H
+ o„_iDw + an(z)w = 0
(2.6)
mit den analytischen Koeffizienten a,k(z), (k = 1,2,..., n) wobei Dw = {ux - v'y) + i(uy + v'x) = 2w'g (Dnw =
D{Dn-lw))
der bekannte Operator von Kolossov ist. Keckic zeigte, dass die allgemeine Losung der Gleichung (2.6) die Form w(z, z) = (piiz^^*
+ ip2{z)er2^'s
+ ••• + ipn{z)elhi^li
(2.7)
besitzt, wobei
^rn{z)
die Losungen der charakteristischen algebraischen Gleichung r" + a^zy71-1
+ ••• + an-i(z)r
+ an(z) = 0
(2.8)
darstellen. Hier betrachten wir zuerst die sogenannte Modell-Differenzengleichung Vw(z,g0)
= w(z,z)
(2.9)
wobei Lo : z = go(z) gegebene Kontur darstellt. Ihre allgemeine Losung besitzt die Form
m(z, z) =
*y—-.
(2.io)
298
Suchen wir auf Grund des Wertes (2.10) die Losung der Differenzengleichung (2.5) in der Form
m
»(*•*)-ITS^Fi'
= 1)
(2 U)
-
wobei b(z) eine unbekannte analytische Funktion ist. Nach einer langeren Rechnung erhalt man die folgende Funktionenfolge w(z,z) = v
;
l +
—— b(z)-z
(l + b(z)-g0)(l ^w(z,go,9i)
+
b(z)-z)
(1 + b(z) - g0)(l + b(z) -
ffi)(l
+ b(z) - z) (2.12)
<M*,S0,5i, • • • ,9n-x) -
( 1 + h{z)
_go)...{l
1 + b{z)
_ gn_i){l
+ b{zy_
-z) •
Durch Substitution der Werte (2.12) in (2.5) erhalten wir die charakteristische, algebraische Gleichung n-ter Ordnung 1 + (1 + b -
9 n _i)oi(z)
+ (1 + b - s„_i)(l + b - gn-2)a2{z)
+ {l + b- ff„_i)(l + b - <7„_2) • • • (1 + b - g0)an(z) = 0
+ ••• + (2.13)
im Bezug auf b = b(z). Nehmen wir an, dass b\{z) ^ b2{z) ^ ••• ^ bn(z). Dann existiert n linear-unabhangigen partikularen Losungen der Differenzengleichung (2.5) in der Form wk(z,z)
= ———— k = l,2,---,n. (2.14) z; 1 + bk(z) — z Es seien C\{z) und C2(z) zwei beliebige, analytische Funktionen. Auf Grund der Eigenschaft ag (Ci(z)wi + C2(z)w2) = Ci(z)agwi
+
C2(z)agw2
folgt der Satz 2.3 Wenn w\{z, z), • • • ,wn(z,z) linear-unabhangigen, partikularen Losungen der Differenzengleichung (2.5) sind, so besitzt die allgemeine Losung die Form W(z, z) = C1(z)w1 + C2(z)w2 + ••• + Cn(z)wn wobei Ci(z), • • • ,Cn(z) beliebige, analytische Funktionen sind.
(2.15)
299 3 3.1
Einige nichtlineare komplexe Differenzengleichungen Komplexe Differenzengleichung vom Riccatischen Typus
Es sei L : z — g(z) die Gleichung einer gegebenen, einfachen, glatten, geschlossenen Kontur und es seien a(z, z), b(z, z) und c(z, z) gegebene, stetige Funktionen. Komplexe Differenzengleichung vom Riccatischen Typus ist die Gleichung der Form ^w{z, g) = a(z, z)w2 + b(z, z)w + c(z, z).
(3.1)
Durch Substitution des Wertes T
^w{z,g)
=
a„w-w ——— 9-z
in (3.1) erhalt man die Relation a(g - z)w2 + [b(g - z) + l]w + (g - z)c - agw = 0.
(3.2)
Da die allgemeine Losung der Gleichung (3.1) eine beliebige analytische Funktion
=0
(3.3)
geniigt und dass heisst, dass sich die unbekannte analytische Funktion a s u; auf die beliebige analytische Funktion ip{z) zuriickgefuhrt wird. Die Losungen der quadratischen Gleichung (3.3) sind + (g- z)bf ~ M A ~ z)\J9 ~ *Y ~
_ - [ 1 + (g - z)b] ±K°[l ~
2->g(z)
unsere Losung auch auf L definieren. Dass ist aber nur fur den ersten Wert moglich. In seiner Arbeit 1 hat der Verfasser den Satz iiber die Entwicklung einer nichtanalytischen, differenzierbaren, komplexen Funktion in eine konvergente Potenzreihe w(z, z) = h{z) + (z- g{z))h{z)
+ (z- g(z))2f2(z)
+ •••
(3.5)
in einer Umgebung der Kontur z = g(z) (z. B. in einem Kreisring die diese Kontur enthalt) bewiesen. Die Koefnzienten der Entwicklung lassen sich durch
300 die Formel a
9i*)Dkw
/ (y\ _
2kk\
bestimmen. In unserem Fall erhalt man y/1+ {g-z)F(z,z)
lim
« 1 + -( - z)F(z, z);
-[1 + (g - *)<>] + Vll + (g - *)6]2 - 4a(ff - z)[(g - f)c - yfo)] _
2^ 9 (z)
2(g - f)a 2 2
lim
z^g(z)
i( f f - *) 6 - 2a(g - zfc + 2a(g - z)ip(z) — 3= 2{g - z)a
=
(3.6)
So besitzt die allgemeine Losung der Riccatischen Differenzengleichung (3.1) die Form (3.4) mit dem positiven Vorzeichen und lasst sich auf der singularen Linie mit dem Wert (3.6) definieren. 3.2
Komplexe Differenzengleichung vom Vekuatypus
In seiner Monographie 5 hat Vekua ausfuhrlich diejenige elliptische Gleichungssysteme untersucht, die sich in der folgenden komplexen Form iuf = b(z, z)w + c(z, z)
(3.7)
darstellen lassen, wobei die KoefRzienten b(z, z) und c(z, z) gegebene, stetige Funktionen sind. Er hat gezeigt dass die allgemeine Losung von (3.7) die Form w(z, z) = $(z) + ff r i ( z , *)*(*) dT + ff T2(z, *)$(*) dTT
T
(3.8)
- - II nfatywar - - II\i2{z,ty(f)dT mit
ri(2,t) = J2K2j(^t),
r2(z,t) =
Kx(z,t) = - A ,
Kn(z,t) = JJ K&^K^faQdT,,
^2K2j+1(z,t),
301
besitzt, wobei
= b(z,z)w + c{z,z)
(3.9)
wobei z = g(z) die Gleichung einer einfachen, glatten, geschlossenen Kontur ist, wahrend b(z,z) und c(z,z) gegebene, stetige, komplexe Funktionen darstellen. Unmittelbar, aus (3.9) folgt . a„w —w T , Vw(z,g) = — — = bw + c
=>
w + (g — z)bw = agw — (g — z)c.
(3.10)
Parallel betrachten wir auch die konjugierte Gleichung w + (g — z)bw = a^w — (g — z)c.
(3-H)
Durch Auflosen des Systems von zwei Gleichungen (3.10) und (3.11) erhalt man =
agW-(g-z)_[c + byJ-(g-z)bc)^ 1 - bb(g - z)(g - z)
Da die allgemeine Losung von (3.9) eine beliebige analytische Funktion ip(z) enthalt, so nehmen wir auf Grund (3.12) an, dass sie die Form w{z,z) =
-=—— . (3.13) 1 - bb{g - z){g - z) hat und das heisst, dass die unbekannte analytische Funktion agw in die beliebige analytische Funktion ip(z) iibergefiihrt wird. Da der Wert (3.13) der Gleichung (3.9) geniigt, so stellt er ihre allgemeine Losung dar. Bemerkung Die Untersuchung der komplexen Differenzengleichungen ist teilweise ahnlich wie bei den reellen, mit folgenden Analogien: a) Anstatt der Punktenfolge XQ,X\, ... ,xn auf der x-Achse erscheinen die Konturen L0 : z = g0(z), Lx: z = gx{z), ••• Ln: z = gn(z). b) Anstatt der Veranderliche x erscheint die Veranderliche z. c) Die Rolle der beliebigen Konstante c ubernimmt die beliebige analytische Funktion
302
e) Die allgemeine Losung der komplexen Differenzengleichung n-ter Ordnung enthalt n beliebigen, analytischen Funktionen. Es besteht auch eine Ahnlichkeit zwischen den linearen komplexen Differenzen- und Differentialgleichungen. Die allgemeine Losung der Polydifferenzengleichung (n + l)-ter Ordnung stellt ein Polynom n-ter Ordnung im Bezug auf z, mit den analytischen Koemzienten dar. Das Auflosen der linearen Differenzengleichung n-ter Ordnung reduziert sich auf eine algebraische Gleichung n-ter Ordnung. Die allgemeine Losung enthalt n linear unabhangige partikulare Losungen. Interessante Einzelheiten erscheinen bei Untersuchung der nichtlinearen, komplexen Differenzengleichungen. Wahrend die allgemeine Losung (3.8) der Vekuaschen Differentialgleichung (3.7) praktisch unanwendbar ist, da sie singulare Doppelintegrale vom Cauchyschen Typus enthalt, so lasst sich die allgemeine Losung der entsprechenden Differenzengleichung leicht bestimmen. Ahnliches gilt auch fur die Riccatische Differenzengleichung. Dabei spielt die erwahnte KRK - Methode eine wichtige Rolle. Sie ermoglicht das Zuruckfiihren der unbekannten analytischen Funktion agw(z, z) auf die beliebige analytische Funktion tp(z) und erleichtert dadurch das Losungsverfahren. 4
Anwendungen
Es sind verschiedene Anwendungen der komplexen Differenzengleichungen moglich. In seiner Arbeit 3 hat der Verfasser das folgende Interpolationsproblem untersucht: Problem 4.1 Es seien LQ : z = go(z), L\ : z — 9i(z),-- • Ln : z — gn{z) die gegebenen Konturen, wobei alle analytischen Funktionen gi(z), i — 0,l,...,n verschiedene sind. Es sei weiterhin W(z, z) eine gegebene, stetige, nichtanalytische Funktion und agoW = SQ(Z), agiW — si(z),---, a97lW = sn(z). Man soil das Interpolationspolynom Pn(z,z) n-ter Ordnung bestimmen, das den Interpolationsbedingungen (Xgo(z)Pn = S0(z),
Otgi(z)Pn
= Si(z),
••• , agn(z)Pn
= Sn(z),
(4.1)
geniigt. Mit Hilfe der allgemeinen Losung (2.4) von der Polydifferenzengleichung (2.3) hat er auch die Losung des Problems (4.1) in der Form Pn(z, z) = ago{z)W + {z- g0)^w(go,gi) + {z - gQ)(z gi)^w(.9o,9\,92)+ + • • • +(z - g0)(z - g{) • • • (z - gn-i)^w(9o, 9i,---,9n) (4.2)
303
gefunden. In dieser Arbeit betrachten wir eine andere Anwendung bei der Methode vom Eulerschen Typus zum Naherungsauflosen einer komplexen Differentialgleichung erster Ordnung. Problem 4.2 Es sei W(z,z) eine gegebene komplexe Funktion, die beliebig oft im Kreisring P : K°a — 5/2 < \z\ < K°a + 5/2 nach z differenzierbar ist. Nehmen wir an, dass die positive Zahl b = sup bk, k = n + l,n + 2,... existiert, wobei bk Majoranten von Q „ / Z f | ' sind. Aus der Formel (3.5) folgt die Approximation W(z, z) « f0(z) + (z- a/z)h{z)
+ ... + (z- a/z)nfn(z).
(4.3)
Die Koefnzienten fk{z) lassen sich durch die Formel a i W^
ausrechnen. Fiir die Abschatzung des Approximationsfehlers konnen wir die Ungleichung
niitzen und \R\ —+ 0 wenn n —> oo. Im speziellen Fall n = 1 haben wir die Approximation W(z,z)*aa/zW+(z-a/z)aa/zW's
(4.4)
mit dem Approximationsfehler
\R\ < ^-f—• Die Formel (4.4) lasst sich auch in der Form ,
W(z,z)-aa/zW v ' J - £ ^ _ (4.5) w z v z-a/z ' schreiben und man ersieht, dass die ^/-Differenz der Funktion W(z, z) eine Approximation fiir die Ableitung dieser Funktion in einer Umgebung des Kreises z = a/z (zB. in einem Kreisring) darstellt. Es sei die komplexe Differentialgleichung W's = F(z,z,W) (4.6) «
mit der Anfangsbedingung aa/zW
= w0(z)
(4.7)
304
gegeben, wobei w0(z) eine gegebene analytische Funktion ist. Nehmen wir an, dass die Funktion F(z, z, W) im Gebiet
'
K°a-f-<\z\
II: <
2
K\W-w\
stetig ist und dass sie der Bedingung \F(z, I, W2) - F{z, z, W{) |< L |W2 - Wi.\\ fiir beliebige Werte W\,W% geniigt. Es sei ein endliches Intervall [a, A], (a, A € R) gegeben. Teilen wir dieses Intervall auf n gleicher Abschnitten a = xo, X\ = XQ + h, x2 = xo + 2h,..., A = xn — xo + nh (h = (A — a)/n) und konstruieren wir ein System von Kreisen Ki : z = Xi/z (i = 0 , 1 , . . . , n ) . Eine nichtanalytische, komplexe Funktion kann einerseits in der expliziten Form W = W(z, z) erscheinen. Andererseits lasst sie sich auch in der Form einer Tabelle, wenn ihre Grenzwerte auf den gegebenen Kreisen W(z,z)\K. bekannt sind, darstellen. Durch Ausniitzung des Operators ag ist moglich, eine Folge der analytischen Funktionen wo(z), w\(z),..., wn(z) zu konstruieren, dere Grenzwerte auf Ki mit den entsprechenden Grenzwerten von W(z, z) identisch sind. Darstellung einer nichtanalytischen Funktion W{z, z) in folgender tabellaren Form
Ki Wi(z)
K0 : z = x0/z w0(z)
K\\
z = x\/z w1(z)
•**• n ' % — %n 1 %
wn(z)
nennen wir a - R e p r a s e n t a t i o n dieser Funktion auf dem System der Kreisen Ki. Wenn aXi/zW(z,z) = Wi(z) (i = 0 , 1 , . . . , n ) , so ist die Representation (4.8) eindentig und jedem Wert z = Xi/z entspricht eine und nur eine analytische Funktion Wi(z). Das Interpolationspolynom (4.2) das die Funktion W(z, z) approximiert, entspricht der Tabelle (4.8). Suchen wir die Naherungslosung der Aufgabe (4.6)-(4.7) in der Form (4.8). Dabei suchen wir solche Folge der analytischen Funktionen Wi(z), (i — 0 , 1 , . . . , n) dere Grenzenwerte auf den Kreisen z = Xi/z (ZJ+I —Xi = h = {A — a)/n) mit den Grenzwerten der exakten Losung naherungsweise gleich sind. Die Formel (4.4) geht auf Grund (4.6) in W(z, z) « aa/zW iiber.
+ [z- a/z)- aa/zF(z,
z, W)
(4.9)
305
Den ersten Naherungswert w\ erhalten wir durch Anwendung des Operators aXl/z auf (4.9), d.h. 3/1 — d
aXl/zW
= w\ = aa/zW
+
aa/zF(z,
z, W)
oder * w ( o , xi) = aa/zF{z,
z, W)
oder Wl
=
z
w0-F(z,x0/z,w0).
Auf dem Kreis z = x\/z geht die Formel (4.9) in W(z, z) w aXl/zW
+ (z- x1/z)aXl/zF(z,
z, W)
(4.10)
iiber. Den zweiten Naherungswert W2 erhalten wir durch Anwendung des Operators aX2/z auf (4.10) d.h. < W 2 W = w2 = w1 +
-F(z,xi/z,wi). z Durch Fortsetzung dieses Verfahrens erhalten wir auf eine gleiche Art und Weise die allgemeine rekurrente Formel wn+i =wn + -F(z, xn/z, wn) (4-11) z die uns die Naherungslosung der Aufgabe (4.6)-(4.7) in der tabellaren Form (4.8) gibt. Bemerkung Die Methode vom Eulerschen Typus (4.11) fur die Aufgabe (4.6)-(4.7) lasst sich verallgemeinern. Anstatt (4.11) konnen wir die allgemeine lineare Methode der Form
Y^ oiiWn+i = -^2 i=0
(3iFn+i
(4.12)
i=0
untersuchen. Wegen Fn+i = F(z,xn+i/z,wn+i) stellt die Relation (4.12) im allgemeinen Fall eine nichtlineare Differenzengleichung dar. Diese Gleichung lasst sich oft mit Hilfe unserer Theorie der <3>-Differenzengleichungen losen.
306
Literatur 1. Canak M., " Uber die a-Approximation einer nichtanalytischen Funktion durch ein areolares Polynom", ZAMM-Z.angew.Math.Mech., 69 (1989) 4, s. 71 - 73. 2. Canak M., " Anwendung der KRK-Methode auf eine inverse Randwertaufgabe", ZAMM-Z.angew.Math.Mech., 70 (1990) 6, s. 573-574. 3. Canak M., " Uber die komplexen Differenzengleichungen", Proceedings of the eighth symposium of mathematics and its applications, Timisoara 1999, s. 31-38. 4. Keckic J., " 0 jednoj klasi parcijalnih jednacina", Mat. Vesnik, Beograd 6 (21), 1969, s. 71-73. 5. Vekua I., "Systeme von Differentialgleichungen erster Ordnung vora elliptischen Typus und Randwertaufgaben", Veb Deutscher Verlag der Wissenschaften, Berlin, 1956.
307
STABILITY OF SOLUTIONS OF N O N U N I F O R M L Y ELLIPTIC SYSTEMS A N D B O U N D A R Y VALUE P R O B L E M S A. MAMOURIAN Department of Mathematics and Computer Sciences Faculty of Sciences, University of Tehran Enghelab Avenue, 14174 Tehran, Iran E-mail: [email protected] This work is aimed at the investigation of systems of nonlinear equations with degeneration of ellipticity in two-dimensional domains. Introduction It is well-known that methods of complex function theory have influenced the theory of partial differential equations for at least fifty years. The possibility and importance of employing complex function theory in partial differetial equations is so wide that it presents a real difficulty to give a survey of them. For a great many special references one may consult for instance 3 or 8 . For the investigation of systems of differential equations with non-uniform ellipticity, we confine ourselves to the nonlinear system of first order of type w-z = H(z,wz)=G{wz)
+ F{z)
(1)
in D, where w = w(z) = u(x,y) + iv(x,y), z = x + iy,wz = §f = (|jjjf + i^)/2, Wz = <£ = (?%- i | e ) / 2 ; G(0(£ = wz) and F(z) are complex valued functions. We assume that D is a multiply-connected Liapounoff region with boundary L = LQ + L\ H + Lm. Clearly, equation (1) contains the complex form of the Cauchy-Riemann system wz = 0. We assume that (1) fulfils the following condition Condition C\ (I) H satisfies the following inequality
|tf(z,6)-ff(*,6)l
(2)
9(*,6,6) < 9(16-61) < i
(3) s
(II) the function q as a function of \i (fi = | 6 — 61) i continuous in [0, co]; q(n) < 1 for /x € (0, oo); the function /xg2(/x) is increasing and concave.
308
Concerning the nonlinear system (1), we study the following boundary values problem: Problem A Re R t M * ) ] = 7 (*)
(4)
on L, where the coefficients a, 7 are given functions on the boundary L. Similar to the Riemann-Hilbert problem for a uniformly elliptic system of equations, the index corresponding to the boundary value problem A is defined as follows l
-- f d(loga(t)). (5) 2m J Li Remark 1 Let us recall that, in the classical Riemann-Hilbert boundary value problem of the type (l)-(4), relative to the uniform ellipticity of the nonlinear system of equations of Lavrentiev type, the solution w is sought in the Sobolev space Wp(D), for some p > 2. For the equation (1) in the case of non-uniform ellipticity (2)-(3), the L p -theory has not been applied directly for the proof of existence of the solution of (l)-(4). Hence the formulation of the boundary value problem A involves the weak boundary condition (see 2 ). We shall consider the problem A with usual assumptions on the coefficients: Condition Ci The complex function a(t) and the real function 7(£) are Holder continuous on the boundary L, with the exponent v, where 0 < v < 1 (01,7 G HV(L), 0 < v < 1). The complex function is F(z) assumed to be measurable and to belong to the class LP(D), for some p > 2. The solution w will be sought in the Sobolev space Wp(D),p > 2. If G = 0 in (1), the non-homogeneous boundary value problem (l)-(4) will be called problem A$. Lemma Under the Hypothesis (Ci),(C2), if n < 0, the non-homogeneous boundary value problem AQ is solvable, if and only if n = inda
/ a{t)X(th(t)dt-2iRe\ JL
f
1
X(z)F(z)da:
= 0
(6)
JD
where x IS a n arbitrary solution of the homogeneous boundary value problem adjoint to the problem AQ (see for instance 3 , pp. 98-101). Remark 2 Making use of representation formula for the solution w of the problem A: w = T(C){z)+iP(z)
(7)
309
(see for instance J ) , where T(() = (T(Q)D,C^ Lp(D),p > 2, and ip{z) is the solution of the boundary values problem AQ, we observe that T, depending on the index n, satisfies the homogeneous boundary condition corresponding to (4) on L, when z -> t (z G D, t G L). Moreover ^f= ((z). Defining S(() = dgP we conclude that the L 2 -norm of S is equal to one, also S is a bounded operator from Lp(D),p > 1 into itself, and the continuity of || S||p with respect to p > 1 can be proved through the well-known RieszThorin convexity theorem. Remark 3 The norm || || is defined by
IKIlL2(i5) = ( ^ / z ) I C W I 2 ^ ) 2 In view of (1), (4), (7), we obtain the following equation for £:
C = G(S(C)+V')-
(8)
If we assume that C G -^(-D), the integral equation (8) can be solved through a successive approximation method, i.e.
0+i=G(s(0)+V')
(9)
£0 = 0, j = 0,1, • • •. According to the concavity property of C2(C)> the well-known Jenssen inequality, we obtain an inequality of the form
IIC 1 -C 2 II<9(II< 1 -C 2 II)IK 1 -C 2 II,
an
d
(10)
and the existence, also uniquencess of the solution of the integral equation in 1/2(-D) can be proved, i.e. lim Cj = C ( s e e 6 )j—»oo We shall prove that the solution w G WjiD) of the problem (l)-(4) actually belongs to Wp{D) for some p > 2. The number q0 = lim sup(g(0) < 1
(11)
C-»+oo
is called the ellipticity coefficient corresponding to the boundary values problem (l)-(4). This go shows how fast the gradient may approach infinity, and consequently qo will influence the exponent p > 2 of the integrability of the gradient (see also 2 ) .
310
Let p > 2 be such that *>||S||p
(12)
Proposition Under the Hypothesis {C\),{C2), condition (6) and inequality (12), the solution w of the problem (1)~(4) belongs to the Sobolev space W}(D). Proof Since 0 converges to C in L2, it is sufficient to show uniform estimates
for ||0|| P . In view of the relation (9), Q (j = 0,1, • • •) is in LP(D). Co G
Clearly
LP(D),
then, if we write
0 + i = G(S(G) + V') - GW) + G(V/),
(13)
|0+iI < 9(|5(0)|)|5(C-)| + \G(i>%
(14)
we obtain
Taking into account the properties of G, q, and inequality (14), we have
|0+1|<|S(0)l+ 1^1^00), which is derived by induction hypothesis and the Lp - continuity of S. Moreover, because of continuity of ||5|| p , relative to p, a number (5 € (qo, 1) can be chosen such that P\\S\\P<1.
Now, according to (11), there exists N > 0 for which g(C) 3
for
|C|>JV.
If we write q(() = q~i(Q + 92(C)) where fg(C)if qi J
^
\0
|C|
otherwise
and ( )
fO if |CI < iV \ 9(C) otherwise
(15)
311
It is clear that
< 9 i ( | S ( 0 ) | ) | S ( 0 ) | +P\S(Q)\ + W\-
(16)
By integration of both sides of (16) it follows \\Q+I\\LT(D)< P\\S\\P
•
(17)
(qi{\S(Q\))\S(Ci)\pdaz)
+ ( [
\\Q\LP(D)
"+
\W\\LV(D)
but since |5(Cj)| < N, we have \\Q+ihp(D)
< P\\S\\P.\\tj\\Lp(D) +N(mes
{D))' + \W\\LP{D)-
(18)
The following inequality holds \\CJ+I\\LP{D)
<
1
_ ^
s
^ (^V(mes D ) i + HV'IU,^)).
We observe that the right-hand side of the latter inequality does not depend on j , that indicate the uniform estimates of ||CJ+I||L P (D)- Therefore we conclude that C £ LP{D), and we obtain the upper bound
IICIIL
N{mssD)
"^ - i-l\\s\\p{
'
+
mL
"^)-
Since if, e W*(D), T : LP(D) -> W ^ D ) , the solution w = T(C) + V belongs to W^(D). References 1. H. Begehr, G. C. Hsiao, The Hilbert boundary value problem for nonlinear elliptic systems, Proc. of the Royal Society of Edinburgh, 94A, (1983) PP. 97-112. 2. T. Iwaniec, A. Mamourian, On the first order nonlinear differential systems with degeneration of ellipticity, Proc of Sec. Finish-Polish Summer school in Complex Analysis, Jyvaskyla, Edited by J. Lawrynowicz and O. Martio, (1984), PP. 40-52. 3. E. Lanckau, W. Tutschke, Complex Analysis, Methods, Trends and Applications. North Oxf. Acad. (1985). This work is partially supported by grant V-CiRA, Univ. of Tehran
312
4. A. Mamourian, Boundary Value problems and general systems of nonlinear equations elliptic in the sense of Lavrentiev, Demonstratio Math. 17, (1984), PP. 633-645. 5. A. Mamourian, On a mixed boundary values problem for Lavrentiev type equations,Ann. Polon. Math. 45, (1985), PP. 149-156. 6. A. Mamourian, First-order nonlinear system of Lavrentiev type equations and Hilbert BVP, Proc. of Asia Vibr, Conf., Edited by W. Bangchun and T. Iwatsubo, Shenzhen, Northeast Univ. of Tech. (1989), PP. 735-738. 7. A. Mamourian, BVP of a non-uniformly elliptic system of partial differential equations, Demon. Math. X X V I , No. 3-4, (1993), PP. 735-741. 8. G. C. Wen, H. Begehr, Boundary value problems for Elliptic Equations and Systems, Pitman New York(1990).
313
A N EXPLICIT SOLUTION TO A CLASS OF A S E C O N D K I N D COMPLEX I N T E G R A L EQUATION WITH SINGULAR A N D SUPER-SINGULAR KERNEL N. RAJABOV Tajik State National University Dushanbe 734025, Tajikistan E-mail: [email protected] In this paper we have proved for a class of two-dimensional complex integral equations of second kind with singular and super-singular kernels on the boundary of a domain that the homogeneous equations have an infinite number of linearly independent solutions and the non-homogeneous integral equations have always a solution provided the kernels and the right-hand sides satisfy certain conditions. It is proved that the solution of the non-homogeneous equation contains an analytic function, which was found in an explicit form. The corresponding solutions of the integral equations are used for formulation, investigation and t h e construction of solutions of boundary value problems of linear conjugation.
Let D+ be the disc \z\ < R, complementary to D+. 1
T be circle \z\ = R, and D
the domain
Explicit solution of the complex model integral equation for the disc
In D+ we shall consider the following integral equation
U{Z)
-~J J (R-P)4-*)=f{z)>
(1)
where A - is complex parameter, a = constant > 0, ip = arg£, £ = £ + in, p2 = £2 + n2, z — x + iy, and f{z) is a given function. Prom equation (1) we can see that in the case, when f(z) € C{D+), equation (1) has solution in the class function U(z) having zero order 7 > a— 1 in r . The kernel of equation (1) has on T a weak singularity for a < 1, a singularity for a = 1 and a super-singularity for a > 1. Therefore the equation (1) is called complex model integral equation with weak singularity of kernel on the boundary V when a < 1, model complex integral equation with singular kernel on V when a = 1 and complex model integral equation with super-singular kernel on V when a > 1.
314
Problems of finding continuous solutions of first and second order elliptic systems with singularity and super-singularity on V are reduced to the consideration of the complex integral equation (1) ? ' ? ? The problem of finding the general solution of the differential equation for generalized analytic functions with regular coefficients ? s reduced to the consideration of regular integral equation of the type (1) (Vekua type integral equation). In the case a < 1 the solution of equation (1) can be found by succession approximations, see ' In this case equation (1) has a unique solution, which is given by formula
uM = /(.) + X-j j -
^
f -J*'-"' f(Q
P)
D+
where w„(r) = [(a - 1)(R - r ) " - 1 ] " 1 . In the case a > 1 we have the following statement. Theorem 1 Suppose a > 1, ReA > 0, f(z) € C(D+) neighbourhood ofT and
and has a zero in a
- r) 71 ]
f(z) = o[exp(-2ReXwa(r)){R
when r —> R where 71 > a — 1. Then the homogenous equation (1) has an infinite number of linearly independent solutions of type Uk{z) = zk exp(-2Au; a (r)),
k = 0,1,2,...
The non-homogenous equation (1) has always a solution and its general continuous solution contains one analytic function and is given by the following formula U(z) =
A f
+
f(z)+exp(-2\cja(r))$(z)+
f exy[2\(LJa(p) - ua(r)) + itp]f(Q
W J
(R-pnc-z)
'
... (3)
D+
where <&(z) is an arbitrary analytic function in D+. In the case a = 1 the following theorem is true: Theorem 2. Let in equation (1) a = 1, ReA > 0, f(z) £ C(D+) and has a zero in a neighbourhood of T and f(z) =
o[(R-rr>)
315
when r —> R where 72 > 2|ReA|. Then the homogenous equation (1) has an infinite number of linearly independent solutions of type Uk(z) = zk(R~r)+2X,
k = 0,1,2.
The non-homogenous equation (1) has always a solution, its general continuous solution contains one analytic function and is given by the following formula
+
+
(4)
"w - ><•> <* ^ ')"*(•> ; //'f^'Vlx?-^ D+
where <&(z) is an arbitrary analytic function. Theorema 1 and 2 are proved using the connection of integral equation (1) and the following elliptic first order system with singular and super-singular coefficients on the circle T dU
j_
+
^
XeiV
rrr s
d
f
U
W=rF M=di'
(^
(5)
where £ = | ( £ + i £ ) . At first we find the solution of equation (5). In the regular case an analogous solution of equation (5) is searched in the form U{z) = V(z)exp[-2XLJa(r)],
(6)
when a > 1, and in the form U(z) = V(z)(R-r)2X,
(7)
when a = 1 , where V(z) is new unknown function. Then we substitute the valued U(z) from the formula (6) when a > 1 and from the formula (7) when a = 1 in the equation (5). As the function exp[—2Xwa(r)} when a > 1 and (R — r)2X when a = 1 are solution of homogenous equation (1) we find the function V(z) correspondingly from the following equalities:
W=e2X„a{r)dl oz ^ = (R-r)~2X^, oz
whena>l
(8)
dz when a = 1. oz
(9)
316
If the equations (8) and (9) have solutions, which can be represented in the form [1]
1 d(
c-
)+
V(z) = {z) - -
•
J
z
-2Xd<; fdf(R / ^ = --p) j - 1 d( z
c-
D+
5
-,
when a =1,
(11)
where $(z) is an arbitrary analytic function. Let function f(z) have zero in the neighbourhood of T and its behaviour is determined by following asymptotic formula f(z) = o[exp(—2\u)a{r)){R — r) 7 1 ],
whereji>a
— l,
when a > 1,
r —> R and f(z) = o[(R — r) 7 1 ],
where 71 > 2,
when a = 1, r —> i?.
Then we find V(z) = * ( , )
+
f(z)eM2X^(r))
+
±ff
^t^™™,
(12)
D+
when a > 1 and
vM-«,H/W(«-o-»+*//v^
(13>
00
when a = 1, by integrating in the right sides of the equalities of the formulas (10), (11) in according to Poincare-Bertrann formula and conditions for the function f(z) (exp(2\uia{r)f(z))r=R ((R-r)-2Xf(z))r=R
= 0, = 0,
ReA > 0 if a > 1, ReA>0
ifa = l,
Then we substitute the value of V(z) from the equalities (12), (13) into the formulas (6) and (7) accordingly to a > 1 and a — 1. Hence we find the solution of integral equation (1) correspondingly for a > 1 and a = 1. Let in equation (1) ReA < 0. In this case, if exist the solution of the equation (1) from class C(D+), then it represented in the form (3) by $(z) = 0, when a > 1 and in the form (4) by $(z) = 0 , when a = 1. Besides, easily it is possible see, that U(Relv) = 0. Prom here follows, that in this case
317
U(z) in neighbourhood V has first order zero. But at a > 1 it is necessary that the solution equation (1) U(z) has zero order 5 > a - 1. If f(z) in neighbourhood of T has zero order 5\ > a - 1, then solution of the type (3) U(z) in neighbourhood of T has zero order 5 > a — 1. Then from theorem 1 and 2 is follows: Theorem 3 Suppose a > 1, ReA < 0. Besides, let f(z) G C ( 5 + ) and / ( z ) = 0[(i? - r)s], S > a - I, when r —> R, a > 1. Then the homogeneous equation (1) has no non-trivial solution. The non-homogeneous equation (1) has a unique solution, which is given by the formula (3) with $(z) = 0 a > 1 and by the formula (4) with $(z) = 0 a = 1, Besides U(z) = 0[(R - r)s], 5 > a — 1 by a > 1. 2
Explicit solution of the non-model complex integral equation for the disc
At present we consider the following integral equation:
D+
where A+(r) is given function in D+,A+(r) £ C{D+). To find a solution of the equation (14), we represent it in the following form A+(R)
f f
——J
J
u(z}
e^UjQdC
_
(R-Pnc-*)-fix)-
D+
HI 1 f
fe^(A+(R)-A+(p))U(C)dC
(R-pnc-z)
D
We assume, that function A+(r) fulfils the following inequality in a neighbourhood of circle T: \A+(R)-A+(r)\
7 > a - 1.
Moreover, assuming that,
n*) = s(*)-lj je^(A+(R)-A+(p))U(C)dC (R-p)»(C-z) D
(15)
318
is a known function, we resolve the model integral equation
vw-Z&ff A+(R)
f f
e^U{QdC (iJ-p)a(C-z)
F(z).
D+
Writing the solution of this equation by a > 1 and a = 1, after solving the corresponding integral equations with weakly singular kernels ? ' ? we shall obtain the folloving solution of equation (14) U(z) =
(16) f(z) + exp
2A+(R)cja(r)-W+(z) e^A+(p)exp{2A+(R)Lva(p) (R-p)*(£-z)
•w+i// =
+
W+(0}f(Od(
K+[$(z),f{z)],
if a > 1, and (17)
U(z) = 2A+
f(z) + {R- r)
^
*(z) + \f j D+
=
n J Jr. K+[$(z)J(z)],
exp [ - W%{z)] x A+W (R-p)^+(R)+1
exp[W+(0] f(Q
if a = 1, where
"CfM-i//
(A+(JZ)-A+(p))e^dC (i?-p)«
(c-*)- 1
L>+
The solution of the forms (16) and (17) exists if functions f(z), satisfy in neighbourhood of T the inequality (15) and f(z) = o[exp(-2ReA+(R)iJQ(r))(R Re(A+(R))
> 0
- r)™],
72 > a - 1
A(r) (18)
if a > 1, and f(z) = o[(R-r)'»],
if a = 1. Consequently, we have proved:
K>2\ReA+(R)\,
(19)
319 Theorem 4 Suppose a > 1, A+(r) e C(D+), ReA+(ft) > 0, / ( z ) 6 C(D ) and has a zero in a neighbourhood ofY, and the behaviour of A+(r) and f(z) is given correspondingly by the inequality (15) for a > 1 and equality (18) for r —> R. Then the homogeneous equation (1) has an infinite number of linearly independent solutions of type +
Uk(z) = zk exp[-2A+(R)ua(r)
- W+(z)],
k = 0,1,2,...
The non-homogenous equation (1) is always solvable, its general solution contains one analytic function and is determined by the formula (16). Theorem 5. Let a = 1, A+(r) e C(D+), ReA+(R) > 0, f(z) € C(D+) and has a zero in a neighbourhood ofT, and the behaviour of A+(r) and f(z) is given correspondingly by the inequality (15) for a = 1 and equality (19) for r —> R. Then the homogenous equation (1) has infinity a number of linearly independent solutions of type Uk(z) = zk exp[-W+(z)](R
- r)2A+(R\
k = 0,1,2,...
The non-homogenous equation (1) is always solvable, its general solution contains one analytic function and is determined by formula (17). Let in equation (14) a > 1, A+(r) £ C(D+), ReA+{R) < 0 and in a neighbourhood of circle T fulfile the unequality (15). Then from theorem 4 and 5 are follows: Theorem 6 Let a > 1, A+{r) G C(D+), ReA+{R) < 0, f{z) e C{D+). The behaviour of A+(r), f(z) is defined correspondingly by the inequality (15) and the following asumptotic formula f(z) = o[(R-r)5>},
S1>a-1.
Then the equation (14) has a unique solution, which is given by the formula U(z) = K+[0,f(z)},
when
a>\
U(z) = K+[0,f(z)},
when a = 1.
and by the formula
Now we consider the integral equation transposed to equation (14), that is the following equation
D+
320
Introducing the new unknown function ip(z) = (R-
r)-ae-ie(4+(r))-1V(.z))
we come to an integral equation of the type (14) with the right-hand side = g(z)(R rrae-ie(A+(r))-\ gi(z) It follows from the theorem 3 that the particular solution of the homogenous equation (20) are the following functions: Vk(z) = A+(r)ei@(R
- r)~azk exp[-2A+(R)wa(r)
- W+(z)},
k = 0,1, 2 , . . . (21)
when ReA+(R) > 0 and a > 1. General solution of non-homogenous equation (20) is the following function: (22)
V(z) = g(z) + eieA+(r)(R
- r)~a exp
-2A+(R)cja(r)-W+(z)
W + ljj exp[2^+(JZ)a,C (p) + W + ( C ) ] a — z
g(c)tfc
D+
M+ when ReA+(R) > 0, g(z) in a neighbourhood F has zero, and its behaviour is defined by the following asymptotic formula g(z) = o[exp(-2ReA+(R)uia(r)},
if
r -* R
(23)
The above investigation can be stated as follows: Theorem 7 Suppose in equation (20) a > 1, A+(r) G C(D+), g{z) G C{D), RQA+(R) > 0. The function A+(r) satisfies in a neighbourhood of V the inequality (15). The function g(z) has zero in a neighbourhood ofT and its behaviour is determined by the assymptotic formula (23). Then the homogenous equation (20) has an infinite number of linearly independent solutions of the type (21). The non-homogenous equation (20) is always solvable, its general solution contains one analytic function and is determined by the formula (22) where $i(z) an arbitrary analytic function. The solvability of the equation (20) for a — 1 is formulated in the following assertion. Theorem 8 Suppose in equation (20) a — 1, A+(r) G C(D+), g(z) £ C(D), ReA+(R) > 0. The function A+(r) satisfies in a neighbourhood ofT
321
the inequality (15). The function g{z) has zero in a neighbourhood ofY and its behaviour is determined by the assymptotic formula g{z) = o[(R - r ) 7 4 " 1 ] ,
74 > 2ReA+(R)
as r -> R.
Then the homogenous equation (20) has an infinite number of independent solutions of type: Vk{z) = zk(R - r)2A+W-lA+{r)ei@
exp(-W+(z)),
k = 0,1,2,...
The non-homogenous equation (20) is always solvable, its general solution contains one analytic function and is determined by the formula V(z) =
(24) g(z) + (R-
2
l+ R
1
+
r) ^ ( )- A (r)e
i0
exp ( -
W+(z)}
$(*) + ! / / eMwA(0)g(OdC (R-p)2A+(0(C-Z)
= M+\^i(z),g(z)], where $(z) is an arbitrary analytic function. Suppose a > 1, A+{r) e C(D+), g{z) G C(D+), ReA+{R) < 0. Function A+(r) satisfies in a neighbourhood of T the inequality (15). Then from theorems 7 and 8 follows: Theorem 9 Consider in equation (20). Suppose a > 1, A+(r) G C(D+), g(z) G C(D+), HeA+(R) < 0. Function A+(r) satisfies in a neighbourhood of r the inequality (15). Then the equation (20) has a unique solution, which is given by the formula V(z) = M+[0,g(z)],
when
a > 1
V{z) = M?[0,g{z)],
when
a = 1
and formula
3
Explicit solution of a complex nonmodel integral equation for unbounded domains
In D
we shall consider the integral equation _ 1 f
f D~
e^A-(p)U(QdC
M,
(25)
322
where a = constant > 0, A~(r), f(z) are given functions in D~, if = arg£. By the analogy with p.l. it is possible to prove the following assertions about solvability of the equation (25): Theorem 10 Consider in equation (25). Suppose a > 1, A~(r), f(z) £ C(D~), Re(^4 _ (i?)) < 0. The function A~(r) satisfies in a neighbourhood of r the following inequality \A-(r)-A-((R)\
73
> a - 1.
(26)
The function f(z) has a zero in a neighbourhood of T and its behaviour is determined by the following asymptotic formula f{z) = o[exp(2ReA-(R)wa{r))(r
- R)-*],
73
> a - 1,
A~(oo) — Ao = constant. Then any solution of the equation (25) of class C(D~) can be represented in the form U-(z) =
(27) f{z) + exp [2A-(R)wa(r) [ ]
=
1 f
+ W^{z)^ x
f exp[-2A-(R)uja(p)
W J
- WX(Q + i
(p-RWC-z)
K-[*-(z),f(z)],
where w a (r) = [(a - l)(p - i ? ) " " 1 ] - 1 ,
wiM^-JJ (A-(p)-A-(R))dC (p-R)°(C-z)
'
D-
$(z) is an arbitrary analytic function in D~. Theorem 11 Consicer in equation (25). Suppose a = 1, A~(r), f(z) G C(D~), BB(A~(R)) < 0. The function A~(r) satisfies in a neighbourhood ofV the condition (26) by a = 1. The function f(z) has a zero in a neighbourhood of r and its behaviour is determined with the following asymptotic formula f(z) = o[(r - R)-*],
74 >
2\ReA-(R)\,
A~(oo) = Ao, /(oo) = /o is bounded. Then any solution of the equation (25) of class C(D~) can be represented in the form U~(z) = f(z) + * - ( z ) ( r - R)'2A~^
^//'^)"' D-
,a)expiw (
exp(WX(z))+
( iy /(cK
(28
t i)
323
where $ (z) is an arbitrary analytic function in D and its behaviour in a neighbourhood of z = oo determined by the following assumptotic formula $-(*) = 0[r~6], 6 > 2\ReA-{R)\, SeN. It follows from the representations (27) and (28) of the solution of equation (25) the following statement: Suppose in equation (25) a > 1, A~(r) £ C(D~), ReA~(R) > 0, and suppose the condition (26)is satisfied. Then we get from theorem 10 and 11: Theorem 12 Consider in equation (25). Suppose a > 1, A~(r), g(z) € C(D~), ReA~(R) > 0. Besides, A~(r) the condition (26) satisfies. The function f(z) satisfies in a neighbourhood ofT be the condition
f(z) = o (R-r)
5x > a - 1.
Suppose, further, that in a neighbourhood infinity the following condition is satisfied: f(z) — o(r~e),
e>0
a = 1, r—>oo;
/ is bounded for a > 1, /(oo) = /o. Then equation (25) has a unique solution in the class C(D+), which is given by the formula U(z) = K-\0,f{z)},
when
a > 1
U(z) = # r [ 0 , /(z)], when
a = 1.
and formula
In this case the behaviour of the solution of equation (25) in a neighbourhood of r and of the point at infinity correspondingly are given by the following asumptotic formulas: U(z)=o[(r-Rf% U(z) = o(l), U(z) = o{r~e),
52>a-l,
byr-+R,a>l;
by r —> oo, a > 1; e > 0, by r -> oo, a = 1.
Remark 1 Any solution of integral equation (25) of class C(D~) has zero in r and its behaviour is determined by the following asymptotic formula U{z)=o[(r-R)2\RelA~W\
for
a = l
and U(z) = o[exp{-2\Re{A-(R))\)},
for
a >1
324
Remark 2 Solution of the form (27) unlimited for \z\ —» oo and its behaviour is determined by the following asymptotic formula
0\r^Re^^\
U{{z) =
Solution of the form (27) is limited for \z\ —» oo and its value is determined by following equality [/-(oo) = / ( o o ) + $~(oo). 4
Explicit solution of a class of complex model integral equations for kernels with two singular lines
Let Df be the ring D\ = {z : R\ < \z\ < R2}, I \ the circle \z\ = Ri, T2 the circle \z\ = R2. In D~i we consider the integral equation, whose kernel has singularities on Ti and I V
where A is a piece-wise constant function: A = Ai, for R\ < r < R, A = X2 for R < r < R2, R! < R < R2. As in p.l., using the connection of the integral equation (29) with the generalised Cauchy-Riemann system dU_ \ei&U(z) dz + (r-R1)(R2-r)
Of ~ dl'
we prove that the function UQ{Z) — <&(z)k(r), where Rr> — r
2X
i
k(r) = ( )«2-*i for r — R\
R1
and (Ro
— r \ «2-«l
*>-(;=*)
Rr, — R 2(A1-A2)
t^ft)
"•-/-•*<'<«•.
$(z) is an arbitrary analytic function for ReAi < 0, and ReA2 > 0 gives the general solution of the homogeneous equation (29) of class C(D^).
325
By a first-hand calculation is proved that if the function f{z) has zeros in neighbourhoods of Ti and T% and its behaviour is determined by the following asymptotic formulas f{z)=o[{r-R{f% ^ > ^ ~ ^ -
1
'
for r-*Ru
(30)
f(z) = 0{(R2 - r)
- 1,
for r - R2,
(31)
S2 > ^ ~ ^
then the particular solution of equation (29) is given by the following equality
^ " W M + ^ Z /k<j>y Q c-z -d( D+
Then the general solution of integral equation (29) of class C(D^) is represented in the form U(z) = ${z)k{r) + M(f),
(32)
where Q(z) is an arbitrary analytic function. The solution of type (32) has zero in neighbourhoods of Ti and T2 and its behaviour is determined by the following asymptotic formulas U(z) = o[{r - R^1^1*^11},
if r-^Rx
U(z) = o[{R2-r)^2^lReX%
if
r-^R2.
Therefore we have the following result: Theorem 13 Let in equation (28) ReAi < 0, and Re\2 > 0, f(z) G C(D^) and f has zeros in neighbourhoods ofT\ and T2 and its behaviour is determined by the asymptotic formulas (30), (31). Then any solution of the integral equation (29) of class C(D^) can be represented in the form (32), where $(z) is an arbitrary analytic function in D^. In the case, when ReAi > 0, ReA2 < 0, we have the following assertion. Theorem 14 Let in equation (28) ReAi > 0, ReA2 < 0, f(z) £ C{D+), has zeros in neighbourhoods ofTi, T2 and its behaviour is determined by the formulas /(z)=o((ili-r)ei),
£i>0,
for r -> R±
f{z) = o((r-R2y*),
e2>0,
for r -> R2.
326
Then the integral equation (29) has a unique solution, which is given by the formula U(z) =
5
M(f).
Boundary value problems
The above obtained solutions of the integral equations (1), (14), (25), (28) containing an arbitrary analytic functions in the case a = 1 and a > 1, permits us to study a number of boundary value problems of Schwarz, RiemannHilbert and of linear conjugation type. For example the linear conjugation boundary value problem for integral equations (14), (25) if a = 1 and a > 1 sets as follows: Problem Ri Let a = 1. Find the solutions of integral equation (14) in D+ and of integral equation (25) in D~ of classes C(D+ UT) and C(D~ UT) such that the function V~(z) = U~(z)(r — R)2A ^ is bounded at infinity and satisfies the boundary condition [U(z)exp(W+(z))(R-r)-2A+W]^R G(t)[U(z)exp(-WX(z))(r
- R)2A~^];=R
= +g(t),
(Rl)
where G(t) and g(t), t GT, are given functions that satisfy Holder's condition and G{t) ^ 0. Problem Ri Let a > 1. Find the solutions of integral equation (14) in D+ and integral equation (25) in D~ of classes C(D+UT) andC(D~lir) such that the function V~(z) = U~(z) exp(—2A(R)uja(r)) is bounded at infinity, satisfies the boundary condition [U(z)exp(2A-(R)wa(r)
+ WA(z))}+=R
=
G(t)[U(z) exp(-2A-(R)wa(r)
- W+(z))];=R
+ g(t).
(R2)
where G(t) and g(t), t £T, are given functions that satisfy Holder's condition and G(t) ^ 0. We can analogously formulate various other problems, prescribing conditions of a problems of linear conjugation type for some values of a dependence and conditions of an interior and exterior Riemann-Hilbert problem, or of an interior and exterior Schwarz type problem. Using the general solutions of the integral equations (14) and (25) for a = 1 and a > 1 from the formulas (16), (17), (26), (27) the above problems can be
327
reduced to the successive solution of linear conjugation problems for analytic functions. Problems Ri, R2 are reduced to the following linear conjugation problems for analytic function: *+(*) = G(t)
(33)
where 9i(t) =
(34)
u\ + 9Vl I ( exp[-^(C) + iy]A-(p)/(QdC (p-R)1-2*-W(<:-Re**)
7T J J D~
exp[W+(C)+M.4+(p)/(CR {p-Ry+2A+(R){£-Re*®)
Ml
D+
if a = 1 (for problem Ri) and 5i (*) =
(35) 9{t) +
~ J
J
(p-RWC-R**)
_ 1 f f exp[2A+(R)cja((p) nj J
mdC
+ W+(Q +iip}A+(p)f(Qd( (R-p)«((-Ret®)
D+
if a > 1 (for problem R2). Let K = IndG(i). If K > 0, then the problem (32) is always solvable and its general solution contains K + 1 arbitrary complex constants and is given by the following formula 6 : *(z) = X(z)[PK{z) + *(z)], where *[Z)
2niJ r
X+(t)(t-zy
when z e D+ and x(z) — z~Ker(z\
X[Z
>
when z G D _ ,
(36)
328 K
G(t)]dt r(*) = - Wln[t^(t)(t-z) If K < 0, then problem (33) is solvable if and only if K — 1 solvability conditions tgi
J r
^dt
X+(t)
= 0,
k = l,2,...,K-l
(37)
are satisfied. In this case the solution of problem (33) is given by the formulas (36) if PK^(z)=0. Then we obtain the solutions of problems R^ and Ri replacing the values of $(z) which are found in this way in the representations (16), (27) for a > 1 and representations (17), (28) for a = 1. Therefore we conclude: Theorem 15 Let a > 1, K = IndG(i) and functions A±(r),f(z) from integral equations (14), (25) satisfy conditions of the theorem 3 and 7. If K > 0, then problem R2 is always solvable and its general solution contains K + 1 arbitrary complex constants. If K < 0, then problem R2 is solvable if and only if K — 1 solvability conditions (37) are satisfied (gi(t) - are given by equality (35) ) . In this case general solution of problem R2 are given by formulas (16), (26), where analytic function $>(z) are defined by the formulas (36), (35) (at K<0, PK{Z) = 0). Theorem 16 Let a = 1, n = IndG(£) and functions A±(r),f(z) from integral equations (14), (25) satisfy conditions of the theorem 4 and 8. If K > S, then problem R\ is always solvable and its general solution contains K — 5 arbitrary complex constants. If K < 5, then problem R2 is solvable if and only if S — K solvability conditions (37) are satisfied (g\ (t) - is given by equation (34) )• In this case the general solution of problem R\ is given by formulas (17), (27), where the analytic function $(z) is defined by the formulas (36), (34) (at K < 0, PK-i(z) = 0).
References 1. Vekua I. N., Generalized analytic functions, Fizmatgiz, Moscow, 1959, English transl., Pergamon Press, Oxford, and Addison-Wesley, Reading, Mass., 1962, 628 p.
329 2. Rajabov N., On the one methods solution of the Vecua I.N. integral equation. Dokl. An. Taj. SSR, vol. 4, N 5 (1961), pp. 3-7. 3. Rajabov N., Riemann-Hilbert boundary value problems for the second order linear elliptic systems with singular coefficients. Boundary value and initial value problems in complex analysis: studies in complex analysis and its applications to partial differential equation I, Longman, Scietific and Technical, New York 1991, pp. 13-28. 4. Rajabov N., To theory second order linear elliptic systems which that all boundary is singular lines. Mathematical Herald v. 40 N 3-4 (1988), p. 301-307 (Materials third international symposium-Complex analysis and appications Herceg-Novi, Yugoslavia, May 23-29, 1988). 5. Rajabov N., Integral representations and boundary value problems for some second order linear elliptic systems with regular and singular coefficients. Complex analysis and applications 87, Sofia 1989, pp. 431-441. 6. Gachov F. D., Boundary value problems, "Nauka", M. 1977, 640 p.
330
A N EXPLICIT SOLUTION TO A CLASS OF S E C O N D K I N D L I N E A R SYSTEMS OF COMPLEX I N T E G R A L EQUATIONS WITH SINGULAR A N D SUPER-SINGULAR KERNELS (ABSTRACT) N. RAJABOV Tajik State National University Dushanbe 734025, Tajikistan E-mail: [email protected] Let D+ be the disk \z\ < R,T the circle \z\ = R. In D+ we shall consider the following system of integral equations
R - l
D
±
where ajk (j, k = 1,2) - are given real constants,
an — A, ai2 = 0, 021, a-22 — A
(2)
and of the exponent of the singularity (a < l;a = l;a > 1). We have proved, that for a = 1 and a > 1 the homogeneous system (1) has an infinite number of linearly independent solutions, when the roots of the equation (2) real and different, Aj < 0 (j = 1,2) . The general solution homogeneous system (1) from class C(D+) depends on two analytic functions. In this case, if the conditions fj(z) = 0[exp((Ai + X2)oja(r))(R - r p ] 7 > a - 1 for
a > 1,
331
and /,-(*) = 0 [ ( f l - r ) 2 « A l + A a ) ] , for
a = 1,
wa(r) = [(a — 1)(-R — ?*) a _ 1 ] _ 1 , for r —> R are satisfied, the non-homogeneous system (1) has always a solution. Next consider the case that a > 1 and that the roots of the characteristic equation are real and equal (Ai = A2 = A < 0). Then the homogeneous system (1) has an infinite number of linearly independent solutions. Provided the functions fj (z) satisfy for r —» R the following conditions fj{z)=0[(R-r)'*>],
72
= 2|A| + £ by a = 1,
/,-(*) = 0[exp(+2Aw Q (r)), {R-r)™),
73
> 2(a - 1),
the non-homogeneous system (1) as always a solution. Its general solution from the class C(D+) contains two arbitrary analytic functions. If a > 1 and if the roots of the equation (2) are conjugate complex with ReA < 0, then the homogeneous (1) has again an infinite number of linearly independent solutions. The non-homogeneous system (1) has always a solution if for r —> R the funcitons fj(z) G C(D+) satisfy the following conditions: fj(z) = 0[exp(2i?eAa,Q(r)) • (R -
r)^}
73 > 2|J?eA| + e, 7 = 1,2 at a > 1, fj(z) = 0[{R-r)J],
7 4 > 2 | i ? e A | + e at
a=l.
References 1. Vekua I. N., Generalized analytic functions, Fizmatgiz, Moscow, 1959, English transl., Pergamon Press, Oxford, and Addison-Wesley, Reading, Mass., 1962, 628 p. 2. Rajabov N., On a method for solving the I.N. Vekua integral equation. Dokl. AN Taj SSR, vol. 4, N 5 (1961), pp. 3-7. 3. Rajabov N., Riemann-Hilbert boundary value problems for second order linear elliptic systems with singular coefficients. Boundary value and initial value problems in complex analysis; studies in complex analysis and its application to partial differential equation I, Longman, Scientific and Technical, New York 1991, pp. 13-28.
332
4. Rajabov N., On the theory of second order linear elliptic systems for which the whole boundary are singular lines. Mathematical Herald, v. 40 N 3-4 (1988), p. 301-307 (Materials third international symposium Complex analysis and applications, Hercegnovi, Yugoslavia, May 23-29, 1988). 5. Rajabov N., Integral representations and boundary value problems for some second order linear elliptic systems with regular and singular coefficients. Complex analysis and applications 87, Sofia 1989, pp. 431-441. 6. Rajabov N., An explicit solution to a class of two-dimentional second kind complex integral equation with singularities and super-singularities on the boundary of the domain. Materials International scientific conference "Differential equation and its applications", Dushanbe - 2000, p. 72-73.
333
INITIAL VALUE P R O B L E M S FOR PSEUDOHOLOMORPHIC FUNCTIONS (ABSTRACT) A. O. gELEBI Middle East Technical University Department of Mathematics 06531 Ankara, Turkey E-mail: [email protected] In this talk we consider the initial value problem dw ~dt
+
*"- ^4(^) Mi(f9 _ ,
S
_, ,
. / (LEW
dz \ dz + A0(t, z)w + B0(t, z)w + D0(t, z) w(0,z) = wo(z)
(1) (2)
in which dsui dw . _ _ • — 3 AEW — BEW dz ' dz for time dependent Holder continuous pseudoholomorphic functions which are characterized by lw\= —r - aEw - bEw = 0, dz
w e CX(D)
where a,E,bE,AE,BE are characteristic coefficients 1 . First, we have derived the sufficient conditions under which L is associated t o f 2 . Next we define a scale of Banach spaces Ws := Pr}3(E)r\Cx(Ds), where {Ds}o<s
334
References 1. Bers, L., Theory of Pseudoanalytic Functions, New York University. (1953) 2. Tutschke, W., Solution of Initial Value Problems in Classes of Generalized Analytic Functions, Teubner Leipzig and Springer Verlag. (1989) 3. Yiiksel, U. and Celebi, A.O., The Cauchy-Kowalewski Theorem in the Space of Pseudoholomorphic Functions, Complex Variables, 29, 305- 311. (1996)
335
A B O U N D A R Y VALUE P R O B L E M FOR A SPECIAL CLASS OF GENERALIZED ANALYTIC F U N C T I O N S A N D ITS APPLICATION TO S E C O N D O R D E R D I F F E R E N T I A L EQUATIONS (ABSTRACT) U. AKSOY Middle East Technical University, Department of Mathematics 06531 Ankara, Turkey E-mail: [email protected] In this study, the Dirichlet boundary value problem for a first order partial complex differential equation —— + AiD = 0 in oz Re w = g on Im w(zo) = c,
0 dfl,
z0 £ Ct
is considered in a special class of generalized analytic functions where fi is a bounded domain in the complex plane, w S CQ(fi) and A is a complex constant. The problem is converted to a fixed point problem for integral operators. Using the contraction mapping principle, a condition on A is obtained for the uniqueness of the solution. We have used this solution for the discussion of the Dirichlet problem for the second order partial complex differential equation
H-IAIW
(!)
The equation (1) is decomposed into a system of first order partial complex differential equations
oz oz Then, we have defined a boundary value problem for this system of equations. We have also given the properties of the solutions.
336
References 1. U. Aksoy, On a boundary value problem for generalized analytic functions. Master of Science Thesis, Middle East Technical University, 2000.
337
C O M P L E X M E T H O D S IN O P E R A T O R THEORY (ABSTRACT) H. L. VASUDEVA Panjab University, Dept. of Mathematics Chandigarh - 160014, India E-mail: [email protected] Suppose f(x) is a real function defined on the interval (a, 6). Let A be a bounded selfadjoint transformation on a Hilbert spacei? with spectrum in (a, b). By f{A), we understand the operator J f(x)dEx defined from the spectral decomposition. The domain of / is a class of operators admitting a natural order: A
iff
B-A>0,ie,((B-A)u,u)>0
for every ueH. The function / is said to be operator monotone if A < B implies f(A) < f(B). A Pick function is a function ip(Q = U(Q + iV(() holomorphic in the upper half plane with positive imaginary part, ie, if C = £ + ir] then
V(C) > 0
for
n > 0.
We denote this class by P. Let (a, b) be an open interval of the real axis. By P(a, b), we denote the subclass of P consisting of those Pick functions which admit analytic continuation across the interval into the lower half plane and where the continuation is by reflection. Thus the functions in this class are real on the interval (a, b) and are continuable throughout the lower half plane. It is proposed to briefly discuss Loewners theory of monotone matrix functions and his analytic continuation theorem which guarantees that a real function on an interval of the real axis which is monotone operator function is the restriction to that interval of a Pick function. References 1. T. Ando, Topics in operator inequalities, Hokkaido University, Sapporo, 1976. 2. R. Bhatia, Matrix Analysis, Springer Verlag, New York, 1997. 3. K. Lowner, Uber monotone Matrix Punktionen, Math Z. 38 (1934), 177 216.
338
O N O N E B O U N D A R Y VALUE P R O B L E M OF T H E T H E O R Y OF ANALYTIC F U N C T I O N S O N A C U T P L A N E (ABSTRACT) N. MANJAVIDZE N. Muskhelishvili Instiute of computing Mathematics I. Chavchavadze Ave. 2/2, Apt. 72, 380097 Tbilisi, Georgia E-mail: [email protected] On a complex plane cut along Liapunov-smooth arcs we consider the following boundary value problem: Find an analytic vector $(z) = ( $ 1 ( 2 ) , . . . , <&n{z)) satisfying the boundary condition m
k=0
where T denotes the union of arcs. Under certain restrictions on the given coefficients and the right-hand sides necessary and sufficient solvability conditions and an index formula for this problem in some classes of analytic vectors are established.
C H A P T E R 4:
COMPLEX METHODS IN HIGHER DIMENSIONS
341
O N A CLASS OF ELLIPTIC SYSTEMS IN T H E H A L F P L A N E W H I C H A R E S I N G U L A R AT T H E B O U N D A R Y A. D Z H U R A E V Mathematical Rudaki prospect
Institute of the Tajik Academy of Sciences 33, 734025 Dushanbe, Republik of Tajikistan E-mail: dzhuraev@khj. tajik, net
In this paper for first and second order systems of partial differential equations which are elliptic in the halfplane and singular at the boundary, necessary and sufficient solvability conditions are derived.
1
Introduction
Here we consider some complex partial differential equations of elliptic type in the halfplane, with coefficients in lower parts having strong singularities at the boundary which arise, for instance, in the following situation. In the space R3 of the variables (x,y,t) — (z,t),z = x + iy any linear system of partial differential equations of first order for two real functions u\(x, y, t), U2(x, y, t) can be written in the following form as an equation for the complex valued function w(z, t) — u\ + iu^ (w = u\ — IU2) : . dw , , . dw , , dw ,, . dw a(z,t)+ b(Z,t)-+c(z,t)-+d(z,t)+
+e(z,t)-£
+ f(z,t)-^
+ A0(z,t)w
+ B0{z,t)w
= g(z,t)
(1.1)
Apparantly this equation cannot be elliptic in R3. The surface w(x, y, t) = const with grad w / 0 is a characteristic for (1.1) if w(x,y,t) satisfies the equation ,du>.2
ail
W
,9u,2
+a22(
^
,9LJ.2
dw duj
^
fe-^
} +a33(
} +ai2
du) dw
+ai3
^-^
du) du
+a23
^ - ^ = 0;
where a n = \a\2 + \c\2 - \b\2 - \d\2 + 2Re (ac - bd), a 22 = \a\2 + \c\2 - \b\2 - \d\2 - 2Re (ac - bd), a 33 = 4(|e| 2 - | / | 2 ) , an = -41m (ac-bd), a13 = 4Re [(a+c)e—(b+d)f], a23 = -41m
[(a-c)e-(b-d)J].
342
In particular case when b = d — f = 0 this equation splits into two linear equations L\UJ = Re (a + c) — ox ,
\ dw ox
Im (a — c)——I- 2Re c • —— = 0, ay dt _
.
L2UJ = Im (a + c)——hRe a - c
.du! du) — + 21m c • —- = 0, oy at
which is integrable if the commutator [ L i , ^ ] is a linear combination of the operators L\ and L2. If \a\ ^ \c\, then we get the system du) 2Re(a — c)e dw „ 1 — 2 2 • — = 0, dx \a\ — \c\ dt '
dw dy
21m (a + c)e 9w —• — = 0 \a\2 — |c| 2 dt '
which has a solution w(x, y, t) with ^ ^ 0 if and only if d ,Re (a — c)e d^ ( | a | 2 - | c | 2 '
+
d Im (a + c)e fe( | a | 2 - | c | 2 ' +
2Re(a — c)e d Im (a + c)e. | a | 2 - | c | 2 0 T |a| 2 - |c| 2 ^~
2Im(a + c)e 9 R e ( a - c)e i( | a | 2 - | c | 2 )
=
In case when coefficients do not depend on t this last condition is reduced to d Re(a-c)e V |a|2-|c|2 '
d l m ( a + c)e dx | a | 2 - | c | 2
u
;
When the integrability condition holds, equation (1.1) can be integrated passing to the characteristic variables for any smooth right-hand side g(z,t). For example, consider the following particular case of (1.1): dw ,. ^ + *
. dw „, % = /(M)
.„ „. (1.3)
If A does not depend on t and satisfies the condition dI™xx = a ^ e A , then in the variables £ = x, r\ = y, r = t—w(x, y), where w(x, y) = J Re A(z, y)dx+ Im A(a;, 2/)eh/ and curvilinear integral do not depend on the path of integration, connecting points (0,0) and (x, y) equation (1.2) reduces to the inhomogeneous Cauchy-Riemann equation §
= /(C,T + w(£,»?)), C = £ + M?
343
and therefore for any right-hand side such that f(z, t) £ Lp for any t e R, 2 it has a solution f(C,t +
•(*•')-;//
w(£,Ti)-w(x,y))
p>
d^drj.
If X(z,t) is an enough smooth function, then formally it can be represented as oo
oo
A(z,t) = ]>>_ f c (r 2 ,i)z f c + ^A f c (7- 2 ,i)z f c ,
(1.4)
fc=0 fc=l
where p= 2ir r/•Z7T
A fc (r 2 ,t) = r~k / Jo
2 r
= \z\2 = x2 + y2,
\(z,t)e-ik9d6,
\-k(r2,t)
pZTT r2ir
= r~k / Jo
\(z,t)eAk6 d6.
In particular, if A_fc = 0 for k > 1, Afe = 0 for k = 0, k > 2 andAi = i, then equation (??) coincides with well known Hans Lewy equation 6 : l ^ | + » ^
= / ( ^ ) , M e «
3
,
(1.5)
for which the integralility condition (1.2) is not fulfilled. Representing the right-hand side of (1.5) in view (1.4) let us seek a solution of (1.5) also in view (1.4). Then comparing the coefficients of the series near powers zk and ~zk we obtain the following equations dwk .dwk . . -Q- +l-Qf = fk+i{P,t), k = 0,1,...; p(—Q^L+i—^L)
+ kw-k(p,t)=f^k_1)(p,t),
A; = 1,2,...;
(1.6)
in the halfplane C+ = {( = p + it £ C, Re C = P > 0}. The first group of the equations in (1.6) are just the inhomogeneous Cauchy-Riemann equations in C + and, therefore, they are solvable for any right-hand sides fk+i(p,t) G LPLP>(C+), p > 2, 1 < p' < 2. If the right-hand side of this equation has compact support in C + , then this equation has a solution with compact support in C+ if and only if / fk+i(Otkdtdy Jc+
= 0k =
0,l,-
344
The second group of equations in (1.6)
l T + £ = *b'-<«>
(L60)
are elliptic equations in C+ with coefficients, having singularity on the boundary Re C = 0 of C+. If we apply the same procedure to the following second order equation r» T
1 IW
d2w
= i^
+
. l9d2w +l{z
^
z
.. d
+l
d . dw
dw
f{z t)
,
irz-- ^iH iH= >
^
which is obtained by composition of an adjoint operator r*_
1
d
._d
d-z-lzdl
=
to (1.5), then for the coefficients of a decomposition of w(z,t) the form (1.4) we obtain the following equations: P(
^ 2 + 0^2 H
+ (k + ! ) ( ^ + * ^ K = fk,
k = 0,1,...;
The following equations hw = T^+izk-^
(z,t) = («!,...,z n ,t) e R2n+1,
= fk(z,t),
l
may be considered as a counterpart of the H.Lewy equation in the space R2n+1,i.e. the operator H.Lewy in R2n+1 is the operator / = (Ii,...,/„) mapping from C to C n and its adjoint
K=l
n
is a mapping from C to C, so that a counterpart of (1.7) in R2n+1 is the following second order equation, obtained by composition of I* with I: T*T
v^
^-E^-
92w
. ,od2w
.,_
+
+ l-lV
^-
-=r,dw
i?)
aF
. dw
+m
k=\
where R, R are radial operators: n
o
n
o
^
..
,.
= /( i)
^ '
,,
0,
(L8)
345
Let us represent the right-hand side of (1.8)
/(-M) = E /w(r2>*)l$. /W = r-p-q j f(C,t)Y^da(C) S
p,q>0
and seek a solution w(z,t) of (1.8) in view (see 5 ): w(z,t)=
^(r2,*)^,
£
(1-9)
p,q>0
where Y?l- homogeneous harmonic polynomials of bi-degree (p,q) with boundary values on the sphere S in C n such that ||y p9 (C)||L 2 (s) — 1- Then for the coefficients wpq(p,t) one obtains the following equations ,d2w„a
p{
+
d2wva.
,
)+{n+p+q)
~^ ~^
sdwV(l
+l{n+p q)
~df
..
,3IDOT
~ ~d?
,
= /p<
p; q
"
in the halfplane p = r2 > 0. Considering the composition of the operator
^ „
- °'
,„ , „ .
(L10)
k=l n
(a mapping from C to C) with the H. Lewy operator in R2n+1, instead of (1.8) the following second order equation W - E ^ - | % + ^ + f i )
¥
+
i
n
¥
= /(M)
we obtain
(1.11)
fc=i
and if we seek a solution of this equation in the form (1.9), then we obtain instead of (1.10) the following equations g ^ a-2
+
n+p + qdwp ^ 2p
g
1 ~ Aphq'
P , 9
~U
(L12j
in the halfplane C+ = {C = p + it e C : Re < = p = r 2 > 0}. The composition of the operator A/f *
_ \ ^ d(pn
_ d(pk
(a mapping from C n to C) with the operator M = (Mi,..., M„) - (a mapping from C to C n ) ,
346
leads to the following second order equation
E fc=l
d2w ^ = -
+
. l2,2dd22w w \z\>-w
+
—. dw dw . „ —. (R + R)dt ,..m
which in contrast with equations (1.7),(1.11) possesses a multiple family of characteristics t— \z\2 = const, which allows to write down its general solution: w(z,t) = h{z,t-
\z\2) - j
/(C a
' | ^ ' f | l L : 2 | 2 | 2 ) ^ A dl,
where h(z,u>)- is an arbitrary twice differentiable function, harmonic in the domain Q C C of variable z = (z\,..., zn). We shall seek solutions of equations (1.6),(1.6'),(1.10),(1.12) in the halfplane C + having there compact support assuming that their right-hand sides have compact supports there. Then by (??) we obtain the formal solutions of equations (1.5),(1.7),(1.8),(1.11) having compact supports in C + , provided their right-hand sides have compact supports in C + . When corresponding series are convergent, the formal solutions will be the strong solutions. The following particular case of (1.1): dw , dw ,, gZr+Az—=/(z,^),
A = const
,, (1.13)
possesses two families of real characteristics t ± |A|(a;2 + y2)) = const . It is easy to see that solutions w(z,t) of this equation are obtained through the formula
where
which degenerates on z = 0. If we seek solutions of this last equation in the form (1.4), then we obtain for the coefficients (fk{r2,t), ?_fc(r2,£) of such decompositions the following equations
which are just Euler-Darboux equations d2v + fc + i gg + d£)= dtdr, 2(e + ry) v 9e V
J 4|A|(£ + 7j)
(L16)
347
in the characteristic real variables £ = |A|/9 + £, V = |A|p —i. For investigation of the Euler-Poisson equation (1.10) and the Euler-Darboux equation (1.16) the Green function (see 3 , p.184) and the Riemann function (see 3 , p.267) can be involved. If equation (1.6°) has a solution, bounded up to the boundary p = 0, then its right-hand side necessarily satisfies the condition
I
/-(fc-i)(C)Pfc~V(Odpdt = 0
c+ for any function
v = p*-V(0 evidently is a solution of the following homogeneous equation, adjoint to (1.6°): dv fc — 1 -u = 0 d( ip in C+, continuous up to the p — 0. The homogeneous equation, adjoint to (1.10) has the form .d2v
d2v.
dv
.,
.dv
in the halfplane p > 0, t € R. This equation is the Euler-Darboux equation (see 3 , p.420): d2v
0 — 1 dv 1 H
n+ F
p—ldv = =0
(1.17)
in the complex variable £ = t + ip and the functions v
= (c - (y+p+o-1 f $(c + (c-0*)* n+, '" 1 (i-*)* _1 *
Jo (where $(w) is an arbitrary holomorphic function in to) are solutions of (1.17) vanishing on the boundary p = 0 of the halfplane Im £ = p > 0, t s Rin case p, q > 0. Therefore it is expected for the inhomogeneous equations (1.10) to be solvable in a class of functions bounded up to the boundary p = 0 together with their first order derivatives provided their right-hand sides satisfy an infinite number of orthogonality conditions with respect to the solutions of the corresponding homogeneous equation.
348
2
The Dirichlet Problem for elliptic first order s y s t e m s
1°. Let G be a multiply connected domain in the complex plane C which is bounded by a finite number of closed, non-itersecting smooth curves Tk,k = 0,1, ...,m, with To containing the remainding in its interior. Let a(z),b(z),c(z),a°(z),b°(z),f(z) be complex valued functions given in G, smooth enough in G = G + F, T = TQ + ... + Tm. Any linear first order system of two real equations with respect to two real valued functions may be put into the following complex form with respect to complex valued w(z) = u\(x, y) =p iv,2(x,y), z = x + iy: , .dw
,, .dw
, sdw
,, .dw
, .
, . .
...
. „.
We assume for this equation to be elliptic in G which means that its principal coefficients satisfy the conditions (see 4 ) : a)\A{z)\ > \a{z)\ + |/J(z)|, \a(z)\ + \(3(z)\ > \B(z)\, z G G, A = | a | 2 - | 6 | 2 , JB = | d | 2 - | c | 2 or b)_\B{z)\ > \a_(z)\ + \/3(z)\, \a(z)\ + \0{z)\ > \A(z)\, z e G, d = tie — bd, (3 — ad — be The Dirichlet problem D for the first order elliptic system is to find a solution w(z) of (2.1) in G, continuous in G, satisfying the condition w(Q = 7(C)
(2-2)
on r , where 7(C) is a given continuous function on T. Obviously this problem is overdetermined, so that it cannot be solved for arbitrary given data a, b, c, ao, 60, / , 7- Indeed, let us first consider this problem for the inhomogeneous Cauchy-Riemann equation
or for the inhomogeneous anti-Cauchy-Riemann equation
Lemma 2.1 Problem (2.3), (2.2) is solvable iff for any function
f 7(CMCK = 0 Jr
(2.5)
349
holds and its unique solution is given then by w
2m Jr
C- z
2m JG
£-z
v
Problem (2.4), (2.2) is solvable iff for any function ip(z) holomorphic in G and continuous in G the equality [ f(zjj(z)dz Adz+ [ ~f(()W)
Mw, } =
w
^
w/(MAdc.
(2.7)
(2.8)
2-Ki JT C-z 2m JG (-1 Proof The necessity of (2.5), (2.7) follows from Green's identity. The sufficiency of (2.5) for differentiable f(z) can be proved as follows: let w(z) be the solution of the Dirichlet problem (2.2) for the inhomogeneous Laplace equation d2w _ df_ dzdz dz in G. Prom this equation it follows that the function ip{z) = dw/dl — f(z) is antiholomorphic in G, so that an application of the Green identity by virtue of (2.5) gives / \
/ (-g= ~
f{z))ip{z)dxdy
/ —[w(z)
~
f l(C)W)d<; - f f(z)^)dxdy = 0, J1
J Cr
i.e. (p(z) = 0 and w(z) satisfies (2.3). If f(z) is not differentiable, then, using the representation * JG C-Z following from (2.3) with an arbitrary function
350
Theorem 2.1 Problem (2.1), (2.2) in case the inequalities a) hold is solvable iff for any function ip(z) holomorphic in G and continuous in G the equality J p(z)ip(z)dz Adz-
J
7
(CMCR = 0
(2.9)
holds where p{z) is the solution of the following uniquely solvable integral equation (see [3]): a(z)p(z) + b(z)p(z) + c(z)Sp + d{z)Sp + a0(z)Tp + b0(z)Tp = /„(*) (2.10) and in case the inequalites b) hold this problem is solvable iff for any function tp(z) holomorphic in G and continuous in G the equality f v{z)W)dzdz
+ f 7 ( C W = 0 (2.11) Jr holds, where v(z) is the solution of the following uniquelly solvable integral equation JG
d(z)v(z) + c{z)v(z) + b{z)SV + a(z)Sv + b0{z)Tu + a0{z)TV = g0(z),
(2.12)
where K
JG
C-Z
TT JG
{( -
Z)2
fo(z) = f(z) - c{z)S'Tl - d(z)Sfr
- a0(z)Sr7
-
b0(z)S^,
9o(z) = f(z) - b(z)Sri
- b0(z)Srl
-
ao(z)Srj,
5r7
1
- a(z)S^f
y7(CK
-2^yrT^'
<,,
SrJ
1
f
J(CH_
~ ^i JrTTW
Proof If the inequalities a) hold, then we put dw and solve the Dirichlet problem (2.2) for this inhomogeneous Cauchy-Riemann equation to obtain the unique representation of w(z) through p and 7 according Lemma 2.1 by w(z) =TP + Sr7,
(2-12')
provided (2.9) holds. Substituting (2.12') into (2.1), we derive the equation (2.10), which is uniqualy solvable if the inequalities a) hold.
351
If the inequalities b) hold, then we put dw
Tz =
u{z)
and solve the Dirichlet problem (2.2) for this inhomogeneous anti-CauchyRiemann equation to obtain the unique representation of w(z) through v{z) and 7(C) according Lemma 2.1. by
__L w[z)= v
fm
- if im*,
(2.i3)
' 2mJr C-z 7T JG C - 2 ' provided (2.11) holds. Substituting (2.13) into (2.1) we derive the equation (2.12), which is uniquely solvable if the inequalities b) hold (see 4 ) . 2°. Let A(z) = (Aki(z)) be a square matrix of order n with smooth enough elements, and consider the Dirichlet problem Dn which is to find a solution w(z) = (wi(z),..., wn(z)) of the first order system ^ + A{z)w = F(z) oz in G and continuous in G, satisfying the condition
(2.14)
w{Q = r(C)
(2.15)
on T, where F(z) = (fi{z),..., fn{z)) a given smooth vector-function in G and F(C) = (71(C)* •••7n(C)) is a vector-function given and continuous on T. Theorem 2.2 Problem (2.14), (2.15) is solvable if and only if (up to a finite number of additional conditions) for any solution
= 0,
(2.16)
(f continuous up to the boundary V, the following equality J
< F(z),
r(0,
V(0 > ^C = 0
(2.17)
holds, where n
n
fc=l fc=l
and A'(z) is the conjuate and transposed matrix to A(z).
352
Proof If (2.14), (2.15) is solvable, then by means of Green's identity we obtain for any solution ip of (2.16): / < JG
F(z),tp(z)
> dxdy
= / < —- + A(z)w, ip(z) > dxdy JG VZ ^ r j-t r = E / -g^-fk(z)dxdy + < w(z)A'(z)ip(z) = ^2 fe=i •'G
-~=-[wk(z)(pk(z))dxdy - ^2 k
+
wk(z)—-^-dxdy
JG
fc=i
> dxdy
k
< w(z), A'(z)
= h E / 7fc(C)^(CR - I < w(z), ^
-
A'(z)dxdy
= ^ < r ( C ) , y(C)>dC. To prove the second part of the theorem, let us consider the Dirichlet problem (2.15) for the following second order system of equations {£--7J(z)){^+A(z))w =
(2.18)
d2w d ,£ , - 7 7 ^ dw —--r , , , dF + —(Aw) - -A'{z)) — - A'(z)A(z)w = — - A'(z)F dzdz dz dz dz This system is strongly elliptic, so that the Dirichlet problem for such a system is always solvable up to a finite number of solvability conditions. The vector-function
^+A(z)w-F(z)
is according (2.18) a solution of the homogeneous system (2.16), so that if (2.17) holds, then an application of the Green identity gives: / <
OZ
< Aw, tp > dxdy — / < F,tp > dxdy = JG
JG
353
= h I < r(C), ip((>d(M- JT
[ < F(z), ip(z) > dxdy = 0, JG
i.e. (p = 0, and w(z) satisfies the system (2.14) in G and the conditions (2.15) onT. 3°). Let us now consider the Dirichlet problem £)(") <0 = 7 ( 0 , £ e r = dti
(2.19)
for the general elliptic first order system YiAM(x)-p-+B{x)u = f(x) dxk
(2.20)
*ti
in a bounded domain Q of i? n , where u(x) = (ui,...,U2m) is the desired unknown real vector-function, A^k\ B(x) are (2m x 2m) - square matrices, f(x) = (/i,..., /2m) is a vector-function with real smooth enough elements given in fl and 7(£) = (71, ...,72m) is a continuous real vector-function given on the boundary T = dft. Note that elliptic first order systems do not exist in Rn for each dimension n (see *). Theorem 2.3 T/»e Dirichlet problem (2.19), (2.20) is solvable if and only if (up to a finite number of additional conditions) for any solution
E ^ (A{ky ^) - B'Wv = °
( 2 - 21 )
continuous up to the boundary T the following equality [
[ 7 ( 0 E AW (Ofcos(n, JT
JO.
£fcHr = 0
(2.22)
fc=1
holds, and for any solution tp = (^1, ...,ip2m) °f the homogeneous system E
£~k
( A ^ * ^ )
- B*(x)4, = 0
(2.23)
continuous up to the boundary T the following equality f
/7(0Ej4(fc)*(0V'cos(n)^)d€r = 0 fc=i Jr 7~,
(2.24)
354
holds, where means the transposed matrix and * means the following matrix:
A(k>
(k) _
(
A{k)
4{k)? -A4) k
{k)
\ A
^1,2
A
•••
2m,2
{k A(fc) 2m
-
2m,1 AW
A
^2,2
(k)
..-A
/1
iW ^2m-l,l
Ak)
^lm-1,2
2m,2m
/1
2m-l,2m'
Proof If problem (2.19), (2.20) is solvable, then by means of Green's identity we obtain /
< / , ip > dx n
.
5Z / fk(x)(pk(x)dx k=lJn
k=1Jn
Ja
\k=1
J
/7(C)E^'(fcVcoS(n,a)^r, JT
/ < /*, V > dx Jo.
^ r V
/ f2ii>2i-l 2771
r /
i = l •'" 1= 1
L V
771
«
f2i-l-ll>2i)dx
7J
r.
\
fc=l
'
2 ,-cos(n,6 ) V^iZ / ^ o E (E4S J
i
!
Ej42i-2,jCOS(n'^))V'2i ^ r fc=l Z77i
' /
,
r
7
n
r
n
^
)
/
\
355
-{B2i,j4>2i-l,j1p2i)
dx
i.e., (2.22) holds for any solution
E^(A'(fcV)~5V = 0
(2.25)
in ft with
p=
JTAW(x)-^k+B(x)u-f(x).
The principal symbol of (2.25) is
ip>dx=
= f 7(0 E
/ ( V # ( i ) - + B(x)u-f(x))tp( Jn £r[ oxk
x)ax =
' (Ov cos(n, ^ V
= 0,
A{k)
- [
i.e.
in ft with V = ( V ' l . - . ^ m ) , 2m 2m
/
p.
n
v
^-1 = E ( E 4 S g + * * J « J ) - /»(«), 2m
, n
„
.
356
Taking into account that the principal symbol of (2.26) is a*(£) — A*'(£) where A*(£) = 23/c=i A^ (x)£k and hence (2.26) is strongly elliptic (because (a*r),r)) = (A*'rj, A*'r/) > 0 for any 77 e R2m), we conclude again that the Dirichlet problem (2.22), (2.26) is solvable up to at most a finite number of solvability conditions. Then using (2.4) we obtain I < ip,
ip > dx
JQ 2m
p
m
n
*
~
B
u
-.
= £ / £ £ 4& (*) I?+ ^ - /* ^-1 (x)dx j=i
J
& i=i jt=i \ 2m „ m n
fc
s
/
r\
x
- E / E E l ^ S W ^ + ^ - i ^ + ^-iWlfeWda; ,•=1 J" i = i
fc=i
OXn
V
J
= Jr/7(6E4 f e ) *^ C 0 S ( n '^K r - 7nI
a; =
an(
i.e. V'( ) 0 i hence M satisfies (2.20). Here we give an immediate application of theorem 2.3 to the Dirichlet problem: find a solution u(x) = (ui, 112,113) of the system curl u + Xu = f(x),
A = const ^ 0
(2.27)
3
in a bounded domain H c H , continuous in f2 = fi + T, F = dCl, satisfying the condition "(0=7(0.
eer.
(2.28)
system (2.27) is determined, but the principal symbol degenerates identically at every point of 0:
/o,-6,M det
6,0, - 6
=0
Applying the operator div to both sides of (2.27), one gets the following overdetermined system div u = A _1 div / ,
curlu + Xu = f(x)
(2.29)
in O, and the Dirichlet problem for this last system is equivalent to the following Dirichlet problem: Find a solution (uo,u) = (uo, 111,112,113) of the determined first order elliptic system div u = A - 1 div / ,
357
grad UQ + curl u + Xu = f
(2.30)
in fi, continuous in Q,, satisfying the condition: «o(0=0,
« « = 7(0,
^ T .
(2.31)
The Dirichlet problem (2.30), (2.31) is just a particular case of (2.19), (2.20), so that the application of theorem 2.3 gives: The Dirichlet problem (2.27), (2.28) is solvable if and only if (up to a finite number of additional solvability conditions) for any solution (<£oi¥>) = (Vo,¥>i,
(2.32)
which is continuous up to the boundary T, the following equality A - 1 / div f(x)ipo(x)dx
Jo.
I < 7 ( 0 , g r a d P(0 > MO^
+ / < f(x),tp(x)
> dx—
Jn
~ J < Srad p(0
x
¥>(0->(£) > d«7 = °
holds. 3
Elliptic systems in the halfplane, which are singular on the boundary
1° Let C = {z = x + iy € C, Re z >)} be the right half-plane of the complex plane C, and let a{z), f(z) be given functions such that a(z) £ C 1 ( C + ) , f(z) £ LPV(C+),p>2,Kp'<2. If a(iy) ^ 0, y G R, then the equation dw W
a(z) + — » = /(*)
(3-1)
has a first order singularity in the coefficient at the boundary x = 0 of C + , so that to this equation the results of I.Vekua 7 are not applicable. Theorem 3.1 Let §§ log a; € LpLp,(C+),p > 2 , 1 < p' < 2. 7/Re a(iy) < 0, then in a class of functions, bounded up to the boundary x = 0 and behaving as O(|.z| - ( 1+ao °)) at infinity, where a^ = Re lim a(z), equation (3.1) \z\—*oo
is solvable for any right-hand side such that x2a^f(z) 6 LpLpi(C+),p > 2,1 < p' < 2. But if Re a{iy) > 0, then (3.1) is solvable in a class of functions, bounded up to the boundary x = 0 if and only if for any function
358 holomorphic in C + , continuous up to the boundary x = 0 and decreasing as 0(\z\~1~e), e > 0 at infinity, the equality [ f{z)x2a(z) Jc+
expu>(z)dxdy = 0,
holds, where w z
() = 1 / S —d^dr) n /c+ Jc Q~z Proof If we assume for a moment for a(z) to be holomorphic in C + , then a general solution of the homogeneous equation, corresponding to (3.1) is evidently represented as w{z)=x-2a{z\
$(*),
(3.2) +
where $(z) is an arbitrary function, holomorphic in C . Now we seek solutions of the inhomogeneous equation (3.1) in the form even if a(z) is not holomorphic in C + . Then we obtain ^ = a(z)x-2a^-^(z) dz
- 2~x~2a^ dz
logo; • *(z) +
So that the function <&(z) = uj{z)x2a^z\
x~2a^^, dz
satisfies the equation
d
±-2d^\ogx-$ = x-2^.f{z)
(3.3)
in C + . This equation is an inhomogeneous Cauchy-Riemann equation for the function §\{z) = $(JZ) • exp w{z): ^-=x2a^-expw(z)-f(z) and as 4>i(z) vanishes at the boundary x = 0 if Re a(iy) > 0, then the result follows from Lemma 2.1. 2°. Let us now consider the following second order elliptic system d2u 2 dz,*
a(z) du
t
b(z
+ - rx 4 = dz + ^ « =/(*)
(3-4)
in C + , where a(z),b(z),f(z) are given complex-valued functions in C + . If a(iy) and b(iy) do not vanish on x = 0, then equation (3.4) has a singularity of order one in the coefficient of du/dz and of order two in the cofficient of u on the boundary x = 0.
359 First let us consider the case 166(2) = (1 - 2a(z))2, i.e. when equation (3.4) has the form
#j
+
«(£)a» + ( 1 -Mj)) ! u
az
I6xz
x oz
Let us assume that the functions aj,a^ logo;, a^ log x,x1^2+a^f(z) belong to LpLp,(C+),p > 2 , 1 < p' < 2. Theorem 3.2 / / R e a(iy) < 1/2, y e R, then in a class of functions, bounded up to the boundary x = 0 and behaving as O(|z| _ 1 / 2 _ a o °) at infinity, equation (3.5) is always solvable. But if Re a(iy) > 1/2, y € R, then it is solvable in this class if and only if (up to at most a finite number of additional conditions) its right-hand side f(z) is orthogonal to any solution u*(z) of the homogeneous adjoint equation d2u* dz2
|
a(z)du* x dz
|
(l + 2a(z))2-xaz^ 16a;2
Q
mC+. Proof If a(z) is holomorphic in C+, then the general solution of the homogeneous equation corresponding to (3.5) is evidently represented as u{z) = xxl2-
+ logx • ip(z))
(3.7) +
where
,
dip
, 0
-£= + logo; • — = ajloga; • ip + az log oz az
x-ip,
+ a 7 l o g x ( ( i - a{z)) logx + 2)i/> + 2x1'2+a^
• f(z)
(3.8)
in C + , we find from (3.7) du dU _ 1 1 = k \ - a(z))x-W+«'» dz ~ 2^2 ^
•
a{z)) l o g x +
= \(\-a(z))(l-+a(z))x-^».
^
360
+ I x -(f +-(«)) . ((I _ a ( 2 ))(I +
o(z))ioga;
_ 2a(z)^
From here and (3.7): tfi(z) = x-i+a{z\a(z)
- 1/2) logz + l)u(z) - 2x^+a^
log a; • $ , oz
1>(z) = a;- 1 / 2 + a ( z )(a(z) - l/2)u(z) + 2a;i + «(i) . | ^ . az From these equalities it follows that if u(z) is a solution of (3.5) bounded up to the boundary x = 0, then ip and V vanish at the boundary x = 0 of C + in case if Re a(iy) > 1/2, y G i?, i.e. these functions are solution of the Dirichlet problem in C + with the homogeneous Dirichlet condition:
~-+az-tp*
= 0,
-^-azlog2x-ip*+2azlogx-ip*
=0,
(3.10)
(continuous up to the boundary x = 0 and vanishing at the infinity) the following equality
L
f(z)x1/2+a<-z)
• (logx • (p*(z) - i)*{z))dxdy = 0 (3.11) /c+ holds. This condition means that the right-hand side f(z) of equation (3.5) is orthogonal to the function u*(z) = x1/2+7^>(logx
• tp*(z) - ^*(z))
which easily can be verified to be the general solution of the equation (3.6). Indeed, if a(z) is holomorphic in C + , then equation (3.6) reduces to the following 9 V _ o(£) dv^ dz2 x dz
(l + 2 a ( z ) ) 2 u . 16x2
= Q
361
the general solution of which has the form u*{z) = x1/2+^{\ogx-~^^-iF(7j),
(3.12)
where
dtp* _ , 2 * - T — + a z l o g x-(p -az\ogx-ip az
,* = 0,
+ a z ( i + a)log 2 :r • ip* + az{\ - {l- + alogx))^
=0
(3.13)
from (3.12) we obtain 1 du* ~dz~ =-2X~'2'
i fa
[(l + ( i + a l o g x ) V - ( i + a ) V * ] ,
d2u* = Iar* + 5[(2a[ ( 2 S - ( i + a){±+a\ogx))
(
;
|z|—>oo
dkr I -S=-(l j az k2 dki xkl~k* d~z k\ — k2'
log a:), fci
dk2 1 -%=•{-. r + l o g : r ) , oz k2-k\
dk2 xk*~ki xl~k d~z &2 — fci' k\ —k2
x1-^ ' k\ —k2
belong to LpLp>(C+,p > 2,1 < p' < 2. Theorem 3.3 If Re k\{iy) > 0, Re k2(iy) > 0, then in a class of function u(z), bounded up to the boundary x = 0, bounded at infinity with the derivative decreasing as 0 ( | z | ~ ( 1 + R e fc°°') at infinity, equation (3.4) is always solvable in C + . But if Tie k\(iy) < 0, Re k2(iy) < 0, then it is solvable in this class if and
362
only if (up to at most a finite number of additional conditions) its right-hand side f(z) is orthogonal to any solution of the homogeneous adjoint equation d2u* dz2
a(z) du* x dz
|
b{z) + a(z)/2 - az • x ^ _ x2
Q
in C + decreasing as 0(\z\~e), e > 0 with the derivative u*z decreasing as 0(\z\~1~e), e > 0, at infinity. Proof If a(z),b(z) are holomorphic in C + , then the general solution of the homogeneous equation corresponding to (3.4) has the form: u(z) = xkl^
•
(3.15)
where ip, ip a r e arbitrary holomorphic functions in C + . In the general case, when a(z),b(z) are not holomorphic, we seek solutions of the equation (3.4) by varying tp and tp so that they satisfy the following first order system j. du> . dip t , dk\ , kri dk2, x1 -ZZ + xfc2T^r + xkl —f- logx •
dz
dz
+xk^1~^-(k2logx
az + l)iP = 2f(z)
(3.16)
in C+. Prom (3.15) we find dz S az
2
2
- 7*1 (fci - l ) ^ 2 " 2 • V + 7*2 (*2 - l ) ^ 2 - 2 • >. 4 4
Prom these equalites and from (3.15) we find k2
2x1~k> du
_fcl , , —X
Kl
u(z)
-
T--^-,W
kj = 1
7~
x
2xl~k> du
_k2 U(Z) -
;—"^Z-
w w k2-h k2-k!dzr kY-k2 kx-k2dz Prom these expressions it follows that if u{z) is a solution of (3.4), bounded at infinity, then the functions ip and ip will be solutions of the Dirichlet problem (p(iy) = 0, ip(iy) = 0 , y £ R for the system (3.16) which can be written also as the following first order elliptic system
^
d
, , dk2 xk2~kl , 2x 1 - fcl . logorV - — 7 77^ = T 77/, dz k2 — k\ k\ — k2
363
dip dz
dk! xkl-k? dz k2 - k\
,dk2, 1 dz k2 — k\
,
2x1'k' k2 — fci
,,
i.e. (ip,ip) is a solution of a particular case of the Dirichlet problem (2.14), (2.15), so that by Theorem 2.2 this problem and hence equation (3.4) is solvable if and only if (up to at most a finite number of additional conditions) for any solutions (ip*,ip*) of the homogeneous adjoint system ,. , dk! x1*-1* ., n + l)
dip* dk[n -£r - -^-(logx oz oz
d^* dhx^-1^ , dk2n 1 - ^ - - 5 - 1 i-y ~-5-(logar-7- y-)^ = 0 (3.17) 9^ 92: fci - k2 dz ki - k2 decreasing as 0 ( | z | - 1 - e ) , e > 0, continuous up to x = 0, the following equality
L m i£=^+Sr^)dxdy=°
holds, i.e. the right-hand side f(z) u*{z)/{k\ — k2), where the function u*(z) = x1-^
(318)
-
of (3.4) is orthogonal to the function
• ip*{z) -
xl^^*{z),
as it is easy to see, is the general solution of equation (3.14). Indeed, if a(z), b(z) are holomorphic in C + , then (3.14) reduces to the equation d2u* dz2
a{z)du* x dz
6(2) + q ( 2 ) / 2 ^ _ 0 x2
|
u*(z) = a: 1 -*V(.8) - x1'1* • ip*(z)
(3.19)
where
dz
_ xi-l»°f _ fV-^logo: • V* + f V ^ l o g ^ * = 0
(1 - k~i)x-^%-
dz
dz
- (1 " ^ ) x -
+ ^-x-T*{{l-k2)\ogx
dz
T
^
- ^x-Tl((l
~ h) logx + l)y*+
+ l)iP* = 2az(x-l~1v* -x-^ip*)
(3.20)
364
and from (3.19) we obtain du*
1 - ki _rr *
1 - k2
_T~
,,
^ 2 = -MI_^-*7-y _ 5 ( 1 - 5 ) ^ . ^
az 4 4 Substituting these expressions into (3.14) and taking into account (3.20) we convince ourselves that (3.19) is a solution of (3.14). 4
Overdetermined elliptic systems in the half-space which are singular at t h e boundary
1°. Let R+ = {(t,x) = (t,Xl,...,xn) e Rn+\t > Q},aj{t,x),fj{t,x) given bounded functions in i?+, desreasing of order greater then one at infinity, H{x) is a continuous function given on the hyperplane t = 0, i £ Rn. Consider the following Dirichlet problem: find a solution w(t, x) of the first order overdetermined system
^-+Mt,x)W
= Mt,x), l<j
^^(l-H^-).
(4.1)
in i?+, decreasing not less then of order one at infinity, continuous up to the boundary t = 0, and satisfying the condition w(0,x)=H(x)
(4.2)
We assume that the system (4.1) is compatible in i?+, i.e. dAk -5= dzi
dAi -x=- = 0, dzk
dfk dfi -^r - -^=- - (Aifk - Akfi) = 0 , dzi dzk
k^l
inR+. Theorem 4.1 The Dirichlet problem (4-1), U-2) is solvable if and only if (up to at most a finite number of additional conditions) for any solution ip(t,x) = (ipi,...,ipn) of the system n
E
d(fij -r
.
_
d
d
1 d
.d
(4.3) continuous up to the boundary t = 0, decreasing at infinity the following equality / JR+
< f,tp>dtdx-2
JRn
H(x)(ip1(0,x)
+ ... + tpn(0,x))dx
= 0, (4.4)
365
holds, where < f, f >— fvf\ + ••• + / n ^ „ Proof If the problem (4.1), (4.2) has a solution, then (4.4) is a consequence of the Green identity. Conversely, let w(t, x) be a solution of the Dirichlet problem (4.2) for the following strongly elliptic second order equation , , dzudzk dzk dzk f—' Ozk fe=i fc=i in i?+. If (4.4) holds, then from (4.5) it follows that the functions
2_\ k=i
p
\ipk\2dtdx
/ jR
i
= /^ I Z^jRt fc=l'
{-^=~ + Ak)wTpkdtdx —I dz k JR+
lim > .. _ ^°°,, fc=1
R-l
/ J2 fl+n(t +|x| <-R2) 2
< f,w>
-—^(wipk)dtdx k
dz
w V^(— TT\ "zk
Ak)ipkdtdx
Rtn(t2+\x\2
dtdx
— I < f,ip > dtdx J R+
— / < f,(p > dtdx J R+
+ ... + ipn(0,x))dx-
< f,(p>dtdx
= 0,
JR+
i.e., ipk = 0, 1 < fc < n, which means that w(t,x) is a solution of the Dirichlet problem (4.1), (4.2). Let a(t, x) be a given complex valued function bounded in ii+ and such that a(0, x) ^0,x £ Rn and consider the following first order overdetermined system, having a coefficient which is singular on t = 0:
^+(^-+Ak(t,x)\w
= fk(t,x),
l
366
We assume that this system is compatible in i?+, i.e. <5L4fc_cM£ dzi dzk
|&_M
+ (
'
da _ da dxk dxi'
!&»)+A)A_(!M
+ J W / ._O
,«,
Theorem 4.2 £ei -§§-\ogt be bounded or have at most weak singularity at the bounded part of R£ and decreasing in power more that one at infinity and let a,*, = lim a(z). If Re a(0,cc) > 0,x € Rn} then this system is |z|-*oo
solvable in a class of functions, bounded up to the boundary t = 0, behaving as 0 ( | z | ~ ( 1 + R e °°°)) at infinity if and only if (up to at most a finite number of additional conditions) for any solution w*(t, x) — {w\,..., w%) of the following homogeneous first order system
^
-
^
(Ae-^-2atlogt)W;~(Ak-^-2atlogt)W:-0
+
in R%, continuous up to t — 0, and decreasing at infinity, the equality /
< f,
w* > dtdx = 0
R.+
holds, while if Re a(0, x) < 0, x G Rn, in the above class this problem is always solvable for any its right-hand sides such the fk (t, x)t2a^t,x' are bounded or have at most a weak singularity in a finite part of R„ . Proof If a(t, x) satisfies the equations J=£- = 0 in i?+, then a solution of the system dw dzk
a(t,x) t
in R£ is given by w(t,x) =
$(t,x)t-2a(t'x),
where $(£, x) is an arbitrary solution of the equations J=5- = 0, which consists of holomorphic functions of the complex variable t + i(x\ +... + xn). If a(t, x)
367
does not satisfy the equations da/dzk — 0, we can still factorize w(t, x) as above if we choose <£(i, x) to be a solution of the system = fk(t,x)t2a^x\
^ - + (ak(t,x)-2aJklogt)^
l
(4.8)
OZk
Since Re a(0, x) > 0, x € Rn, the function <& = t2a • w vanishes on t — 0 if w is bounded in a neighborhood of t = 0, and the result follows from Theorem 4.1, because the regular system (4.8) is obviously compatible according (4.6), and for any solution
fe=i
^
- ^
+ (Aj(t,a;) - 2a z , l o g % £ - (4fc(*,a0 - 2aZfc logt)tf = 0
we have
L
< / ,
But then the function w* (t,x) = ip* (£, x)t2a^'x^ is a solution of the system (4.7). 2°. Now we turn to the following overdetermined elliptic second order system having coefficients which are singular at the boundary t = 0 of the half-space i?+: d2u
^i^
+
ait.x)
du
*^
+
b(t,x) du
+
c(t,x)
*^ V
, .
, ,
, ,
U = /u( a:) 1 fc
.
n (4 9)
*' ' ^ '^ "
where a(t,x), b(t, x), c(t, x), fki{tx) are given complex valued bounded functions .R+ such that fki(t,x) is decreasing at infinity. Writing (4.9) as
with the right-hand sides ,
Fkl(t,X)
.
= fkl{t,X)
a du
b du
- - • — - - --— t OZk t OZl
c
-j:U. t2
The compatibility conditions Fik(t,x) = Fki(t,x) imply the equations a(t, x) — bit, x), du
t
du.
fe ~w?
„ , . x)„ . Mt x) = fkl{t
' - >>
,
(4 10)
-
368
and the compatibility conditions ^M^- = ^ ^ yield a(t, x)/2 + c(t, x) — a(t, x)b(t, x)
1 da du 1 [dzi dfzk
da du dzk dJi
_ dfu
du du
db db du dzi dzk dli
dfki
dc dc dzi dzk
b{t,x)
-dz--^-~rifli'fki)-
(4
-n)
Let us consider first the following particular case of the system (4.9): d2u dzkdzi
a(t,x) du b(t,x) du (1 - 2a(t,x) - 2b(t,x))2 t dzk t dzi 16t2
, . . (4.12)
Ifa(t,x),
b(t,x) satisfy the equations
|^=0,
J?-=0,
l
(4.13)
ozk dzk in i?+, then any solution of the homogeneous system (4.12) (fki = 0) can be represented as u(t,X)
=i1/2-a(t,x)-6(M)($(i);c)
+
(4.14)
where $ and ^ are arbitrary functions, satisfying the equations d^/dzk 0, d^/dlk = 0 , 1 < k < n. In this case we obtain from (4.14) du _ du dlk dze d2u SzfcSze
=
_i/9_„_h/,l a + 6 N I . ,,1 a + bs, , , 1, = .*-^-»((I-i±*)* + ((J-i±*)Iog*+i)*),
a + b,a + b 1.,. 2 v 2 4 '
,a + bl.,a + b 1. ^ 1 N 2 4 " 2 4 ' ° 2' (4.14') Prom these equations it follows that in this case the equalities (4.10), (4.11) are reduced to the follwing: fik = fku
^ - ^ -
. . 1 a + b. 4 2 y
v v
£
v
T ^ ( / « - / « )
= 0,
M*.
(4.15)
If we choose the functions <3> and vp to be solutions of the more general overdetermined first order system ^L + (a + b)zk\og2t-* dzk
=
2fkk-ta+b+1/2,
369
~
= 2fkk-ta+b+1/2,
+ (a + b)z-k-
l
(4.16)
then the general solution of the system (4.12) with coefficients a, b not necessarily satisfying the equations (4.13) again can be represented by (4.14) and we obtain the same expressions (4.14') for its derivatives and then the equalities (4.10), (4.11) will be fulfilled provided (4.15) is fulfilled and the equations da
dxk
_
da
db
dx{
dxk
_
db
(A-\7}
dxi'
hold in i?+. Then system (4.12) evidently takes view 32u , a + bdu , ( l - 2 ( a + 6)) 2 . ,. +
8% ~TWk
+
le*
u
,
hk x)
= ^
..... (4 18)
'
The system (4.16) is similar to (2.14), and according (4.17) it is compatible. Therefore, if Re (a(0,x) + 6(0, x)) < 1/2, then up to at most of a finite number of solvability conditions it is solvable for any right-hand sides, and the solution is decreasing at infinity with an order larger than one. But if Re (a(o,x) + b(0,x)) > 1/2, then according to (4.14) the functions $(£,x) and ^ ( t , x) must vanish on t = 0, in order to ensure that u(t, x) is bounded at t = 0. In other words, $ and \& must to be solutions of the elliptic first order system (4.16) in i?+ with homogeneous Dirichlet conditions on t = 0, so that this system is solvable in a class of functions, bounded up to t = 0 and decreasing of an order not less then one at infinity if and only if for any solution if*(£,x) = tp\, •••,¥>*), ip*(t,x) = tp*, •••,V'n) of the system
^ ( t r " ( s + ^ l o g 2 * • ^ - 2 ( s +*)** log* • V-D = o, H - H = (a + b)-Zktf ~ (a + b)-Zkrk, dib*
dib*
'dYl~mk
(4.19)
= a
( +%^:-(«+%i^+2(a+%.1°g*-V';-2(a+%iiogt-Vfc-
The equality
Y, f / f c f c ( t , x ) t H a ^ ) + b ^ ) - ( ^ * ( ^ l o g i + ( ^ ( i ^ ) ) d ^ = 0 (4.20) fc=i M
370
holds, which means that the vector-function (fu(t,x),..., fnn(t,x)) is orthogonal to the vector function (uj,...,u*) = ti/2+a(t,x)+6(t,a:)^* iQgt + ipi,...,(Pn logt + tpn) which is nothing but the general solution of the following second order equation ^d*u*k p(arf
a + bdut t 9zfc
+
(l + 2(a + 5))» (S + 5). t . . 16*2 w * t «*)-0.
, (4.21)
K
fc=i
the adjoint to (4.18). Indeed, if (p*k, ipk satisfy the equations dtp*/dzk = 0, 1 < k < n in R+, then we have <9i/*
_i
1- =
-
_^+6-i/2(^((s+6
+
_
i/2)iogt + i ) + ^ ( a + 6+l/2))
d 2 «2 * / / " + & , l w ^ + 6 l x , , , 3 + 6, t ,*,a + 6 l.,a + b 1 , a § f = ^ « — + 4)(^-4)l0gi+^-) +^ ( ^ + 4 ) ( — - 4 } Substituting these expressions into (4.21) and taking into account that d(a + b)/dzk = 0, 1 < k < n we obtain the identity. If ip*k and r/>£ are solutions of system (4.19), then substituting into (4.21) the values of uk and their derivatives, we obtain the identity again. Thus we reached the following result. Theorem4.3 Suppose the equations (4-15) and (4-17) hold, and suppose the functions (a + b)jk, (a + b)zk log t, (a + b)zk log 2 1 are bounded or have no more than a weak singularity in a finite part of R+, and are decreasing of an order larger than one at infinity. / / R e (a(0,x) + 6(0,a;)) < 1/2, x € Rn, then the system (4-18) is solvable up to the at most a finite number solvability conditions in a class of functions bounded up to the t = 0 and behaving as 0(\z\~(1+Re a ~ + R e b°°)) at infinity for any right-hand sides such that fkk(t,x)ta+b+1/2, fkk(t,x)t(-a+b+1^2 logt are bounded or have no more than a weak singulary at infinity. But if Re (a(0,x) + 6(0, a;)) > 1/2, x £ Rn, then this system is solvable in the above class if and only if (up to at most of a finite number of additional conditions) the vector-function (fu{t,x), . . . , / n n ( i , x)) is orthogonal to the solutions of the adjoint system (4-21). If 16c ^ ( l - 2 ( a + 6)) in R+, then the equationfc2+ (2(a+6)-l)fc+4c = 0 has different roots in i?+ : ki(z) ^ k2(z). If a(t, x), b(t, x), c(t, x) satisfy the equations da/ffzk = 0 , 1 < k < n, in i?+, then the general solution of the homogeneous equation (4.9) (fki = 0) has the form u(t,x) = $(t,z)t f c l ( z ) +^{t,x)tk^z\
(4.22)
371
where
(4.23)
azfcz; 4 4 From these expressions it follows that in this case the equations (4.10) and (4.11) are reduced to the equations (4.15). If we choose $ and ^ not as solutions of (4.23), but as solutions of the more general system OZk
OZk
K2 — ki
OZk
K2 — Ki
K2 — Kl
»
pL.£±..,_«> ( _i_ + logi,* + JAL(1-M
OZfc
OZfe
Ki - K2
dZfc «2 — Kl
K2 - Kl
(4.24) which is compatible in i?+ (provided together with (4.15), (4.17) also the equations Jj£- = gjr-, fc/I in i?+ hold), then the general solution of (4.9) with coefficients a, b, c (not necessarily satisfying the equations da/dzk = 0) again can be represented in view (4.22), from which we obtain some expressions for its derivatives, and then the compatibility conditions will be fulfilled if (4.15), (4.17) and dc/dxk = dc/dxi hold. In a class of functions bounded up to t = 0 the system (4.24) is solvable (up to a finite number of conditions) for any right-hand sides such that fkk(t,x)t1~kl, fkk(t,x)t1~h2 are bounded or have no more than a weak singularities at a finite part of i?+, and are decreasing not less than of order one at infinity. Let Refcoo= max(Refcioo>Re feoo), %oo = lim kj(z). If Re fcj(0, x) > 0, x G Rn, j = 1,2, then in a class of functions, |2|->00
bounded up to the boundary t = 0 and decreasing as 0 ( | ; z | - ( 1 + R e x°°^) at infinity, the system (4.9) is solvable for any right-hand sides (up to the finite number of solvability conditions) such that fkk(t,x)t1~kl, fkk(t,x)t1~k2 are bounded or have no more than a weak singularities at a finite part of R+. But if Re kj(0, x) < 0, x € Rn, i = 1,2, then in the above class it is solvable if and only if (up to the finite number additional conditions) for any solution
^,d
dk[.
1
,
. „
dYx
fc-T*
T „,
n
372
A , c ^ , dk2
tk*~k^
,
dk2.
1
,
aif - m = {%2^T1 ~ l o g i ) ( ^ r - a^V
+
, ,,,
n
l ^ k - ^~
^
in i?+ the following equality n
r
K2 — k\
holds which means that the vector-function (fu(t,x),..., onal with weight (k2 — &i) _ 1 to the vector-function
fnn(t,x))
is orthog-
As above it is not difficult to show that this vector-function gives the general solution of the following second order equation ST(d2<
a + bdu*k + k
a + b + 2c-t(a
P}~dzl ~~~TdzK=l
"•
+ b)zk
Uk)
2^
~°
(425)
adjoint to the system (4.9) which is compatible, i.e. to the system d2u
+
a + b du
M ^^
+
c
„
,
^
t
fci
'
dk2( 1 &zk k2- ki
j '
„.
(426)
--
Thus we have reached the following result. Theorem 4.4 Suppose the equations (4-15), (4-U) hold in R+, and suppose the functions dki 1 dzk k2 -
,,
u==fkkjl k n an
d dc/dx^. = dc/dxi
dki tk*-k> <9z/t fei - k2'
dk2 c ^
tk*-ki &2 - k\
are bounded or have no more then weak singularities at a finite part ofR+, and are decreasing of an order larger than one at infinity. If Re kj(0,x) >Q,x£ Rn,j = 1,2, then in a class of functions, bounded up to t = 0 and behaving as 0(\z\~(1+Ke fco°)) at infinity, the system (4-26) is solvable up to a finite number of conditions for any right-hand sides such that fkk(t,x)t1~kl,fkk{t,x)t1~k'2 are bounded or have no more than a weak singularity in a finite part of R+ and decreasing of an order larger than one at infinity.
373
But if Re kj(0,x) < 0, x e -Rn, j = 1,2, t/ien i£ is solvable in the same class if and only if (up to at most a finite number of additional conditions) its right-hand side (fn(t,x),..., fnn(t,x)) is orthogonal with weight (k% — fe)-1 to any solution of an adjoint equation (4-25). 5
Generalized Moisil-Theodorescu system in half-space, singular on its boundary
1°. Consider the following first order elliptic system with respect to a pair of complex valued functions u(z,t), v(z,t): du dv ~m ~ ~di + Au(z>t)u
2
+
Oil dv — -2—+A21(z,t)u
dz~
M2{z,t)v
=
+ A22(z,t)v
2{^x+^^y',
dz~
2^3x 3
in the half-space B?+ = {(x,y,t) = (z,t) e -R , are bounded functions given in R3, decreasing The Dirichlet problem for (5.1) is to find a (5.1) in R\, continuous up to the boundary t satisfying the conditions u(z,0) = 7i(z),
fi(z,t),
= f2(z,t),
(5.1)
%
dy''
t > 0}, where Aij(z,t), fi(z,t) at infinity as 0(R~1~S), e > 0. pair u(z,t), v(z,t), satisfying = 0, decreasing at infinity and
v(z,0)=j2(z)
(5.2)
on t = 0, where 7j(z) are given functions, continuous on the plane z = x+iy € C. Theorem 5.1 The Dirichlet problem (5.1), (5.2) is solvable if and only if (up to at most a finite number of additional conditions) for any solution ip(z,t),ip(z,t) of the homogeneous system adjoint to (5.1) 2
1T + S - Mx{z,t)ip - A21{z,t)^ = 0, oz
^
at
- 2 ^ + A12{z,t)ip + A22(z,t)^
= 0,
(5.3)
which are continuous up to the boundary t = 0, decreasing at infinity, the equality (fi(z,t)ip(z,t)
+
f2(z,t)i/}(z,t))dxdydt
374
f (-Y2(z)
(5.4)
holds. Proof. If problem (5.1), (5.2) has a solution, then equality (5.4) is a consequence of the Green identity. Conversely, if (5.4) holds, then let a pair u(z,t), v(z,t) be a solution of the Dirichlet problem (5.2) for the following strongly elliptic second order system . d2u d2u dAn dA21 du -j du dA12 ^ dA22. ^ - ) « - 2An— dzdz + ^72" dt2 + ( 2 -dz= - + " dt dz -A21— dt + ( 2 — dz - + dt-^-)v+ + ^ i i — - 2A 2 i— - (l^lnl 2 + \A21\2)u - {AUA12
d2v ^
+4
A
d2v
w dz^
+ (2
+A12-QJ:
-
8A21
dAu
-j
du
-j
Q~i ~ (^11^12 + M\A22)U
=2
a? " ^it + Jufl
+
A2iA22)v
du^.dA22
^ T ~ ~dT)u ~ 2A" af ~A™M+
2A22
+
{2
dAl2.
-bT - ~dT)v+
- (|A 12 | 2 + \A22^)V
~k22h-
(5 5)
'
Prom (5.5) it follows that the pair of functions du dv . . , du dv , . , . ,
dv
,
=
, . ,du dv . . .—, , , , {(2^-^+AllU+Al2V-f^+(^+2-^+A2iu+A22v-f2)'ilj}dxdydt
= / (72(2)^(2) --fx^{z))dxdy JC
- \ {fiip + f2tp)dxdydt JR%
i.e.
= 0, is a solution
375
2°. Let us now consider the following system: ndu
dv a(z,t) 2 T = - ^T + ^-^v oz at t
. , . . , ,. . , .. + An(z,t)u + A12(z,t)v = h(z,t),
^ + 2 ^ - ^ l u + A21(z,t)u + A22(z,t)v = h(z,t). (5.6) at oz t If a(z,0) ^ 0, z S C, then this system being elliptic in the halfspace R+ is singular on its boundary t = 0. Let us consider the following homogeneous system: du* oz
dv* at
a(z,t) t
*
-r
*
-r
*
o
du* dv* a(z,t) * -r » -r * „ -5T - 2 ^ r r + - ^ - ^ u * - Ai 2 u* - A22v* = 0, at oz t
,_ „N (5.7)
adjoint to (5.6). Theorem 5.2 Letazlogt, az\ogt, at log t be bounded in a finite part of R+ and enough fast decreasing at infinity. If a(z, 0) > 0, z € C, then in a class of functions bounded up to the boundary t = 0 and decreasing at the infinity as 0(R~(1+Rea<x'}), where a^ = lim a, R2 = \z\2+t2 inhomogeneous R—»oo
system (5.6) is solvable (up to at most a finite number of conditions) for any its right-hand sides bounded in finite parts of R+, decreasing at infinity. But if Re a(z, 0) < 0, z € C, then this system is solvable in the above class if and only if (up to at most a finite number of additional conditions) for any solution u*, v* of the system (5.7), continuous up to t = 0 and decreasing at infinity as 0(R~2~e), e > 0, the equality / < (fiu* + f2v*)dxdydt
=0
JR\
holds. Proof Introducing a pair of functions
v(z, t) = t
we obtain instead of (5.6) the following system + A*21^ = t-af1,
2^-^+A*nV
^
+
2
^
+ A
*^
+ A
^
= t~ah
(5-9)
376
where A*n = 2aTlogt + An,
A*12 = -atlogt
+ A12,
A21 = 2at log t + A2i,
A*22 = 2az log t + A22 •
According to the assumptions of the theorem, the system (5.9) has regular coefficients, so that if Re a(z, 0) > 0, z = € C, then this system is solvable (up to a finite number of solvability conditions on its right-hand sides). But if Re a(z,0) < 0, z € C, then according to Theorem 5.1 this system is solvable if and only if (up to at most a finite number of additional conditions) for any solution ip*,ip* of the homogeneous system adjoint to (5.9), 3d*
2
+
dtp —* , A p A
W m- »' - "
-r* ,» r =0
'
dp* dtp* -T** .* ,* „ — -2-^r-A12ip -A22tp =0
,_ i m (5.10)
in R+ continuous up to t = 0 and enough fast decreasing at infinity, the equality
f t -«(z,t) ( / i ( 2 , ) t j^^y
+ f2(Zjt)ljS(z~Fj)dxdydt
=0
JR3+
holds. In order to verify the equality (5.8) it is enough to convince ourselves that a pair of functions u* = t~a •
377
5. Dzhuraev A., Singular partial differential equations, Chapman and Hall / CRC, Boca Raton, USA, 2000 6. Lewy H., An example of smooth linear partial differential equation without solution, Ann. Math., 66, 155-158, 1957 7. Vekua T. N., Generalized analinic functions, Nauka, Moskow, 1959 (Russian) (English translation Pergamon Press, Oxford (1962)).
378 I N T E G R A L R E P R E S E N T A T I O N S FOR I N H O M O G E N E O U S O V E R - D E T E R M I N E D S E C O N D O R D E R S Y S T E M OF SEVERAL COMPLEX EQUATIONS
H. BEGEHR F. U. Berlin, Institut f. Mathematik 1 Arnimallee 2-6, 14195 Berlin, Germany E-mail: [email protected]. de D. Q. DAI Department of Mathematics, Zhongshan Guangzhou, 510275 China E-mail: stsddq@zsu. edu. en
University
A. DZHURAEV Mathematical Institute of Tajik Academy of Science Prospekt Rudaki 33, 734025 Dushanbe, Tajikistan E-mail: dzhuraevQkhj. tajik, net Partial differential equations with constant coefficients are well-studied, see e.g. 10 . In particular existence and uniqueness results are well known. The aim of this note is to present representation formulas for solutions to overdetermined systems of higher order with constant coefficients via a Cauchy Pompeiu type integral operator. In the special case where the system is studied in polydomains this operator is explicitly given.
1
Introduction
This paper is concerned with two types of over-determined system of equations d2u dzkdzk
fk,k,l
(1)
and d2u fl__2
= /*,*> ! < * < " •
(2)
System (1) is an n-dimensional analogue of the Poisson equation
a2
S-/-
(3)
dzdz They have also less defining equations than the system of the non-homogeneous pluriharmonic equations. System (2) consists of the non-homogeneous
379 bi-analytic equations 1 . When n = 1, it reduces to the well-known Bitsadze equation 3 . From classical potential theory, equation (3) is known to have the Newtonpotential representation
w{z) = - - / " / ( £ ) l o g — L -Zj d C c ™ Jc \Q- \ which solves the equation (3). In this paper, we shall construct linear integrodifferential operators T\ and T2 such that T\f and T2/ solve respectively (1) and (2). The organization of this paper is as follows: in section 2, we are concerned with the solvability of the Dirichlet problem and integral representations of the system (4) and (5). They are modified versions of du = f and come out naturally when solving the system of equations (1). Using induction procedures, in sections 3 and 4, we get integral representation for the non-homogeneous systems of equations (1) and (2). In section 5, examples are given to show the procedures presented in sections 3 and 4. Finally in section 6, explicit representation formulas are given when the domain is a polydomain.
2
Solvability of a first order system
Let ei, e2 C {1,2, • • •, n} be multi-indices such that e\ Ue2 = {1,2, • • •, n) and ei n e2 = 0. Let 0 c C n be a bounded smooth domain. Consider the first order over-determined system of complex equations:
du(z) = /j,jeei,zGfi, dz]
(4)
du(z) = /j,jee2,zeSl. dzj
(5)
and
Remark
e\ or 62 may be empty.
380
Definition 1 Let fk G C 1 (Q),fc= 1,2, • • •, n. The system of equations (4), (5) is called compatible if dfj dfk . . ^— = -^=,.7 S ei,fc € e 2)
dfi dzk
dfk dzj
..
Let the function g be continuous on the boundary dfi of f2. Consider the Dirichlet boundary condition: u = g on dCl.
(6)
For the solvability of the problem (4),(5),(6), we have the following result: Theorem 1 Let p(z) be the defining function for the domain fi and the system (4), (5) be compatible. Then the problem (4), (5) and (6) is solvable if and only if p
Y,
i~i
P
/ fjWjdZ =J2
m^da
P
+Y
j-i
m-^rda
(7)
for any tpj € C1 (f2)(j = 1,2, • • •, n) satisfying
(8) j£ei
jee2
Moreover, if the condition (7) is satisfied, the solution to the problem (4), (5) and (6) is unique and can be represented by dfi JdQ.
dV<;
Ju
dfj
*> ' * £ <*
de,
where G is the Green function of the domain Q. Proof If the problem (4), (5) and (6) is solvable, by Green's formula, we have for any solution of (8),
381
E Jn fmdt=E J | | ^ + E / £•*&
3=1 J
n
J
j6ei£
3
J'eeao
9 , _ , drp~'
da
«
Y.jup^da+^ju^da J' 6 e i an
=E/w^+E/wg^ ^ aa Sei
•?ee2dfi
which proves (7). Conversely, let (7) and (8) hold and let u(z) be a solution of the Dirichlet problem
E J
d2U dzjdzj J
3=1
dfj . df: E *—* S dz •i +- E!>»«. dz] :
J
jeei
, u = 9 on <9fi, which exists and is unique. Let du du VJ = Q=- fjiJ e e i , ^ = — - fhj
G e2.
Then from dtp~j jeei
r-v / jGei
92u dzjdzj
9/j dzj
and
E 09.z£ -j 7
J
J6e 2
^—' Vcte-iCte? j€e2
x
J
J
c*z7J
it follows that {
.
n
2
r
E /fe-wi ^= E / < ^ ) ^ R
J=1n
^=1n
382
•£/(S-")W + £J(;(S-")W
/*
J-i
£1
7 1 / 1
/
r^
/i
o
'*'
/*
/
gVi-JLdo- +J2
9Wi^-da - ^ / / ^ ^
= 0.
It then follows that (fij•. = 0, j = 1, 2, • • •, n, that is, u is a solution to (4), (5) and (6). The rest of the theorem follows from the integral representation for solutions of the Poisson equation. This completes the proof of Theorem 1. We now turn to seeking integral representations for solutions to the nonhomogeneous system of equations (4) and (5). Let u(z) be a solution to (4) and (5) and let v(zi,z2,
and fj(z)
• • • ,zn)
= u{- • • ,zh,
be similarly defined from fj{z),j
• • • ,~z~, • • •), where j i € ei,j2
e e2
— 1,2, • • •, n. Then v(z) satisfies
dv where Q* is the image of Q under the map (zi,z2,---,zn)
-> (••-,zjl,---,zj;,---),
ji e ei,j2
e e2.
It is easily verified that df^/dzk = df£/dz~],j,k = l , 2 , - - - , n , or dv — / * , / * = (fi,f2,---,fn)F ° r this function v, let Pv be its Bergman projection, see 9 . We define a mapping S by (Sf*) (z) — v(z) — (Pv)(z). Then the linear operator S is well defined. Returning to the equations (4) and (5), we have proved: Theorem 2 Let fl be a strictly pseudoconvex domain with smooth boundary. Then there is a linear integral operator T such that u — Tf solves the system of equations (4) and (5). Remark There were works devoted to integral representations and estimates for the solutions of du = / , see e.g. 6'7. There are also explicit formulas for kernels when the domain is the unit ball, see e.g. 4 ' 8 and *, p.73.
383
When Si is a product domain, i.e., Si = X£ = 1 ilfe, where Slfc is a smooth bounded plane domain in C, 1 < k < n, we have the following result, the proof of which can be carried out as in 1 , n with some modifications. Theorem 2' Let fk 6 C n_1 (f2),A; = 1,2, • • • ,n. Then u = f'f solves the system of equations (4) and (5), where T' is the integro-differential operator defined by
f'f=E(-ir+i v=l
En ^ n ^ l
d
x
11 k,: i 6e;\{fe 1 }
where e\ := e\ fl {k\,...
T-T
fcjGeJ
kj£e^
d
a 7 — 1 1 QC, ^fcl'
U
^
fc^UM
,/c„},e2 := e2 n {ki,...
^ ,kv} and
(Tkj9)(zk
7T V
3
Cfc,- - Zfc,
Inhomogeneous bi-analytic equations
In this section, we consider the over-determined system of second order complex equations (2). Let {fk,k, 1 < k
d2fk',k< ! / , , / / 1 71
si^^i^' -^-
-
/0N (9)
We seek a linear operator T\ such that u — T\f,f = (/i,i,fa2, ••• ,fn,n) solves the non-homogeneous equation (2). When / has compact support, i.e., supp/fc^ c SI, 1 < k < n, the operator T\ can be constructed via a one-dimensional integral operator. We have Proposition 1 The function U(z) =
/ y -/l,l(Cl,22,-",Zn)
satisfies d2u/d~Zk2 = fk,k{z), 1 < k
384
Lemma 1
Let 9m = -z= ~ fl ozi--- dzm-idzm+i
z
==,1 • • • dzn
<m
where {fm,m} satisfies (9). Then dgm/dzmi = dgmi/dzm n. Proof From the definition, it follows for m^m' that
d9m
V Jm,Tn
n&
|
dz1---dzm-idzm-^---dzndzm>
for all 1 < m,m' <
TT
\
^ fc=i
&
1 & Jm,n
dzm,2
dlj )
. k ^ m, in'
\ d2fm',m'
TT
_v_
11
Pnrz dzk
k=l
ic^m.m'
_
QJ^2
I TT
_9_
I dfm',m'
| LL gj£ J
g^
_
d(h
Qz^'
fc = l , \fc?!..
J/
This proves Lemma 1. Consider now the system for a: da -^=1 = 9m,l < m < n,
(10)
where {gm} is defined in Lemma 1. By virtue of Theorem 2, there is an a which solves (10) and a = Tf = 0\f. We denote ai,2,-,n = aSuppose that for some L, 1 < L < n, for any {ii,i2, • • • , « L } , 1 < «i < i 2 < . . . < iL < 7j,j o.ii,i2,---,iL a n d m c a s e L < n also aj li i 2) ... ) i t+1 for any 1 < i\ < 12 < • • • < IL+I
d
I A
d
a o -a* >i,»2,••-,«£ — I LL ff—r~ I /"i,m> m ^ {*15 *2j " - • j * i } , .•A
*•»
OZrn^
{ji,ji, • •
-JL+I}
= {ii,»2, • • •, ix,,m}.
385
Define Gm by induction assumption as L-l
Q
n
\
a dzj.
m G {ji,J2,- • •
,JL-I},
m£ {ji,J2,---
JL-I},
Gm — < J l , j 2 , •••,JX-'
.
{il,i2,---,jL} = 0 ' l , j 2 , - - - , J L - l , m } .
Lemma 2 For 1 <m,m'
dGn
Jm',m'/Vzm
= O
d dz^r
(L-l \
n A= l
n d dzj:J*
\
d dzZ
/
Jm' ,m' —
dGm, &zZ '
b) m,m' <£ {ji, j 2 , • • •, J L - I } Then denoting {ji, •• • J ^ - - , j L _ i , m } = {ji, J2, • • •, J L } and { J ' I , J 2 • • • ,JL-i,m',m} = {ji,j2, • • • ,JL+I}, by assumption,
dG„
d 2
jl,J2,-,j~L
=
a
j1J2,-,JL+l
dGm'/dzm.
c) Only one of m and ml is in {ji,J2, • • •, JL-I}- We let m <£ {ji,h, • • and ml G {J1J2, • • • JL-I}Then { J V - -, • • •_, jL-i,m} = {ji,j2, • • an L-tuple. Moreover, from ml G {ji,J2, • • • ,3L} it follows that dGn
d
dz^7
dz^
^••••j*.
J_[
HT=\ dz.
d
n
TT JL\ / fm
11 Ate-
-,JL~I} -,JL} is
Jm'yTi
- dG""
' , m ' ~ 9^„
This completes the proof of Lemma 2. Consider now the system of equations da = Gm, 1 < m < n. dz^,
(11)
386
By virtue of Theorem 2 and Lemma 2, the above system has a solution a and a = TG = O^f. We denote ajli...jL_1 = a, 2 < L < n. Hence for L = 2, the functions a,j,l < j < n, are defined satisfying da • I •' m ' m ' •) = m ' ~r= = < Oj,m, j < m, 0m ( amtj, m < j .
(12)
By symmetry, daj/dz^ = dam/&zj, 1 < j,m < n. Let u be a solution to the system u-^ = am, 1 < m < n, then obviously, ttZtrtZt„ = fm,m, 1 < m < n. Summarizing, we have proved the next result. Theorem 3 There exists a linear integro-differential operator T\ such that u(z) = (Tif)(z) solves the system of equations (2). 4
Non-homogeneous equations (1)
In this section, we solve the non-homogeneous over-determined system of complex equations (1), with the functions {fk,k} being compatible, i.e.
d2fk,k
d2f,m.m , 1 < k,m < n
dzmdzm dzkdlk~ Proposition 2 Let the function f have compact support, i.e., supp fk,k C Q, 1 < k < n. Then the function u(z) =
2 /" 1 / /i,i(Ci,22,---,z„)log-dC^
satisfies the system of equations (1). Proof See 1 . When the function / is not compactly supported, we again construct an integro-differential operator T2 by an induction argument. The system
IH'=[n£|j,M.l£*£n. •/#*:
is compatible as for k ^ m
dG
« _
d
( TT
d
If _ A f rr A1 f _ ^
(13)
387
Remark
We may also begin with
°k = n
v= \
*F dz^
\f^ •
Here some difference between the system (1) and (2) occur. By virtue of Theorem 2, there exists b which solves (13). We denote &l,2,-,n = b. Suppose for any L,2 < L < n and any { j i , j 2 • • -,3L}, 1 < J I < h < • • • < 3L < n a function bj1j2t...jL is given. Define for 1 < m < n and any {ji,32, • • • ,JL-I}, 1 < h < h < • • • < JL-i < n, the coefficients L-l
Gm
— Gm(ji,j2,
• • • ,3 L-l)
d
= <
m^ ,
0I,J2,---,JL}
{ji,J2,---,3L-i},
= {ji,J2,---,JL-i,m}.
Consider the system of equations db
Gm, m £
{jl,J2,---,JL-l}, (14)
db
I dzm
Gm,
m <£
{JI,J2,---,JL-I}-
Lemma 3 The system of equations (14) is compatible. Proof Three cases are possible: (a) m,m' e {ji,J2, • • • ,JL-I} and m ^ m!. dGn
L-l
n
d
dZm'
d
/m,m
" ^ I n dXix
dG„ dz„
\3\*»
(b) m,m' £ {ji,J2, • • • ,3L-I}, {ji,J2, • • • ,JL+I} := {ji,h, • • • ,J~L,m'}. This case does occur only if L < n — 1. Then bj1j2r..jL+1 is assumed to be given as bji,j2,---,jL 1S a s solutions to a proper system (14) with L +1 or L, respectively rather than for L — 1. <9G =
9
aZT a Z T ^ w * = Gm'Ui, j 2 , • • •, JL) = ^ ii2i .
388
(c) Only one of m and m! belongs to {ji,J2, • • • {h,32,---,JL-i}, m' G {ji,J2,---,JL-i}-
-£== ~ OZm>
•£==
= (*m'Ul> 32, •••,3L)
,JL-I}-
Let m
-
OZmi
dGn dz„ This completes the proof of Lemma 3. By virtue of Theorem 2 and Lemma 3, the system (14) has a solution b. We denote bj1j2i...tjL_1 = b. For L = 2 we have the system -£= = Gk, ^ — = Gm,m dzfc dzm for fc = 1,2, • • •, n where G
^ k, 1 < m < n,
(15)
_ f /*,*> m = A;, I &n j2 ,m^k, {J! ,32} = {k, m}.
m
Lemma 4 TTie system of equations (15) is compatible. Proof Two cases are possible: (a) m,m' ^k,{k,m,m'} = {ji,32,h}dGm ~dz~, (b)
=
dbj1 j 2 ~dz~T
.. . . = b '^ ' ) h,h,h
= Gm J1 j2
dGm - -57-
m^k. dGm _ dbiuh dzk~ dzj
_ dfk,k dzm
=
dGk dzm
The proof of Lemma 4 is completed. Denoting a solution of (15) by bk = b at last, the system du
bk,l
dbm
.
(16)
.
^
389 Any solution u of (16) satisfies in particular 5 = = ^=z = fk,k, 1 < K < n. dzkdzk dzk We have thus proved the following results. Theorem 4 There exists a linear integro-differential operator Ti such that u — Tif solves the system of equations (1). 5
Examples when n = 3
In this section we give two examples when n = 3 to illustrate the above methods. 5.1
d2u/m2=fk,k,k
= \,2,Z
According to (10), we first solve 01,2,3 which is defined by ' doi,2,3 _
dz~\
d/1,1
dzidzi"
doi.2,3 _ &Z2
9/2,2 dzidzi'
dQl,2,3 = 9/3,3 9^3 &Zidz~2 Then we find 01,2,01,3,02,3 by (11). 01,2 is defined by ' 9ai,2 _ 9/i,i 9zi dz2 9ai,2 9Z2
9/2,2 dz{
9oi, 2 a
I 9z3
— Oi,2,3)
and 01,3,02,3 are similarly defined. We now find 01,02,03 by (12). oi is defined by
390
and the rest are similarly defined. Finally the unknown function u is given through ( du A=
=
Oil
OZ\
du &Z2
= a2,
du I oz3 5.2
d2u/dzkdzk
= fk,k, k = 1,2,3
From (13), we need to determine first 61,2,3- It is defined by 06l,2,3 _ # 2 /'1,1 l dz2dz3' dz\
d~Z~2~
#61,2,3
dz3
d2/2,2 C?Zi9^3' 3 2 /;3,3 dz\dz2
The second step is to find 61,2,61,3,62,31 by (14). 61,2 satisfies r dbh2
9/i,i
dz\
dz2
96i, 2
9/2,2 9^i
C?22
<96i,2
= 61,2,3-
The remaining terms are similarly defined. The last induction step is to find 61,62,63 also by (14). 61 satisfies
391
62,63 are similarly denned. After completion of the induction process, we arrive at du du dz2
62,
du I oz3 which is (16). 6
Potential operators for polydomains
Theorem 5 Particular solutions to systems (1) and (2) in a polydomain ft = Xfe=i ^fc are given by
£ ( _ ir+ i v=l
£
TkJK...TklTkJ
^-
^-
(17)
l
and
Y^(-\)v+1 v=l
T
t---TkJklMc^o^-a:o^
J2
(18)
l
respectively, where for g € L1(fifc; C) Cfe)
(Tkg)(zk) = - - I i^^dnk, zZk 7T J Cfc -- z k nk
(Tkg)(zk) = - - [ M±Ldnk k - -Z 77T T JJ C C, k k
n..
and instead ofT% and TkTk the operators Tk-o,2 and Tk;i^ given by 1
P £
{Tk;o,2g)(zk) = -
.,
~—-g{Ck)dilk,
A" J Cfc - z k
(Tk-i,ig)(zk)
=-
loglCfc - Zk\g(Ck)dQk Qk
can be used, respectively.
392 Proof Instead of deducing (17) and (18) from (14), (16) and (11), respectively we argue inductively. As in both cases the procedure is the same it is enough to concentrate on (17). For n — 1 it is known that
u = TTf is a particular solution, see e.g. [2,5,11]. Assuming (17) holds for some n the system u
zkTZ — fk,k , 1 < k < n + 1 ,
is considered in XJJii &k- If u would be a solution then v := u — T „ + 1 T „ + i / n + i i 7 l + i would satisfy in particular Vzkjz = fkk — Tn+iTn+xfn+itn+iZkj£ (and vZn+l-z^i
, 1 < k < n,
= 0). Hence, by assumption
« = E(-!r+1
E
Tk-^---Tk~1Tklfkl,kUlCk Ck2'^Ck Ck , 2
u
v
l
I/=l
+ ^2(-1T+2 i/=i
T
E l
"+lT»+lT^r*:--"TfeiTfci^+i,n+ia1ar-a>,a
..
E TkTkfk,k + D - 1 ) ^ 1 k=l
f=2
+ E(~1)"+2 v=l
T
**T*~ • • •
E
T
^fklM(k Gk ---(k„(kv 2
2
l
"+iTk"+i'''TkiTk*fk1MCi.2a2---a„+1
E
l
u=2
k=i
E .l
+
£
l
that n+l i/=l
l
Tk„Tku • • •rfcirfci/fc1,fc1^ Cfc 2 -a„a
393 Acknowledgements The second-named author is partly supported by Alexander von Humboldt Stiftung and National Science Foundation of China. The third-named author is supported by the European Union through INTAS 93-10322 and an Alexander von Humboldt grant. References 1. H. Begehr, A. Dzhuraev, An introduction to several complex variables and partial differential equations, Pitman Monographs and Surveys in Pure and Applied Mathematics 88, Longman, Harlow 1997. 2. H. Begehr, G. N. Hile, A hierarachy of integral operators. Rocky Mountain J. Math. 27 (1997), 669-706. 3. A. Bitsadze, On the uniqueness of solutions of the Dirichlet problem for elliptic partial differential equations, Uspechi Math. Nauk 3 (1948), no. 6, 211-212 (Russian). 4. C. P. Charpentier, Formules explicites pour les solutions minimales de I'equation du = / dans la boul et dans It polydisque de Cn, Ann. Inst. Fourier 30,4(1980), 121-154. 5. A. Dzhuraev, Methods of singular integral equations. Longman, Harlow, 1992. 6. G. M. Henkin, The method of integral representation in complex analysis, in A. G. Vitushkin(ed.), Several Complex Variables I, Springer-Verlag, Berlin, 1990, 19-116. 7. G. M. Henkin, A. Iordan, Compactness of the Neumann operator for hyperconvex domains with non-smooth B-regular boundary, Math. Ann. 307(1997), 151-168. 8. F. R. Harvey, J. C. Polking, The d-Neumann solution to the inhomogeneous Cauchy-Riemann equation in the ball in C", Trans. Amer. Math. Soc. 281,2(1984), 587-613. 9. S. G. Krantz, Partial differential equations and complex analysis, CRC Press Inc., Boca Raton, 1992. 10. V. P. Palamadov, Linear differential operators with constant coefficients. Springer Verlag, Berlin etc., 1970. 11. W. Tutschke, Pariielle komplexe Differentialgleichungen in einer und mehrerer komplexen Variablen. Deutscher Verlag Wiss., Berlin, 1977.
394 C O M P A C T N E S S OF THE C A N O N I C A L SOLUTION OPERATOR TO d RESTRICTED TO B E R G M A N SPACES
F. HASLINGER Institut fur Mathematik, Universitdt Wien Strudlhofgasse 4, A-1090 Wien, Austria E-mail: [email protected] In this paper we characterize compactness of the canonical solution operator to d restricted to radial symmetric Bergman spaces in one complex variable. The necessary and sufficient condition is expressed in terms of the Bergman space norms of the monomials zn.
1
Introduction
Let Q denote a bounded domain in C" and consider the canonical solution operator to d S : A2(0A)(i})
—>L2(Q)
which has the properties dS(g) = g and S(g) ± ^4 2 (0), here A201JQ,) denotes the space of all (0, l)-forms g = 5Z? =1 9j(z) d^j with holomorphic coefficients gj belonging to the Bergman space A2{Q) = if
-n—> C holomorphic
: /
\f(z)\2d\{z)
< oo
here A denotes the Lebesgue measure in Cra. In 6 the following result is shown Proposition 1 The canonical solution operator S : A 2 0il) (fi) — L 2 (0) has the form S{g){z)=
l B(z,w)
d\(w),
n
for z = (zx,.. .,zn)
< g(w), z-w>=
Y^9j(w){zj
and w = (wi,..
.,wn).
- Wj),
395 In the sequel the Hilbert Schmidt property of the canonical solution operator is investigated: it is shown that the canonical solution operator for A 2 (ID), where B is the unit disc in C, has the Hilbert Schmidt property, but the canonical solution operator for A 2 (B n ), where B™ is the unit ball in C", n > 1, fails to be Hilbert Schmidt, for further details see 6 . Here we consider Bergman spaces A2(D, dfi), where D is a disc in C and dfi(z) = m(z)d\(z), m being a radial symmetric weight function. We suppose that the monomials {zn}, n £ No constitute an orthogonal basis in A2(D, dfi). Let c2 = /
\z\2ndfi(z).
JD
We solve the 9-equation du = g, where g € A2(D,dfi) and obtain a necessary and sufficient condition for the canonical solution operator to d restricted to A2{D,dfi) to be a compact operator. The canonical solution operator S has the property S(g) _L A2(D,dfi). This condition is expressed in terms of the sequence (c n )„ defined above. For this purpose we use the fact that the canonical solution operator S : A2(D,dfi) —• L2(D,dfi) can be expressed in the form S(g)(z)=
/
B(z,w)g(w)(z-w)~dfi(w),
JD
where B denotes the Bergman kernel of A2(D,dfi) and g £ A2(D,dfi) (see 7 )The adjoint operator 5* : L2(D, dfj) —> A2(D, dfi) can be written in the form S * ( / ) M = / B(w, z)f(z)(z
-
w)dfi(z),
JD
where / G L2(D,dfi). We will show that S*S : A2(D,dfx) —> A2{D,df£) is a diagonal operator and will then use the fact that S*S is compact if and only if S is compact. It is pointed out in 4 that in the proof that compactness of the solution operator for d on (0, l)-forms implies that the boundary of Cl does not contain any analytic variety of dimension grearter than or equal to 1, it is only used that there is a compact solution operator to d on the (0, l)-forms with holomorphic coefficients. In this case compactness of the solution operator restricted to (0, l)-forms with holomorphic coefficients implies already compactness of the solution operator on general (0, l)-forms.
396
A similar situation appears in 10 where the Toeplitz C* -algebra T(fi) is considered and the relation between the structure of T{0) and the d-Neumann problem is discussed (see 10 , Corollary 4.6). The question of compactness of the 9-Neumann operator is of interest for various reasons, see 5 for an excellent survey. In 6 and 7 we investigated the Hilbert Schmidt property of the canonical solution operator to d the weaker property, of compactness appears to be more difficult in the case of several variables where S*S fails to be a diagonal operator. The canonical solution operator to d restricted to (0, l)-forms with holomorphic coefficients can also be interpreted as the Hankel operator H^g) = (I2
P)(zg),
where P : L (Q) —> A (Q,) denotes the Bergman projection. See 1, 2 , 3 , 8 , 9 , 11 and 13 for details. 2
2
Compact solution operators
Proposition 2 Let ft, be a bounded domain in C". The adjoint operator S*:L2(Sl)^A2(0A)(n) of the canonical solution operator S to d restricted to the Bergman space can be written in the form S*g(w) = Y, where B(w,z)
/
(zj-u>i)B(w,z)g{z)d*(z)
denotes the Bergman kernel of CI and g € L 2 (Q).
Proof. Let f(z) = £)™=1 fj(z)dzj be a (0,l)-form with coefficents fj A2(n), j = 1 , . . . n and let g e L2{tt). Then (S(f),g)=
[
= / E / » which implies the result.
IB{z,w)Y,fj{w)^j-wj)gJz)d\{z)dX{w)
( I B{w,z){zj-wj)g(z)d\(z)) •
d\(w),
£
397 By analogous methods we obtain Proposition 3 The adjoint operator S* : L2(D,dfi) written in the form S*(f)W=
I
—> A2(D,dfi)
can be
B(w,z)f{z){z-w)dn{z),
JD
where f € L2{D,dfi).
denotes the Bergman kernel of A2 (D, d/j.).
Here B(w,z)
^Prom 7 we know that for the orthonormal basis {un(z) = zn/cn} S(un)(z)
= zun(z)
we have
c 2n_1
^ C
n-1
and that the Bergman kernel can be written in the form
B(z,w) = Y,—ra". fe=0
k
and the expansion of the Bergman kernel converges uniformly on compact subsets. Now we are able to show that Proposition 4 For the orthonormal basis {un{z) = zn/cn} S*S(un)(w)=(^~-^-)un(w) V cn
we have
,n = l , 2 , . . . c
n-lJ
and S*S(u0)(w)
= % uQ(w). c o
Proof. ^Prom Proposition 3 it follows that S*S(un)(w)
= [ B(w,z)(z-w) JD
r °°^ wk~zk
(—c \ n f~zzn
C -^~] dn(z) cn-i J c zn~ 1 \
This integral is computed in two steps: first the multiplication by z
398 f zn+! ~ WkZk+1
C
= ^ [ \*\*+2M*)--/^ c
n
f \z\*>Mz)
c
n-lCn
JD
°° WkZk
f
JD
- I £S±! _ _±!L. ^ wn And now the multiplication by w
f ±^f (^L-Safl) Mz) c
JD . _ n f Zn ^
to '
c„u;
V C«
C
n-1 /
u; fc z fc+1
/" c„2™
C
JD C n _ !
•/£> °n k=Q n
fc
J
2
c;• n - l
k
c ra u;
X
^
WkZk , , .
fc=Q
Cfc
n J
.2 c
n-l
= 0, which implies that .2
„2
n w w H ^c - x - h - H ,n = i,2,..., 2
the case n = 0 follows from an analogous computation.
•
With the help of the last result it is not difficult to characterize compactness of the canonical solution operator on A2(D, d/i) Proposition 5 The canonical solution operator S : A2(D,dfi)
—+
L2(D,dfi)
is compact if and only if
lim I ^ ± i - •£-) = 0. c
n-l/
399 Proof. Proposition 4 says that S*S is a diagonal operator with respect to the orthonormal basis {un(z) = zn/cn} of A2(D,d/j,). Therefore it is easily seen that S*S is compact if and only if lim ( % - # - ) =
0.
Now the conclusion follows, since S*S is compact if and only if S is compact (see for instance 1 2 ). • Remarks. a) If D is the unit disc in C and m(z) = (1 — |z| 2 ) a , where a > 0, then the condition appearing in Proposition 5 is always satisfied. The solution operator to d is even Hilbert Schmidt (see 7 ) . The condition is violated in certain weighted spaces of entire functions, but there an additional difficulty appears (see Remark c). b) It turns out that in the case of several variables the operator S*S does not behave like a diagonal operator, the images S*S{un){w) are in this case much more complicated. c) In our reasoning it is important to suppose that the domains involved are bounded, since we consider multiplication by z. The case of weighted Bergman spaces of entire functions will be treated in a forthcoming paper. References 1. S. Axler, The Bergman space, the Bloch space, and commutators of multiplication operators, Duke Math. J.53 (1986), 315-332. 2. J. Arazy, S. Fisher and J. Peetre, Hankel operators on weighted Bergman spaces, Amer. J. of Math. 110 (1988), 989-1054. 3. F.F. Bonsall, Hankel operators on the Bergman space for the disc, J. London Math. Soc. (2) 33 (1986), 355-364. 4. S. Fu and E.J. Straube, Compactness of the d—Neumann problem on convex domains, J. of Functional Analysis 159 (1998), 629-641. 5. S. Fu and E.J. Straube, Compactness in the d—Neumann problem, preprint 1999. 6. F. Haslinger, The canonical solution operator to d restricted to Bergman spaces, Proc. Amer. Math. Soc, to appear. 7. F. Haslinger, The canonical solution operator to d restricted to radial symmetric Bergman spaces, ESI preprint 387, 2000. 8. S. Janson, Hankel operators between weighted Bergman spaces, Ark. Mat. 26 (1988), 205-219.
400
9. R. Rochberg, Trace ideal criteria for Hankel operators and commutators, Indiana Univ. Math. J. 31 (1982), 913-925 10. N. Salinas, A. Sheu and H. Upmeier, Toeplitz operators on pseudoconvex domains and foliation C* — algebras, Ann. of Math. 130 (1989), 531-565. 11. R. Wallsten, Hankel operators between weighted Bergman spaces in the ball, Ark. Mat. 28 (1990), 183-192. 12. J. Weidmann, Lineare Operatoren in Hilbertrdumen, B.G.Teubner Stuttgart-Leipzig-Wiesbaden, 2000. 13. K.H. Zhu, Hilbert-Schmidt Hankel operators on the Bergman space, Proc. Amer. Math. Soc. 109 (1990), 721-730.
401
THE THEOREM OF THE REGULAR CONTINUATION FOR PARTIAL DIFFERENTIAL EQUATIONS IN GENERAL FORM AND ITS APPLICATIONS LE HUNG SON Hanoi
University
of Technology, E-mail:
Department of Applied Vietnam [email protected]
Mathematics
Let A be a Clifford algebra, Q be a domain in Rn. Denote by F{Cl,A) of t h e functions defined in CI which take values in .A and D
the space
:F(n;A)->F(Sl;A)
be a linear differential operator. Moreover, let R(Cl; A) be the set of all regular solutions of the equation: Df = 0 (1) for f&F(n;A). This paper deals with t h e two following problems: P r o b l e m 1 Can each / G R(Cl; A) be extended in a larger domain CI D fi as a solution of (1) for the given CI. P r o b l e m 2 For which domains CI there exists a function / € R(Cl; A) which can not be extended in any larger domain CI 3 CI as a solution of (1). Problem 1 is solved by the theorem of regular continuation for the solutions of the partial differential equations (1) and the Problem 2 is t h e characterization of a "Domain of regularity" for (1). The Problem 1 is solved for some special cases when the differential operator D is elliptic.
1
Introduction
In mathematical applications the following situation is often encountered: It is well known that a physical law or an experimental event is fullfiled in a region (or domain). It is to ask: When this law or this event is valid in a larger region (or domain), too? The physical laws or the experimental events are described by partial differential equations. Therefore we can state this problem as follows. Let A be an algebra (.4 can be the algebra of the complex numbers C, the
402
algebra 7i of the real quaternions or a Clifford algebra...) and Q, be a set (or a domain) in Rn. Denote by F{Q,, A) the set of functions which are defined and differentiable in Q, and which take values in A. We define a linear differential operator
D:F{9.;A)^T(Q.;A) and denoting by 1Z(il; A) the set of all solutions of the equation Df = 0
(1)
We say that a solution / € 7£(fi; A) can be extended in fl D Q if there exists a / G K(Q,;A) such that / = / in O. In the following it is assumed that the following theorem is fullfiled. Theorem of Uniqueness For / , g £ 7l(Q; A) with / = g in a non-empty open subset u c f i , then / = g in Q if fi is a domain of Rn. We are interested in the following 2 problems. Problem 1 For the given domain ficii", when there exists a larger set f2 D fi such that each / £ 7£(fi; .4.) can be extended in a larger set Q ^ O. Remark 1 The Problem I means that the considered physical laws (or the experimental events) in Q are fulfilled in a larger set Q, too. Problem 2 For the given algebra A and the partial differential operator D, it is to find a domain d c i ? " and an / e 7£(Q; .A) which cannot be extended in any larger set fl ^ 0. These domains with the last property are called the " domain of regularity for the equation (1). Concerning with the physical laws the domain of regularity is the largest domain in which these laws are valid. This paper deals with the Problem 1 in the case of linear elliptic differential equations, and A is a Clifford algebra.
403
2
Preliminaries
In the (n + l)-dimensional Euclidian space Rn+1 it is given a non-degenerate quadratic form 771
71
F(x) = xl + ^2 x) -
x
Y^
)
0 < m < n.
(2)
Let eo, ei,..., en be the corresponding basis of the quadratic form (2). We define a product in Rn+1 which is associative but not commutative and satisfies the following properties e^ = e 0
e^ = - e 0
for
j = 1,..., m
e? = eo ej-e/t + ek&j = 0
for for
j = m + 1,..., n l<j
Denote by R^1 the above product.
the space Rn+1
(3)
with the quadratic form (2) and with
Definition 1 (see n ) The universal Clifford algebra -R(„im) (n > 2) over i?^ + 1 is an associative real 2 n -dimensional (n > 2) non-commutative vector space with basis e 0 , ex,..., en, eie 2 ,..., e n _ie„,..., e i e 2 - - - e n . (4) In below we consider the case of A = R(n,m)- With the abbreviation a = (ai, ...,aft.) C {0,1, ...,n} ea = eai • • • eah, each element a € A has the form n
a = aoeo + 2 ^ 2 _ ^ a a e a h=l
ao,aQGi?,
(5)
a
where 1 < a\ < • • • < a.k < n. Furthermore, we define by „ ii(h+i)
eQ : = ( - ! )
= ea
(6)
and the conjugation of a by a = ^ ^ a
a
e
a
.
(6a)
We abbreviate CLQ =: Sea, a — ao := Veca what denotes the scalar part and the vector part, correspondingly.
404
Definition 2 An element a € A is called vectorial if it has the form a = a0e0 + aid H
V anen.
Let O be a domain in Rn f : Cl—>A = R(n,m) then / is of the form
f = Y,f«(*)ea
(7)
a
a = (ao,-.,ah)
C {0, l,...,n}
/ is called a function defined on 0 and taking values in the Clifford algebra A. We denote the set of such functions by J^"(fi;^4). The function / € f(fi;.4) is said to be of the class Ck, C°°, Lp, C#(O; A) iff fa are belonging to Ck,C°°,Lp,C^(n), respectively. Now we define the Dirac operator
D
= t-&e dx k k=l
k
(8)
and the Cauchy-Riemann operator
fc=0
and the operator d = - — e 0 - £>. dx0
(9a)
Definition 3 A function u(x) £ C 1 (£);.4) is said to be left (respectively right) regular in Cl if Du = 0
(resp. u£> = 0)
<9u = 0
(resp. ud = 0)
or
(10)
405
Remark 2 (see bers.
12
) #(i,i) = C is the algebra of the usual complex num-
R(2,2) = H is the Hamilton quaternion algebra. We denote #(„,„) (n > 1) by i?(„) for short. This algebra will be used to consider the elliptic PDEs. The algebra -R(n,„_i) will be used to consider the hyperbolic PDEs. 2) The theory of the regular function (by means of the operator d) in i?(„) has been studied in 1 by Delanghe, F. Sommen and other mathematicians. 3) It is
k
fc=0
k
k=m+l
'
Thus in i?(n) (m = n) this will be the Laplace operator, in R(n,n-i ( m = n —1) it will be the wave operator and in R(n,n-2) it will be the ultrahyperbolic operator in sense of R. Courant (see 3 and n ) . Definition 4 The Clifford algebras denoted by R9. and R9 n_1> are associative real 2 n -dimensional non-commutative (n > 2) vector spaces with the basis (4) and with the relations 4 = - e 0 , j = l , . . . , n - l , e2n = 0
(12)
and e) = - e 0 , j = l,...,n-2
,
t?n_x = e 0 , e£ = 0,
resp.
(13)
In i?9 N and .R9n JJ_1N we have, respectively, 3 9 =
L & 2 0
and
" = L ^ 2 - ^ 2 - -
Udj
k
0
aa;
fc
(14)
OX
n-l
Then consider the operator d-Pn
(15)
where the linear operator Pn is defined by 0Pnu=-^-.
(16)
406
Then d(d — Pn)u is the heat operator in R9, whose principal part is the Laplacian).
(i.e. the parabolic operator
Definition 5 u G C 1 (0; A) is said to be h-regular if du + uh = 0
(17)
du + uh = 0
(17a)
or
where h e ^(fi; A) and u = ^uQea
u = y^uaea
a
— y
2
Ij
(18)
a
ea
— &ah ' • • 6 a i
6a,
€.j —
6j,
J — 1, . . . , 71
3
The extension theorems for elliptic partial differential equations
In this section we take the algebra A — 7£(\) and the partial differential operator T> as either the Dirac Operator D or the Cauchy Riemann Operator d (resp. d). Then the regular functions satisfy the following systems either
Du = 0
or
du = 0
(20)
(du = 0). Because of (14) the system (20) is elliptic. If u e K(Q,A) fl C2(Q,A) then Aua — 0 for each a (where A is the Laplace operator). Hence the following theorem is fullfiled for such u. The uniqueness theorem for regular functions Suppose that Q. is a connected open set of Rn (such a set we call later a "domain"), a C £1 is a non-empty subset of 0 . Further suppose that u^ u(l)
=
u(2)
•
a
t h e n
u(l)
=
u(2)
and u^ i n
Q^
are the regular functions in CI. If
407
Problem 1 for regular functions Let Qi be a domain in fi. In which case there exists a domain fii such that fii ^ fii C fi such that for each u € TZ(Q.\,A) there exists a u £ TZ(fti,A) such that u = u in fij. The function u is called the regular extension of u from fii to Qi. Remark 3 Because of the Uniqueness theorem, the extension it of u is uniquely determined. For l < f c < n — l w e set
We consider the systems Du = 0
,
Dku = 0
(22)
du = 0
,
5fcu = 0.
(22a)
and
Suppose that Q.\ = Q,\' x 0,^ ' c fi, where fl[ and fi^ ' are domains in Rk(xi,...,xk) and Rn~k(xk+i, ...,xn), respectively, let E be an open neighbourhood of the boundary dili of fii. Then we get Theorem 1 For each C2-solution u of (22) (respectively (22a)) in E there exist a solution u of the same system in Q.\ such that u = u in E. Namely each regular function u in E can be extended regularily in Oi. Proof We prove the theorem for the system (22). For the system (22a) the proof is similar. From (22) it follows that u is a solution of the system DkU = 0 D n _ fc u = 0 in E, where Dn-k
=
(a) (6)
(23)
ek+i-\ 1-7—e„. Denote by x = dxk+i oxn (xi,...,xk), y = (yi,...,y n -fc) = {xk+i,.--,xn). Because of (23a) the function u is regular on (xi,...,xk) e Q\k' by fixed y = (yi,...,yn-k) such that (xi,...,xk,yi,...,yn-k) e E.
408
Let Ki(t,x) be the Cauchy kernel for the system (23a) where t = (ti,...,tk). We define the function u:=
/ K1(t,x)datu(t,y) Jda.\k)
(see 1 )
Then it is easily to show that u is the regular extension of u in VL\.
(24) Q.e.d.
Example 1 We consider the following example for the application of the above theorem. Let A = "H be the algebra of the Hamilton quaternions with basis eo = 1, ei, e 2 , e 3 = eie 2 . u = y2uiei ~
d = yZei~x— -n9xj
di=e01- ex——. dxQ dxi
Then the system (23) leads to du = 0 diu = 0
(23a)
which is equivalent to the following system of PDEs duo dxo du\
du\ dx\ dun
— - H
dxo du2 dxo
&U2 dx2 dux
dus _ X3 du2
0x2 duo dx2
8x3 du\ _ dx3
H
dx\ dus dxi
= 0
pL_p=0 OXQ
dui dxo du2 _ dxo du3 dxo Hence the extension
OX l
duo = „ dxi du3 = dx\ dva = „ dxi Problem 1 is true for the solutions of system (25).
(25)
409
Now let us consider the system du + Lu = du + ^2Ca(x)
+ Ha(u(x))=0
(26)
a
where Ca are functions with values in .R(„) and Ha(u) are linear forms of u in i? ( n ) , Ha = Hai • • • Hah and for j ^ k, 1 < j < n.
Hj(ej) = -ejt
Hk{ej) = e,(k) —
Suppose that all Ca(x) are (real) analytic in x\,...,xn, denoted as in the Theorem 1.
Cli,Q\
,dk,--- are
Remark 4 Prom the theorem of E. Hopf (see 8 ) it follows that the C 3 -solutions of (26)-(27) are analytic. Therefore the Uniqueness theorem is fullfiled for such solutions. We consider the system diu = 0.
(27)
Theorem 2 Suppose that u is a C 3 -solution of the system (26)-(27) in E. Then there exists a unique solution u of this system in Q,\ = Q,\ x f l j n _ ' such that u = u onT,. Proof Because of the theorem of E. Hopf (see 8 ) if u e C 3 and u is a solution of (26)-(27) then u is (real) analytic. Now define u by the formula (24) and we consider F{x) :=du + Y,Ca(x)Ha(u(x))
(28)
a
F is defined for all x £ Q,\ and (real) analytic. If y = (x/.+i, ...,£n) is enough close to 9 0 j ~ ' then x = (x\, ...,#„) G S. For such x it is u(x) = u(x) because of (24). Therefore F(x) =du + Y, C(x)Ha(u{x))
= 0.
(29)
a
From (29) it follows that there exists a non-empty open subset a of S such that F(x) = 0 in a. Because of the Uniqueness theorem (for real analytic functions) we have F{x) = 0
for all
1 6 ^ .
410
Hence u is the solution of the system (26)-(27). Since u = u in a, then from the Uniqueness theorem for the solution of (26)-(27) (see Remark 4) it follows that u = u in S. Thus u is the desired extension of u. Q.e.d. G i? (n+1 )(:r), y = (yo,yi,-,yn)
Denote by x = {x0,xi,...,xn) i?(" )(y). +1
G
Let Oi be a domain in i?(™+1)(a;), fi2 be a domain in R(n+1^(y) with smooth boundaries, O = fii x fi2> E be an open neighbourhood of dfl. We consider the function u(x,y) defined on Cl and taking values in i?(„). It is u(x,y) =
'^2ua(x,y)ea. a
Further we consider the system dxu + uh — 0
(a)
dyu + uk = 0
(b)
(30)
where dx is defined as in (9) and dy is defined as dx by changing the letter x to y; h, k are any two Clifford numbers in /?(„). From the theory of elliptic partial differential operators it follows that each C 3 -solution of the system (30) is (real) analytic (see 8 ) , therefore the Uniqueness theorem is valid for the class of such solutions. In the sequel we consider only this class. Theorem 3 Let u be a solution of (30) in E. Then there exists a unique solution U of this system in Q such that U = u on E. Proof At first we give some denotations. Denote by q(x,y)=u\dni n
3=1
gn+i is the solution of the Helmholz equation Ag-\h\2g We define the function U =
Ks(q(Z,y),h,x)
(31)
= 0 in IV (32)
411
:
= — w
/ [degn+i(r)r,(£)u(i,y)
+
9n+i(rm)u(Z)h]dSt
n + l Js
where S = dQf, £ e S, r = \x - £\ (see 12 , formula (1.9) on page 31). U is defined in the whole of Q and U satisfies (30a). If y is close enough to dfl2, then (x,y) S E hence £/ = u for such (x,y). Therefore there exists a non-empty open subset a = o\ x a2 C E such that [/ = u on a. Further CT can be choosen so that o\ and (72 are open subsets of Rn+1(x) and Rn+1(y) respectively. Now define for each fixed x GQI the function F(y) = dyu + uk
(33)
If x is close enough to d£l\ then U = u and hence Fx{y) = dyu + uk = 0. Therefore there exists an open subset ax of -R"+1(a;) x Q2) n E such that Fx{y) = 0 on CTX. Prom the Uniqueness theorem for the solutions of (30b) it follows that Fx(y) = 0 for all y G Rn+1(x) x Q2- This means that U is a solution of (30b) in Q,. Because of the Uniqueness theorem, U is the desired extension of u. Q.e.d. To apply this theorem we consider the following example: E x a m p l e 2 Let u(x,y),h(x,y),k(x,y) R(n),
be vectorial functions with values in n
u(x,y) = u0(x,y)e0
-
^uj{x,y)ej 3=1 n
h(x,y) = h0{x,y) - '^hj{x,y)ej 3=1 n
k(x,y) = k0(x,y)
-y^2lkj{x,y)ej. 3=1
(34)
412
Then the system (30) can be written in the form
E(Sr + M;)=o dxi K
diij
duk
,
,
,
duj
duk , , , . ^ kkUj + kjuk = 0 (36) dyk dyj and the Theorem 3 is true for the system (35) with condition (36). If h = 0, k = 0, n = 3 the system (35)-(36) leads to the following "bi-Riesz" system div x u = 0, AbfyU = 0 rotrM = 0, xotyU — 0 (37) where u = (ui,U2,u3) we get
x = (xi,x2,x3)
y = (2/1,2/2,2/3)- Using Theorem 3
Corollary Suppose that u is a given solution of the system (37) (bi-Riesze system) in an open neighbourhood of the boundary dCl of a given domain O in R3. Then U can be (uniquely) extended in the whole of O as a solution of the same system.
References 1. F. Brackx, R. Delanghe and F. Sommen, Clifford Analysis, Pitman, London, 1982. 2. F. Brackx and W. Pincket, Two Hartogs theorems for nullsolution of overdetermined system in Euclidian space, Complex variables, Vol.5, 1985. 3. R. Courant and D. Hilbert, Methods of Mathematical Physics, New York 1962. 4. B. Goldschmidt, Properties of generalized analytic vectors in Rn, Math. Nachr. 103, 1981, 245-254. 5. K. Giirlebeck and W. Sproessig, Quaternionic Analysis and Elliptic Boundary Value Problems, Academie-Verlag, Berlin 1989.
413
6. K. Habetha, Function theory in Algebras. Complex Analysis Methods Trends and Applications, Akademie-Verlag Berlin, 1985, 225-237. 7. L. Hoermander, An Introduction to Complex Analysis in Several Variables, North Holland Publishing Co., Amsterdam, 1973. 8. E. Hopf, Math. Ztschr. Bd. 34, p.194. 9. Le Hung Son, Extension problem for functions with values in a Clifford algebra, Archiv fuer Math. Vol.55 (1990). 10. Le Hung Son, Some New Results of Clifford analysis in higher dimensions
"finite or infinite dimensional complex analysis". Lecture Notes in Pure and Applied Mathematics, Vol.214, Marcel Dekker Inc. New York 2000, 245-265. 11. Le Hung Son and Nguyen Thanh Van, Matrix criteria for the extension of solutions of the general linear system of partial differential equations with function coefficients, "Lecture Notes in Pure and Applied Mathematics, Vol. 214", 267-281. 12. E. Obolashvili, Partial differential equations in Clifford analysis. Pitman Monographs vol. 96, Longman 1998. 13. D. Pertici, Funzioni regulari di piu variabili quatemioniche, Publication of U. Dini University. Monography Nr. 67/A, 50134, Firenze.
414
SOME HIGHER O R D E R EQUATIONS IN CLIFFORD ANALYSIS E. O B O L A S H V I L I A. Razmadze
Mathematical Institute 380093 Tbilisi E-mail: [email protected]
Using tools from Clifford analysis, in this paper some new higher order partial differential equations are obtained. Some boundary value problems ( = BVP) and initial value problems as well are solved for them.
1
Introduction
The genius Johann Kepler thought that "Mathematics is the world's primary beauty". The famous physicist and mathematician Paul Dirac expressed the same by saying: "I am always aspired to obtain beautiful formulas as it is a symbol of belief and a basis of important success". The Dirac operator just is beautiful and is a powerful tool for Clifford analysis. It is known that the classical equations of mathematical physics, electromagnetic fields, relativistic quantum mechanics and their generalizations can be obtained using the Dirac operator without applications of any physical laws. In this paper new higher order equations, which really have mathematical beauty, are obtained using Clifford analysis. Probably they will have important applications. First some basic notions and definitions will be described. Elements of Clifford analysis (e.g., 5 ) Let R(n), R(n,n-i) a n d R?n) (n > 1) be Clifford algebras with the basis {e^}, A = ( a i , . . . , a^) with 1 < o.\ < • • • < ak < n, and with the multiplication rules eo = e 0 , e2j = -e0 for j = 1 , . . . , n - 1, ej-efc + ekej = 0 for j , k = 1 , . . . , n and j =/= k,
(1)
e^ = — eo in the case i?(„),
(2)
e2n = e 0 in the case
(3)
fl(„,„_i),
e^ = 0 in the case R®n->, where eo is the identity element. Thus, these spaces are associative, 2ndimensional as real spaces, non-commutative (for n > 2), and any element
415
can be represented as
= YlUAeA-
(4)
u=^2ukek-
(5)
An element u is vectorial if
fc=o For every u two conjugations are denned: u = ^2uAeA,
u = y^uAeA,
' A
(6)
A
where eo = eo, e.j = ej = —e^, j — 1 , . . . , n, and eA = e a f c - - - e a i = ( - l ) f c ( f e + 1 ) / 2 e , i ,
e A = e Ql • • -eak = {-l)keA.
(7)
Consider the modifications of the Dirac operator [BDS], n
p.
n
p.
9 = ^ 3 ^ — e f c = — e0 + D, fe ax ° fc=C)
n
d = — e0 - D, OX °
x = ~Y^xkek, fc=o
where D is the Dirac operator. One has in i?( n ), R(n,n-i) spondingly, dd = dd = A{nh
d2 3d = A ( „_ 1 ) - ^ - ,
an
(8)
d ^( n )i corre-
dd = A( n _i),
(9)
where A(j.) (fc = n, n — 1) is the Laplace operator with respect to the variables XQ, ..., xk. From these equalities it follows that the equations du = 0,
Pu = du + uh = 0
(10)
are elliptic in R^ and hyperbolic in #(„,„_ i). In these spaces Beltrami and generalized Beltrami equations can be considered 6 : ~3u + qdu = Q,
(11)
du + q\du + q^du = 0.
(12)
We will see that these equations can be elliptic or hyperbolic depending on the conditions imposed on the coefficients. Further, pluriregular, plurigeneralized regular and pluri-Beltrami equations will be considered in i?(n) and R(n,n-i) '• dmu = 0, m
Pmu = 0,
(d + qd) u = 0,
m>2.
(13) (14)
416
In F9s pluriparabolic equations will be considered. If u(x) is a solution of (13), then it will be a solution of the polyharmonic or poly-Helmholtz equation in i?(„), and of the polywave or poly-Klein-Gordon equation in R(n,n-i) supposing h = const: A m u = 0, ( 2 2.1
A
~ ^ )
(A - \h\2)mu = 0, u = 0
'
(A_|/l1
(15) dfi)
u
= 0'
* » = '•
(16)
Elliptic Higher Order Equations BVP for pluriregular equations in the space with the cuts
In the two-dimensional case many problems are solved for holomorphic functions in some plane domain with cuts. In high-dimensional cases we have not such solutions. We will consider the three-dimensional space with a cut along the circular domain XQ + x2 < a2, and some problems for harmonic functions will be solved. Let fl+ be the half-space X2 > 0, x = (10,^1,12) G fi+- The domain XQ + x\ < o? in the boundary X2 = 0 will be denoted by 5+, and the domain XQ + X\ > a2 by 5 _ , a = const. Let CI be infinite space R3 with a cut along S+. To solve corresponding problems, we will use the solution of some problems for harmonic functions constructed by Hobson. At first Hobson's representation will be given. Problem (Hobson) Find a harmonic function u(x) in CI vanishing at infinity, and satisfying the conditions u ± (a;o,a;i,0) = / ( z o . ^ i )
on S+,
(17)
where u ± (a;o,2;i,0) =
lim
U{XQ,X\,X2).
xi—»±0
The given function here and everywhere are supposed to be sufficiently smooth. The solution is represented by Hobson's formula: u(x0,x1,x2)
=
f(tv) s+
^3(jyr
+ arctgM
)
d dri
£ >
(18)
417
where
j2x2ja?-?-tf
M= 2
r^x
Q
+ x\ + x22- a2 + R'
r* = (Xo-t;)2 + (xi-v)2 R2 = (a2 - x l - x \ - x\f
+ xl + 4a2xl.
[
}
It is clear that when x2 = 0 and XQ + x\ > a2, then R = x\ + x\ — a 2 , and if XQ + x\ < a2, then R — a2 — XQ — x\. If we have the boundary conditions u + (x o ,a;i,0) — h{xQ,x{),
u~(x0,x1,0)
= f2(x0,Xi),
(20)
then one can consider two harmonic functions u1(x0,xi,x2)
= -[u(x0,x1,x2)
u2(x0,x1,x2)
= -[u(x0,xi,x2)
+
u(x0,xi,-x2)] (21) -u(x0,xi,-x2)]
in ft satisfying the boundary conditions u
t =ui
= g (-ft + ^ 2 ) =
u
f{xo,xi)
t = ~u2 = ^ ( / i - h) =
g(x0,xi)
by (20) on S+. Thus u\ can be represented by (18) and u2 by Poisson's formula _ ^2 u2 ~2TrJJ
ffg(Z,v)dZdri r* •
^
Problem Find a harmonic function u(x) in fi+ vanishing at infinity, and satisfying the conditions u{x0,xi,0)
= f(x0,x!)
- — = g(x0,xi)
for
(i0,ii) G 5+,
for a;2 = 0, (x0,xi)
G 5_.
(23) (24)
Using the solution of the Neumann problem in a half-space, one can reduce (24) to the homogeneous condition g = 0. Then, by the Schwarz reflection principle, the function \u(x0,xi,x2) for x2 > 0, «i(a:o,a:i,a:2)= ^ ' I u(a: 0 ,ii,—X2) tor x2 < 0,
(25)
418
will be harmonic in Q will satisfy on the cordination Ui{x0, xt,0) = uJ"(a;o,a;i,0) = f(x0,xi)
(26)
By (23) on S+. Thus u\ can be represented by the Hobson formula (18). Let D be the quarter x\ > 0, X2 > 0, —oo < XQ < oo of the threedimensional Euclidian space. Define in D a harmonic function u(x) vanishing at infinity by the conditions 011
~—=f(xo,xi) u(xQ,Q,x2)
for 5 - ,
u(xo,x1,0)
= 0 for S+,
(27)
du = Q or - — = 0 for xx = 0, x2 > 0.
(28)
OXi
By the Schwarz reflection principle this problem can be easily reduced to the problem with the conditions (26). Thus the solution can be represented by (18). Problem Let D be the half-space x2 > 0 with a cut along the half-circle XQ+X2 < a2. Define in D a harmonic function vanishing at infinity by the boundary conditions u(xo,xi,0) u±(x0,0,x2)
= 0,
(x0,xi)
G R2, xl+x\
= f(x0,X2),
Solution Consider the following harmonic function in the space with a cut along XQ + x\ < a2: [/( x )
=
/"W. \-u(x0,xi,-X2),
z 2 > 0, x2<0.
Then it will satisfy the conditions ±
(x
0 x ) = l^X°'X2^ l-/(a:o,a;2),
X2>0
' x2 < 0,
x2Q+xl
Again using Hobson's representation (18), the solution can be found by quadratures. Now consider problems like Hobson one for biharmonic functions instead of harmonic functions. Problem Find a biharmonic function in the half-space x2 > 0 vanishing at infinity, and satisfying the conditions
419 u(xo,Xi,0)
x2=0
(29)
a;o+Xi>a2,
Aw| X2=0 = /i(o;o,xi), dX2
(x 0 ,xi) G R2,
= fo(xo,Xi),
j^c^i)
Xg +a;i < a2-
(30)
Solution For u(x) = X2U1 + Mo
(31)
with harmonic functions «o, v-i by force of (29), (30), we will have the boundary conditions w(xi,a; o ,0) =u0(x0,xi,0) Au| X2= o du dxi
(10,0:1) G R2,
= fo(x0,xi), 8x2
du0 X2=0
xl+x\>a2,
/i(a:o,a;i),
aa:2
xl+xj
f2{x(hx1),
Here uo, as the solution of the Dirichlet problem in the half-space, will be found by quadratures, while for u\ we will have the conditions (23), (24), thus the solution can be represented using (18). Problem Find in the space with a cut along XQ + x\ < a? biharmonic function vanishing at infinity and satisfying the conditions u ± (o;o,a;i,0) =/ ± (a;o,a:i), du±
8x2
±<
:
2 ^ x\
2
,
\
X2=0
Solution For the harmonic functions UQ, U\ we will have the boundary conditions (20) and thus they can be represented using Hobson's formula. It is obvious that for polyharmonic function in the case m > 2 the problem with the boundary conditions dku ±
dx% X 2 = 0 = ip^{xo,xx), fc = 0 , . . . , m - l , can be reduced to problems for harmonic functions with conditions like (20) m—1
by the ansatz u — Yl, x2uk> i-e-> the solution again will be represented with fe=0
the help of the Hobson formula. Consider the space -R(2)> u(x) = uoeo — u\e\ — U2e2 — wi2eie2-
420
Problem Find the solution of the pluriregular equation (29) in the halfspace, for instance, in the case m = 2 vanishing at infinity and satisfying the conditions: A u 2 ( i o , i i , 0 ) = / i ( i o , i i ) , Au12(x0,xi,0) =
\q\ < 1, q — Y^Qk^k, Qk are real constants, then by a linear transformation of 0
the independent variables it can be reduced to the pluriregular equation. Thus the above considered problems for the pluriregular equation can be solved for pluri-Beltrami equation by quadratures, too. 2.2
Properties and more problems for pluriregular and plurigeneralized regular functions
Let O be a bounded domain in Rn+1 with a closed piecewise smooth Liapunov surface S, u(x) : f2 —> i?(„). Consider pluriregular and plurigeneralized regular equations: dmu(x)=0, m
P u = 0,
x{x0,...,xn),
Pu = du + uh,
(32) m > 1.
(33)
In the case m = 1, i.e., for regular and generalized regular functions Liouville theorem is proved 5 : Ifu(x) is regular or generalized regular function in the whole space Rn+i and vanishes at infinity, then u(x) must be zero. For the equations (32), (33) we can prove Liouville theorem Let u(x) be the solution of (32) or (33) in the whole space Rn+1 and at infinity satisfies the conditions lim dku{x) = 0, fc = 0 , l , . . . , m - l , \x\—»oo
(34)
421 then u(x) = 0 for every x £ Rn+1. As in the case m = 1 the theorem is proved, for m > 1 it follows at once. Let ili and fi 2 be bounded domains in Rn+1 having no interior points in common, with the boundaries Si and 52, respectively, moreover, SiflS^ = SoThey are supposed to be Liapunov surfaces. In the case m = 1 in 5 following theorem is proved. Extension theorem If u(x) and v(x) are regular or generalized regular in Hi and &2, respectively, and Holder-continuous in the closed domains Hi and H2 with the condition u(x) = v{x),
x £ So,
(35)
then the function
(
u(x),
x € ili,
v(x), x £ il2, (36) u(x) = v{x), x £ So is regular or generalized regular in ili U O2 U So- Moreover, the extension is unique. For holomorphic functions of one complex variable this theorem is well known 4 . Extension theorem for pluriregular or plurigeneralized regular functions will be formulated in the following form: Theorem Let u(x) and v(x) are solutions of the equations (32) or (33) in ill and O2, respectively, and Holder continuous in the closure of the domains iliand O2 with the conditions dku(x) = dkv(x), xeS0, fc = 0 , l , . . . , m - l , (37) then the function u(x), w(x) = < v(x), ^u(x) = v(x),
x £ ili, x £ il2, x £ So,
is pluriregular or plurigeneralized regular function in ili U ^2 U 5o, moreover, the extension is unique. This theorem is obviously true. One can also prove that plurigeneralized regular functions in il £ Rn+X have derivatives of each order at each internal point.
422
Now for the solutions of (32) and (33) the Hilbert and the Compound BVP will be considered. Let S be a set of finitely many piecewise smooth Liapunov surfaces. Hilbert problem Find a solution of the equation (32) or (33) with jump surfaces S, vanishing at infinity by the conditions (dku)+-
(dku)~ = gk(x),
x€S,
fc
= 0,l,...,m-l,
(38)
where gk{x) are given Holder continuous functions. Compound B V P Let Q.+ be the half-space xn > 0, and S piecewise smooth Liapunov surfaces in Jl + . Find in Cl a piecewise pluriregular function with jump surface S vanishing at infinity by the conditions [dpu(x)}+ - [dpu(x)]~ = gp(x), P
Re[d u(x)eA] = /A(X),
xeS,
p=
xn=0,
p=
0,l,...,m-l, 0,l,...,m-l,
_1
where A takes 2 " different values from ( a i , . . . , ak), 0 < ot\ < • • • < ak < n. These problems can be solved in the same way as they are solved in the case m — 1 in 6 . Note that in the two-dimensional case for pluriholomorphic functions w{z) dnw _ dzn ~ some integral representations are obtained in 1. Using the representations by holomorphic functions
w(z) = ^zktpk(z)
n—1
or w(z) = ^{r2
0
-
l)kyk{z),
0
in the plane with cuts along segments of the straight line or along arcs of the circle, many boundary value problems can be solved in quadratures. But for plurigeneralized holomorphic function w(z) Pnw(z) = 0 ,
Pw = ^ + Bw, az boundary value problems in the domain with cuts can be solved explicitly only if one has one cut along the half axis. First we consider some problems for generalized holomorphic function. Let D+ be the half-plane y > 0, z = x + iy and let w(z) = u — iv be a solution of the equation - ^ + Bw = 0, oz
(39)
423
where B is supposed to be a real constant. Problem Find in D+ a regular solution of (39) vanishing at infinity by the conditions u(x,0) = f(x),
x>0,
v(x,0)=g(x),
x<0,
(40)
where the given functions / , g are of the class L and vanish at infinity. Solution This problem can be solved using a Fourier Integral Transform (=FIT). The system (39) can be written in the form: du
dv
„
a" + 7T + Bu = °'
: l „
<«)
n
— - — + Bv = 0. dy ox Some problems for generalized holomorphic functions in the sense of solvability are studied in 9 . FIT of a Lebesgue integrale function u(x, y) £ L with respect to the variable x is by definition -\
r
V^
JR
u(x,y)e
ixt
dx.
It is easy to obtain dw = itu. .dx. The inverse formula for u £ L, u e l is u(x,y) = - 1 = / u(t,y)eixtdt. V27T JR Then one can obtain by FIT of (41): dv ,. -T + (tt + dy du .. — - (it dy
(42)
„.^ B)u = 0, „.^ B)u = 0.
Representing the solution of these equations by u = A1{t)eXy,
v = A2(t)exy,
by force of (42), (43) one has for A\, Ai A2X + {it + B)A1 = 0, - A2{it -B) + XAX = 0.
(43)
424
These equations will have nonzero solutions for X = ±\/t2 and correspondingly A2 = —iAi^=^-. from (43) u(x,y) = -^= ***
+ B2 Thus by the inverse formula we have
A1{t)e-/W+Wyeixtdt,
f JR
(44) t
V^TT
~
l B
2
C-Vt
+B^y„ixtr
t + iB
JR
Using the boundary conditions (1.24), we get for A\{t) the couple of integral equations l
= [ A1(t)eixtdt
2n
= f(x),
x>0,
U
(45) t
ixt
—^-e dt t + iB
V2.TT JR
= g(x), v ;
x<0.
It will be solved using the Wiener-Hopf method. In the first equation in place of x write x + £, £ > 0, and in the second equation in place of x write x — £, £ > 0, then multiply the first one with the unknown function -/Vi(£), the second one with the function N2(£) and integrate by £ on [0,oo]. Supposing a change of the order of integrations is possible, one gets:
- = J Ax{t)eixtdt J°° N^y^dt
=
/•OO
= /
NtiOfix + Odz^Mx),
Jo
(46)
/•OO
= -i / N2{£)g{x - £ K = 9l(x), Jo )o Consider new unknown functions: /•OO
*+(*)= / Jo
x<0.
POO
NifteWdt,
*-(*)=/ Jo
NtiOe-^dt.
(47)
z = t+iS in place of t. It is easy to see that $+(t) is the limit of a holomorphic function of z in the half-plane a > 0 , when a —> 0, and $ _ ( i ) is the limit of
425
a holomorphic function of z in the half-plane a < 0 , when a —> 0. Thus (46) can be written as \= f Ai(t)$+(*)e f a t dt = /i(x), x > 0, 2 J *«
— I A (t)^ -^^-(t)e t
1
ixt
dt
T
= g1(x),
(48)
x<0,
B > 0.
Suppose the holomorphic function Q(z) vanishing at infinity satisfies the condition
* + W = A / ^ § *-(*),
t€R,
It is clear VZ + iB
yz — iB
By force of (47), using the inverse formula, one has
These integrals can be calculated in the following way: $ i (z) is holomorphic function for a > 0, and e~l& for t = p(cos a+i sin a), 0 < a < 7r, tends to oo when p —> oo. But $i(z) has for cr < 0 a singularity in t = —iB and e~^t tends to zero when p —> oo, 7r < a < 27r. $ I ( . Z ) is a multi-valued function in the half-plane a < 0. In order to use Cauchy's theorem, we consider a domain where &i{z) will be single-valued. It is the half-plane a < 0 with the straight line t — 0, — o o < < 7 < — B. On the left side of this line let $i(icr) = ,.~] .„ and on the right hand side $i (ia) = ,. 1, ...ff. x
'
M
V»c+«B
'
\/io+iB
Then Cauchy's formula gives: 1 riB e-*z 1(0 1 f e-t'dt J JVi(€) = TT- / ,- ^ = - / , ^ dz. Vi+iB TT J-ioo \Jz + iB
= s/.-
Let 2 + iB = —IT, then
Wl(0 =
' r ^f^
V i 7T Jo
=
V
r
dT
_ *di?i r «-*•*. =
^feXP["^_il]'
^
S>
°-
io
(49)
426
Now consider <&2{z) in the half-plane a > 0. In the same way we obtain 1
N2(Z)
exp -£B
.7T
+ i-
,
(50)
<£>0.
By force of (46) we can write: fi(x), gi(x),
x>0, x < 0,
and using the inverse formula, A\ (t) is given by,
^ ± 2 f F(x)e-^dx
Ax(t)
V27T
JR
and the solution of the problem (40) is represented in the form (44). Let D be the plane, z = x + iy with a cut along the half-axis y = 0, x > 0. Problem Find in D a regular solution of (39) vanishing at infinity and satisfying the conditions w ± (a;,0) = / ± (2;),
x > 0.
(51)
Solution The solution of this problem can be reduced to the solution of the problem (40). Really, let w = wi
+w2,
where
wi =
w(x,y)+w(x,-y)
,
w(x,y)-w(x,-y) —
w-2 =
(52)
be the solution of (39) satisfying the conditions
Rewf —
f++f~ 2
(53)
+
Rei
±
u>2 will be represented as
f -f~
= ±ip(x),
x > 0,
y = 0.
6 ,0
w2{z) = -i / Jo
dg(t - z) -Bg(t-z) dt
tp(t)dt.
427
To define w\(z) = u + ivwe will consider the problem for the half-plane y > 0 with the conditions u(a;,0) = 0, x < 0,
u(x,0) = f(x),
x > 0.
The solution of this problem is given in the form (44). Then using reflection principle we will obtain w\{z) satisfying the condition (53). Now consider in D+ the bigeneralized holomorphic function w(z):
~
+ Bw^F(z),
(54)
dF — ^-+BF = 0,
(55)
where B is supposed to be a real constant. Mixed Boundary Value Problems Find in D+ a regular solution of (54), (55) vanishing at infinity by the conditions
Rew(x,0)
=
lmw(x,0)
— if3(x),
Re—r dz dw Im—-
= f2(x),
x > 0,
(56)
= tp4(x),
x<0,
(57)
~ !/=0
where the given functions
— ip(x),
x>0,
and
ImF(x,0)
= ip(x),
x<0.
Thus for F(z) we will have the problem (40) whose solution is given above. Then the solution of (54) can be represented as
w(z) - wi(z) + W2{z),
(58)
where w\{z) is the solution of the homogeneous equation (39) and wz(z) is a partial solution of the nonhomogeneous equation. By the conditions (56), (57), we will get the boundary conditions for w\{z) in the form (40), i.e., w(z) can be found by quadratures. For the domain D with a cut along the half-axis y = 0, x > 0 the following problem can be solved in an analogue way:
428
Problem Find in D a regular solution of (54), (55) vanishing at infinity and satisfying the conditions Re[w±{x,0)} =
f±(x),
= ^(z).
Re&
ldziy=0 Using the problem (51), by these conditions w(z) can be found by quadratures, too. 3 3.1
Hyperbolic and Parabolic Higher Order Equations Cauchy and Goursat problems for pluriregular equations
Let u(x, t) e -R^n-i) be the solution of the equation dmu = 0 or Pmu = 0,
Pu = du + uh,
m > 2,
(59)
n
where h = ^/i^efe is constant in i?( n , n _i). Cauchy's problem for this equao tions is solved explicitly in the case m = 1 in 6 . Cauchy's problem in the case m > 2 Define a regular solution u(x, t) of the equation (59) for X(XQ, . . . , xn-\) £ Rn, t > 0, t = xn, by the conditions du dm~1u — t=0 = h{x),..., = fm-i{x) ^ "•••> Qtm-l dt The problem can be solved explicitly using the solution obtained for m = 1 and the solution of the wave equation 3 . Let u[x) in -Rn,n_i) be the solution of plurigeneralized Beltrami equation u{x,0) = f0(x),
Bmu
= 0,
J
Bu = ~du + q1du + q2Bu = 0,
|gi| + \q2\ < l,
with q\, Q2 vectorial constants. Using the de Moivre formula in the hyperbolic case which, for instance, in -R(2,i) has the form q = eo cos ao + e\ sin a.§ ch at\ + e2 sin c*o sh a\, qm = eo cos m«o + e\ sin m«o ch a\ + e2 sin mao sh a\, the equation (12) can be reduced to the equation with a real q2. Then supposing qi is real, Bmu = 0 can by a linear transformation of the independent variables and of the unknown function be reduced to the pluriregular equation (59). Thus all initial value problems, which are solved for (59) can be solved for Bmu = 0 too.
429 Cauchy's problems for some hyperbolic equations in the sense of solvability are studied in 8 , while Cauchy problems with generalized analytic functions as initial functions are investigated in 7 . As is well known, for the wave equation and for the corresponding simple hyperbolic system with one space variable and one time variable not only the Cauchy's problem, some characteristic problems, for instance, Goursat and Darboux problems, can be solved explicitly in a simple way using a general representation of the solution. But when there are more than one space variable it is not always possible to solve the characteristic problems explicitly. So for the pluriregular equation (59) characteristic problems in a multidimensional space are very complicated. That is why we will consider (59) in the space i?(i,o): u(x) = u0eo + uiei, x = x0eo + xiei, ^ d 8 o= ^—e0 + -r—ei. OXQ axi
e\ = eo, (60)
Goursat problem Let m = 2, if m > 2 the problem will be solved gradually. Then (59) can be written as du0 dx0 du0 -5— +
dux dxi dux -K— =
OX 1
,gl, Fi(x0,xi),
OXo
where F\, F2 are the solution of the equations dF0
|
DXQ
dF0 dx\
|
0 Fi = Q dx\ dFx = 0. dxo
(62)
Find regular solutions of (61), (62) for x e R2 by the following conditions along the characteristics: u0(x0, X0) —
FQ(X0,XQ)
(63) (64)
Solution By the conditions (64), the solution of (62) can be represented as
430
2
Z
. +
Fi = -
J M—2
(65)
)
+(pi
W-
Then the solution of the equation (61) can be defined by the conditions (63) as fX0+X!\ /Xo-X!\ X0-X! /X0+Xi\
+
~2
^i (
g — J - aroV'i(O),
/XQ+XX}
xo + ^i
+ —jj
./Xo-X!\
X0-X!
fXo
+
X!}
/a;o-a;i\
) +Vi(°)xo-
M—2
It is easy to see that they really satisfy all conditions supposing that the given functions have continuous first order derivatives. Let in place of (63), (64) the conditions u0(x0, XQ) = ip(x0), FQ(X0,X0) = (pi(x0),
u0(x0, -x0) = ip(x0), F0(x0, -x0) = i/>i(x0),
(66) (67)
are given. Obviously, the given functions must satisfy the compatibility conditions ¥>(()) =V(0),
(68)
The solution can be represented explicitly, as in the above case. 3.2
Pluriregular elliptic-hyperbolic equations and boundary-initial value problems
Consider the equation dm[d+—enj
u(x,t)=0,
m>l,
(69)
where 71— 1
=
„
^ Xl^~efc'
e
* = _ e ° ' k = l,...,n-l,
el = e0.
431
This equation will be called pluri-elliptic-hyperbolic equation. It is clear that u(x, t) is at the same time a solution of the equation d2 u (x,t)=0, dt , which can be called poly-harmonic-wave equation. The above equations are so beautiful that they must have some physical applications. In analogy to the biharmonic and biwave equations, it will be interesting to consider m = 1, i.e.,
A ™ ( A - ^2 )
f d2 \ A{A--^)u{x,t)
= 0,
x = (x0,...,xn-i).
(70)
This equation is called the harmonic-wave equation. The following problems are correctly posed and will be solved in quadratures. Dirichlet-Cauchy problem Find a regular solution of (70) for t > 0, xn-i > 0, vanishing at infinity and satisfying the conditions
u{x,0) = (p1{x),
du — = ip2{x),
u(x,t) = (f(xo,...,xn-2,t),
t = 0,
(71)
x„_i=0,t>0.
(72)
Solution Let Au(x,t)
= F(x,t),
(73)
2
dF A i - - ^ = 0 ,
(74)
then by force of (71), (73) the unknown function F satisfies F{x,0) = AVl(x)
= hix),
dF — = A^2{x)
= f2(x),
t = 0,
i.e., to calculate F we have to solve Cauchy's initial value problem for the wave equation. The solution can be represented in quadratures. To find u(x,t), we have the Dirichlet problem for the nonhomogeneous equation (73) with the condition (72). The solution can be represented by quadratures. Neumann-Cauchy problem Find the solution of (70) for t > 0, xn-i > 0, vanishing at infinity by the conditions (71) and satisfying
dxn
= (fi(xQ,...,xn-2,t),
z„_i=0,
i>0.
(75)
432
The solution can be reduced to the Neumann problem for the equation (73) and will be represented in quadratures, too. It is obvious that all problems which are considered for harmonic functions can be correspondingly considered here. For instance, when x = ( : E O , £ I , £ 2 ) belongs to all three-dimensional space with the cut along XQ+X2 < a2, x% = 0, the solution can be represented effectively using Hobson's formula. In the same way the harmonic-Klein-Gordon equation can be considered
A A k2
{ ~ -^hx^
0
for which the problems (71), (72) or (75) can be solved. It is clear that this equation is connected with elliptic regular and hyperbolic generalized regular equation du
d(du + en — + uh\ = 0. Moreover, the Helmholtz-wave equation or Helmholtz-Klein-Gordon equation can be considered d2 \ (A-kl)(l ^)u(x,t)=0, (A-k2)(A-k22-^)u(x,t)=0. For them the problems (71), (72) or (75) are correctly posed and can be solved in quadratures too. For the equation (69) boundary-initial value problems can be considered correspondingly, for instance, in the case m = 1 d(d+
— enju(x,t)
=0,
which can be written as du = F(x,t), ( a + | e n ) F = 0.
(76) (77)
It is clear that corresponding problems for (76) and (77) are correctly posed and can be solved in quadratures. Boundary-initial value problems for the nonhomogeneous equations which belong to the above homogeneous equations will be solved too. In this case the boundary-initial conditions can be supposed to be homogeneous. We will consider only one of them, others can be solved in the same way.
433
Problem Find the solution of the equation A ( A - ^u(x,t) n
x(x0,...,xn^1)
e R,
=
F(x,t),
t > 0,
xn-i
(78) > 0,
vanishing at infinity and satisfying the conditions: u{x,0) = 0, u(x,t) = 0,
On ^-=0,
* = 0,
(79)
x„_i=0,
t>0.
(80)
Solution Let Au = Fi(x,t),
(81)
AF1-^=F(x,t),
(82)
then by force of (80) for Fi(x,t) one has homogeneous Cauchy conditions for nonhomogeneous wave equation (82), thus it can be found by quadratures. Hence u(x,t) is defined as the solution of (81) with the condition (80). 3.3
Pluriparabolic, plurielliptic-parabolic, plurihyperbolic-parabolic, plurielliptic-hyperbolic-parabolic equations
Consider the equation in R9-. (n > 1) (9 - Pn)mu{x,t)
= 0,
m>l,
rr(zo,...,a: n _i), xn = t,
where the operator Pn is defined by the condition
(83)
6
9Pnu=Tt.
(84)
It is obvious, u(x, t) is also a solution of the polyheat equation
( A - - J «(M)=0.
(85)
In the case m = 2 this will be called biheat equation. Cauchy's problem for (85) will be formulated as: Define u(x,t) in x S Rn, t > 0 by the conditions
434
0 u -ftk
t=0
= Vk{x),
A; = 0 , l , . . . , m - 1 .
(86)
Note that if «o, • • •, w m _i are the solutions of the heat equation, then m—\
u = ^2 tkUk 0
will be the solution of polyheat equation (85). This representation can succesfully be used to solve the problem (86) in quadratures, because the solution of Cauchy's problem for the heat equation is well known. Then it is not difficult to solve Cauchy's problem for the equation (83). All components of u(x, t) are given for t = 0. Now consider the equations d(Bu + Pnu) = 0,
(87)
(a + e „ _ i ^ p — ) ( d u + i>nu)=0,
(88)
d ( d + e n _ i — — )(Bu + Pnu) = 0,
(89)
where in (87) 71
r*
d = ^2~a—efc> dxk 0
e
k = ~ e o> k = l,...,n-l,
e2n = 0,
(90)
in (88) and (89)
^dxk6
k+
dxn^
e2n = Q, e2k = -eQ, fc = l , . . . , n - 2 ,
(91) e\_x = e0.
It is obvious, dd = A, where A is the Laplace operator with respect to the variables #o, • • • >#n-i m the case (90) and to the variables in the case (91), Pnu is defined by (84). Then one can see that the solutions of (87), (88), (89) will also be the solutions of the equations, correspondingly A^A-—
)U(Z,£)
= 0,
x{x0,...,xn-i),
xn=t>0,
(92)
435
(A-£)(A-D"^=°' x(x0,. ..,xn-2),
xn-i=r,
(93)
xn=t>0,
A A
( -^)( A -l) u(:E ' r ' i)=0 -
(94)
The equations (92), (93), (94) are called harmonic-heat, wave-heat and harmonic-wave-heat equations correspondingly. First we will consider boundary-initial value problems for (92). Dirichlet-Cauchy and Neumann-Cauchy problems Find the regular solution of (92) for z n _ i > 0, t > 0, (10,2:1,..., £n-2) S Rn~1, vanishing at infinity satisfying the conditions u(x,0) = ip(x),
z„_i > 0,
x - (xo,...,xn-i),
u(x,0)=ip(xo,xi,...,xn-2,t),
a;n_!=0,
(95) t > 0,
(96)
or (95) and du dxn-i Solution Let
ip{x0,...,xn-2,t),
a;n_i=0,
t > 0.
Au(x,t)=F(x,t), dF A F - = 0,
(97)
(98) (99)
then by force of (95), the unknown function F(x,t) will satisfy F(x,0) = Aip(x) = f{x)
(100)
and one has for (99) Cauchy's initial value problem. To define u(x, t) we have the Dirichlet problem (96) or the Neumann problem (97) for the equation (98). It is clear that all problems which are solved for harmonic functions can be solved correspondingly for the equation (92). Cauchy's problem for the equation (93) Find the regular solution of the equation (93) f o r i > 0 , r > 0 , a ; e i ? n _ 1 , by the conditions: u{x,0,t)
=
Ou —=tp2(x,t),
T = 0,
(101)
436
u(x,T,0) = tp(x,T).
(102)
Solution Let Au-
— =F(x,r,t),
(103)
AF-
d2F — =0.
(104)
Then by force of (101) the unknown function F(x, r, t) will satisfy the conditions of Cauchy's problem whose solution is known. In order to get u(x, r, t), we have to solve Cauchy's problem for the nonhomogeneous heat equation (103) with the condition (102). The solution will be represented in quadratures too. It is obvious that one can consider also the heat-Klein-Gordon equation
(
A
- | ) (
A
- *
a
- | ^ ' ' > =
0
with the conditions (101), (102), and the solution will be represented in quadratures. In the same way one can consider Helmholtz-heat equation
(A-k2)[A-^)u(x,t)
=0
with the boundary-initial conditions. The solutions can be represented in quadratures too. Now consider a problem for the harmonic-wave-heat equation (94) for t > 0, r > 0, x„_2 > 0 with the conditions: u(x,0,t) u(x,
T,
= h{x,t),
dii
^
= f2(x,t),
T = 0,
0) = ip(x, r ) ,
u(x,T,t)=1p(xo,...,Xn-3,T,t),
(105) (106)
Xn-2
= 0-
(107)
Solution Let Au = F(x,T,t),
(108)
then by force of (105), (106), F will satisfy conditions of the form (101),(102), i.e., F as solution of (109) will be constructed effectively. Hence u as solution
437
of (108) can be represented in quadratures, too, by the condition (107) or the condition of the Neumann problem. Now it is clear, in order to formulate the boundary-initial value problems for the equations (87), (88), (89), all those conditions must be given which are necessary for each factor. Thus, using the solutions of each problem, one can obtain the corresponding solutions in quadratures. Acknowledgement I should like to express my appreciation to Technical University in Graz, especially to Professor Wolfgang Tutschke for the invitation at the remarkable conference, for the financial support, for the warm hospitality in Graz, the wonderful place of the fairyland Austria. References 1. Begehr, H., Complex analytic methods for PDE. World Scientific, Singapure, London, 1994. 2. Brackx, F; Delanghe, R., and Sommen, F., Clifford analysis. Pitman, London, 1982. 3. Courant, R. and Hilbert, D., Methods of mathematical physics, vol. II. Interscience Publishers, New York, 1962. 4. Muskhelishvili, N., Some basic problems of the mathematical theory of elasticity. Nauka, Moscow, 1966 (in Russian). 5. Obolashvili, E., PDE in Clifford analysis. Longman, Edinburg, United Kingdom. 1998. 6. Obolashvili, E., Beltrami equations and generalizations in Clifford analysis. Applicable Analysis, vol. 73(1-2) pp. 167-185, 1999. 7. Tutschke, W., Solutions of initial value problems in classes of Generalized analytic functions. Teubner, Leipzig, 1989. 8. Tutschke, W., Solution of initial value problems for first order systems using matrix notation. Appl. Anal., vol. 73, 271-280, 1999. 9. Vekua I.N., Generalized analytic functions. Pergamon Press, Oxford, 1962.
438
GENERALIZATIONS OF T H E C O M P L E X ANALYTIC T R I G O N O M E T R I C F U N C T I O N S TO CLIFFORD ANALYSIS B Y EISENSTEIN SERIES R. S. KRAUSSHAR Vakgroep Wiskundige Analyse, Universiteit Gent Galglaan 2, 9000 Gent, Belgium E-mail: [email protected] We deal with monogenic generalizations of the classical tangent, cotangent, secant and cosecant function constructed by generalized Eisenstein series associated with p-dimensional lattices in R fe+1 , where 1 < p < k. We discuss some characteristic properties of them. In particular, the generalizations of the cotangent turn out to be uniquely characterized by oddness, its principal parts and a generalized double angle formula. Further, we deduce a generalization of the classical Herglotz Lemma to Clifford analysis stating that every function which is a monogenic in a sufficiently large ball is a constant provided it satisfies the generalized cotangent double angle formula. Moreover, we show that an arbitrary p-fold periodic meromorphic function in R^"*"1 can be represented modulo an entire function by a finite sum of the generalized cotangent functions and their partial derivatives.
1
Introduction
The generalization of the elementary complex-analytic trigonometric functions to higher dimensions is one of the main concerns in hypercomplex function theory. There are several methods to extend classical functions to higher dimensions. One possibility to extend complex-analytic functions to higher dimensions is to apply Fueter's Theorem (cf. 7 , 8 , 13 ) generating a hypercomplex function starting from a given complex-analytic function considered in the upper halfplane. The non-monogenic generalized trigonometric functions described in 12 and also very recently in Section 2 of 18 are based on this construction principle. Applying the Laplace operator to these functions provide then monogenic functions. A further method to extend complex-analytic functions to higher dimensions is Cauchy-Kowalewksi extension. The monogenic generalizations of the sine, cosine, hyperbolic sine, hyperbolic cosine and of the exponential function presented in 1 and 4 are based on this construction principle. We observe that one cannot introduce monogenic generalizations of the tangent, cotangent, secant and cosecant functions by means of a quotient of the functions described in *, since multiplication or division of monogenic functions does not preserve
439
monogenicity. In complex analysis there is also a method to construct the elementary complex-analytic functions in a way not using multiplication or division of functions proposed by G. Eisenstein in 1847. In 6 G. Eisenstein introduced the series
which provide according to the classical Mittag-Leffler theorem the simplest example of a normally convergent series of meromorphic functions having poles of order n in the points of a lattice with codimension greater than zero. Without much loss of generality G. Eisenstein considered the normalized onedimensional lattice Z. He introduced the cotangent function by means of the Eisenstein series ei:
e1(z):=-+
T
(_L_-J-),
*G
(2)
The complex function ir cot(7rz) is characterized by the properties of being an odd meromorphic function with principal parts j ^ in each m € Z satisfying the double angle formula 2g(2z)=g(z)
+ g{z+1-).
(3)
One can show (cf. e.g. 22 ) that the Eisenstein series e\ satisfies these conditions. Therefore, e\(z) = 7rcot(7r;z). Also the tangent, secant and cosecant function can be introduced by means of the Eisenstein series e\ without using multiplications (cf. also 2 1 ) , namely by tan(z) := — cot (2 + —), cosec(z) := cot(-) — cot(z), sec(2;) := cosec(z + —). (4) By Eisenstein series of higher degree one can proceed to introduce the sine, cosine and the exponential function. For details we refer to 6 and to 24 . It is possible to generalize this construction approach to Clifford analysis (cf. 16 1 7 , )The left and right fundamental solution of the generalized Cauchy-Riemann operator and its partial derivatives denoted by *>(*) : =
raTT
a n d
9 n ( z ) : = g^loiz)
(5)
440
generalize the negative complex power functions z >—> z~n to the theory of monogenic functions in H*"1"1. In view of the Mittag-Leffler Theorem from 1, summations of the functions <7n over a p-dimensional discrete lattice in R + 1 , where 1 < p < k, generalize the Eisenstein series en to Clifford analysis. They admit the construction of monogenic generalizations of the classical cotangent, tangent, cosecant and secant function in IR + 1 being of p-fold periodic nature, where 1 < p < k. We study properties of these generalized trigonometric functions and prove duplication formulas generalizing well-known relations between the corresponding complex trigonometric functions. We prove that the p-fold periodic cotangent is strictly characterized by its principal parts, oddness and the property of being a solution of a functional equation which generalizes the classical cotangent double angle formula. Furthermore, we prove a generalization of the classical Herglotz Lemma (cf. 22 ) stating that a function which is monogenic in a sufficiently large ball satisfying there the generalized cotangent double angle formula must be a constant. Moreover, we show that an arbitrary p-fold periodic meromorphic function in I t + 1 , where 1 < p < k, which might have non-isolated non-essencial singular sets, can be constructed up to an entire function by a finite sum of the generalized p-fold periodic cotangent functions. 2
Preliminaries
For detailed readings in Clifford algebra and its function theory we refer for example to x and 4 . In this paper we denote by {e\, • • •, e^} the canonical basis of the Euclidean vector space IR and by Clofe the real Clifford algebra generated by IR in which the multiplication rule e ^ -I- e ^ = —25^ holds, where 6^ is the Kronecker symbol. The dimension of Clofc, considered as an ft-vector space, is 2k. Any arbitrary element a € Clofc can be written as a = J2A aAeA, with a A S H, where {e^ : A C {1, • • •, k}} with e^ = e^e^ • • • eir, 1 < l\ < • • • < lr < k, and e0 = eo = 1. Two examples for real Clifford algebras are the complex number field C and the Hamiltonian skew field H. On the set of the Clifford numbers the conjugation is defined by a = ^T,A aAeA, where e^ — ~e~ireir_1 • --e^;5,- •= —ej (j = 1,• • •,k), and e 0 = e 0 = 1An important subspace of the Clifford algebra Clofc is the space of paravectors. We can identify each element {XQ,X\, • • • ,Xk) = (XQ,X) e IR + with the hypercomplex number z = xo + x\e\ + x2e2 + • • • + a^e^ G Ak+i •= span R {l, ei, • • •, efe} = R © 1R,k, often called a paravector. For many applica-
441
tions in Clifford analysis one often identifies simply Ak+i with Jlk+1. The Clifford norm of an arbitrary Clifford number a = ^2 CLA^-A is ||a|| = (52 WA]2)1 • A
A
In order to present many calculations in a more suggestive way, the following notations will be used, where n = ( r i j , . . . , rik) G NQ is a fc-dimensional multi index: x n := x™1 ••• x^k,
n! := ni! • • • rifc! and |n| := n\ ~\
\- n^.
A.C. Dixon 5 , R. Fueter 10 , G.C. Moisil, N. Theodorescu 19 , V. Iftimie 14 and R. Delanghe 2 are some of the most important creators of a function theory in Clifford algebras. The generalized Cauchy-Riemann operator in M fc+1 is k
said to be D := g|—h Y^ £jf~e«
an
d
rea
l differentiable functions satisfying
Df = 0 (or fD = 0) are called left (right) monogenic. The notion of left (right) monogenicity in Ak+i generalizes the concept of complex analyticity to Clifford analysis in the sense of the Cauchy-Riemann approach. A lot of classical theorems from complex analysis could be generalized to higher dimensions by this approach. For details we refer for example to 10 and 1 . However, the positive and negative powers of the hypercomplex variable z are not monogenic which is a consequence of the non-commutativity of the Clifford algebra. Therefore, in Clifford analysis the positive powers are substituted by the following polynomials, mentioned firstly in 9 :
V n ( z ) :— . ,|
Z 2_^ Tt(ni)zir(n2) 7r£perm(n)
'''
z
n(nk)i
where perm(n) denotes the set of all permutations of the sequence (ni,ri2, •. • ,rik) and z$ := Xi — x^ei for i = 1 , . . . ,/c and VQ(Z) := 1. The negative powers are substituted (cf. 9 , 3 ) by the function qo(z) := ., ,,zfc+1 and its partial derivatives qn{z) := §^r<7o(z)- An essencial difference to classical complex analysis is that the set of left (right) monogenic functions forms just a Clifford right (left) module for k > 1. The product, the quotient or the composition of two monogenic functions gives in general no monogenic function for k > 1.
442
3 3.1
Generalizations of the cotangent by Eisenstein series and their properties Definition and basic properties
According to Mittag Leffler's theorem the Eisenstein series e„ represent the simplest example of a normally convergent series of meromorphic functions in C having poles of the order n in a lattice with codimension greater than zero. Lattices in 1R + 1 with codimension greater than zero are p-dimensional Z modules, where 1 < p < k. More precisely: Definition 1. Suppose p G IN with 1 < p < k. Let u\, • • •,UJP be H-linear independent paravectors in Ak+i- The associatedp-dimensional lattice is defined by Qp :— 7iW\ + • • • Zujp.
The following convergence lemma is already due to G. Eisenstein (cf. 6 , 2 3 ) : Lemma 1. Suppose o o , a i , . . . , a t are M,-linear independent paravectors in Ak+i- Then the series ||moao + m 1 ai + --- + m t a t | r ( t + Q )
Y^
(6)
1
(m o ,mi,...,m t )GZ*+ \{(0,...,0)}
converges if and only if a > 2. The following series generalize the complex analytic Eisenstein series to Clifford analysis for the case n > 1. Definition 2. (Hypercomplex Eisenstein series) Let p 6 N with 1 < p < k and let n G JNf0 be a multi index with |n| > 0. To a given p-dimensional lattice J7P C Ak+i the associated monogenic Eisenstein series eif : -4fc+i\Op —> Ak+i are defined by: #>(*)== J2qn(z
+ oj).
(7)
wGnp
In order to show the convergence one applies Lemma 1 in combination with the following inequality (cf. 16 ) 11^)11 < ( | l | +
fc-l)!||z||-IH-*.
(8)
The detailed proof can be found in 16 and 17 . According to Mittag Leffler's theorem from x the series defined in (7) represent the simplest example of a normally convergent series of meromorphic functions in Ak+i having poles of order (k + |n|) in the points of a lattice of codimension greater than zero. G. Eisenstein introduced in 6 the cotangent function as the Eisenstein series
443
with the lowest possible pole order. We transfer this approach to Clifford analysis. The lowest possible pole order that a meromorphic function in Ak+i can have is k. We observe that for 1 < p < k — 1 the series Yl 1o(z + w ) converges normally in Ak+i\QP which is a again consequence of Lemma 1 applying (8). However, if p = k, then the series £) qo(z + w) is divergent. In order to guaranty convergence we have now to add convergence-preserving terms as proposed in the proof of Mittag-Leffler's theorem from 1. In this sense we introduce Definition 3. (Hypercomplex p-fold periodic monogenic cotangent function) Let p s K with 1 < p < k and O p be a p-dimensional lattice in Ak+i • Then the associated monogenic cotangent function c o t ^ : ^4fe4-i\Qp —> Ak+i is defined by: Qo{z)+ cot<*>(*) : = \
E [Qo{z + w) - q0(uj)} -en^°>
p=k (9)
Proposition 1. The series defined in (9) converge normally in Ak+i\flpProof: We only have to consider the case p = k. For an arbitrary compact subset K. C Ak+i one takes a suitable real R > 0, such that the compact ball B(0, R) covers /C. Assume z G B(0, R). For the qualitative analysis of the convergence of the series we can drop a finite number of terms. Therefore, we can restrict ourselves to consider the sum over those elements u> € Qfc\{0} which satisfy ||«;|| >kR>
\\kz\\.
We consider the function g(z) = q0{z + w) — qo(u>) which is left and right monogenic in 0 < ||z|| < k R. For ||z|| < R its Taylor series expansion reads qo(z + u)-
q0{uj) = ^
Vp{z)qp(w).
1PI=I
With the inequalities ||Vp(z)|| < M ^ -
and
HgiWII^dll +
we get oo
\\q0(z + oj)-qo(u>)\\
= \\ Y,
V
p(z)Qp(f>)\\
fc-lJIINI-111-*
444 OO
k— 1
I j.
^E[n(ipi+")]#i^ii lpl iMi-* | p | = l u=l
V-
OO
,
\kz„i
\\z\\
= £('+*)•••('+m+2)k\\-\i 1=0
"
\z\ t l i , with an I e M , |W|K+1
"
fez if II —II < 1. II
w
II
Thus, we obtain finally: ||
53 9o(^ + w) -qo(u)\\ < L R ]£ TMF+Twenfc\{0} w€Sik\{o} " The remaining series converges according to Lemma 1, if a > k. Thus, the given series c o t ^ converges normally in Ak+i\£lkD By Weierstrass' convergence theorem, the functions cot(p) are left and right meromorphic in the whole space Ak+i- Via construction they take all their values in Ak+i- They have poles of minimal order k in the points of the lattice Q p . Furthermore, as in the complex case, the generalized cotangent functions are odd. Remark: If z is a hypercomplex variable of an even dimensional space Aim m £ JNf\{l}, then there is a real constant c(m) such that q0(z) = c M A ? - 1 ^ - 1 )
(* G Mm,
with
m G N\{1}).
In particular, if z is a quaternionic variable, i.e. z e A4, then there is the special relation q0(z) =
--A^Z-1).
This leads to the following observations concerning the quaternionic case: In the third section of the very recent work 18 G. Laville and R. RamadanofF consider the following non-monogenic functions as generalizations of WeierstraB' £ function in the quaternions: N-l
CN(Z)=Z'1+
J2 [(s-aO- 1 +X>- 1 *) M "- 1 ] )
wenw\{o}
n=o
where z = XQ + e\Xi + ei%2 + 630:3 is a quaternionic variable and where N € {1,2,3,4}. The function £4 appears already in 13 , while A z (^4(z)) is up
445
to a constant the generalized monogenic Weierstrafi' £- function introduced and analyzed by R. Fueter in 10 and n in the quaternionic case which has been generalized to Clifford analysis by J. Ryan in 1982 (cf. 2 3 ) . We observe further that c o t ^ ^ z ) = —jAz(£N(z)) for TV = 1,2,3, when z is assumed to be an element of AA- However, in particular the functions £2 a n d C3 show a quite different behavior as the functions cot^2^ and cot' 3 ). On the one hand the functions (jv itselves are not monogenic. On the other hand the functions C.2 and £3 are not periodic with respect to the lattice Q2 or JI3 respectively. They show a quasi-periodic behavior, similarly to that of the complex Weierstrafi (^-function. They are more closely related to the Weierstrafi ^-function than to the cotangent. This motivates the authors of 18 to concentrate mainly on the analysis of the quasi-periodicity of the functions £jv in their work in order to obtain generalizations of the Legendre relation. However, the functions cot^2) and cot' 3 ) turn out to be periodic with respect to XI2 or ^3 respectively. We will see that they are actually more closely related to the classical cotangent. They turn out to have zeros precisely in the points in between the poles. Moreover, we prove that they satisfy a duplication formula generalizing the classical cotangent double angle formula which admits a characterization of them in a similar way as one can characterize their complex counterpart providing a justification to consider the functions cot(p) actually as generalizations of the cotangent. For this reason and because of their monogenicity, we later exploit the cot' p ) functions to construct generalizations of the tangent, cosecant and secant in Clifford analysis. In order to analyze the location of the zeros and also in view of further applications we first introduce the following notion: Definition 4. (System of representatives) (cf. 15 ) Let dp C Ak+i be a p-dimensional lattice with 1 < p < k. A set Vp is called a system of representatives of the quotient module O p /2Q p , if the following conditions are satisfied: 1. For all UJ G Clp, there is a v G Vp and an UJ* G 2 Qp with UJ = v + UJ*. 2. If v, v' G Vp and u>* G 2 Clp, such that v' — v + LJ*, then w* = 0. In other words: O p /2 ilp = l j (v + 2 O). uev„ Remark: Without loss of generality we can take for Vp the canonical system of representatives of Slp/2£lp, i.e. V p := {0, OJI, ..., wp, wi + LJ2, • • •, wi -I 1- u)p}. (10) In the case 1 < p < fc - 1 we conclude directly by the definition that c o t ^ is
446
p-fo\d periodic with respect to fip. Therefore, - c o t ( p ) ( i w ) = - c o t & ^ t ; -v)=
cotW(iu),
or in other words: Proposition 2. Let Q,p be a p-dimensional lattice with 1 < p < k — 1. Vp denotes a system of representatives of the quotient module fip/2fip. Then each v g Vp\20 p satisfies cot( p )(iw) = 0.
(11)
Note that we cannot use this argument for the case p = k since, we have not yet shown that cot(fc) is a fc-fold periodic. In order to treat this case we need the following lemma. Lemma 2. (Lattice lemma) (cf. 16 , 17 ) Let Qk •= Zwi H h Zwjt and let 0 ^ I = {h,..., ir} C { 1 , . . . , k}. Then J2 w£a f c \{0}
[«b(2w + S ^ ) ~ «>(2w)] = - 9 b £ Wi). i6J
(12)
i£l
A sketch of the proof can be found in
17
. For the detailed proof we refer to
16
With this lemma we obtain immediately: Proposition 3. Let fife = Zwi + • • • + Zu)k be a lattice and let further I C { 1 , . . . , k}. Then the associated cotangent function satisfies: c o # > ( l ] [ > ) = 0. Z
(13)
iei
With this proposition and the knowledge that for |n| > 1 the associated Eisenstein series en are fc-fold periodic functions with periodicity lattice fi/. and that the cot(fc) function is odd one can show finally that Proposition 4. The function cov"(z) is periodic with respect to QkTo the detailed proof see 16 and 17 . As a consequence of the periodicity with respect to Clp (1 < p < fc)we infer that cot(p) has zeros in the points in between the poles, i.e. in | O p \ f i p . 3.2
Characterization of the hypercomplex cotangent
We recall that the complex cotangent is uniquely characterized by its principal parts, oddness and its double angle formula. The generalized cotangent functions can be characterized in an analogous way. The p-iold periodic cotangent
447
function satisfies a duplication formula which generalizes the classical cotangent double angle formula in a canonical way: Theorem 1. (Generalized double angle formula) Let £}p be a p-dimensional lattice where 1 < p < k. Let further Vp be a system of representatives of the quotient module f i p / 2 0 p . Then the associated monogenic cotangent function in Ak+i satisfies the following generalized double angle formula: 2kco&\2z)
= Y
cot (p) (z + )-v).
(14)
JJGVp
Sketch of the proof: Without loss of generality we suppose Vp to be the canonical system of representatives. We consider first the case p = k: Y veVfc
cot(fc) {z + j-v) - 2k cot(fc) (2z) = 2k
Y Qo{2z + v) + 2k Y Y [Qo^z + 2u + v) - q0(2uj)} vevk\{o} «6Vfcuent\{o}
-2 f e
Y [qo(2z + uenk\{o}
-2k
Y ] L [q0(2z + 2u + v) - q0{2uj + v)} v6Vfc\{o}wenfc
2w)-q0{2u;)}
= 2k
( Y Io(v)+2k( Y E lQo(2u; + v&vk\{oy vevk\{o} uenk\{o}
= 2k
Y 1o(v)-2h f€Vfc\{0}
Y u<=Vfc\{0}
v)-qQ(2w)})
1o(v)=0.
In the final line we applied Lemma 2. For the detailed proof we refer to 17 . For the case 1 < p < k — 1 one can proceed in a similar way to obtain this result. • The following theorem generalizes a classical characterization theorem of the complex cotangent (cf. 22 p.326) to Clifford analysis. It provides an argument to consider the functions cot^p' as generalizations of the complex analytic cotangent. Theorem 2. (Characterization of the hypercomplex cotangent functions) (cf. 16 1 7 , j Suppose ftp = ZUJI + • • • + Ziujp is an arbitrary p-dimensional lattice, where 1 < p < k. Let Vp be the canonical system of representatives of £lp/2Q.p defined in (10).
448
Suppose g : Ak+i\QP —> C\ok is left or right monogenic having principal parts qo(z—ui) in the lattice points ofClp. If moreover g is an odd function satisfying the duplication formula 2kg(2z)=Y,g(z vevp
+ \v),
(15)
then g(z) = co&\z)
VzeAk+i\Qp.
Proof: One defines the function h(z):=g(z)-cotW(z),
(16)
which is via construction a left or right monogenic respectively in the whole space Ak+i- Moreover, we observe that it is an odd function satisfying: 2kh(2z) = E h(z + \v), vevP
MO) = 0.
(17)
In the sequel we assume that h is not identically 0. We define (3 := ||u>i + hU!p\\. According to the maximum modulus theorem (cf. *) there must be a c G dB(0,2/3) such that \\h(z)\\ < \\h(c)\\ W e 5(0,2/3). Since the points f, **&>, • • •, ^ , c + V open ball 5(0,2/3), one can conclude that 2fc||Mc)||
= II E h(c+\v)\\ vevp
which is a contradiction. 4
8
(18)
. • • •. c + h ' 1 + ^ + - + h , p lie all in the
<E>(c+5")H v£VP
<2 p |IMc)||
<2k\\h(c)\\
•
Further trigonometric functions
By means of the monogenic Eisenstein series we can introduce to each pdimensional lattice flp with 1 < p < k a hypercomplex p-fold periodic monogenic tangent, cosecant and secant function without using multiplication or division of functions. In analogy to (4) one can introduce tangent functions in the following way:
449 Definition 5. Let ilp c Ak+i be a p-dimensional lattice where 1 < p < k. Let further Vp be the canonical system of representatives of Q,p/2£lp. The associated tangent function is then defined by: tan(p)(z):=-
^ c o t ^ ( z + |w). »evp\{o}
(19)
The p-fold periodic tangent function is left and right meromorphic in the whole space Ak+i- It has the periodicity grid Clp. In analogy to the complex case, it has poles in points where cot^p^(z) has zeros and zeros where cot^p\z) has poles. As a consequence of the generalized cotangent double angle formula one gets the following relation: Proposition 5. For all z G Ak+i and 1 < p < k: taato(z)
= cot (p) (z) - 2*cot (p) (2z).
(20)
This formula provides a generalization of the well-known relation tan(z) = cot(z) — 2 cot(2z) which exists between the classical tangent and cotangent. As it has been proposed in 2 1 for the classical secant and cosecant function, we can introduce monogenic generalizations of them to Clifford analysis. Definition 6. (Monogenic cosecant) Suppose fl p is a p-dimensional lattice in Ak+i, where 1 < p < k. Then the associated monogenic cosecant function cosec^ : .Afc_|-i\fip —> Ak+i is defined by cosecW(z) := - L - c o t ^ f l ) _ cot^(z). z z
(21)
By Weierstrass' convergence theorem the function cosec(p) is left and right monogenic in .4fc+i\f2p. It has poles of order k in the lattice points of Q p . Prom the definition we can deduce directly that its period lattice is 2 Q,p. In 16 and 17 we have already shown that cosec^ has a similar partial series representation as the complex cosecant. Proposition 6. (Partial fraction development of the generalized cosecant functions) The p-fold periodic cosecant function cosec^fc) in Ak+i associated with the lat-
450
tice ilp has the series representation 'qo(z)+
E *M[?o(2 + u ; ) - g o M ] , P=k wef2fc\{0} E * M « o ( * + w)> l
cosec^fz) — I [ ) ~ \
with lT,/
* ^
\ :=
f 1 , «/w £ 2 Sl„ { - 1 , tf W € fiP\2
, . <23>
With the generalized cotangent double angle formula we can deduce a duplication formula for the p-fold periodic cosecant. Theorem 3. (Duplication formula for the p-fold periodic monogenic cosecant) Let 1 < p < k. Then the p-fold periodic monogenic cosecant in Ak+i satisfies the duplication formula: 2fccosec(p)(2z) = cosec(p)(2) + tan (p) (^) - — L t a n W ^ ) . Proof: In definition (21) we apply on co t<">(z) and on co t^(2z) which leads to
(24)
Theorem 1
2W( 2 ) ( 2.) = ^ ( £ «»tW(| + £ ) ) - £ c o t ( p ) ^ + 5 ) veVP
vev„
= if cl C o t W (vf ) - c o t W ( z ) 2 -! 2 +
£
[^TCOt(| + | ) - c o t W ( , + |)]
c6V„\{0}
= cosec^(z) - i t a n ^ ( | ) + t a n ^ ( z ) .
D
This formula provides the generalization the following relation 2cosec(2z) = cosec(z) + tan(^) — t a n ( - ) between the corresponding classical trigonometric functions. Finally we mention that one can introduce a monogenic generalization of the secant function in Clifford analysis by means of a cosecant function, again as in 21 without multiplying functions:
451
Definition 7. (Monogenic secant) Let Qp be a p-dimensional lattice with 1 < p < k. Then the associated monogenic secant function s e c ^ : Ak+i\QP —y Ak+i is defined by: sec ( p ) (z)=
^Z
cosec(p\z+^v),
(25)
vevk\{0}
where Vp denotes again the canonical system of representatives ofQ.p/2 Qp. The function sec(p) is left and right meromorphic in Ak+i- It is p-fold periodic with respect to the lattice 2 Q p . While cosec(p) has poles in the points of f2, the functions sec^p' have poles precisely in the points in between, i.e. in ifip\f2 p , providing a further analogy to the classical complex case. At the end we remark further that the monogenic sine, cosine and exponential functions of * which are constructed via Cauchy-Kowalewski extension take values in the general Clifford algebra Clofc and not only in the subspace Ak+i while the generalizations of the cotangent, tangent, cosecant and secant constructed by Eisenstein series take all their values in Ak+i providing a symmetric relation between the domain of definition and the range of values of these functions. 5
Generalization of the Herglotz Lemma to Clifford analysis
One classical result of complex analysis is that a complex valued function which is analytic in a sufficiently large disc satisfying the cotangent double angle formula is a constant. This statement is called the Herglotz Lemma. The following lemma provides a more precise formulation: Lemma 3. (Herglotz Lemma) (cf. 22 p.328) Let r > 1 and assume that h : B(0, r) —> <E is an analytic function satisfying 2h{2z) = h(z) +
h{z+-),
whenever the points z,z + ^,2z lie all in the ball JB(0, r). Then h is a constant function. For the proof we refer to 22 p. 328. Now we present a generalization of this lemma in the framework of Clifford analysis. Theorem 4. (Generalized Herglotz-Lemma) Suppose p € IN with 1 < p < k. By Vp we denote the canonical system of representatives ofVLp/2 £lp. Let .8(0, r) be the open ball in Ak+i with radius r > j3 := ||wi + • • • +w p ||. If h : B(0,r) —> Clot is a left monogenic function
452
satisfying the generalized double angle formula
2kh(2z) = J2h(z+ \v)
( 26 )
vevP whenever the points z, 2z and z + ^v (v G Vp) lie all in the ball B(0, r), then h is a constant. Proof: Assume that h satisfies (26). Now we let act ^ - for i = 0, • • •, k on (26) which leads to
i>evp The function hi(z) := ^rh(z) d
is again left monogenic in B(0,r). k
dx\2
h{2z)}
=
Hence,
2khl(2z),
and further — [h(z + ^v)} = hi(z + i « )
Vu G Vp.
Therefore equation (27) is equivalent to
2khi(2z)=Y,hi(z+b.
(28)
vevP Now we choose (3
max ||/ii(z)||. z£B(0,t)
Under the condition that z lies in B(0,t), the points \(z + v), where v G VP, lie also in the ball B(0,t). Now we substitute z by \z in equation (28) and infer that
2*||M*)II< E 11^(^)11 ^ 2 *" lM ' vevP or in other words: 2 M < 2 ~ M which yields M = 0. This leads to: /i« = 0 Vz = 0 , 1 , . . . , k. Thus, h must be a constant. • k
6
k 1
Representation of p-fold periodic functions by Eisenstein series
In the last section of this paper we mention that any arbitrary p-fold periodic meromorphic function (1 < p < k) in Ak+i having non-essential singularities can be represented by means of the Eisenstein series e„ and thereby by
453
the p-fold periodic cotangent and its partial derivatives. At first we consider p-fold. periodic left meromorphic functions in Ak+i which have just a finite number of modulo O p incongruent isolated poles. l
We assume that / : ,4fc + i\( |J a, + $lp) —> Clofe is a p-fold periodic left monoid genie function having the isolated poles a\,... ,ai being all incongruent modulo Qp with pole order N(a,i) and principal parts N(ai)-k
£
9n(s-Oi)&W
|n|=0
respectively. Then l
N(a.i)-k
t=l
|j|=0
has the same principal part as / in Ak+i- With Mittag-Leffler's theorem from 1 one can infer: Theorem 5. (Representation of a p-fold periodic function with isolated poles) l
Suppose f : Ak+i\( U a i + ^ P )
—¥
Clofc is p-fold periodic (1 < p < k) having
»=i
only a finite number of modulo O p incongruent isolated poles a\,...,ai and being left monogenic elsewhere. Suppose that the pole order of a,i with (1 < i < I) is N(ai) and that the principal parts are given as above. Then there is a left entire function g : Ak+i —> Clofe with l
/(*) = E »=i
N(ai)-k
E
(j|
^cot^ (z-a^+giz).
(29)
|j|=o
With the same argumentation applying the version of Mittag-Leffler's theorem from 20 for the general (fc + l)-dimensional case (see also 16 ) it is possible to prove the following more general representation theorem. For the definition of singular sets and their corresponding order we refer to 20 and to 16 . Theorem 6. (Representation of a p-fold periodic function with non-isolated singularities) Assume that f is a Clifford algebra valued function that is p-fold periodic with respect to Q,p being left monogenic in Ak+i except in just a finite number of components of non-isolated singular sets Si,...,Si of the orders N(Si),..., N(Si) respectively which are incongruent modulo O p .
454
Then there is a left entire function g : Ak+i —> Clojt and functions 6j of bounded variation such that l
/W = E *=i
JV(a ; )-l
£ IJI=O
- „|j|
(/^cotW(^- c WM6f( C W)])+^)
(30)
£
where the integral has to be interpreted as Lebesgue-Stieltjes integral. References 1. Brackx, F., Delanghe, R. and Sommen, F., Clifford Analysis, Pitman 76, Boston-London-Melbourne, 1982. 2. Delanghe, R., On regular-analytic functions with values in a Clifford algebra, Math. Ann., 185 (1970), 91-111. 3. Delanghe, R., On the singularities of functions with values in a Clifford algebra, Math. Ann., 196 (1972), 293-319. 4. Delanghe, R., Sommen, F., Soucek, V., Clifford Algebra and Spinor Valued Functions, Kluwer, Dordrecht-Boston-London, 1992. 5. Dixon, A., On the Newtonian Potential, Quarterly Journal of Mathematics, 35 (1904), 283-296. 6. Eisenstein, G., Genaue Untersuchung der unendlichen Doppelproducte, aus welchen die elliptischen Functionen als Quotienten zusammengesetzt sind, und der rait ihnen zusammenhdngenden Doppelreihen (als eine neue Begriindung der Theorie der elliptischen Functionen, rait besonderer Beriicksichtigung ihrer Analogie zu den Kreisfunctionen), Crelle's Journal, 35 (1847), 153-274. 7. Fueter, R., Analytische Funktionen einer Quaternionenvariablen, Comment. Math. Helv., 4 (1931-32), 9-20. 8. Fueter, R., Die Funktionentheorie der Differentialgleichung Au = 0 und AAu = 0 mit vier reellen Variablen, Comment. Math. Helv., 7 (193435), 307-330. 9. Fueter, R., Uber die analytische Darstellung der regularen Funktionen einer Quaternionenvariablen, Comment. Math. Helv., 8 (1935-36), 371378. 10. Fueter, R., Functions of a Hyper Complex Variable, Lecture notes written and supplemented by E. Bareiss, Fall Semester 1948/49, Math. Inst. Univ. Zurich. 11. Fueter, R., Ueber Abelsche Funktionen von zwei Komplexen Variablen, Ann. Mat. Pura Appl., IV Ser. 28 (1949), 211-215.
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12. Giirlebeck, K., Sprossig, W., Quatemionic and Clifford Calculus for Physicists and Engineers, John Wiley & Sons, Chichester-New York, 1997. 13. Giirsey, F., Tze, H., Complex and Quatemionic Analyticity in Chiral and Gauge Theories, I, Annals of Physics, 128 (1980), 29-130. 14. Iftimie, V., Fonctions hypercomplexes, Bull. Math. Soc. Sci. Math. Repub. Soc. Roum., Nouv. Ser. 9 (57), (1965), 279-332. 15. Koecher, M., Krieg, A., Elliptische Funktionen und Modulformen, Springer, Berlin-Heidelberg, 1998. 16. Krausshar, R. S., Eisenstein Series in Clifford Analysis, PhD Thesis RWTH Aachen, Aachener Beitrage zur Mathematik 28, Wissenschaftsverlag Mainz, Aachen, 2000. 17. Krausshar, R. S., Monogenic Multiperiodic Functions in Clifford Analysis, accepted for publication in Complex Variables. 18. Laville, G., Ramadanoff, I., Elliptic Cliffordian Functions, submitted for publication. 19. Moisil, G. C., Theodorescu, N., Fonctions holomorphes dans I'espace, Bui. Soc. Stiint. Cluij, 6, (1931), 177-194. 20. Nef, W., Die unwesentlichen Singularitaten der reguldren Funktionen einer Quaternionenvariablen, Comment. Math. Helv., 16 (1943-44), 284-304. 21. Pringsheim, A., Faber, G., Algebraische Analysis in: Encyklopddie der mathematischen Wissenschaften mit Einschluss ihrer Anwendungen, Band II CI, Teubner, Leipzig, 1909. 22. Remmert, R., Theory of Complex Functions, Springer-Verlag BerlinHeidelberg, 1991. 23. Ryan, J., Clifford Analysis with Generalized Elliptic and Quasi Elliptic Functions, Appl. Anal. 13 (1982), 151-171. 24. Weil, A., Elliptic Functions according to Eisenstein and Kronecker, Springer-Verlag, Berlin-Heidelberg-New York, 1976.
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S O M E IMPLICATIONS OF CLIFFORD ANALYSIS (ABSTRACT) J. RYAN Mathematics Department, University of Arkansas Fayetteville, AR 72703, USA E-mail: [email protected] While Clifford analysis started about a hundred years ago as an attempt to generalize one variable complex analysis it has grown to find many profound applications in a number of areas including classical harmonic analysis over non-smooth domains, free boundary problems and Riemannian geometry. An essential idea is that given a sufficently smooth hypersurface S in Rn or on a more general manifold one can use a Dirac operator and Cauchy integral formula arising from Clifford analysis to show that LP(S) = HP(S+)®HP(S~) p ± where 1 < p < oo and i7 (S' ) are the Hardy p-spaces of solutions to the Dirac equation on the complementary domains 5 * of S. This type of decomposition and the associated calculus is used recently by Sijue Wu to tackle water wave problems in three dimensions. In our setting we are interested in setting up a Laplace equation on the sphere and solving Dirichlet and Neumann problems on domains on spheres and hyperbolas. This we do using Dirac operators and singular integral operators arising in the context of Clifford analysis. It is hoped to carry over these techniques eventually to more general manifolds, particularly conformally flat manifolds.
457
A R O U N D ZEROES OF M O N O G E N I C A N D HYPERMONOGENIC FUNCTIONS (ABSTRACT) T. HEMPPLING TU Bergakademie Freiberg, Institut fur angewandte Mathematik 1 Agricolastrasse 1, 09596 Freiberg, Germany E-mail: hempfl@mathe. tu-freiberg. de In this talk some old and new results on the zeroes of monogenic and hypermonogenic functions are presented. Talking about such zeroes everybody wants results but it seems that there are not too many interesting ones yet. This may be the case because the structure of zero sets in the higherdimensional setting is much more complicated than in the complex case where the zeroes are isolated. We deal with jacobians of the functions under consideration and try to construct certain monogenic functions out of 'small' sets of given zeroes, especially the zeroes lying on special curves.
458 I D E N T I T Y SURFACES W.TUTSCHKE Department of Mathematics D, Graz University of Technology Steyrergasse SO, 8010 Graz, Austria E-mail: tutschke@matd. tu-graz. ac. at Let be given a system of partial differential equation in a domain Q (in a Euclidean space). A surface is called an identity surface if a solution vanishes everywhere if only it is zero (or the zero vector) on this surface. Consider, for instance, the CAUCHY-RIEMANN system in two complex variables z and C,. Then the complex-one-dimensional plane defined by z — C, = 0 is not an identity surface because the holomorphic function f(z, C) = z — C is not identically equal to zero, whereas it vanishes on the above plane. However, each (complex one-dimensional) plane defined by 2z = (1 - c)C + (1 + c)< where c is a real or complex constant is an identity surface provided the constant is different from — 1. Using compatibility conditions for overdetermined first order systems, in the talk a general method for the construction of identity surfaces will be obtained. References 1. W. Tutschke, Identity Surfaces. Journal for Analysis and its Applications, vol. 19, No. 2, 529-537, 2000.