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English Pages 376 Year 1988
G. S. Litvinchuk • I. M. Spitkovskii Factorization of Measurable Matrix Functions
Mathematical Research
Mathematische Forschung
Wissenschaftliche Beiträge herausgegeben von der Akademie der Wissenschaften der DDR Karl-WeierstraB-lnstitut für Mathematik
Band 37 Factorization of Measurable Matrix Functions by C . S. Litvinchuk and I. M. Spitkovskii
Factorization of Measurable Matrix Functions
by Georgi Semenovich Litvinchuk and llya Matveyevich Spitkovskii edited by Georg Heinig with a foreword by Bernd Silbermann
Akademie-Verlag Berlin 1987
Autoren: Prof. Dr.
Dr.
Xlya
Georgi
Semenovich
Matveyevich
Litvinchuk
Spitkovskil
Akademie
der
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Odessa
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Technische Sektion
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Foreword In t r e a t i n g mathematical problems, i t i s o f t e n necessary t o f a c t o r i z e matrix-valued ( o r even operator-valued) f u n c t i o n s in a c e r t a i n manner. F a c t o r i z a t i o n s c l o s e l y connected with the notion of Wiener-Hopf f a c t o r i z a t i o n play a prominent r o l e . The development of f a c t o r i z a t i o n theory was, among other t h i n g s , stimulated by needs a r i s i n g i n t h e theory o f s i n g u l a r i n t e g r a l operators and i t s manifold m o d i f i c a t i o n s . Richness and profundity of the r e s u l t s obtained as w e l l as t h e i r s i g n i f i c a n c e f o r the theory of s i n g u l a r i n t e g r a l operators and o t h e r branches of mathematics required e x p l a n a t i o n of t h i s theory in monographs. A f t e r the book " F a c t o r i z a t i o n o f Matrix Functions and S i n g u l a r i n t e g r a l Operators" (Birkhauser Verlag, Basel 1 9 8 1 ) ,
excellently
w r i t t e n by K. CLANCEY and I . GOHBiSRG, the present monograph o f G. S . LITVINCHUK and I . M. SPITKOVSKlY " F a c t o r i z a t i o n of Measurable Matrix Functions" i s now the second work a v a i l a b l e on problems of ffiener-Hopf
factorization.
In addition to problems already discussed i n the book of CLANCEY and GOHBjiRG, i t c o n t a i n s a s e r i e s of more r e c e n t r e s u l t s p a r t l y due t o the authors and of considerable i n t e r e s t . I t should be emphasized t h a t the monograph r e f l e c t s not only the s t a t e of the a r t i n Wiener-Hopf f a c t o r i z a t i o n o f m a t r i x f u n c t i o n s , but i t a l s o f o c u s s e s the r e a d e r ' s a t t e n t i o n on many problems which remain t o be solved. The r i c h b i b l i o graphy containing both t h e o r e t i c a l papers and work on p r a c t i c a l
appli-
c a t i o n s i s a f u r t h e r advantage of the book, which w i l l g r e a t l y b e n e f i t a l l those i n t e r e s t e d in f a c t o r i z a t i o n
theory. B. Silbermann
Preface A series of reviews and original papers on factorization theory, which were read at the Odessa city seminar on boundary value problems and singular integral equations in 1973-77, served as a source of the present book. Furthermore, lectures given by the authors at the Department of Mechanics and Mathematics of the Odessa University have been incorporated. The authors are aware that their contribution to factorization theory, although it is very comprehensive (ranging from existence problems of a factorization, questions of estimates and stability of partial indices, to applications to the theory of the generalized Riemann boundary value problem), looks much more modest than the successes of their predecessors. Nevertheless, the necessity of creating a sufficiently complete review of factorization problems of measurable matrix functions explained from a unified point of view seemed so evident to the authors that they decided to write this booklet. It may be considered complementary to the well-known monographs of N. I. MUSKHELISHVILI and N. P. VBKUA, which are devoted to the classical factorization theory of matrix functions with Holder elements. We wish to emphasize that the subject matter will be discussed along lines meant not only for specialists familiar with the material, but also for readers who first become acquainted with the topic as well as for persons whose interest focusses, above all, on applications. The reader's judgment will show in how far this attempt has been successful. The authors
7
CONTENTS
Introduction Chapter 1. Background information 1.1. Some facts on the geometry of Banach spaces and operator theory in these spaces 1.2. Some information on boundary properties of functions analytic and meromorphic in finitely connected domains 1#3 On the operator of singular integration in spaces of summable functions
11 17 17
Chapter 2. General properties of factorization 2.1. The definition of factorization 2.2. Properties of factorization factors 2.3. The domain of factorability 2.4. Factorization of meromorphic matrix functions and their products 2.5. Comments
55 56 58 63 67
Chapter 3. The criterion of factorability. si-factorization and its basic properties
82
3.1. On solvability of the Riemann boundary value problem with factorable matrix coefficient 3.2. A criterion of factorability 3.3« On the normal solvability of the vector-valued Riemann boundary value problem and the problem associate to it 3.4. Left and right S-factorization. A criterion of simultaneous Fredholmness of the Riemann boundary value problem and the associate problem to it 3.5. ^-factorization of unbounded matrix functions on contouiBof class (R. 3.6. ^-factorization of bounded measurable matrix functions on contours of class S. 3.7. Comments
Chapter 4. ^-factorization of triangular matrix functions and reducible to them 4.1. Existence problems of a ^-factorization of triangular matrix functions 4.2. Effective construction of a ^-factorization and estimates for the partial indices of triangular matrix functions with ^-factorable diagonal elements 4.3. Calculation of partial indices of second-order triangular matrix functions 4.4. ¿¡»-factorization of functionally conmutable matrix functions 4.5« Comments Chapter 5. Some classes of factorable matrix functions 5.1. ^-factorization of matrix functions from classes L± + C CO 5.2. Factorization in Banach algebras of matrix functions 5.3« ^-factorization of piecewisp continuous matrix functions 5.4. Comments
29 45
80
84 93 99 105 109 116 126
132 135 140
147 154 163 169 172 180 195 202
Chapter 6. On the stability of factorization factors 6.1. Stability criterion for partial indices 6.2. On the behaviour of partial indices under small perturbations. The structure of the family of ^-factorable matrix functions 6.3. Several estimates for the partial indices of measurable bounded matrix functions 6.4-. Sufficient conditions for coincidence of partial indices of matrix functions whose Hausdorff set is separated from zero 6.5. On partial indices of matrix functions of classes 6.6. On the stability of the factorization factors G, 6.7. Comments -
211 214 218 223 229 236 240 247
Chapter 7» Factorization on the circle 253 7.1. Definition of factorization on the circle 255 7.2. Factorization of Hermitian matrix functions 258 7.3« Factorization of definite matrix functions 265 7.4. Criteria for existence of $-factorization and 272 coincidence of partial indices associated with the behaviour of the numerical domain 7.5. Definiteness criteria and stability of partial 276 indices of bounded measurable matrix functions 7.6. On partial indices of continuous matrix functions 285 7.7. Comments 288 Chapter 8. Conditions of $-factorability in the space L 5 . Criterion of $-factorability in L a of bounded measurable matrix functions 8.1. Auxiliary results 8.2. Sufficient conditions of $-factorability 8.3. Criterion of $-factorability in L t 8.4. Comments
296
Chapter 9» The generalized Riemann boundary value problem 9.1. Criterion of Fredholmness of the generalized Riemann boundary value problem in the space L^ 9.2. Sufficient conditions of Fredholmness and stability. Estimates for the defect numbers of the generalized Riemann boundary value problem in the space L 2 9.3« The generalized Riemann boundary value problem with continuous coefficients. A stability criterion ' 9.4. Comments
315 316
References Subject index Notation index
340 371 372
10
297 304 307 309
325 333 336
INTRODUCTION The notion of factorization is widely used in different branches of mathematics. The term factorization itself simply means the representation of some mathematical object (number, function, matrix, operator, etc.) as a product of objects of the same type, but having certain additional properties. According to the type of the objects and the character of the problem studied (multiplication of numbers, pointwise multiplication of functions, their composition, etc.) this product can be understood in a different manner. Many mathematical propositions are, in fact, theorems on the existence and properties of a certain factorization. In principle, even the fundamental theorem of arithmetic (on the factorization of natural numbers in prime factors) and the fundamental theorem of algebra (on the polynomial factorization over the complex field) can be considered as examples of factorization theorems. The importance of these theorems needs no comments. As more special examples we mention the representation of matrices and operators in a Hilbert space in the form of a product of isometric by positively definite ones (so-called polar representation), the representation of functions of Hardy classes as a product of an inner and an outer one and its generalization to the case of matrix and operator functions, but also the representation of entire functions as product of other entire functions. Many methods for solving equations and boundary value problems of a different kind are based on the idea of factorization. The schema for using factorization in solving equations may be described in the following ways Let some operator A be represented in the form A = A~1A_.
(1)
Then the equation y = Ax is equivalent to the equation A + y = A_x. For a suitable choice of representation (1), the latter relation turns out to be more convenient for investigation, and sometimes it can be solved explicitly. Simultaneously, the original equation will also be solved. For instance, the representation of a square matrix A with principal minors different from zero as the product of non-singular triangular matrices allows us to reduce the solution of a system of linear equations with matrix A to a triangular system. There exists a continuous analogue of the mentioned result for Fredholm integral operators and a, more general result on the factorization of an operator acting in a v
Hilbert space along a chain of projections as well (GOHBEHG, KREIN [5], BAEKAH', GOHBERG [1,2]). 11
The f a c t o r i z a t i o n of matrix functions defined on some contour, which i s studied in the present book also belongs to f a c t o r i z a t i o n s of t h i s t y p e . I t appeared in connection with the study of systems of singular i n t e g r a l equations and boundary value problems f o r analytic functions» Throughout the book, by a f a c t o r i z a t i o n of the matrix function G defined on a closed contour r , which divides the closed complex plane into parts D + ( 3 0 ) and D " ( 3 » ) , we understand a representation of G in the form G(t) = G+(t) where
G+
A(t) G _ ( t )
(t 6
r),
are boundary values of a matrix function analytic and
non-singular in
D~, and
A ( t ) = diag(t
1
,...,t
a
).
Under s u f f i c i e n t l y general assumptions, the integers K 1 i . . . , K q are uniquely defined (up t o o r d e r ) by the matrix function G and are c a l l e d i t s p a r t i a l indices 1 The f a c t o r i z a t i o n of matrix functions i s the main part in the theory of vector-valued Riemann boundary value problems. I t permits us t o reduce the general case of t h i s problem t o the s o - c a l l e d jump problem* In t h i s aspect, the problem of f a c t o r i z a t i o n has been studied under d i f f e r e n t r e s t r i c t i o n s on the smoothness of the contour r and the matrix function G, s t a r t i n g from the end of the previous century by several generations of mathematicians. The r e s u l t of t h i s work f o r the case of piecewise Holder matrix functions and piecewise smooth contours are summed up in the well-known monographs of MUSKHELISHVTLI [ 1 ] , VEEUA [ 4 ] , in the survey of GAKHOV [ 3 ] and the paper of KHV3DSLIDZB [ 1 ] , Since the l a t e f i f t i e s , the f u r t h e r development of the theory of the Riemann boundary value problem, systems of singular i n t e g r a l equations with Cauchy kernel and systems of Wiener-Hopf equations has stimulated
•O A more complete and exact d e f i n i t i o n of f a c t o r i z a t i o n w i l l be given at the beginning of the second chapter. I n c i d e n t a l l y , we note that t o v e c t o r boundary value problems with a s h i f t ( i n p a r t i c u l a r , t o the Gazemann problem) there correspond d e f i n i t i o n s of f a c t o r i z a t i o n d i f f e r e n t from that one given above. In the present book we do not study f a c t o r i z a t i o n s of such a type, since in the v e c t o r case the theory has not been s u f f i c i e n t l y e l a b o rated h i t h e r t o . The corresponding f a c t o r i z a t i o n s f o r the scalar case can be found in the monograph of LITVINCHUK [ 3 ] .
12
the creation of new directions in the factorization problem. The faotorization of matrix functions with elements from the Wiener algebra (GOHBERG, KKEÍN [3]), the factorization of continuous (SIMONENXO [2]) and piecewise continuous (GOHBERG, KRUPNIK [1], MANDZHAVIDZE [6]) matrix functions has been studied, and a number of results concerning the factorization of measurable bounded matrix functions was obtained (DANILYUK [4,5], SIMONENKO [4,6], DOUGLAS [1]). At the Same time, it became clear that even in case of a continuous non-singular matrix function G a factorization with continuous factors G± does not always exist. On the one hand, this gave rise to the search for new classes of matrix functions admitting a factorization with continuous factors (see BUDYAHU, GOHBERG [3,4]) and, on the other hand, it led to the creation of the notion of factorization in classes 1 < p < oo. In case of continuous non-singular matrix functions, this factorization does not depend upon the choice of p. However, such a dependence holds already for piecewise continuous matrix functions. In this connection, there arises the task of studying the set of parameter values p , for which a given matrix function G can be factored. Moreover, in the Riemann boundary value problem theory in L^ spaces, a situation may emerge where the problem has a finite index, but is not normally solvable. Owing to this, we have to impose additional demands upon the factorization in order to guarantee the normal solvability of the boundary value problem. In the following, a factorization satisfying these requirements will be called a ^-factorization. There were also studies on the enlargement of the class of contours r, for which factorization theorems continue to be valid. The crucial idea of these studies reduces to the development of sufficient conditions for the boundedness of the operator of singular integration on I" (see e.g. KHVEDELIDZB [4]). In connection with the problem of calculating defect numbers and the approximate solution of the vector-valued Riemann boundary value pro blem and singular integral equations, the questions of stability of the factorization factors G + and A as well as of finding estimates for partial indices are not yet well understood, even under the classic assumptions made in VEKUA [4], GAKHOV [3], MUSKHBLISHVILI [1]. In the last 15 years a number of new results has been obtained in this direction (sufficient stability conditions, which can effectively be verified, sign preservation of all partial indices, which is also necessary in some cases (cf. VERBITSKIÍ, KRUPNIK [1,2], SPITKOVSKlf [5, 10], POUSSON [2], RABINDRAIUTHAN [1] and others),). In obtaining these results, the notion and properties of the numerical
13
range (or Hausdorff s e t ) of a matrix (MARCUS, MINC [ 1 ] ) i s used, i . e . questions related to the formula f o r the norm of a Hankel operator (see ADAMYAN, AROV, KREfN [ 1 ] ) and the operator of singular integration (VEBBITSKli, KRUPNIK [ 1 ] , KRUPNIK [ 4 ] ) . We would also l i k e to note that the factorization problem for the spectral density of a stationary random process (ROZAUOV [ 1 ] ) which arose in probability theory, some problems of projection methods f o r the solution of systems of singular integral and convolution type equations (GOHBERG, FELDMAN [ 3 ] ) and the theory of canonical systems of linear differential equations (KBe¥n, MELIK-ADAMYAN [ 1 , 2 ] ) show that the importance of the factorization problem f o r matrix functions i s not limited by i t s role in the theory of the vector-valued Riemann boundaryvalue problem. The factorization problem f o r matrix functions arises also in a natural way in the study of convolution type equations on a f i n i t e interval and on systems of intervals (GANIN [ 1 ] , KAHLOVICH, SPITKOVSKli [ 1 ] , KOMXAK [1—4], NOVOKSHENOV [ 1 ] , PAL'TSEV [2-6]. SPITKOVSKli [ 1 5 ] ) . We emphasize that here(in contrast to the classical case of the h a l f - l i n e ) even scalar equations yield a matrix problem of factorization. A l l this increases interest in the peculiarities of factorization of special type matrix functions (unitary, Heimitian, functionally oommutable f a t e . ) , information on which i s scattered in various papers (GORDIENKO [ 1 ] , GOHBERG, KREfN [ 3 ] , KHEfe, MELIK-ADAMYAN [ 1 , 2 ] , NIKOLAICHUK, SPITKOVSKli [ 1 , 2 ] , CHEBOTAREV [ 1 , 2 ] , SHMUL1 YAW [1,2] and others). At present there do not exist monographs or reviews on the factorization of matrix functions, in which the problems mentioned above would be discussed in a s u f f i c i e n t l y complete manner1K There are only three papers of a general nature by BOJARSKI [ 3 ] , GOHBERG, KREIN [ 3 ] , KHVEDKLIDZE [ 4 ] and the monographs of GOHBERG, FELDMAN [ 3 ] , DANILYUK [ 6 ] , PRbSSDORF [ 1 ] and PR'dSSDORP, MICHLIN [ 1 ] , in which some questions on the factorization of matrix functions are explained. The authors hope that the present book w i l l contribute towards f i l l i n g the gaps existing in the literature concerning this topic. We now intend to b r i e f l y describe the contents of the book. The f i r s t chapter is of auxiliary character. I t contains propositions from operator theory in Banach spaces and information on d i f f e r e n t olasses of analytic functions (mainly on Smirnov classes) necessary f o r understandin g the material contained in the main part of the book. In Chaptor 2 the notions of factorization and the domain of factorability of matrix 1'
While this manuscript was in preparation f o r publication, the mono- graph QLANGBI, GOHBERG [ 3 ] came out. I t s contents i s essentially covered by the prytgnn-h ftp^y,
14
functions are introduced, and t h e i r simplest properties are established* Besides, the f a c t o r i z a t i o n problem f o r matrix functions meromorphic i a D+ or D~" ( i n p a r t i c u l a r , r a t i o n a l matrix f u n c t i o n s ) i s treated t h e r e , and the problem of the change of p a r t i a l indices when being multiplied by matrix functions of the same kind i s studied. The connection between the f a c t o r i z a t i o n problem f o r matrix functions and the vector—valued Riemann boundary value problem i s regarded in Chapter 3 . ^ - f a c t o r i z a t i o n properties resulting from t h i s connection and corresponding propositions of the theory of Fredholm operators are established! Chapter 4 i s devoted to triangular and f u n c t i o n a l l y commutable matrix functions. In t h i s chapter the c r i t e r i o n of $ - f a c t o r a b i l i t y and e s t i mates for p a r t i a l indices (but f o r second-order matrix functions even exact foimulae) are derived. In Chapter 5 necessary and s u f f i c i e n t conditions of $ - f a c t o r a b i l i t y of continuous and piecewise continuous matrix functions, but also f o r matrix functions of the c l a s s L^ + C are established. The f a c t o r i z a tion problem in decomposing algebras of functions including the f a c t o r i z a t i o n problem of Holder matrix functions on a piecewise smooth contour and matrix functions from the Wiener algebra on the c i r c l e w i l l be studied. The c r i t e r i o n f o r s t a b i l i t y of p a r t i a l i n d i c e s , s u f f i c i e n t conditions f o r t h e i r non-positivity, non-negativity, coincidence or equality to zero are explained in Chapter 6 . In addition, we s h a l l i n v e s t i g a t e the behaviour of the f a c t o r i z a t i o n f a c t o r s G+ under small perturbations of the matrix function
G .
Chapter 7 i s dedicated to the f a c t o r i z a t i o n problem on the unit c i r c l e . Furthermore, the f a c t o r i z a t i o n of Hermitian and unitary matrix functions w i l l be studied. The necessity of several s u f f i c i e n t conditions f o r non-negativity (non-positivity, e q u a l i t y to zero, e t c . ) of p a r t i a l indices established in Chapter 6 w i l l be proved. Chapter 8 i s concerned with s u f f i c i e n t conditions f o r $ - f a c t o r a b i l i t y based on l o c a l principle and r e s u l t s of Chapters 5 - 7 . F i n a l l y , in Chapter 9 the theory developed in Chapters 3 - 8 i s used f o r the study of the generalized Riemann boundary value problem, which has manifold applications in geometry, mechanics, and physics (see BUDYAMJ [ 1 ] , GAKHOV [ 2 ] ) . The l a s t section of each chapter contains information and comments on r e s u l t s , which were not r e f l e c t e d in the main p a r t of the chapter, but
15
axe r e l a t e d to i t in c e r t a i n ways. Some unsolved problems are formulat e d . The f i r s t chapter makes an exception. For the r e a d e r ' s convenience, comments on references accompany every proposition (or a group of c l o s e l y connected propositions). L a s t l y , we want to remark that in the book we do not focus oux a t t e n t i o n on such problems as the f a c t o r i z a t i o n problem r e l a t i v e to a contour lying on a Riemann surface ( c f . L . F . ZVEROVICH [ 2 ] , E . I . ZVEROVICH [ 1 ] , ZVEROVICH, PANCHENKO [ 1 ] , iCVITKO [ 1 ] , KRUGLOV [ 1 ] , PAJUCHENKO [ 1 ] , RODIN [ 1 , 2 ] , RODIN, TURAKULOV [ 1 ] , SKLEZNEV [ 2 ] , KOPPELMAN [ 1 ] , R B h R L [ 1 ] ) or with respect to complex (GOHBERG, FELDMAN [ 1 ] , MAHDZHAVIDZS [ 7 , 8 ] ) and Jordan n o n - r e c t i f i a b l e (among them quasiconformal) contours (see KATS [ 3 ] , SELEZNEV [ 1 - 3 ] ) . Furthermore, we do not deal with the natural generalization of the f a c t o r i z a t i o n problem f o r matrix functions - the question on f a c t o r a b i l i t y of operator functions. Concerning t h i s topic the reader i s referred to Chapter 6 in the monograph of GLANCEY and GOHBERG [ 3 ] and the l i t e r a t u r e c i t e d there, but also to the papers of BUDYANU [ 1 ] , LEITERER [ 1 ] , SERGEEV [ 1 ] , GOHBERG, KAASHOEK, van SCHAGEN [ 1 ] , van der MEE [ 1 , 2 ] , MUCKENHOUPT [ 1 ] , NAKAZI TAKAHIKO [ 1 ] , SUCIU [1].1>We do not dwell on various applicat i o n s of the f a c t o r i z a t i o n problem. We only r e f e r to GUSAK [ 1 , 2 ] , DUKHOVNYI [ 1 ] , MALYSHEV [ 1 ] , ROZAtiOV [ 1 ] , where methods and r e s u l t s of the f a c t o r i z a t i o n theory are applied to p r o b a b i l i t y - t h e o r e t i c problems. Applications to mechanics one can find in the monograph of VOROTICH, ALEKSANDROV, BABESHKO [ 1 ] as well as the papers BABESHKO [ 1 , 2 ] , BELOKOPYTOVA, IVANENKO, FH 1 SHTINSKII [ 1 ] , VOROB'EV [ 1 ] , KULIEV, SADYKHOV [ 1 ] , MOSSAKOVSKII, MISHCHISHIN [ 1 ] , TOLOKONNIKOV, PEN'KOV [ 1 ] , KHRAPKOV [ 1 ] , TSITSKISHVILI [3,4],CHERBPANOV [ 1 ] . Concerning a p p l i c a tions to d i f r a c t i o n problems, see the monograph VIROZUB, MATSAEV [ 1 ] and the a r t i c l e POPOV [ 1 ] , CHAKRABARTI [ 2 ] , HEINS [ 1 , 2 ] , IDEMEN [ 2 J . F i n a l l y , f o r applications of the f a c t o r i z a t i o n theory to the method of inverse problems and other questions of t h e o r e t i c a l physics, the reader i s referred to the monograph NOVIKOV ( e d . ) [ 1 ] and the papers of EMEUS [ 1 ] , ZAKHAROV, SHABAT [ 1 ] , ITS [ 1 ] , KRICHEVER [ 1 , 2 ] , MASKUDOV, VELIEV [ 1 ] , MEUNARGIYA [ 1 ] , NOVOSHENOV [ 2 , 3 ] , TROITSKII [ 1 ] , DTJVACZ, ZELAZNY [ 1 ] , IDEMEN [ 1 ] , MEISTER [ 1 ] , RAJAMAKI [ 1 ] , REYMAN, SEMENOVTIAN—SHANSKY [ 2 ] , SIEWERT, KELLEY, GARCIA [ l ] .
1
> see also GOHBERG, LEITEHER [ 1 - 2 ] .
16
CHAPTER 1.
BACKGROUND INFORMATION
This chapter is of an auxiliary character. Its first section contains facts neoessary for the further explanations concerning lineals of finite oodimension as well as aemi-Fredholm and Fredholm operators in Banach spaces» Most of these statements are well-known and have been published in several recent monographs15However, Theorem 1.12 on the Fredholmness of block operators and the local principle in the theory of Fredholm operators make an exception. The latter was proved in the form we need only in SBtONENKO1 s paper [5]» Therefore, Theorems 1.12 and 1.14 will be given with detailed proofs. The remaining theorems in Section 1.1 we state without proof, referring the reader in every case to available souroes. We do not intend to explain the history of semi— Fredholm and Fredholm operator theory, since this has already been excellently described (see, e.g. KATO [1]). In the second section of the present chapter., above all, known theorems on analytic functions of Smirnov classes are stated, whereas in Section 1.3 properties of singular integral operators related to the results of Section 1.2 are described. Here as well as in Section 1,1, we give proofs only for those statements, which we did not find in an appropriate form (Theorems 1,26, 1.27, 1,29, 1.31, 1.35) or which are published only in several articles (Theorems 1.20, 1.32, 1.33)» Since the genesis of the formation of many,results of the theory of Smirnov olasses has received little attention in modern monographic literature, we give some historic information and comments on the material of Sections 1.2 and '1,3. 1.1,
SOME FACTS ON THE GEOMETRY OF BANACH SPACES AND OPERATOR THEORY IN THESE SPACES
A linear manifold in a Banach space not necessarily closed we shall call a lineal. For a closed lineal we use the term subspace. The dimension of the factor-space lineal C
8|C is said to be the codimension of the
being located in a Banach space codim£,
U
9:
= dim(8|£).
See e.g. SOHBIiRG, KRUPNIK [4], S.KREIN [1], MICHLIN, PROSSDORF [1] 17
THEOREM 1 . 1 ,
Suppose £ 1
and l e t £ t 2.
to be a subspaoe o f the Banach space
be a l i n e a l . Then
dim £
< oo implies t h a t £ «
i s also a subspace. On the other hand, i f X a £1 £
i s a subspace and
i s the range o f a olosed operator, theQ
implies that
8,
dim £
< oo
i s a subspaoe, t o o .
The f i r s t part of the theorem i s an elementary f a c t (we r e f e r t o GOHBEBfc, KRUPNIK [ 4 ] , p, 50 f o r i t s p r o o f ) . The second p a r t i s a consequence o f the closed graph theorem ( s e e , e . g . , PALAIS [ 1 ] , Ch, 7 , l b * 1)* DEFINITION 1 , 1 , with
f(x) = 0
The s e t of a l l elements
for a l l
f
of the dual space
x 6 £ i s c a l l e d the orthogonal complement
to the l i n e a l £ (s. »). Obviously,
i s a subspace of the space
ment to the l i n e a l £
8», The orthogonal comple-
coincides with the orthogonal complement to i t s
closure £ . There i s a natural isomorphism between dual to
and the space
8 j Z , As a c o r o l l a r y of t h i s isomorphism, we mention
THEOREM 1 . 2 ,
For any l i n e a l £ ( c s ) , the dimension of the orthogonal
complement coincides with the oodimension of i t s closure ( i n the sense that e i t h e r both values are i n f i n i t e or both values are f i n i t e , and then they are equal to each o t h e r ) . DEFINITION 1 . 2 .
A subspace £ Q
of the Banach space
complementable. i f there e x i s t s a subspace £ , ( c 8 ) vector
x € 8
8
i s called
such t h a t each
admits a unique representation in the foim
x = xQ + x 1
( x . € £ i f j = 0 , 1 ) . In t h i s case, the subspace i s said to be the U V d i r e c t complement to £ Q (with respect to 8 ) , and the space 8 i s saiH to be decomposed in the d i r e c t sum of i t s subspaces £ 0 (written
8 =
and
+ £1),
The notion of the d i r e c t sum i s transferred to the case of an a r b i t r a r y f i n i t e number of summands in an obvious manner. Every subspace in a Hilbert space can be complemented} one of i t s d i r e c t complements i s the orthogonal complement. In every Banach space not isomorphic to a Hilbert one, there are non-complementable subspaces
18
(LBE,SARASON [ 1 ] ) . Nevertheless, there holds THEOREM 1 , 3 ( S . KRBIN M l . p. 3 1 ) . 390
Let
9
a subspaoe of f i a i t e codimension. Then
be a Banach space and SQ
i s complementable, and
the dimension of a l l i t s d i r e c t complements i s equal to I f , moreover, £ i s a l i n e a l dense in dense in to
9
8 , then the l i n e a l C D 8 Q
S Q , and there e x i s t s a d i r e c t complement to
lying in £
codim 8 Q . is
53Q with r e s p e c t
.
We s h a l l say t h a t a l i n e a r (generally speaking, unbounded) operator a c t s in the Banach space l i e in
8
1
3 , i f i t s domain
geneous equation
A , i . e . , the solution s e t of the homo-
Ax = 0 , w i l l be denoted by
Owing to the l i n e a r i t y of the operator ker A are l i n e a l s in
8 .
By
l i n e a r bounded operators acting in with
im A
>.
The kernel of the operator
and
dom A and image
A
ker A.
A , the s e t s
[8]
dom A , im A
we denote the c l a s s of a l l
8 , the domain of which coincides
8 . This c l a s s of operators supplied with the norm
||A|| = sup {||Axj| J x € 8 , Furthermore, the c l a s s
||x|| < 1 }
[8]
i s i t s e l f a Banach space.
i s a Banach algebra, i . e . such a Banach
space, in which the operation of m u l t i p l i c a t i o n i s defined ( i n the case under study, i t s role plays the composition of operators) c o n s i s t e n t with the l i n e a r structure and possessing the property ||AB|| < ||A|| *||B|] * >. DEFINITION 1 . 3 . operator
A , if
The operator
B
dom B c dom A and
i s referred to as a part of the Ax = Bx
for all
Under the conditions of Definition 1.3» the operator also said to be the r e s t r i c t i o n of DEFINITION 1 . 4 .
The values
A on
15
B
dom B (written
a(A) = dim ker A and
are c a l l e d defect numbers of the operator
x € dom B . i s sometimes B = A| dom
B
)»
0(A) » dim(8|Im~A)
A, and t h e i r difference
Most of the d e f i n i t i o n s and r e s u l t s stated below can be transferred to operators acting from one space into another. However, f o r our aims i t i s s u f f i c i e n t to regard operators actiqgin one space. A short survey of the theory of Banach algebras can be found,for example,in the appendix written by 7.M. TIKHOMIROV to the book KGLMOGOROV, FOMIN [ 1 ] .
19
ind A = oc(a) - 3 ( a )
is the index of the operator
A •
The index is defined, if at least one of the defect numbers is finite. If both are finite, then
A
is called an operator with finite index.
In case the image of the operator
A
is closed, the equation
Ax = y
is usually said to be nonaally solvable. For the sake of brevity, in this case the operator
A
itself is also called normally solvable.
DEFINITION 1.5. A closed normally solvable operator Fredholm iff cc(A) and A
is called
p(A) are finite. In case that at least one
of these numbers is finite, A If a(A) 0
1) the operator
($„-, Fredholm) operator
such that if B €[8] and
A + B
is also a
A acting in 8,
||B|| < e , then
($_-, Fredholm) operator,
2) ind (A+B) = ind A, 3) a(A+B) < a(A),
0(A+B) < p(A).
Theorem 1.4 means the stability of semi-Fredholmness or Fredholmness of the index as well as the semi-stability of defect numbers under perturbations of the operator with a sufficiently small noim. THEORfiM 1.5.
If the operator
holm) operator and the operator also a
A
acting in 8
is a
B e[8] is compact, then
($_-, Fredholm) operator and
($_-, *redA+B
is
ind (A+B) = ind A.
Theorem 1.5 expresses the stability of semi-Fredholmness and Fredholmness and of the index of the operator 20
A
under compact perturbations.
Sometimes Theorems 1 . 4 and 1 . 5 are c a l l e d the f i r s t and second s t a b i l i t y theorem* THEOREM 1 . 6 . and
I f the operators
A and
B acting i n
B i s densely d e f i n e d , then t h e operator
8
are iredholm
BA i s also Fredholm and
ind BA = ind A + ind B. DEFINITION 1 . 6 . (see KATO f l l . p . 212). acting i n
8
and
8*
The operators
A and
B
r e s p e c t i v e l y , are r e f e r r e d t o as ad.loint t o
each o t h e r , i f f o r a l l
z 6 dom A and
f € dom B , there holds
(Bf)(x) = f(Ax). Generally speaking, t h e r e are many operators a c t i n g i n a d j o i n t to
A . But i f the operator
8* , which are
A i s densely d e f i n e d , then a l l
operators a d j o i n t t o i t are p a r t s of one and the same uniquely defined operator,which w i l l be denoted by
A* . The operator
A* i s always
closed. THEOREM 1 . 7 .
Let the operator
l y d e f i n e d . Then
A acting i n
(im a / " = ker A*
l a s t inclusion
and
be closed and dense-
(ker a / " 3 i s i * , where i n the
e q u a l i t y holds i f and only i f the o p e r a t o r
( o r , e q u i v a l e n t l y , A*) COROLLARY 1 . 2 .
The closed and densely defined operator
Fredholm) o p e r a t o r . In t h i s case we have DEFINITION 1 . 7 .
A
i s normally s o l v a b l e .
( $ _ - , Fredholm) operator i f f the operator
The operator
r e g u l a r i z e r of the operator i s compact. I f
8
M e[s]
A*
A is a
is a
a(A) = 0(A*), {3(A) = a(A*). i s called a l e f t (right)
A ( € [ 8 ] ) , i f the operator
UA - I
(AM - I )
M i s simultaneously a l e f t and r i g h t r e g u l a r i z e r , then
i t i s c a l l e d a (two-sided) r e g u l a r i z e r . I t follows from the d e f i n i t i o n t h a t i f an operator has l e f t and r i g h t r e g u l a r i z e r s , then a l l of them are r e g u l a r i z a r a and d i f f e r from each other by compact summands. THEOREM 1 . 8 .
The operator
A 6[8]
l e f t ( r i g h t ) i f and only i f i t i s a im A (ker A)
admits a r e g u l a r i z a t i o n from the ( $ _ - ) operator and t h e subspace
i s complementable. Among a l l operators of c l a s s
[8],
21
the Fredholm operators and only they admit a regularization. A simple consequence of Theorem 1«8 i s THEOREM 1,9« class
[8]
I f the product
i s Eredholm, then
I f in t h i s case
B
is a
BA A
(A
of operators
is a
and
A B
and
B
of the
a $_-operator«
i s a $ _ - ) operator, then
A (respec-
t i v e l y B) i s Fredholm. DEFINITION 1 . 8 .
The f a c t o r algebra of the Banach algebra
[»]
with
respect to the ideal ¥ of compact operators i s called Calkin algebra. According to t h i s d e f i n i t i o n , the elements of the Oalkin algebra are classes of equivalent operators, where two operators said to be equivalent, i f equivalence by A €[8]
A-B
A
B
are
In a l l what f o l l o w s , we denote this
A ~ B. The norm of the image
& of the operator
in the Calkin algebra i s called essential norm of
|A|). In other words:
and
A (written
|A| = inf{||A+T|| 1 T t f ) .
Owing to the closedness of the ideal of compact operators, the Calkin algebra provides a Banach algebra. From theorem 1.8 we deduce that the operator and only i f i t s image inverse of
1
i s iredholm i f
& i s i n v e r t i b l e in the Calkin algebra, and the
i s that element of the Calkin algebra, which consists
of a l l regularizers of from the class
A e[8]
A ( o r , what i s the same, of any other operator
A ).
Next we formulate a simple and well-known result from the theory of Banach algebras, which we need below both in general fonn, and f o r the special case of the Calkin algebra. THEOREM 1.10.
Let
{x^}
be a sequence of i n v e r t i b l e elements of the
Banach algebra £
converging in 3 to x . Then the relation supHxj^ || < oo i s necessary and s u f f i c i e n t f o r the i n v e r t i b i l i t y of k
22
x.
Applying Theorem 1.10 to the Calkin algebra we obtain THEOREM 1.11,
Let
{A^} c [ a ]
converging to the operator
be a sequence of Fredholm operators
A . The operator
only i f there e x i s t s a sequence tors
Ak
such that
i s Fredholm i f and
of regularize is of the opera-
supHB^U < 0 0 .
L e t the Banach space spaces»
{B^}
A
8
9 a 9i + 9 t .
be represented as the direct sum of i t s subThen every operator
A e[9]
may be written in
the form of a block-matrix
(1.1)
A = where A ^
*22 •
i s a l i n e a r bounded operator from
into
( i , d = 1,2').
The equation ( 1 . 1 ) must be understood in the sense that the decomposition
x s x 1 + xa
Ax s y , + y »
(x^j 6 8^)
(y^ 6 9^), where
corresponds to the decomposition y, =
+ Alax2,
y 2 = A a l x^ +
Aa a^a• Supposing that in the representation ( 1 . 1 ) one of the blocks
A^
is
compact we can formulate the c r i t e r i o n of Fredholmness of the operator A
in terms of i t s remaining blocks. For the sake of definiteness, we
assume the block THEOREM 1.12. A €[9]
A 12
Let in the representation ( 1 . 1 ) of the operator
the block
operator
A
to be compact.
A 12
be compact. Then f o r the Ji'redholmness of the
i t i s necessary and s u f f i c i e n t that the following condi-
tions holdt 1)
An
i s a $_-operator,
2)
Aaa
i s a $ + ~operator,
3)
Y 1 = dim
4-)
Ya = codim C t < 00, where .£2 = i m A 2 2 + A 2 1
< oo, where
= ker A n D (x€8., : A 2 1 x € im A 2 2 } ker A 1 1 .
I f the conditions 1 ) - 4 ) are s a t i s f i e d , then the index of the operator
A
i s calculated by the fomiula
(1.2)
ind A a oc(Aaa) - P ( A , , ) + Yi - Ya. Moreover, i f
A 1 t = 0, then
a(A) = a(A tl ) + Y1 1 », M
=
+ y
(1.3) 23
Proof.
Owing t o Theorem 1.5 i t s u f f i c e s t o study the case
A 1 t = 0.
F i r s t l e t us assume t h a t the conditions 1 ) - 4 ) are f u l f i l l e d . We show that of
A 8
i s Fredholm and ( 1 . 2 ) holds. L e t onto
along
82
and
P°
P,
denote the p r o j e c t i o n
i t s r e s t r i c t i o n on
leer A. I t
is
e a s i l y v e r i f i e d that im P? -- Li Since
ker A|ker P °
and
ker P ° = ker A 1 1 (
i s isomorphic t o
im P?, t h i s i m p l i e s
oc(A) < oo
and dim ker A|ker P? = a ( A ) - a ( A n ) = dim ^
1
= Yi*
T h e r e f o r e , the f i r s t r e l a t i o n ( 1 . 3 ) i s proved. Next we prove that
im A
has f i n i t e codimension and ( 1 . 3 ) holds. By
assumption, there e x i s t d i r e c t complements M2
to £
of
im A
i n 82« We show that
2
in 8. L e t
Mi
M = Mi + M2
y € im A D M. Since and, on the other hand,
From t h i s we g e t
y € im A fl M,. In view of
Taking now
y = 0. Thus
y = y i + y2
im A n
in 8i
and
i s a d i r e c t complement
P n im A = im A n , we have
y , = P i y € im A i i
y e C t n Ma, i . e .
to
y i € M1# Henoe = im A D ! ! ,
y^ = 0. t h i s means
im A 0 M = { 0 } .
(y H € 8.= , j = 1 , 2 ) u u
a r b i t r a r i l y , we have a
decomposition 7i = A11X1
+ f»
y2 = AjiUi + A2ax2 + f t , where
u, € ker A , 1 f
f ^ € M..,
x.. 6 8^ (d = 1 , 2 ) .
vVe have, furthermore, a decomposition AaiXi = A21u!, + A 2 2 x 2 + f a with
ui 6 ker A n , x 2 € 8 a , f i 6 M a . Putting
x = Xi+Ui-Ui + x 2 - x 2
we obtain Ax = y i - f , + y 2 - f 2 + f i , which i s We proved
y = Ax + f , where
f = f i + f 2 - f' 2 € M.
8 = im A + M. In p a r t i c u l a r , t h i s implies that
f i n i t e codimension equal t o
im A
f 3 ( A i i ) + Y 2 « Since by Theorem 1.1
has a im A
i s c l o s e d , the second r e l a t i o n ( 1 . 3 ) r e s u l t s . The index formula ( 1 . 2 ) i s a consequence of ( 1 . 3 ) * 24
Now l e t us assume that R i s a regidarlrer of An
and
Rta
A i s Fredholm and
[
Hi 1
Ria |
®ai
®2a J
A* Then, obviously,
Rn
i s a r i g h t r e g u l i z e r of
a l e f t regularizer of A 2 t . Hence 1 ) and 2) are f u l f i l l e d .
Since, a s proved above,
ker A|ker A 2 2
Yi < oo. Further, the f i n i t e n e s s of codimension of £ , = im A n 8 t
i s isomorphic to CM we have
(3(A)
implies the f i n i t e n e s s of the
in 8 « . Hence 3) and 4 ) are s a t i s f i e d ,
too, and the theorom i s proved.
=
Theorem 1.12 i s formulated in SPITKOVSKlf [11] (see a l s o SPITKOVSKI* [ 1 2 ] , where t h i s theorem was presented with p r o o f ) . Formulae ( 1 . 2 ) allow f o r obtaining in case s u r j e c t i v i t y of the operator
A i a a 0, a c r i t e r i o n of i n a c t i v i t y and A. This r e s u l t was obtained independently
by STOROZH [ 1 ] . I t i s omitted here, since we do not need i t . Of course, various special cases of Theorem 1*12 were known previously. One of them important f o r the following i s the case that some of the diagonal blocks of the operator
A i s Fredholm. This case can be investigated
(even without compactness assumption f o r
Ai») with the help of
Frobenius' formulae ( s e e KIRILLOV, GVISHIANI [ 1 ] p. 85 as well as PETROV [ 1 ] ) . However, we need only the case i f
Ai a
i s compact.
Thus, we obtain the corresponding r e s u l t as a consequence of Theorem 1 . 1 2 . COROLLARY 1 . 3 .
Let in the representation ( 1 . 1 ) of the operator
A
the block
be compact, and l e t one of the diagonal blocks
At ,
and
A 22
A1t
be Fredholm. Then f o r the Fredholmness of the operator
A
i t i s necessary and s u f f i c i e n t that the second block i s a l s o Fredholm. I f t h i s condition i s f u l f i l l e d , then ind A = ind An + ind A 2 2 . I f , in addition,
A 12 = °>
then
a(A) = a ( A t i ) + a ( A l 2 ) - m, p(A) = p ( A n ) + P(A 2 1 ) - m, where
m = dim(A 21 ker An)|&m A cx D A 21 ker A n ) .
In f a c t , i f e . g . the operator
A4i
i s Fredholm, then conditions 1 ) 25
and 3 ) of %eorem 1 . 1 2 are automatically s a t i s f i e d , and thanks t o the f i n i t e dimension of the l i n e a l t o the condition that
A aa
A t 1 ker A , , ,
condition 4 ) i s equivalent
i s a 4_-operator.
The v a l i d i t y of the formulae f o r the index and the defect numbers follows from the corresponding formulae of Theorem 1 . 1 2 , taking i n t o account that f o r Fredholm
An
and
A aa
we have
dim(ker An D £ 1 ) = dim ker An - m, dim(8 a |£ a ) = dim(8 a |im A aa ) - m. In view of Corollary 1 . 3 , the condition of Fredholmness of the diagonal 1 blocks of the operator ( 1 . 1 ) with compact blocks outside the diagonal i s s u f f i c i e n t f o r the Fredholmness of the operator
A i t s e l f . In the
general case, t h i s condition i 3 not necessary. A simple example i s provided by the operator of two-sided s h i f t of i n f i n i t e m u l t i p l i c i t y acting in a Hilbert space f j . This operator i s i n v e r t i b l e , but,decomposing ^ in a suitable manner in an orthogonal sum, i t can be represented in the form(1.1), where
At a = 0
and
An
i s the operator of one-
sided s h i f t with an i n f i n i t e dimensional kernel. In Chapter 4 we shall consider some examples in d e t a i l , which i l l u s t r a t e the same s i t u a t i o n , but are d i r e c t l y related to the subject of the present book. QOROLIiARY 1 . 4 .
Let the Banach space
8
be represented as the d i r e c t
sum of i t s 3ubspaces operator Pj
( j = 1 , . . . , k ) in such a way that the u commutes up to a compact summand with any operator
A €[8]
projecting
8
on
8^
p a r a l l e l to the d i r e c t sum of the remain-
ing subspaces«
APuS - PuHA . Then f o r the Fredholmness of i s necessary and s u f f i c i e n t that the operators A - • = 0J u 3-i k ered in 8.= be Fredholm. In t h i s case ind A = £ ind "
Corollary 1 . 4 can be proved by induction on
k
A
it
consid-
0=1
with the help of
Theorem 1 . 1 2 . However, we do not intend to v e r i f y t h i s a s s e r t i o n , since the r e s u l t of Corollary 1 . 4 can be e a s i l y obtained d i r e c t l y and i s wellknown (see e . g . GOHBiiHG, KBiSIH [ 3 ] ) . As a r u l e , in the present book the role of the Banach space played by the space 26
L?(r)
(briefly
L^)
8
will be
of n-dimensional vector
functions given on the rectifiable contour is summable in the pth power
V , each component of which
(1 ^ p < »). in addition to the general
theorems given above, we need the following propositions connected with the specific nature of the space L^ . THEOREM 1.13 (M. RIBSZ-TORIH)» subspace
L^
If the operator
A«[L° ] maps the
(1 < p^ < p
P e(Pi»P03> to® operator
< oo) into itself, then, for all n A| Q belongs to the class [it-]. L P
The proof of this well-known theorem can be found, for instance, in KRASNOSEL1 SKli et al. [1]. Now we are going to explain the local principle of the theory of $redholm operators by changing the abstract local principle for Banach algebras described in Ch. 12 of the book GOHBERG, KRUPNIK [4] in an appropriate manner. The formulation of the local principle is premised by several definitions. We denote by by
R
C(r) (=C) the space of continuous functions on
the lineal of rational functions with poles off
DEFINITION 1.9.
The operator
T, and
T .
A e[Lp] is called an operator of
local type, if it commutes up to a compact summand with the operator of multiplication by an arbitrary function of class Since the lineal
R
is dense in
R .
0 with respect to the uniform norm
(see WALSH [1] p. 67), local type operators possess, for any the property
aA - Aal € if .
We denote the class of continuous functions on
r equal to one in some
neighbourhood (depending on the function) of the point DEFINITION 1.10. at the point a € 0t
a € C,
The operators
A, B
tQ(e r) , if, for every
such that
DEFINITION 1.11.
t € r by 0^..
are said to be equivalent e > 0,
one can find a function
|(A-B)al| < e , |a(A-B)| < e.
The operator B 1 (Br respectively) e[L°] is referre
ed to as a left (right) local regal arizer of the operator
A €[lp]
at the point
such that
t Q € r , if there exists a function
a €
al - B-L Aal £ ¿f (al - aABr 6 f ).
27
An operator point
t
A having a l e f t and a right l o c a l regularizer a t some
6 T will be c a l l e d l o c a l l y ffredholm at t h i s point,
THEOREM 1,14 ( I . B , SIMOKEHKO). Let t o r , I f we can, f o r every Iredholm at the point
t
point, then the operator Proof,
A e[L°]
be a l o c a l type opera-
t 6 T , specify an operator and equivalent to the operator
locally
A at this
A i s Fredholm,
Above a l l , we show that the existence of a right l o c a l regula-
r i z e r of the operator the operator
Aj. a t the point
t € r
and i t s equivalence to
A a t t h i s point imply that the operator
a l o c a l regulorization from the right at the point use that the operator Let
Aj.
Br
point
A a l s o admits
t . Here we do not
A i s of l o c a l type.
be a right l o c a l regularizer of the operator t
and
a1
be some function from
a t the
C^. s a t i s f y i n g the condition
a.,I - a^A^Bj, 6 cf , Due to the equivalence of the operators t , there e x i s t s a function
at the point
a2 G
A and
Aj.
with
< ||Br|| ^ , In other words, i t i3 possible to choose an operator
T €f
in such a way that
HaaCA-Aj.) + T|| < ||B r ||~ 1 , But then
||a a (A-A b )B r + TBr|| < 1 , The operator
K = I + a a (A-A^.)B r + TB r
by Theorem 1 , 5 , the operator Let
B0
i s Predholm, I + a^A-A^B
, and
a^. to be a non-negative function of c l a s s C^ equal to zero
hose points
Then
I + a a (A-A t )B r
be some regularizer of the operator
suppose at
i s i n v e r t i b l e , and consequently
t € T f o r which e i t h e r
a^ = a^a-i = a^a»
and, therefore,
a^t) £ 1
or
a 2 ( x ) £ 1,
a^I - a t AB p B o =
= a t I - a t ( I + (A-A t )B p )B 0 + a t ( l - A,jBp)B0 = a t ( l - ( l + a 2 (A-A f c )B r )B o ) + a^Cail - a 1 A t B r )B Q , Taking into account the compactness of the operators
I - ( I + a2(A-Aj.)B r )B o
the operator B
t
=
r o
B B
point
i s
a^.1 - a t AB r B 0 a
ri
and
a i l - a i A ^ j , , we deduce that
i a also compact, i . e . , the operator
S h t l o c a l regularizer of the operator
A at the
t ,
Using that
A i s an operator of l o c a l type, we show now how to con-
s t r u c t a "global" right regularizer from i t s right l o c a l ones.
28
The neighbourhoods
U^
of the points
t € r
in which the functions
Gi_ are p o s i t i v e form an open covering of the contour r . We choose N N a f i n i t e subcovering {a,. }.= ,, from i t . Then the function a = E &+. ^ d D_n d=1 d i s p o s i t i v e at a l l points of the contour r . Hence the operator N . B = ( E ( L B + )a I i s well-defined. I t i s just the desired r e g u l a r i d=i ^ d z e r . Indeed, since A i s of l o c a l type, we have Aa^. I ~ a^ A and, d i) therefore, Aaj. B^ ~ a^ AB^ • But we have a^. AB^ ~ a^. I » which d d d d d d d implies ACEat B t ) a " 1 I = £ ( A i t B t ) a " 1 I ~ E (eu. l ) a ~ 1 I = I . d d d d d The existence of a l e f t regularizer of the operator
A
i s proved i n a
similar way (of course, from i t s existence we conclude that the r i g h t regularizer constructed above i s also a l e f t one). Owing to Theorem 1.8, there results the Fredholmness of
A .
=
We remark that the proof of the local principle described here can be l i t e r a l l y transferred to the case of operators acting in where
X
Lp(x) »
i s a compact Hausdorff space with measure.
This general case was considered in the fundamental work of the theory of l o c a l type operators by SIMONENKO [ 5 ] , where f o r the f i r s t time the notion of such operators was introduced and the l o c a l principle was proved. 1.2.
SOME INFORMATION ON BOUNDARY PROPERTIES OF FUNCTIONS ANALYTIC AND MEROMORPHIC IN FINITELY CONNECTED DOMAINS
Let us begin with the consideration of functions analytic in the unit disk
A = {£ * |£| < 1} . '-Che proofs of the results on such functions
formulated here can be found in Ch. 2 of the book of PRIVALOV [ 2 ] and in Ch. 5 of HOFFMAN [ 1 ] . DEFINITION 1.12.
Functions of the form
f ( * \ z ) = exp(iv + ^
/ ¿ g ^ " 5 i n k(e)de) , —u e - z
(1.7)
29
where
v
i s a r e a l constant and
k
a non-negative function Kith
summable logarithm, are said to be outer. Before formulating the theorem about properties of outer functions, we r e c a l l t h a t we understand by angular boundary values ( o r l i m i t s ) of the function
f
when the point THEOREM 1 . 1 5 .
a t the points z
tends to
t
t
of a contour the l i m i t
lim f ( z ) , z -* t along paths non-tangent to the contour.
Functions of the form ( 1 . 7 ) are analytic in
have a . e . on the unit c i r c l e angular boundary values
A and
f^e^(eie)
f u l f i l l i n g the condition
| f ^ e \ e i e ) | = k ( 6 ) . Every a n a l y t i c func-
tion not having zeros in
A with a continuous bounded logarithm i s
an outer function. The c l a s s of a l l functions analytic and bounded in
A i s denoted by
Hg . According to Fatou's theorem, the angular boundary values e x i s t a . e . on the c i r c l e f o r any function from DEFINITION 1 . 1 3 .
A function from
H^ .
H^ , the angular boundary values
of which are a.e* equal to one, taken absolutely, i s c a l l e d inner. In p a r t i c u l a r , Blaschke products, i . e . functions of the form ,
B(z) = z 1
oo a t a, - z n ~7 ^ _ , k=1 |ak| 1 - afcz
are inner functions, where a sequence of points from
1
i s a non-negative integer and
A with
product vanishes a t the points
a^,
{a^}
is
£ ( l - | a^.1 ) < » . a Blaschke and, in case
1 > 0 , at
z = 0
and only at these p o i n t s . An example of an inner function not having zeros in
A i s provided by
the function S ( z ) = exp(- ^ where
|i i s a singular ( i . e . concentrated on a s e t of Lebesgue measure
zero) measure on THEOREM 1 . 1 6 . form 30
/ *n(e)) , —u e —z
. Such a function i s referred to as singular. Any inner function
f i * ) a ABS , where
B
f^^
can be represented in the
i s a Blaschke product,
S
i s a singular
f u n c t i o n and
\
i s a constant
(|X| = 1 ) . Such a r e p r e s e n t a t i o n
is
unique. DEFINITION 1.14-,
All f u n c t i o n s r e p r e s e n t a b l e i n the form o f a
q u o t i e n t o f a f u n c t i o n from THEOREM 1 . 1 7 , class
D
A function
Hw f
t o an o u t e r f u n c t i o n form the c l a s s D.
not i d e n t i c a l l y zero belongs t o t h e
i f and only i f i t can be r e p r e s e n t e d i n t h e form o f a
product o f an o u t e r by an i n n e r f u n c t i o n « Such a r e p r e s e n t a t i o n u n i q u e . Outer f u n c t i o n s and only t h e y belong t o t h e c l a s s g e t h e r with t h e i r r e c i p r o c a l
Hp,
'^he f u n c t i o n
0 < p < 00 , sup
D have a n g u l a r boundary v a l u e s
circle.
DEFINITION 1 . 1 5 « class
to-
ones.
I t i s evident t h a t functions of c l a s s a . e . on the u n i t
D
is
f
analytic in
A
belongs t o t h e
if
/^If(reie)|p
a e < 00 .
r < 1 -it
We note t h a t , f o r any f u n c t i o n
f
(1.8)
analytic in
A ,
M ^>(r) =
/ I f C r e 1 ® ) ! 1 * d6 i s a non-decreasing f u n c t i o n o f r . Consequently, -n c o n d i t i o n ( 1 . 8 ) i s e q u i v a l e n t t o l i m M .p(r) < 00 o r , what i s t h e r-»1-0 p > 1 same,
sup M f ( r i r ) < 00 , where
{rk}
i s an a r b i t r a r y sequence o f
p o s i t i v e s c a l a r s tending to one from below. The c l a s s e s
Hp
with
0 < p < 00 a r e c a l l e d Ifardy c l a s s e s . The r e l a -
t i o n between Hardy c l a s s e s and the c l a s s
D i s e x p r e s s e d by the f o l l o w -
ing theorem. THEOREM 1 . 1 8 ( P . Y a . POLUBARINOVA-KOCHINA). A
belongs t o the c l a s s
the f u n c t i o n
f(k)
Hp
COROLLARY 1 . 5 ( V . I , SkURHOV). then
f
i f and only i f
defined i n f € D
and
made up o f i t s angular boundary v a l u e s on the
c i r c l e belongs t o the c l a s s
p^ > p ,
( 0 < p < 00)
A function
Lp . If
f 6 Hp
and
L^
f o r some
f e
L e t J 0 be a simply connected domain i n t h e extended complex p l a n e , boundary o f which i s a c l o s e d r e c t i f i a b l e Jordan curve
the
T .
31
DEFINITION 1.16.
We shall say that a function
i s an element of the class
D
rk
analytic in &
) , 0 < p < oo , i f i t i s possible
to f i n d an expanding sequence of domains boundaries
f
with r e c t i f i a b l e
such that:
U r k C £> ,
2)
u f i = i ) k K sup J |f(t)|P|dt| < co . krk
3)
The classes
Ep(-© )
Smirnov classes LAVBENT'EV. In curves disk A
are called Smirnov classes. This d e f i n i t i o n of
E^O© ) SMIHNOV1
was suggested by M.V. KELDYSH and M.A. s original definition i t was required that the
are images of a c i r c l e under a conformal mapping of the onto the domain
. The definitions of KELDYSH/LAVRSNT'ev
and SMIHNOV are equivalent (concerning this topic, see DANILYUK [ 6 ] p. 91, GQLUZIN [ 1 ] p. 423 and PRIVALOV [ 2 ] p.. 203). Consequently, the following c r i t e r i o n of the membership of functions to Smirnov classes holds. THEOHBM 1.19.
'•'•'he function
cp defined in a simply connected
domain £) belongs to the class = q> « 0)
i f and only i f the function
belongs to the Hardy class
H^ . Here by
u
a func-
tion i s denoted, which r e a l i z e s the conformal mapping of the disk onto the domain £) , and root of
u)1
continuous in
A
i s an arbitrary branch of the pth A .
Below we shall be concerned with functions analytic, generally speaking, in a multiply connected domain J0 + * I t i s assumed that this domain i s obtained from a bounded simply connected domain JB + (0) pairwise d i s j o i n t simply connected domains £
+(o)
lying inside i t . The boundaries of the domains
by removal of
( j = 1,...,m-1) ( j = 0,...,m-l)
are supposed to be Jordan r e c t i f i a b l e curves. We denote by 2) " ( j ) the m-1 complement to S ( d ) U r ( j ) . The contour r = U r ( j ) i s assumed to be oriented in such a manner that at an anticlockwise revolution along i t the domain
32
i s on the l e f t .
LEMMA 1.1»
Every f u n c t i o n
f
+
a n a l y t i c i n t h e domain
admits
a unique r e p r e s e n t a t i o n * ( • ) = " e V 0U ) d=o where t h e f u n c t i o n £. u Proof.
Set
« € z>+ ,
are a n a l y t i c i n J2)~( j )
£,(2) = J cm
v
J
£(t)
T.-a
which i s o r i e n t e d i n the same way as t h a t i t borders t o g e t h e r with i n 2)
+
(1.9)
i a a n a l y t i c i n £ ) + ( 0 ) , and the f u n c t i o n s
£
(j = 1,...,m-l)
,
,
and vanish a t i n f i n i t y .
where the contour
r ( j ) , i s chosen i n such a manner
r(j)
a doubly connected domain l y i n g
and not containing the p o i n t
z . Clearly,
y., _
b u t , i n view of Cauchy's i n t e g r a l theorem, the value depend on the choice of
Yj
a
•
y . „ (c.©*"), ~(k) UJZ> U.S (k) , i . e . i n the e n t i r e complex p l a n e . Since, i n a d d i t i o n ,
f ^ i 0 0 ) = 0 , we can conclude t h a t
L i o u v i l l e ' s theorem. But then we have tion
fQ
f „0 ( z ) = -
m-1 E f>(z) = 0 k=1 K
for
f k = 0 , by
z
. Thus, the f u n c -
i s a l s o i d e n t i c a l l y equal t o zero i n J 0 + ( O ) . This proves t h e
uniqueness of the r e p r e s e n t a t i o n i n the form ( 1 . 9 ) f o r Hence IAmma 1.1 has been proved.
f(z) = 0 .
=
In what f o l l o w s , we need a g e n e r a l i z a t i o n of the Smirnov c l a s s e s t o the case of m u l t i p l y connected domains. DEFINITION 1.17 (KHAVINSOH h i ) . m-connected domain JB
+
The f u n c t i o n
belongs t o c l a s s
£
a n a l y t i c i n the
+
if
Ep(«S ) (0 < p < oo)
and only i f t h e r e e x i s t s an expanding sequence of m-connected 33
domains
s a t i s f y i n g c o n d i t i o n s 1 ) - 3 ) of D e f i n i t i o n 1 . 1 6 and,
moreover, the requirement 4-) t h e l e n g t h s
| r k | of the c o n t o u r s
THfiOBBM 1 , 2 0 (Decomposition t h e o r e m ) . the m-connected domain £>
+
rk
a r e equibounded.
The f u n c t i o n
belongs t o the c l a s s
f
analytic in
B^(«© + )
i f and
only i f t h e f u n c t i o n s
f • from t h e r e p r e s e n t a t i o n ( 1 . 9 ) f u l f i l t h e u f „o €p E ( i & ( 0 ) ) , f ,J e E pj . S ~ ( d ) ) , j = 1 , . . . , m - 1 . +
conditions Proof.
f € Ep (,8 + ) . We r e p r e s e n t t h e boundaiy
Let
o c c u r r i n g i n D e f i n i t i o n 1 . 1 7 i n the form rk(d)
rk
r k of the domain m-1 = U I ^ Q ) , where j=o
i s a c l o s e d c u r v e , which b o r d e r s t o g e t h e r w i t h
connected domain l y i n g i n «0
+
r(d)
a doubly
. According t o e q u a t i o n ( 1 . 9 ) and
Minkowski's i n t e g r a l i n e q u a l i t y , t h e f o l l o w i n g r e l a t i o n holds» 1
f | f d ( T ) p | d T | < (( E I lf1(T)|P|dT|)SSETO7 1 r kK( d ) 3 i?d r K ( d ) k 1 + (
S
rk(d)
if(T)|P|dT|)5SE^P^)ma3C(l'P)
Denoting by f^
(1.10)
•
t h e upper bound of t h e a b s o l u t e v a l u e of the f u n c t i o n
i n the domain
f ^ , on t h e s t r e n g t h of t h e maximum modulus p r i n c i -
p l e , we can claim t h a t i t i s a l s o an upper bound f o r
|f("E)| f o r
T € r k ( d ) (d + 1 ) . T h e r e f o r e ,
Moreover,
/
|f(-c)|
rk(d) t o the c l a s s
p
|
describing a confonnal mapping of the disk on a domain with r e c t i f i a b l e boundary, always belongs to the c l a s s
H.,
(see PRIVALOV [ 2 ] p. 173,
DMILYUK [ 6 ] p . 88, GOLUZIN [ 1 ] ) . Now condition 3 ) can be r e a d i l y v e r i f i e d in the same manner as i t was done above f o r the function f J• . Consequently £ € Ep(JiD + ) , which completes the proof of the theorem. = In TUMABKIN, KHAV1NS0N [ 1 ] i t was shown t h a t the omission of condit i o n 4 ) in Definition 1.17 does not lead to an extension of the notion of c l a s s e s
Kp
in f i n i t e l y connected domains ( f o r a simply connected
domain t h i s f a c t i s a consequence of Theorem 1 . 1 9 and the r e l a t i o n o)' 6 H 1 ) . In other words, Definition 1 . 1 6 can be used f o r a r b i t r a r y f i n i t e l y connected domains1 This allowed f o r considering Smirnov c l a s s e s in Jordan domains with n o n - r e c t i f i a b l e boundary. For such domains tjie decomposition theorem does not hold as i t was c l a r i f i e d in TUMARKIN, KHAVINSON [ 2 , 3 ] . She c l a s s of a l l functions analytic and bounded in some domain 2) w i l l be denoted by
2^(2) ) .
In what follows, we s h a l l simply write whereas
E~ P
Bp
instead of
E p (JD + ) ,
denotes the c l a s s of functions defined on the s e t m-1
ST => JEf*(0) u^y,, J © + ( o ) ) , the r e s t r i c t i o n of which on £>"(0) r e s p e c t i v e l y ) i s a function of c l a s s class
c o n s i s t s of functions from
Ep(je) " ( 0 ) ) E~
(£>+( j )
(E p (.& + ( j ) ) ) . The
vanishing at i n f i n i t y .
I t i s c l e a r from the proof of Theorem 1 . 2 0 that the system of domains^ -
Note t h a t in the monograph DUREN [ 1 l the problem of description o f multiply conneoted domains f o r which Definitions 1 . 1 6 and 1.17 are equivalent i s referred to as an open one. 35
occurring i n D e f i n i t i o n 1.17 can be chosen as one and the same f o r a l l functions o f a Smirnov c l a s s . Hence, applying Minkowski's and H&lder's i n t e g r a l i n e q u a l i t i e s in a standard manner, we can e a s i l y derive the following result. THEOREM 1.21. 2)
f o r any
1) pif
The c l a s s e s
1
and
B~
are l i n e a l s ,
p a €(0,oo] , Pi < p* , the i n c l u s i o n s
h°ld' ®Pi 2 BPa 3) i f f € B^ (S^)
P = (PT 1 + p T
B*, E~
r
1
,
g e
(E^)
, then
E^ o E^
,
f g 6 B j ( E ~ ) , where
.
More profound p r o p e r t i e s of functions from Smirnov c l a s s e s are gathered below i n Theorems 1.22, domain JD
+
1.24, 1.25. For the case
of a simply connected
, the arguments of these theorems can be found i n the mono-
graphs GdLUZIN [ 1 ] , DMILYUK [ 6 ] , PRIVALOV [ 2 ] . With the help of the decomposition theorem 1.20, these theorems can be t r a n s f e r r e d t o the more general case of a f i n i t e l y connected domain i n an obvious manner 1 > f which j u s t i f i e s the r e f e r e n c e s t o GOLUZIN [ 1 ] , DANHYUK [ 6 ] , PRIVALOV [ 2 ] b e f o r e the formulations o f Theorems 1.22, 1.24, 1 . 2 5 . THEORiiM 1-.22 ( s e e PRIVALOV \2~\ p . 204. DANILYUK T6l p . 91. GOLUZIN M l P» 4 2 2 ) . p > 0 , has l i m i t s
f+(t)
almost a l l p o i n t s on
T
of the c l a s s
The f u n c t i o n
f u n c t i o n of c l a s s cide with
f
f+
We denote by i n the form
M^ ( =
( f ~ ) , which i s d e f i n e d L^ .
defined a . e . on
L * ( L ~ , L ^ ) , 0 < p < co , i f \ + / — Bp
( B p , E^)
a t almost a l l +
f
B* ( E ~ ) ,
along a l l non-tangent paths at
t 6 r . The f u n c t i o n
belong t o the c l a s s
36
(f~(t))
f
by these l i m i t s , belongs t o the c l a s s
DEFINITION 1.18.
-
Every f u n c t i o n
r
we assume t o
there e x i s t s a
the boundary values of which c o i n -
t 6 r
.
+ + R)
f = f, + f,
the c l a s s of functions
, where
f< 6 if"
and
f
representable
f,€ R .
Concerning t h i s t o p i c , see UMARKIN, KHAVTNSON [ 3 ] , where Theorem 1.24 i s formulated ( i n p a r t i c u l a r , on p . 7 3 ) f o r the case of a f i n i t e l y connected domain.
+ + If" + R , If" + C axe introduced in a similar way* SomeP P + + times i t w i l l be convenient to use the notations L~ = U L~ , + + P > 0 p 1T= U i C . p > 0 P Beginning with Chapter 2, we s h a l l , as a r u l e , not deal with s c a l a r + + functions from c l a s s e s , L^ , e t c . , but with n-dimensional vecThe c l a s s e s
t o r functions and
oxa matrix functions, the elements of which belong
to these c l a s s e s . We denote by
X°
the space of n-dimensional v e c t o r
functions, the components of which belong to some function c l a s s ( i n the case
X = L^ , t h i s notation was already used in Section 1*1)•
I t would be natural to denote t&s c l a s s of elements from
X
X by
nxn matrix functions with
• However, we renounce t h i s notation, since
i t i s too troublesome. Instead, the c l a s s of such matrix funotions i s simply denoted by
X . From the context i t w i l l be always c l e a r whether
we speak about a s c a l a r or a matrix function* + Vector functions of the c l a s s (E^ + R) can be reproduced from t h e i r l i m i t s on tions
r
in a unique manner. L e t us show t h i s . I f the vector func+ and f t from the c l a s s (S^ + R) have angular l i m i t s
f1
coinciding a . e . on
r , then t h e i r difference f a f , - f , i s also a + vector function from (Ei^ + R) and has angular l i m i t s equal to zero a . e . on
r . But in view of the following uniqueness theorem, t h i s i s
possible only f o r
f = 0 .
THEOREM 1 . 2 3 (PRIVALOV f2l p. 292, GQLUZIN M l p. 4 1 3 ) .
A function
meromorphic in a domain with r e c t i f i a b l e boundary, which has singular l i m i t s equal to zero on a s e t of p o s i t i v e l i n e a r measure, i s i d e n t i c a l l y equal to zero. Taking into+ account the +i n a c t i v i t y of the correspondence between + + c l a s s e s B~" + R and If" (respectively between E and L J), we some— r
Jr
^
Jr
jr
times shall i d + e n t i f y vector functions from (E~p + R ) a with vector func* t i o a s from foimed by t h e i r l i m i t s . + a + In p a r t i c u l a r , i f f e ( ^ ) , under f ( z ) , z € SB ~ we s h a l l simply understand the value a t the point
z
of t h a t vector function o f c l a s s
(E~ + R ) a , the boundary value of which i s
f . In connection with t h i s , 37
note that the i d e n t i f i c a t i o n of functions of class ing functions of class
L*
H^
with corresponds
on the c i r c l e i s in general use. For the
l a t t e r class even the notation
Hp (or
H*)
i s preserved (see HOFFMAN
[ 1 ] ) , For the sake of uniformity, the class L~ on the c i r c l e i s denoted by
H~ . Clearly, a l l the assertions of Theorem 1.21 may be transferred + + n ± n ±n
from the classes the product
fg
to classes
+ R)
, (Lp)
and
(M p )
, if
i s defined componentwise.
In the classic case of functions analytic in a domain and continuous up to the boundary, the values in the domain are expressed v i a boundary ones with the aid of Cauchy's i n t e g r a l . This method cannot be transferred d i r e c t l y to the case of classes
+
for
p < 1 , because a
i s not summable. However, f o r functions from the boundary function + classes
B1 , Oauchy1s integral remains to be a natural means of con-
tinuation from a contour to a domain. THEOREM 1.24 (PRIVALOV f2l pp. 202. 206, DANILYUK T6l p. 133, SQLUZIN f l l pp. 420-423)» The vector function f defined on belongs to r
(l«t)n
J f (t)
=0
((i" .
In accordance with Theorems 1.24 and 1.22, any vector function the class
(Lp) Q
((£~)a)
»
P > 1
l i e s in the subspace of
of a l l functions satisfying (1.11) and, f o r
f
consisting
p = 1 , coincides with i t .
Corollary 1.5 shows that f o r the c i r c l e the coincidence holds f o r
38
of
p > 1 , too* To c h a r a c t e r i z e the s i t u a t i o n i n g e n e r a l , we introduce another d e f i n i t i o n « DEFINITION 1.19 (aee PRIVALOV [2~\ p . 250. DANILYPK f6~l p . 90)» A simply connected domain Jb i s c a l l e d Smirnov. i f t h e d e r i v a t i v e of the f u n c t i o n
u> , which maps
A conformally on £> , i s an o u t e r
function. A closed Jordan curve f
w i l l be c a l l e d Smirnov (curve of c l a s s C),
i f each of the domains i n which T decomposes the extended complex plane i s Smirnov. The c l a s s of Smirnov ourves i s so wide t h a t i t i s r a t h e r d i f f i c u l t t o c o n s t r u c t examples of ourves not belonging t o t h i s c l a s s . ? o r t h e f i r s t time, such an example was b u i l t by M.V. KBLDYSH and M.A. LAVEENT1 EV. Their c o n s t r u c t i o n , with some s i m p l i f i c a t i o n s , i s described i n PRIVALOV [2] pp. 229-250. ^n a n a l y t i c d e s c r i p t i o n of a l l non-Smirnov curves the i n t e r e s t e d reader can f i n d i n DUREN, SHAPIRO, SHIELDS [ 4 ] . Various s u f f i c i e n t conditions of membership of curves t o t h e Smirnov c l a s s are e s t a b l i s h e d i n PRIVALOV [ 2 ] pp. 250-257» I n p a r t i c u l a r , one can f i n d there LAVRENT1 EV1 s r e s u l t t h a t a curve i s Smirnov as soon as
(1.12) Here along
s(t1,t2)
i s the distance between p o i n t s
t1
and
tt
measured
T .
THEOREM 1.&5 (PRIVALOV [ 2 ] pp. 26^-266. DANILYUK T6l pp. 92-95). I f the contour
r c o n s i s t s only of Smirnov curves, then, f o r
0 < Pi < Pa < « , the e q u a l i t i e s ) Q = (Lp ) n H we have
f € (L*)
a
( L p f ) n =* ( i ^ ) n H
and
are v a l i d . E s p e c i a l l y , i n case t h a t ((£~)
a
r e s p e c t i v e l y ) i f and only i f
p > 1
f €
and
condition (1.11) i s f u l f i l l e d . I f a t l e a s t one component of t h e contour
r
such t h a t
i s not a Smirnov curve, then there e x i s t s a f u n c t i o n f € L i (£7) » b u t
f f L* (£~)
Due t o Theorem 1.25, i n t h e case of a contour curves, the l i n e a l s
(L*)
n
and
(L~)
n
for all r
f € L00
p > 1.
c o n s i s t i n g of Smirnov
are subspaoes i n
L a . In f a o t , 39
this assertion i s true f o r every r e c t i f i a b l e contour
r , however, the
corresponding argument requires some preliminary constructions, which we are now going to deal with* We shall i d e n t i f y the space q. = p/(p - 1 ) )
f =
with the dual to --
E e L^ , 0=1 3 0 p
g =
L^
form (1.13) ( i . e . satisfying the condition - D)
(1.13)
E g^, e . 3=1 3 0 , Lp r ja1 J where
n f =» E f -¡ 6 h 3=1 3 3
and
e., 3
denotes the j th unit vector.
THEOREM 1.26.
The orthogonal ( i n the sense of the form ( 1 . 1 3 ) )
complement to
(Lpn
Proof. If
((L~)a)
coincides with
(L*)a
((L~)Q) .
Obviously, i t i s s u f f i c i e n t to prove the statement f o r
f € L* , g € L* , then we deduce
f g € h*
and
= 0 for all , «— k g e Lp ( L p ) . Setting g ( t ) = t , where k i s a non-negative (negative) integer, we obtain + means that i e l i
r
/ f ( t ) t k d t = 0 . According to Theorem 1.24, this (Li) .
The following considerations are f i r s t made f o r the case of a simply connected domain £) + . Suppose that the function formal mapping of the unit disk onto T = W(G)
40
the condition
/ f(T)g(x)dr = 0
r
CD realizes a con-
. A f t e r substituting can be rewritten as
/ *(»(£)) i-^Ts) s(»(5)) P V+(0))
the boundary value on
r
fQ
i s the
.
taking as
g
of functions from the class
Ep(J2T( j ) )
and acting by the scheme described, we can state that
i s in f a c t the boundary value of a function from By Theorem 1.20, this just means that
f^
•
f € L* . Thus, also in case of
a multiply connected domain the orthogonal complement to L* i s the + o_ L^ • Analogously, the assertion concerning the classes L^ , oclass . L^
allow to be transferred to the case of multiply connected domains.^
COROLLARY 1.6. For any p €[1,oo] , the sets spaces in Lp . Indeed, f o r
p €(1,oo] , ( L p )
((L~) )
( L p a , (L~) a
are sub-
is the orthogonal complement to
some lineal and i s therefore a subspace. The closedness of the classes (Lt)a
and
(li7) n
THEOREM 1.27.
already mentioned. Let the vector functions
coincide a.e. on some arc
6(wtf)a
and
€ (M7)a
y c r . Then each of these vector functions
i s the analytical continuation of the other through
y .
+
Proof.
By definition of the classes
tions
= cp+ + r 1 f
In i t s turn,
r^ = r^
+
=_9~ + r a
with ±
- r^ , where
r^
with poles concentrated in £> functions
and
functions classes
and
(l7)D
1
then i t contains
.
£ ® as a proper
p a r t . However, f o r our p u r p o s e s i t i s c o n v e n i e n t t o c o n s i d e r t h e operators
S , P
and
Q i n t h e spaces
L^ , assuming t h e i r domains of
d e f i n i t i o n t o be t h e l i n e a l X, ^ , i r r e s p e c t i v e of t h e n a t u r e of t h e contour
r . H e n c e f o r t h we s h a l l do s o .
THEOREM 1 . 3 1 . 1)
The o p e r a t o r s
S, P
c l o s e d and, f o r 2)
the operators
and
Q studied i a
(1 < p < oo)
are
p < co , d e n s e l y d e f i n e d , S (P, Q)
and
- S (Q, P )
c o n s i d e r e d i n t h e spaces
L^ and (1 < p < oo, q = p / ( p - 1 ) ) , r e s p e c t i v e l y a r e a d j o i n t f H t o each o t h e r i n t h e sense of D e f i n i t i o n 1 . 6 , 3)
4)
the operator
S
idempotent:
2
S
f o r the function
i s i n v o l u t o r y , and
P
2
= I|
a s well as
Q
are
2
, P = P , Q* = Q , *P 9 6 - i 2 p the e q u a l i t y
( S 9 ) 1 = 2S(fSq>) - +
Thus
< Sf,g
-
... > x j ^
,
€ M* , and the number o f zeros of
det
c a l c u l a t e d with regard to t h e i r m u l t i p l i c i t y i s equal t o
G ^
d•
Obviously, such r e p r e s e n t a t i o n s e x i s t . We s h a l l obtain one o f them by introdmcing the s c a l a r r a t i o n a l f u n c t i o n and p o l e s o f which are concentrated i n
f
of index
P+(G)
the zeros
«8+ , where we suppose t h a t
fG e L^ . Furtheimore, we s e t = fG , where
A
« ( t )
= t'P+C
,
G
W(z) =
N i s the number o f zeros of the function
I ,
f(z)
det(fG)
i n Jb
In v i r t u e of the f a c t t h a t t h i s f u n c t i o n has no p o l e s i n «S
+
(2.17) +
.
, N may
be c a l c u l a t e d as f o l l o w s : N = ind + det ( f G ) = n ind f + i n d + d e t G = n P + ( G ) + ind + det G . Now we d e s c r i b e the procedure of "zero separation" of
det G ^ ^ , which
permits, f o r a given r e p r e s e n t a t i o n ( 2 . 1 6 ) o f the m a t r i x f u n c t i o n a r e p r e s e n t a t i o n o f p r e c i s e l y t h i s type but with an index by one. S t a r t i n g from the r e p r e s e n t a t i o n ( 2 . 1 6 ) of formulae ( 2 . 1 7 ) f o r
j = Ii
r
G
for
j = 0 , i.e.,
smaller
defined by
and applying t h i s procedure
get a r e p r e s e n t a t i o n ( 2 . 1 6 ) o f of t h i s m a t r i x f u n c t i o n i n
G
j
G ,
N times, we
a factorization
L^ .
fhe procedure mentioned c o n s i s t s in the f o l l o w i n g ; For a given m a t r i x
function
G ^ ^ from the r e p r e s e n t a t i o n ( 2 . 1 6 ) and an a r b i t r a r i l y chosen
zero
of the f u n c t i o n
z„o function By
70
wSj
U
det G+^ ^ i n as i n d i c a t e d in Lemma 2 . 1 .
\...
^
,' we c o n s t r u c t a m a t r i x
we denote the t u p l e obtained by ordering the
sequence
....»«¡¡¿j »
+ 1 , •^i»***»*^
i a
a
aon-increasing
manner. I t i 3 c l e a r that such an ordering can be carried out with the help of one transposition permuting the k th element of the sequence with the 1 th one ( l < k ) . By
T^)
we
denote the matrix obtained
from the unit matrix a f t e r permutation of the columns with the same numbers. Then, s e t t i n g
= diag[t H *
= T 1/2
and p i q » / ( p i + q 2 ) > 1 / 2 , +1 thus, the elements of the matrix functions 7T are summable with e x -
ponent 1/2 . Consequently, t h e i r poles lying on I f , in p a r t i c u l a r ,
1
T must be simple.
i s the triangular polynomial matrix function
occurring in the converse statement, then a l l roots of i t s diagonal 79
elements must be simple. The number of different roots of therefore, between
- [-|*
(1)
V a ]
- x^ 2 ^|/n)
greater than or equal to For
- J
2
det Y
lies,
(i .e. the smallest integer and
|x( 1 ) -
n = 1 , the first value is precisely equal to
-
2.5. COMMENTS The factorization of the type (2.1) as well as the notions of partial and total indices, under classical assumptions concerning the matrix function
G
and the contour
r , where introduced in the paper of
MUSKHKLISHVILI and VEKUA [1] (see also the monographs N. VEKUA [4], MUSKHELISHVIL1 [1]). Factorization in
was first studied by PRIVALOV [1], for a review
of subsequent results, see KHVEDELIDZE [1]. The right-factorization was presented for the first time in GOHBERG, KHEIN [ 3 ] . It would seem that the first detailed study of the relations between the factorization of one and the same matrix function for different values of the parameter
p
is accomplished in the present book.
Theorems 2.1 and 2.3 were formulated in SPITKOVSKII [2]. At the same place the notion of the factorability domain was introduced. Corollary 2.1 is usually called the invariance theorem for partial indices (see N. VEKUA [4], GAKHOV [3], MUSKHELISHVILI [1], SIMONENKO [4]), Theorem 2.2 on the connections between factorizations with one and the same total index was actually proved in MUSKHELISHVILI, VEKUA [1] (see also GOHBERG [4]). For the factorization of power functions, see VEJOJA [4], GAKHOV [ 3 ] , GOHBERG, KRUPNIK [4]'. The method of "splitting off zeros™ was first applied to the factorization problem by GAKHOV [1-3]« The factorization problem for rational matrix functions (Theorem 2.9) was solved by N.P. VBKUA [1] (see also N. VBKUA [4]), and for matrix functions of the type (2.11) with Holder factors
A^
(up to T) by GAKHOV. In a spezial case, the latter problem
was studied by N. VEKUA, KVESELAVA [1,2] and SHERMAN [1]. The general
80
Theorem 2.10 has been proved here, i n p r i n c i p l e , by the same method as was used by GAKHOV f o r the r e s u l t mentioned above* Note t h a t a somewhat d i f f e r e n t procedure of constructing a f a c t o r i z a t i o n based on the preceding t r a n s i t i o n t o a matrix f u n c t i o n with constant determinant and with trigonometric polynomials as elements, has been r e c e n t l y proposed i n JONCKHEEHE, DELSARTE [ 1 ] , This a p p l i e s , i n p a r t i c u l a r , t o r a t i o n a l matrix f u n c t i o n s with z e r o partial In Ch.
indices. 1
of
CEEJABOBX,
GOHBERG
[3]
formulae are presented which express
the p a r t i a l i n d i c e s of r a t i o n a l matrix functions by s p e c t r a l data of the m a t r i x polynomial corresponding t o i t . For more r e s u l t s in t h i s d i r e c t i o n we r e f e r t o
BART,
GOHBERG,
KAASHOEK
of a matrix f u n c t i o n of the kind ( 2 . 1 1 ) , i f l i n e and
det
A+
[1-3].
The f a c t o r i z a t i o n
the contour
are e n t i r e f u n c t i o n s , was considered in
r
i s the r e a l HURD [ 1 ]
in
connection with a p p l i c a t i o n s t o problems of determining a s t a t i o n a r y temperature regime. Theorems 2.6 - 2.8 and 2.11 are proved in SPITKOVSKII [ 1 3 ] ( s e e also SPITKOVSKli [ 2 ] ) . The estimates of the p a r t i a l i n d i c e s e s t a b l i s h e d i n «/
r
n
these theorems g e n e r a l i z e r e s u l t s o f NIKOLAIOHUK |_1J obtained by him f o r the c l a s s i c a l case by the same method of "separating z e r o s " . The formulae f o r the t o t a l index stated in these theorems are analogues of the c l a s s i c a l formula of MUSKHELISHVILI ( s e e VEKUA [ 4 ] , MUSKHELISHVILI [ 1 ] ) , according t o which the t o t a l index of a non-degenerate Holder matrix f u n c t i o n i s equal t o the index of i t s determinant. For M u s k h e l i s h v i l i ' s formula and i t s extensions t o other c l a s s e s , we r e f e r t o Chapter 5 . Hemark that the formula f o r the t o t a l index and the n o n - n e g a t i v i t y of the p a r t i a l i n d i c e s of a matrix f u n c t i o n a n a l y t i c i n ^ uous i n «P + U r )
+
(and c o n t i n -
are a l s o presented in the a r t i c l e of GHEBOTAREV and
GAKHOV [ 1 ] . Theorem 2.12 i s published f o r the f i r s t t i m e .
81
CHAPTER 3. THE CRITERION OF FACTORABILITY. «-FACTORIZATION AMD ITS BASIC PROPERTIES la this chapter we shall study relationships between properties of the Riemann boundary value problem for a piecewise analytic vector function and the factorability of its coefficient, i.e. the matrix function
G .
It is well-known that in the classical case, if we seek for a solution of the Riemann problem with a Holder matrix G , the factorability of G
is equivalent to the Fredholmness of the boundary value problem.
The transition to the solution of the Riemann problem with measurable +
matrix function
G
in the Smirnov classes B~ leads to a new quality.
It turns out that the factorability of G , generally speaking, does not imply the Fredholmness of the corresponding boundary value problem. In fact, the vector-valued Riemann boundary value problem with a factorable matrix function classes L^
G
and the associate problem considered in the
and L^ , respectively, have finite defect numbers, and
the indices of the problems are opposite. However, these problems are, in general, not normally solvable, i.e. their images can be not closed. Nevertheless, these images are in a sense well-situated. More strictly speaking, the following weakened closedness condition is fulfilled! the image of the Riemann boundary value problem (and of the problem associate to it) contains all those rational vector functions belonging to its closure. Moreover, the factorability of the matrix coefficient of a Riemann problem in
is equivalent to the property described
above, a property intermediate between finiteness of the defect numbers and Fredholmness. This fact is the main result of Sections 3.1 and 3*2. In Section 3«3 it will be further stated that to guarantee the normal solvability and, thus, the fredholmness of the Riemann problem with factorable coefficient
G , certain two operators K
with the help of the factorization factors of G well as the projectors
P
and
Q
and K 1
composed
in a certain way as
have to be bounded in
. In order
to make the notions of Fredholmness of a boundary value problem and factorability of its coefficient equivalent, it is natural to confine the definition of factorization given in Ch. 2 by adding the requirement 82
of boundedness of the mentioned operators
K
and
K^
ia the space
. This special type of factorization ensuring the Fredholmness of the corresponding Riemann problem will be introduced in Section 3*4and called S-factorization. In what follows we shall almost always have to deal with just ^-factorization. The results of Sections 3.1 - 3«4 will be fonnulated and proved under the only suppositions that the contour is rectifiable. The matrix function G
is unbounded in general. In Section 3.5, the contour r
is,
in addition, assumed to belong to the class Si , on which, by the very definition, the operator of singular integration spaces Lp , 1 < p < oo . The condition the closed operator P + GQ matrix coefficient
1>
S
is bounded in the
r 6 % permits us to consider
instead of the Riemann problem with
G • This enables us to utilize the powerful appa-
ratus of operator theory for investigation. Here we shall demonstrate the necessity of the condition for P + GQ
G
€ L^
to be a $_-operator and the criterion of $-factorability
resulting from this fact. Finally, under the condition
G € L^ , in Section 3,6 we change over
from the examination of closed, generally speaking, unbounded operators to the study of bounded ones. It will be established that the problem of $-factorability of a matrix function
G
defined on a composite
contour can be reduced to the corresponding problem for its restrictions on the connected components of the contour»
$-factorability is
preserved and of local character if the images of the contours are smooth enough. In 3,7 comments for further reading will be given.
Incidentally, note that the equation (P+GQ)
]. 83
3.1.
ON SOLVABILITY OF THE RIEMANN BOUNDARY VALUE PROBLEM WITH FACTORABLE MATRIX COEFFICIENT
Let
S
be a m a t r i x f u n c t i o n of a t h o r d e r and
t o r f u n c t i o n both d e f i n e d on
g
a n-dimensional v e c -
r . The v e c t o r - v a l u e d Riemann boundary
value -problem i s s t a t e d i n t h e f o l l o w i n g way«
is a vector function, the j th component
is identically zero, if than or equal to
c. of which u and a polynomial of order less
K. > 0 9 u — k. - 1 otherwise. u
The general solution of the homogeneous problem (3-1) is deteimined by formula (3.6) with
(p* = cp~ = 0 . In other words, the " + "-component of
the solution of the homogeneous problem (3.1) is a linear combination (with polynomial coefficients of a certain degree) of the columns of the matrix function
G + , and its "-"-component is the combination —1 —"1
(with opposite coefficients) of the columns of
G_
with this, the matrix function taking the values and
G~^(z)
for
z
. In connection G+(z)
for
z
€«&+
is called a canonical matrix of the
problem (3.1). Analogously, the general solution of the homogeneous problem (3.2) is determined by formula (3«&' ) in which ty* =
= 0 .
It is easy to see that the pairs of vector functions (G + (z)
ea ,
- Gl 1 (z) A ~ 1 ( z ) z k e^}
(k = O.....-1+Xj,
89
where
j ranges over those indices for which x^ > 0) form a basis in
the space of solutions of the homogeneous problem (3.1)• In 'Hie space of solutions of the homogeneous problem (3.2) a basis is generated by pairs of the form where
{(G|)~1(z)zke.. , -Gl(z) A(z)zke.j} (k = 0,...,-1-x;J
j ranges over those indices for which x^ < 0).
From this and Theorem 3.1 we deduce the following result« COROLLARY 3.1» Let the matrix function G admit a factorization (2.1) in Lp . Then 1) the dimensions of the kernels of problems (3.1) and (3.2) can be calculated via the formulae n a, = E max{xj,o} , j=1
J
n aa ® ¡C max{- x.,0} j d=1
J
(3.8)
2) for the solvability of problem (3.1) it is necessary that, for all
d = 1,...,n with x. < 0 , the conditions u / (G^CtJsCtJJj, tkdt = 0 , k = 0,...,-xd-1
(3.9)
are satisfied; 3) for the solvability of problem (3.2) it is necessary that, for all
j = 1,...,n with x. > 0 , the conditions J
1 r/((G:r (t)h(t)).
tkdt = o ,
k = -x^.,.,-1
(3.91)
are valid. According to formulae (3.8), for n > 1 , both defect numbers a., and aa
may be different from zero, so that assertion 3) of theorem 3.1
cannot be transferred to the vector case (for n = 1 , foimula (3.8) in close agreement with assertion 3) of Theorem 3.1 shows that If the vector function G^g
= 0).
lies in ¿C!? (in view of assertion 1)
of Theorem 3.2 only this case is of interest), then condition (3.9) may be rewritten as follows« for those
j for which x. < 0 , the j th u component of the vector function Q(G~ g) has a zero of order not less than 1 - Xj at infinity.
90
The equivalence of the l a t t e r condition with condition ( 3 . 9 ) i s an immediate consequence of the following proposition. LEMMA 3.1.
*or a function
0)
and therefore, S (Q 1 , and x(t) = 1 otherwise). 1
®hen we have cp 6 and, by assumption, x®-i = B
) - zATB(zkcp) = cAe^ . Since the left-hand side of the
latter equation is the difference of two vector functions from we conclude from this that for
100
,
Ae^ e L^ . The relation obtained is valid
j = 1,...,n , which means
A €L
.
2)
Under the conditions
form
1 , ~
€ L^ . Now we choose the interval
Y = {e i6 J 2 1 ~ 2s -1 < | < 2 3 _ 2 s -1} . Then / k(6)pd6 = u(2 2 - 23 + s p .2 1 - 2 8 ) , / k(8)_qde a h(2 2 - 2s +s~ 4 .2 1 ~ 2s ) Y Y and -1- ( / k(e) p de) 1/p ( s k(er^e) 1 /«! = IYI Y Y =
2 ^ 1
.
(22-2S +
aP>2 1-2s ) 1/ P(2 2-2s + S -Q. 2 1-2 S ) 1/
c o i n c i d e with the images o f
Tp(G')
and
the
have the same property, which proves
Lemma 3.5« THEOREM 3 . 1 6 . class X
The m a t r i x f u n c t i o n
i s ^-factorable in
i s tfredholm i n the space kernel of operator indices of
G 6 L^
defined on a contour o f
i f and only i f the operator
P + GQ
L^ . In t h i s c a s e , the dimension o f the
P + GQ c o i n c i d e s with t h e sum o f p o s i t i v e p a r t i a l
G , the codimension o f the image i s opposite t o the sum
o f negative p a r t i a l i n d i c e s , and the index i s equal to the t o t a l index of
G . The operator
K + K1
(where
K
and
K1
are defined
by formulae ( 3 « 1 6 ) ) i s a two-sided r e g u l a x i z e r f o r the o p e r a t o r P + GQ . Proof.
Comparing a s s e r t i o n s 1 ) and 2 ) of Lemma 3 . 5 , we f i n d t h a t the
images o f the operators
P + GQ
(in
L^)
and
Q + G1P
(in
are
c l o s e d only simultaneously. Due to Theorem 3 . 1 , the i n d i c e s o f t h e s e operators sire a l s o f i n i t e only simultaneously. Consequently,
the
Fredholmness of one of these operators i s e q u i v a l e n t to the iredholmnesa o f the o t h e r . With regard to C o r o l l a r y 3.4-, t h i s enables us t o derive 117
the criterion of 4-factorability mentioned la the theorem. Taking Theorem 3.1 into consideration, the formulae for the defeot numbers of the operator
P + GQ
are obtained from relations (3«8).
Now we evaluate the product
K + K1
by
P + GQt
(K+Kn )(P+GQ) = (G~1 A ~ 1 < * v 1 + G + P&; 1 )(P + G + A 0 , we choose a matrix function
(G. .)!?"""] =„ ••-i) i f 0 '
by l a s s than
nant
of which s a t i s f i e s the r e l a t i o n
a(t)
s/2
it
G € L 00 .
d i f f e r i n g from
with r e s p e c t t o the noxm, the determia
€ L^
(by the induction
hypothesis, t h i s can always be done). Setting
G ±n = G ± a , G a j = GQ;j ( i , j = 1 , . . . , n - 1 ) , G a a ( t ) =
e ( t ) + G a a ( t ) , where |«(t)| = e/2 , arg C ( t ) = arg(det G ( t ) / a ( t ) ) , we have | det G ( t ) | = | det G ( t ) + a ( t ) « ( t ) | = | det G(t)| + | a ( t ) e ( t ) | > | | a ( t ) | . Since
—1 a € L^ , the matrix function
At the same time, THEOREM 3 . 1 8 . then Proof.
If
B~1
Let
AP + BQ s > 0
G a l s o belongs to c l a s s
||G - G|| < e , which proves Lemma 3 . 6 .
A" 1 ,
e x i s t s an
A
A , B € LM
and
AP + BQ
L ro .
=
i s a 4 + - or $ _ - o p e r a t o r ,
€ L^ . be a $ _ - o p e r a t o r . Due t o Theorem 1 . 4 ,
such t h a t i f
||A - A.JI < s , then
there
A^P + BQ i s a l s o
a $ _ - o p e r a t o r . In accordance with Lemma 3 . 6 , we may assume t h a t Ai
€ Lm . But then, along with operator
aT^CA^ + BQ) = P + a71BQ —1 the matrix function Therefore,
B
i s a l s o Fredholm. In view of Theorem 3 . 1 3 , —1
Ai
B~ 1 (= B ^ A . ^ 1 )
Furthermore, f o r
B € L^ ,
A1P + BQ , the operator
inverse to
A^ B
also belongs t o Q+ B
AP
belongs to the c l a s s L^ . Lw .
i s a «^-operator t o g e t h e r with
AP + BQ . Using Theorem 3 . 1 3 again ( t h a t p a r t r e l a t e d t o operators of the kind Q + GP), we observe t h a t A" 1 € L00 . If
AP + BQ
P + Ai BQ
A B € L^ . From t h i s we g e t
i s a $ + - o p e r a t o r f then arguing as above, we conclude t h a t
i s a # + -operator # In v i r t u e of Lemma 3*5 and Theorem 3«1,
Q + (Ai B) P
i s then a $ _ - o p e r a t o r .
The f u r t h e r argument i s t r i v i a l .
=
121
THEOREM 3.19. The operator
Let
A
and
AP + BQ
B
be
nxn
matrix function of class
is Fredholm in
and the matrix function
G = A
B
if and only if
is «-factorable in
case the kernel dimension of the operator sum of positive partial indices of
AP + BQ
A
-1
L^.
€ L^
L p . In this
is equal to the
G , and the codimension of the
image is opposite to the sum of negative partial indices. —1 Proof.
The necessity of the condition
A
€ L^
follows from the
preceding theorem. If this condition applies, then in view of the equality
AP + BQ = A(P + G Q ) , the operators
AP + BQ
and
P + GQ
are Fredholm only simultaneously and have the same defect numbers. To complete the proof, we have to apply Theorem 3.16.
=
Notice that the following condition will also be necessary and sufficient for the Fredholmness of the operator AP + BQ in the space n —1 Lp t B € Loo and the matrix function B A is «-factorable from the right in
Lp .
Theorems 3«16 and 3.161
serve as a chain link, with the help of which
results and methods of the theory of linear bounded operators can be used for the study of problems related to «-factorization. In particular, the stability property of Fredholmness under small perturbations (Theorem 1.4) leads to the next result. THEOREM 3.20.
If the matrix function
the left (right) in tion as
F
G € L^
, then, for some
is «-factorable from
e > 0 , the matrix func-
is also «-factorable from the left (right) in
||F - G|| < e , where the total indices of
F
and
L p , as soon G
coincide.
THEOREM 3.21. 1)
Let
T
and
L
be two simple smooth closed contours, and assume 0
to be a diffeomorphism of the contour function
G € L 00 „
(right) in in
122
Lp
Lp
defined on iff
T
L
onto
T . The matrix
is «-factorable from the left
GQ = G o 0
defined on
from the left (right), if
and from the right (left), if
0
first case the total index of
GQ
0
L
is «-factorable
remains the orientation,
changes the orientation. In the is equal to the total index
of
G , and in the second case it is opposite to it.
2)
Assume
r
curves
r• , and let
to be a closed contour consisting of
tion defined on
G
G^ , j = 0,...,m-1
matrix function defined on
in
G
Tj
L
and
P
Gq
GQ
is ^-factorable
Uj , j = 1,...,m-1 , are u
^-factorable from the right (left) in
of
G .
is ^-factorable from the left (right)
from the left (right) in
G
we denote the
and coinciding on it with
if and only if the matrix function
total index of
connected
be a measurable bounded matrix func-
r . By
'•Che matrix function
m
L^ . In this case the
is equal to the left (right) total index
minus the right (left) total indices of
G^t
0 = 1,...,m-1 . Proof. Lp(L)
1)
We introduce the operator
Lp(L)
Fredholm iff the operator ( W G W SQ
- 1
)
and
L°(r)
mapping from
by the rule (Wcp)(t) = 0
and
A^
are
t(€ r ) . a r b i t r a r i l y , we choose an arc
||G(t) - Gt(x)|| < ellQH""1
a way that
A
G w i l l be
G and
owing to the e - l o c a l equivalence of denote a function continuous on takes values from the i n t e r v a l neighbourhood of the point
y
a . e . on
r
Gt
y(s t )
in such
( t h i s i s possible at
t ) . By
a
we
which i s equal t o zero outside
[0,1]
on
Y > aid equals
1
y •
in some
t . Then we have
laCA-A^I < ||a(A-Aj.)|| = ||a(G-Gt)Q|| < ||a(G-Gt)||.||Q|| = ||Q|| ess sup||a(T)(G(T)-G t (T))|| < M - e s s sup||G(x)-Gt(T)|| < e . t€Y
Together with
« r
A
and
A^. , the operator
A - Aj. i s of l o c a l type.
As mentioned in Section 1.1, f o r any function the operator
f(A-A^) - (A-Afc)fl
f
continuous on
T ,
i s compact, In p a r t i c u l a r , we have
| a(A-A^.)| = |(A-A t )aI| and, thus,
KA-A^all < e.
Due to D e f i n i t i o n 1.10, the operators the poitrt
*
A
t , which proves Theorem 3*22.
and
A^
are equivalent at
=
A simple example of matrix functions e - l o c a l l y equivalent at a certain point
t
y i e l d those matrix functions which coincide a*e. in a neigh-
bourhood of t h i s point. Now we mention the e - l o c a l principle c o r r e sponding to t h i s special case. COROLLARY 3.9.
L e t the contour
T
be covered by the system
of open arcs. I f one can, f o r given
{y^}
G , s p e c i f y a c o l l e c t i o n of
matrix functions Gh(t) = G(t) u
G • € L „ which are ^ - f a c t o r a b l e in L such that G » p a . e . on Y-; » then G i s also ^-factorable in L_ • J
P
S u f f i c i e n t conditions of $ - f a c t o r a b i l i t y obtained v i a the e - l o c a l p r i n c i p l e w i l l be derived in Chapter 8. 3.7.
COMMENTS
The material explained in Section 3.1 - 3.5 i s , in p r i n c i p l e , taken from SPITKOVSKII [13,14]. The results of Section 3.1 generalize the
126
classical solution scheme for the Riemann boundary value problem
based
[3],
on factorization of its matrix coefficient (VEKUA [4], GAKHOV MUSKHELISHVILI [1], KHVEDSLIDZB [4]). Assertion 3 ) of Theorem 3»1 f under different assumptions on
G
ensur-
ing, however, its factorability, was mentioned in GOHBERG [1], SIMONBNKO [1,4], Its validity for an arbitrary function of class defined on the circle was, for arbitrary
L^
p = 2 , proved in COBURN [1] and, for
p €(1,oo) , in GOHBERG, KRUPNIK [ 3 ] .
The proof conducted
here is essentially that of COBURN [1], In connection with Theorem 3.2 we still refer to MEUNARGIYA [3], where the general solution of problem (3*1) is obtained in a foisn containing the values of the unknown vector function and its derivatives explicitly. Arguments close to those used in the proof of Theorem 3»4 the reader can find in GOHBERG, FjSLDMAN [ 3 ]
as well as in IDEMEN [ 2 ] ,
where the
case of rational matrix functions given on the circle is examined, but also in HEINIG [1], where a similar approach was used for the inversion N of operators A = a + £ b.Sc H generalizing (from case N = 1 ) opera0=1 3 a tors of the type AP + BG (see also HEINIG/ROST [1]). Theorems 3-5, 3.15, 3.15 1
are explained in SPITKOVSKII [6], The original
variant of Theorems 3.15 and 3.15 1
can be found in SPITKOVSKli
In the same paper the interpolation property of
[2].
factorability
(Theorem 3 . 9 ) was mentioned. In connection with this, we refer to the article KUCHMENT [1], in which the interpolation property of Fredholmnefis with the same index for an arbitrary linear operator acting and bounded in an interpolation family of Banach spaces was proved. The notion of ^-factorization of a bounded measurable matrix function in
Lp
is due to I.B. SIMONBNKO (for
p = 2, in SIMONENKO [3,4], for
the general case, in SIMONENKO [6]. L e m m a 3.5 and Theorems 3.16, 3.21, 3.22 are also due to him. In the case
n = 1 , the notion of ^-factorization, in principle can be
found also in DANILOTIC [1,2] and WIDOivi [1]. 127
The term "^-factorization" was proposed in SPITKOVSKII [2,13] and motivated by Theorem 3,16, according to which the operator
P + GQ
is
Fredholm, i.e., it is a ^-operator if and only if the matrix function G is SB-factorable. Notice that operators of the type
T^F) and
T^(F)
introduced at the
beginning of Section 3.6 are known in the literature as Toeplitz operators, and the matrix function
F
is usually called the symbol of the
corresponding operator. In this way, Lemma 3«5 allows us to reformulate all the assertions about operators of the kind
P +
and
Q + G'p
in terms of Toeplitz operators and vice versa. The results of some authors are
formulated for Toeplitz operators. Henceforth, we shall
refer to such results having in mind their analogues for the operators P + GQ
and
Q + G'P . y/
Theorems 3.6, 3.6' and 3.11 formulated in SPITKOVSKII [6] are a natural extension of Theorem 3*16 to the case of a rectifiable contour and a matrix function not necessarily bounded, whereas Theorems 3«13 and 3»14 are generalizations of corresponding results of SlivlOHENKO [4,6] from the case
G 6 L^ , r € %
Note that the requirement
renouncing the restriction
G € L^.
r { X can here also be omitted
(see SPITKOVSKII [14]). Actually, Theorem 3.13 in the scalar case with p = 2
was proved in WIDOM [1] and, for real-valued functions, in
HARTMAN, WINTHBR[1]. The boundedness criterion (3.21) for the operator with weight
e
S
in the space
L^
has been derived for the circle in HUNT, tíUCKBNHOUPT,
WHEBDEN [1] and, for a smooth contour, in KOKILASHVILI [1]. In the same paper the sufficiency of condition (3.21) in case of piecewise smooth curves was mentioned, whereas the necessity in case of piecewise Lyapunov curves was established in KRUPNIK [5]. Theorem 3«17 (on the $-factorability of power functions) is an auxiliary result for the theory of ^-factorization of piecewise continuous functions, with which we shall be concerned in Chapter 5. Appropriate references will also be given there. 128
Lemmas 3.4-, 3.6 and TheorenB 3.18, 3.19 are borrowed from KRUPNIK [3], Finally, we insert some remarks on results not mentioned in the present chapter, but being directly related to it. First of all, we refer to NYAGA [1] and DZHVAESHEiSHVILI [1], where the study of the scalar Riemann boundary value problem on a rectifiable +
contour
T
in wider classes than
L1
has been initiated (in particu-
lar, in classes of functions which can be represented as a differentiated Cauchy integral). Under sufficiently general assumptions on the coefficient
G , the scalar Riemann boundary value problem in classes
different from
L
was studied in ANTONTSEV [1], KATS [1-3]. The
papers of DANILOV [1], ZAPUSKLALOVA, KATS [1], KATS [3] and SEIFULLABV [1] are devoted to the investigation of new effects occurring in the theory of the scalar Riemann boundary value problem under weakened conditions on the contour Operators of the type
r .
T j (F) = y F | i m j ) , where ?
(bounded) projector in some Banach space
8
and
is an arbitrary F
is an arbitrary
operator from [s] , are an abstract analogue of Toeplitz operators. In particular, Wiener-Hopf operators, i.e. integral operators on the half-line with a kernel depending on the difference of the arguments can be represented in the form T y(F)
Ty (F) . Therefore, the operators
are referred to as generalized Toeplitz operators or general-
ized Wiener-Hopf operators. The general theory of such operators was created in DEVINATZ, SHINBROT [1]. Especially, (under some additional restrictions) the validity of the abstract analogue of Theorem 3.13 is shown there, namely, the necessity of the invertibility condition of the operator
F
for
Ty(F)
to be a
or a $_-operator. For more
results in this direction we refer to the recent monograph of SPECK [1]. Incidentally, note that the theoiy of systems of Wiener-Hopf equations is equivalent to the theory of operators
P + GQ
and
ty + G'P . This equivalence can be established with the help of the Fourier transform} for more detail concerning this topic, see GOHBERG, KRiiiN [3], GOHBERG, FELDMAN [3].
129
In Ch. 8 o f the book GOHBERG, FELDi.lAN [ 3 ] a l s o o t h e r types o f systems o f i n t e g r a l equations are enumerated, the theory of which may be e r e c t e d with the aid of r e s u l t s r e l a t e d to operators studied i n t h e p r e s e n t c h a p t e r . In p a r t i c u l a r , the examination of operators of the foim AP + BQ has been suggested by the study of systems of s o - c a l l e d paired i n t e g r a l e q u a t i o n s . A v a r i e t y of types of i n t e g r a l e q a t i o n s and p r o blems of mathematical physics r e d u c i b l e to the Riemann boundary value problem were discussed i n the monograph by GAKHOV and CHERSKli [ 1 ] ( s e e a l s o Chapters 1 - 7 i n GOHBERG, FELDMAN [3]). V a r i a n t s o f the l o c a l p r i n c i p l e (Theorem 3 . 2 2 ) can be found i n CLANCEY, GOHBiiRG [ 1 ] and GLANCKY, GOSSELIN [ 1 ] , In CLANCEY, GOHBBRG [ 1 ] the notion of l o c a l f a c t o r a b i l i t y o f m a t r i x f u n c t i o n s was introduced ( a matrix function a t the p o i n t
t
G € L^
and m a t r i x f u n c t i o n s
on
A+SA~1
r
i s called locally factorable
€ r , i f t h e r e e x i s t an open a r c
t h i s p o i n t , domains i l
operator
defined on
+
c«8
+
containing
the boundary of which c o n t a i n s +
A + € Ep(£2 )
i s bounded in
Y £ T
such t h a t
Lp(y) , and
-1
A+
-
Y »
±
€ E ^ ( Q " " ) , the
G(t) = A+(t)A_(T)
a.e.
y)» Furthermore, t h e r e was proved t h a t the ^ - f a c t o r a b i l i t y o f
G € L^
i s equivalent t o i t s l o c a l f a c t o r a b i l i t y a t every p o i n t o f the
contour. In GLANOEY, GOHBERG [ 2 ] i t i s e s t a b l i s h e d t h a t i n the s c a l a r case f o r a Lyapunov contour tion tor
G
a t the point
P + GQ
tQ
r , the l o c a l f a c t o r a b i l i t y of the f u n c i m p l i e s the l o c a l Fredholmness o f the opera-
a t t h i s p o i n t . For
p = 2 , the converse a s s e r t i o n
is
also t r u e . In GLAWCEY, GOHBERG [ 2 ] i t was mentioned t h a t f o r
p 4= 2
the question
of v a l i d i t y o f the converse a s s e r t i o n i s s t i l l open. This problem has been solved by I . B . SE.IONENKO, who i n a s e r i e s o f papers (8IM0NENK0 [ 7 - 1 1 ] ) s u c c e s s i v e l y renounced the r e s t r i c t i o n s on
p , n
and
T
and,
f i n a l l y , proved the equivalence o f l o c a l Fredholmness o f the operator P + G 0 ) , i t i s easy
t o deduce the r e l a t i o n s -
(f)r|G+(«)r4
for all finite +
r .
Since
and
G + € Ep
the f u n c t i o n
< (ln|G+(z)|)r
• (k .) and (k\) V ( k . ) i f f the tuple Proof.
(k!.) 0
hold simultaneously
i s some permutation of the tuple
(k.) . 0
F i r s t of a l l , we intend to explain what do conditions ( 4 . 8 ) and
( 4 . 8 ' ) mean f o r some concrete values of
k = max k . , then 0 max{k.,~k,0} = 0 f o r a l l j = 1 , . . . , n . Consequently, inequality ( 4 . 8 ) with J n t h i s choice of k i s equivalent to E max{k'--k,0} < O . In turn, the 0=1
k . If
J
l a t t e r inequality i s s a t i s f i e d i f and only i f (d=1,• • • , n ) , i . e . i f 142
max{k'.-k,0} = 0 0 max k . < max k. . In t h i s way, condition ( 4 . 8 ) J 0 d 3 1
with
k = max k. is equivalent to max k!, < max k. •
i
i
d
i
~
A
3
If the latter inequality is fulfilled, then for k > max k^ , the equalities min{kj-ktO} = k^-k , min{k!j-k,o} = kj. -k are true and, therefore, to say that condition (4.81) is valid amounts n n to saying that E (k,-k) < E (k'.-k) . Obviously, the inequality ob0=1 3 ~ J=1 3 tained is satisfied iff n a . E k < E k' . j=1 « 3=1 « Analogously,one can readily verify that, for 1
k = min k^ , condition
1
(4.8 ) is satisfied iff min k^ < min k . . When the latter inequality J
J
is fulfilled, then, for k < min kj , condition (4.8) is equivalent to J a n "" E k, > E k' . 3=1 3 3=1 0 Thus, if the conditions (4.8) and (4.8') ara fulfilled for and
k = max kH
k = min k. u , then relations (4.9) are true, which proves statement
1) of the lemma. Furthermore, if the relations (4.9) are valid, it follows from what was proved above that conditions (4.8) and (4.81) are satisfied for k k, > ... > k ^ , k, > k, >..•>
= min kj ,
= min k|j , and if
> ^3^=1 '
( k j ) ^ , then in view of relations (4.9), But then, obviously,
( k ^ ) ^ >- (k!j)^=1
and
. In this
k ^
(k^)^ >
=
. • 143
Due to the induction hypothesis, the tuple mutation of the tuple
( k Jj)j = -| provides a p e r -
( k . ) ^ , . . Reordering these tuples in a non-
increasing manner, we thus deduce that they coincide. Consequently, the i n i t i a l tuples proved.
(k-j)^
and
coincide, t o o . Lemma 4.1 i s
=
THEOREM 4.7.
L e t the diagonal elements of the matrix function
^-factorable in
G be
L^ , and assume the index of the j th diagonal e l e -
ment to be equal to of G+
k- . Then the tuple ( k . ) of p a r t i a l indices u J G i s majorized by the tuple ( k . ) . The f a c t o r i z a t i o n factors 0 and A can be obtained with the help of a f i n i t e number of a l g e -
braic operations and solutions of scalar Riemann problems. Proof.
According to Corollary 3.1» the dimension of the kernel of pron blem ( 3 . 1 ) with matrix c o e f f i c i e n t G i s equal to a = £ max{*.,,0} , 0 3=1 and the dimension of the kernel of the scalar problem with the c o e f f i cient G -• i s equal to a- = max{k.,0} . On the strength of Theorem 4.2, JJ
J
J
n n we conclude that E max{K.,o} < E max{k.,0} . 0 0 3=1 0=1 n n n Analogously, - E min{n.,0} < - E min{k.,0} , i . e . E min{n.,0} > J d 3 0=1 ~ 0=1 0=1 ~ n _k > E min{k-,0} . Multiplying G by t ~ , i t s p a r t i a l indices and the
~
J
0=1
indices of the diagonal elements decrease by
k . Consequently, the
inequalities proved continue to be v a l i d , substituting in them K^-k
and
k^
by
k^-k . Thus
G., = GD
D ( t ) = d i a g [ t k l , . . . »t15®] . The
i s triangular along with
elements are ^-factorable in
by
(k^) > ( x ^ ) .
Now we introduce the matrix function —1 matrix function
*. 0
G , i t s diagonal
L^ , and t h e i r indices are equal to zero.
According to Theorem 4.6, the p a r t i a l indices of the matrix function G i are equal to zero and i t s f a c t o r i z a t i o n factors
and
G^ ^
are
constructed with the help of a f i n i t e number of algebraic operations and the solutions of scalar Riemann problems. Using Theorem 2.7» we see that the matrix function
G can be factored with the same degree of
e f f e c t i v e n e s s . The proof o f Theorem 4.7 i s complete,
144
a
From Theorem 4.7 and statement 1 ) of Lemma 4.1 we obtain the following result, COROIiLARY 4.3.
The p a r t i a l indices of a triangular matrix function G
with ^-factorable diagonal elements are situated between the smallest and l a r g e s t index of the diagonal elements, and the t o t a l index i s equal to the sum of the diagonal elements indices. We denote by
(i• •
the order of the zero of the ( i , a ) th entry of the r
matrix function
\
(G^ ')""''
(introduced in the proof of Theorem 4 . 7 ) at
i n f i n i t y . Note that a l l entries outside the diagonal of at
oo , so that
'Ac shall write
n• H > 1
for
^
vanish
i ^ j .
ji.f y. = oo , i f the ( i , j ) th entry of ( G ^ 1 ) ) - 1
is identi-
c a l l y zero. THEOREM 4.8.
The tuple of p a r t i a l indices of a lower (upper) triangu-
l a r matrix function coincides (up to a permutation) with the tuple of indices of i t s diagonal elements i f and only i f k^ - k ± < for i > d ( i < o) . Proof.
(4.10)
We focus our attention on the case of a lower triangular matrix
function. I f condition (4.10) i s f u l f i l l e d , then, setting A = D ,
G_ = D^G^^D , we get a f a c t o r i z a t i o n of
G+ = G^1 ^ ,
G . Thus we have
only to v e r i f y the a n a l y t i c i t y of the entries outside the diagonals of the matrix functions
G_
and
G_
teed by the f a c t that the ( i , o ) i s equal to zero, i f point
z = oo , i f
at the point
z = oo . I t i s guaran-
entry of the matrix function
i < j , and has a zero of order
i > j , and the ( i , o ) th entry of
from i t v i a multiplication by
H. . G_
at the i s obtained
z^ 3 ""^ 1 .
How, l e t condition (4,10) f a i l to be f u l f i l l e d . Suppose, at f i r s t , that k, - k ± < |i±1 Setting
(i=1
n-1) , k 1 > 0
kQ +
< 0 .
n1 = n-1 , n2 = 1 , we represent the matrix function
the form ( 4 . 4 ) . In this case the f a c t o r i z a t i o n of which in + (t)t Gnn ^ ) = Gnn v '
By
and
G2 L^
i s the r i g h t lower entry
G
GQn
in of
G,
we write down in the following way:
aG~
( t )' *. nn^
k . ^
u
( i < j ) , then the p a r t i a l indices coincide with the i n -
dices of the diagonal elements. In order to prove t h i s proposition, we have to use Theorem 4 . 8 and the f a c t that 4.3.
n,J. HJ > 1
for
i I j .
2
CALCULATION OF PARTIAL INDICES OF SECOND-OHDER TRIANGULAR MATRIX FUNCTIONS
In case of second-order triangular matrix functions, the question of c a l c u l a t i n g the p a r t i a l indices admits a complete solution. For the sake 147
of d e f i n i t e n e s s , we study lower triangular matrix functions, i . e . mat r i x functions of the form ( 4 . 4 ) with.
n1 = n2 = 1 .
F i r s t of a l l , consider the oase of ^ - f a c t o r a b l e diagonal elements ( i n accordance with Theorem 4.3, in t h i s case the matrix function
G
S - f a c t o r a b l e ) . Denoting the indices of the functions
G2
k1
and
k2
G^
and
by
r e s p e c t i v e l y , in view of Theorem 4.7 and Corollary 4 . 4 , we
may only claim t h e f o l l o w i n g « the p a r t i a l indices of k.,
and
is
k2 , i f
k.,-k2 < 1 ,
k,-k 2 > 1 , where
X
and are equal to
G coincide with
ki-\
i s an integer situated between
and 0
k 2 +* , i f
and [ ^ ( k ^ k j ) ] .
For the exact calculation of the p a r t i a l indices of a matrix function G of the form ( 4 . 4 ) , we propose the f o l l o w i n g algorithm. As in the proof of Theorem 4.7, we construct matrix functions
such that
G= G ^
The function
^ D
1
.
$ ( z ) = a~(z)/|7(z)
order of the zero of function Then
l i e s in the class
$
at
= Qq(z) + R1(z)/$(z),
$- n 1 .
, Q2 = H 2 - m , • • • . I f the process stops
, qn =
at some stage, i . e .
.
i s a polynomial of degree
Acting in t h i s way, we get a sequence of polynomials of degrees
m > )i
ni +
k1
and
k2 . I f
n
o
,
n
o
+
> k,-k 2 , then the p a r t i a l indices of
n G
kt+l^ .
The f i r s t statement of the theorem f o l l o w s from Theorem 4 . 8 , $
has the same order at
00 as the lower l e f t element of the
< are
matrix function
(G^1
.If
nQ < k 1 -k 2 , but
> k.,-k a , then
we obtain a f a c t o r i z a t i o n of G by setting k«—k»—u " —u 0 5T(t)R1(t) §7(t)Q0(t)t Gjt) = | -k1+ka+u I » a~(t)t 0 5l(t)t ^ / ka+H, t - 0
In case that
H0+Hi
k 1 -k a , we put
/1
/t * ^
\0
1 /U,
1 I
o
lT(t)R1(t)t»A^ Gjt)
s7(t)k'+k«+tX(t)
^
=; ' gT(t)R2(t)tk-"-k^i
etc.
0
sKiOt-^Ci-^Ctte^t))/
=
COROLLARY 4.5. indices
k.,
every integer
Let
and
G 1f G2
ka
(€ L ^ )
be « - f a c t o r a b l e functions with
r e s p e c t i v e l y , and suppose
k 1 > ka . Then f o r
\ 6 ( 0 , [ ^ ( k 1 - k a ) ] ) , one can choose a function
H € L^
in such a manner that the p a r t i a l indices of the matrix function ( 4 . 4 ) are equal to
and
ka+X . — + k
Proof. where
We intend to look f o r functions $ € E7
H
and has a zero of order
z is oo . The condition
H € L^
obviously, f u l f i l l e d i f f
of the foim = k 1 -k a -A.
i s equivalent to
$ = §7 1 •
150
f i n i t e n e s s o f t h e v a l u e p., imply t h a t t h e o p e r a t o r ) i s Fredholm, i . e . , f u n c t i o n G., i a ^ - f a c t o r a b l e i n L^ , which c o n t r a d i c t s t h e assumption o f t h e t h e o r e m . Thus
0 1 = 0 . The e q u a l i t y
at = 0
may
be p r o v e d a n a l o g o u s l y . I n t h i s way, t h e c o n d i t i o n s d e s c r i b e d i n t h e f o r m u l a t i o n o f Theorem 4 . 1 0 a r e a c t u a l l y n e c e s s a r y and s u f f i c i e n t f o r t h e $ - f a c t o r a b i l i t y o f
G •
I n a d d i t i o n , from t h e e q u a l i t i e s
(4.5),
0, = a, = 0
and t h e r e l a t i o n s
t h e f o l l o w i n g formulae f o r t h e d e f e c t numbers o f t h e Riemann boundary v a l u e problem w i t h m a t r i x c o e f f i c i e n t a = Ya >
G
result»
P = Y-i •
Comparing t h e s e f o r m u l a e w i t h t h e e x p r e s s i o n s o f t h e d e f e c t numbers v i a p a r t i a l i n d i c e s e s t a b l i s h e d i n Theorem 3 . 1 6 , we s e e t h a t t h e f o l l o w i n g cases are
1)
possiblet
Hi>0,
Then
x2 < 0 .
Yi = - x a
, y 2 = x-i » i . e . ,
l e s s of the values
2)
x1 > O ,
Then
Yi = 0 ,
Since then
3) Then for
x2
YiYa
and
formulae ( 4 . 1 1 ) a r e f u l f i l l e d
Yi + Ya •
x2 < 0 . y 2 = x , + x 2 > 1 , where
x 2 < *y(x.,+x2) = Ya/2
i s an i n t e g e r , we o b t a i n t h a t
x 2 = 0 , which means
x, < 0 ,
regard-
x 2 < [Ya/2]
.
and, i f
Ya = 1 »
x., = Ya •
x2 < 0 .
Ya = 0 > Yi = ~ ( H i + H a ) > 1 . As i n c a s e 2 ) , we c a n e s t a b l i s h Yi = 1 » t h e e q u a l i t i e s
x2 = -1
and
I n summary, i f e i t h e r o f t h e c o n d i t i o n s fulfilled,
x1 = 0
YiYa 4= 0
hold. and
then f o r m u l a e ( 4 . 1 1 ) a r e t r u e . T h e r e f o r e ,
remains t o be examined, namely, when
Y1+Y2 < 1
o n l y one
Yt = 0 , Ya > 1 • GQ(t) = t_5jG(t)
k = [Ya/2] . The p a r t i a l i n d i c e s
and
3 x,-k
= x2-k
m a t r i x f u n c t i o n meet t h e c o n d i t i o n s o f c a s e 1 ) . I n f a c t , was proved above, and
is
situation
To t h i s end, we i n t r o d u c e t h e m a t r i x f u n c t i o n
x2 < k
that,
x , > ^ ( x 1 + x 2 ) = Ya/2 > k .
the
with of
this
inequality
Consequently
= dim M q , where M q = {cp € k e r T q ( t ~ ^ G 1 ) : Qt-kHcp € IM T Q ( t _ k G 2 ) } I n t h i s way,
x 1 = k + dim M Q , x 2 = Y a - k ~ dim M q
.
, and t h e p r o o f
of
151
the theorem will be perfected as sooa as we establish that cides with the subspace generated in The relation
cp € ker Tq(t~^G 1 )
M
and
may be rewritten in the form t~kG1cp 6
q> 6 ker TQ(G1 ) . In turn, if k
Qt'^PG^ = 0 . If further,
Qt_kH£p s Qt'^jf , where
G1
€ ker TQ(G 1 ) , then
cp € ker T ^ t " " 1 ^ )
Qt^^q» = Qt~ PG 1 9 . Consequently, and
coin-
by conditions (4.13),
€ Lp • If the latter condition applies, then QG.,
,=1
f
D = S*CS , where
C i s the matrix defined by
formula ( 4 . 1 9 ) . I t s ( r , s ) th entry i s determined by the formula ^¿[(l-l)(s-1)-(r-l)(k-l)] 1 ( E c, = n " . e rs ln> k J- E-
E o n+l-k l - Qq> €
6 fl++ ft" * ft i s v a l i d . Thus, 3 ) ==> 4 ) . Vice versa, i f this case
SA — c A, then also
PR c L*
consideration that
f o r any T
PA — c A . Since ft — c L0„0 .-we have in '
p < oo . Hence
FA c A fl L * . Taking i n t o
i s a Smirnov contour, we obtain from Theorem 1.25
that ftfTLp = &0L* = ft+. In other words, FA e f t A n a l o g o u s l y , QR c ft". Since the converse inclusions are obvious, the implication 4 ) ==> 3 ) i s v a l i d . I f 3 ) i s s a t i s f i e d , then, f o r every
a € ft , we have
a = Pa + Qa € ft+ + ft" , i . e . 3 ) ==> 1 ) . Implication 5 ) ==> 4-)
is 183
evident, thus, i t remains to prove the implication 4 ) aa> 5)* In view of 4 ) , the operator
S
i s defined everywhere on ft . Now we want to
show that i t i s closed« i f Pa k = all
+ S)a k
a k -» a ,
-» ¿(a+b) ,
b=1,2,the
Sak -» b
Qak = ¿ ( 1 - S)a fc -» iy(a-b) . Since, f o r
inclusions
Pa k € ft+ , Qafc € ft" hold (here we
use the implication 4 ) ==> 3 ) proved above) and in ft , then Hence,
a+b €
ft+
( a k , a , b € ft), then
ft+,
ft"
are closed
, a-b € ft" .
S(a+b) = a+b , S(a-b) = b-a
and
Ba a S(^(a+b) + iy(a-b))
= ¿(a+b) + ^(b—a) = b . Due to the closed graph theorem, the operator S i s bounded in ft • Thus Lemma 5.5 i s completely proved* In the space
=
ftQ
of u—dimensional vector functions with components n from ft we introduce a norm, setting Bf|| _ = E ||f J L , where a ft jd 3 H Q f s £ f 0jeJ • . To any matrix function A 6 ft we assign the operator of 0=1 multiplication by t h i s matrix function in ftn . As i t can be easily v e r i f i e d , the norm of this operator i s determined by the formula ||A|| = with
A * ( a ^ ) ^
max
(5.8)
.
In the sequel we suppose that the (L 00 ,R)-algebra ft i s decomposing. According to Lemma 5.5, this supposition i s equivalent to the boundedness of
S
viewed as an operator in
ft
and, thus, also in fln •
Consequently, i t plays here the same role as the assumption r € 1 in Section 3,5 and 3.6. Up to the end of the present section (with the exception of Theorems 5.12 and 5.13), the l a t t e r condition ( i . e . r e * . ) can be replaced by the weaker requirement r € € used in the proof of the previous lemma. Every nxn matrix function bounded operators P + GQ numbers of these operators a(P+GQ) < P(Q+G'P)
G € ft can be associated with the linear and Q + G'P acting in ftQ . The defect axe connected by the relations , P(P+GQ) > a(q+G'p) (5.9)
as in case when the operators P + GQ and spaces Lp and L^ , respectively.
Q + G1 P
are studied in the
The relations ( 5 . 9 ) are a simple consequence of the f a c t that the kernel
184
of the operator P + GQ Q
vector functions on fl
(Q + G'P) exactly coincides with the set of orthogonal (in the sense of the bilinear form
(1.13)) to the image of the operator
Q + G*P
(P + GQ) . In its turn,
this assertion can be proved in the same way as the corresponding result from Theorem 3.1. As in Chapter 3» in addition to the operators P + GQ and it is convenient to introduce the operators
T^(G) and
via formulae (3.22). Since in the case in question im Q = (fl~)a t these operators act in
(R+)a
and
Q + G'P ,
Tp(G') defined
im P = (ft+)a and (fl~)n > respectively.
Assertion 1) of Lemma 3*5 on the relationships between defect numbers of the operators P + GQ
and
T^(G) as well as Q + G'P
and
Tp(G')
can be transferred (together with its proof) without any changes to the situation under study. However, assertion 2) of this lemma is no longer valid, since the operators
QGQ and PG'P
do not act in spaces dual
to each other (as it was the case in Chapter 3)» rather in one and the same space ftn . Therefore, nothwithstanding that formulae (5*9) are available, we cannot a priori assert that the operators 1
Q + G P
P + GQ
and
are Fredholm only simultaneously.
THEOREM 5.6. Let ft be a decomposing (L^jRj-algebra, and let
G be
a matrix function of n th order with entries from ft . The matrix function P + GQ
G and
is factorable in ft if and only if the operators Q + G'P
regarded in fln are Fredholm and their indices
are opposite. In addition, the value sum of positive partial indices and
a(P + GQ) coincides with the 0(P + GQ) is opposite to the
sum of negative partial indices of G . Proof. Let operators
G
be factorable in ft . Due to conditions (5»7)« the
G+PG~1 , GIQ(GI)"1 , G~1 A~ 1 QG~ 1
and
(G^)~1 A"1P(Gl)""1
are bounded in flQ . '-^he same calculations which where carried out in the proof of Theorem 3.16 show that the operator G~1 A~1QlG71+G+I>G+1 is a two-sided regularizar of the operator P + GQ . In the same way one can deduce that
(G^)~1 A^PC&l)""1 + G^Q(G^)"1
is a two-sided
regularizer for Q + G'P . Therefore, according to Theorem 1.8, the
185
Fredholmness of the operators be proved oa coaditioa that
P + GQ and G
acting in
can be f a c t o r e d in
Furthermore, in case of a matrix function solutions of the homogeneous equation + formulae ( 3 . 6 ) ( f o r
Q + G'p
will
A .
G f a c t o r a b l e in
(P+GQ)
x Q . Then there exists a
6 > 0
such that
215
every matrix function
G1
from the 6-neighbourhood of
G can be
factored with the same t o t a l index and p a r t i a l indices lying in [*q»H-1 ] • Proof«
-X
Consider the matrix function
t
G ( t ) . I t s p a r t i a l indices
are non-negative. Due to the previous theorem, there e x i s t s a such that a l l matrix functions from the 6^neighbourhood of
6Q > 0 t~* n G(-t)
aire factorable with the same t o t a l index and have non-negative p a r t i a l indices« Analogously, a l l matrix functions from a certain 6-neighbourhood of 6 =
t"*iG(t)
min{6a||t"*>t,l||
have
have non-positive p a r t i a l indices. Set , S^lt""* 1 !!} . Then, provided that
| | t ^ G , - t ^ G l l < 6,
that the matrix function
and
t"-HnG
k,
and
k 1 =...=1^ > k 1 + «j,
k, = k\ •
k a < k^ . Then
2i (k',+1 )-(kJ l -1) > 2 . Therefore, there e x i s t numbers
m,l < m , such that 220
(k..)!?_,j y
k Q < k^ . I f , f o r instance,
Consequently, we shall assume that ki~ka
a j: 1 , we con-
1
and
k t - k ^ j < 1 , ki-k^ > 2 ,
Consider the tuple
obtained from
the elementary operation f o r
with the aid of
r = 1 , s = m and show that
>• (k!j)|j=1 . We restrict ourselves to the v e r i f i c a t i o n of inequality ( 4 . 8 ) in which k^ i s replaced by k ^ . n For k > k, , we have E max{k^-k,0} = 0 , f o r k < k^, 0=1 E max{k^1^-k,0} > E max{kUk,0} . Finally, i f
kL < k < k', , k, > k .
then kj. > k ^ > k^-1 > k j , where k^ > k!j f o r 3=1,...,1, so that n n n n s E max{k',-k,0} < Z max{k,-k,0} - 1 < Z max{k,-k,0} -1 = E max{ky ; -k,0>. J 3 3 3 0=1 ~ d=1 ~ d=1 0=1 Repeating these considerations, after tuple
d (< l )
steps we come to the
( k j j d ) ) ° a 1 > C k |j)j = i t wbere either
or
< k,
(if
(k.)!? =1
?
(k^)jj ^ ^ (kj)j ( k ! , ) ^ , because
Lemma 6.1 i s proved. THEOREM 6.5.
d< l)
N of elementary operations one can for which either
. In any case, as shown above, then
(if
d = l ) . From this we conclude that after the
application of a f i n i t e number obtain a tuple
> kQ
k£ N ) = k^
-» ( k j ) J = 1 .
( k ^
?
(k^))^
or
But
.
=
Let the matrix function
G be factorable, and assume
the tuple of i t s partial indices to be then in an arbitrary neighbourhood of
(*.j)° a• (*!j J ^ p G there exists a matrix func-
tion the tuple of partial indices of which i s
(*!j)jj_,| .
Proof. The assertion i s evident i f (x'.) = ( x . ) . I f (x 1 .) ± ( x . ) , — — J d j j then, according to Lemma 6.1, there exist tuples (xS ')!?_«, , k=0,...,N / \ /• \ u d=I ' such that
= *-j t
x
j
=
*Jj
011(3
'bl:ie (k"*""1) ^
tuple i s obtained
from the k th one with the aid of one elementary operation. Arguing as in the proof of the necessity in Theorem 6.3, we conclude that in any neighbourhood of the given (factorable) matrix function there exists a matrix function whose tuple of partial indices i s obtained from the tuple of partial indices of the i n i t i a l one with the help of one elementary operation previously chosen. Specifying e/2-neighbourhood of
G a matrix function
s > 0 , we choose in the G., with the tuple of partial 221
( H J 1 ' ) ^ , in the e/4-neighbourhood of
indices G»
the tuple of partial indices of which is
After all, we obtain a matrix function G N G
a matrix funotion
with the tuple of partial indices
(x|.
and so on.
from the e-neighbourhood of , which proves Theorem
6.5. s COROLLARY 6.1. In any neighbourhood of a factorable matrix function there exists a matrix function with a stable tuple of partial indices» With the help of Theorem 3*7'
all results derived in the present sec-
tion can be transferred to the case of right-factorization. COROLLARY 6.2. In any neighbourhood of a matrix function factorable from the left and the right there exists a matrix function with a stable tuple of left as well as right indices. Proof. For given e > 0 , we take in the e/2-neighbourhood of the original matrix function G
a matrix function G 1
with a stable tuple
of partial indices (due to Corollary 6.1, this is always possible). If e is sufficiently small, then the matrix function G, will be factorable not only from the left but also from the right. In view of the stability of its left indices there is a 6-neighbourhood of G., to which belong only matrix functions with the same tuple of partial indioes. Setting 6 1 = min{6,e/2} and using an analogue of Corollary 6.1 related to right-factorization, we find in the 6.,-neighbourhood of G,
a matrix function G 2
with a stable tuple of right indices.
This is just the desired one. = The results of the present section admit a topological interpretation. Denote by
of
partial indices of which is
factorable matrix functions1' the tuple of (x.j. The representation
$ =
U
\
yields a decomposition of the class of all factorable matrix functions into disjoint non-empty sets, where« 1) if
^ c clos ®(Mi ^ , »J «) 2) if (x^) } (xj.) , then ^ n clos = 0 . _______________ 0 0 1) Recall that in this section the factorization is always understood as ^-factorization. 222
(Hj) y
(x!j) , then
Properties 1 ) and 2 ) are reformulations of Theorem 6 . 5 and 6 . 4 , respect i v e l y . Theorem 6 . 3 means that 3)
the s e t
i s open i f and only i f the tuple
( H -j)
satisfies
condition ( 6 . 2 ) . Since a tuple
( k . ) having the property ( 6 . 2 ) i s comparable with a l l u tuples with the same sum and i s minimal ( i n the sense of the ordering then property 1 ) means, e s p e c i a l l y , that 4) *x -
under the condition ( 6 . 2 ) , the s e t u
•
f a i l s to have property ( 6 . 2 ) , then the s e t
l i e s in the complement (with respect to are open and d i s j o i n t ,
^
$ H ) o f an open dense s e t .
Therefore, i t i s nowhere dense. Because, f o r d i f f e r e n t $x
i a
M , the s e t s
^ i s nowhere dense in t h e i r union
e i t h e r . Thus! 5)
if
x 1 - x Q > 2 , then
^ i s a nowhere dense subset of
$ .
F i n a l l y , from property 2 ) we can conclude that 6)
the s e t s
^
and
®(x'.)
8X6
separated i f f the tuples
(kL) are not comparable. u With Theorem 3*20 in mind we can imagine the s e t
(*-j)
and
9
as the union o f a
countable number of separated open s e t s ® x ' s divide into an open s e t nowhere dense s e t
6.3.
*(x,
)
(
gn ^ . E
. Now we can every of the n * ^ ( E = * « *•» - * n < 1 ) and a 3=1 x f 2) .
V =
ESTIMATES FOR THE PARTIAL INDICES 0? MEASURABLE BOUNDED MATRIX FUNCTIONS
In Section 6.1 i t was shown that inequality ( 6 . 2 ) i s a necessary and s u f f i c i e n t condition of s t a b i l i t y of p a r t i a l i n d i c e s . However, i f we want to use t h i s c r i t e r i o n , we must know the value of the l a r g e s t and smallest p a r t i a l index. Therefore, we are i n t e r e s t e d in a s s e r t i o n s l a which besides 4 - f a c t o r a b i l i t y of a c e r t a i n matrix function also e s t i mates of i t s p a r t i a l indices are e s t a b l i s h e d . 223
Sufficient c r i t e r i a of non-negativity and non-positivity of partial indices are also of some significance, since the defect numbers of the vector-valued Riemann boundary value problem with matrix coefficient G are stable i f and only i f a l l i t s partial indices have the same sign. The present section i s devoted to a result of precisely such a type. Owing to Theorem 6.2, every nxn matrix function which i s ^-factorable in
Lp
with zero partial indices has a neighbourhood entirely con-
sisting of matrix functions which have the same property. In particular, the matrix function identically equal to bourhood. Denote by
&p > n (r)
I
possesses such a neigh-
the largest possible value of the radius
of such a neighbourhood. In other words, ftp
a(r)
is a number such
that, f o r
||I - G0|| < 6 p > a (r) , the operator function
P + GQQ
(6.6)
i s invertible and there exists an nxn matrix
F f o r which
||I - F|| = 6
(r)
and the operator
P + FQ
i s non-invertible. We denote by LHHHA. 6.2. ———— — 1)
Ap the interval with ends
)
the numbers
3)
6p,n(r)
r -
2||S||Ln ||Q||~2 and 2 " V 1 + IISII'
q = p/(p-1) . p,a_ ( r )
are true:
are estimates from below f o r P
6 p f a ( r ) < Sin u/max{p,q} j
, then
6q,n(r)
6rfB(r) > 6p>a(r)
»
1) The estimate
r € Ap | in particular,
for
= max{6 p t n (r): 1 < p < » } Proof.
and
The following assertions related to
6p > a (r) | i f 2
p
.
_(r) > follows from the contracting ~ Lp mapping principle, since, f o r ||I - G|| < ||Q|| „ , the operator P + GQ = I + (0 - I)Q
P'Q
d i f f e r s from the unity operator by a summand with norm
smaller than one. To prove the second estimate from below f o r we consider an arbitrary matrix function
G from the
neighbourhood of the identity matrix function. Then 224
6p^Q(r) ,
2||S||/(1+11811*)-
||I - G|| < for some G, =
a > ||S||Q L P 1
a* - 1
G
-22 1 + o1
(6.7)
(> 1) . We introduce the matrix functions G = (l-Gi)(l+Gi)~1 . Obviously, G
and
and
G., are
^-factorable only simultaneously and the tuple of their partial indices coincide. Moreover, due to condition (6.7) and the identity i
+ Gi
= -f2!_ (i + £!±1 (G-I)) , a1- 1
the matrix function
2a2
I + G1
is invertible in L^ . Consequently, the
invertibility if the operator P + G,Q = ^(l+GS)(l+G 1) is equivalent A to the invertibility of the operator
I + GS . In this way, the desired
estimate will be obtained, if we clarify that the inequality
||G|| < a"1
holds, provided that condition (6.7) isA valid. In other words, we have to show that the matrix function Y = oG will be contracting as soon + g * (I-G) is contracting. But 2o are connected via the relation
as the matrix function I
X =1
Y = (I - eX)~1(X - el) , where
e = a
X
and
(6,8)
. It remains to use the well-known fact from matrix
theory that, for any
e €[0,1] , transformation (6.8) maps a contrac-
tion into a contraction. The latter can easily been checked by showing that the spectrum of
Y
lies inside the unit disk.
Finally, let the condition continuous function cos^/p + Clearly,
f
T € "R be fulfilled. Consider a piecewise
given on r
sin 2rc/p and
cos it/p - ¿j sin 2rc/p with p = max{p,q} .
||f - 1|| = sin it/p . Furthermore, at the half of the points
of discontinuity of the function 2n/p
which takes only the two values
a
f
the argument jump is equal to
and at the other half it equals
the discontinuities of
f
2it - 2rc/p = 2u/min{p,q} • If at
there exist the tangents to the contour
r
(which can always be effected), then we are able to use Theorem 5.15, according to which this function is not ^-factorable in Hence 6
p
(and L^).
6 ^(r) < sin u/p . From here and the obvious relation rI ' < 6p ^ r ) we deduce the inequality to be proved. 225
2)
I t ia not hard to see that the inverse transforation to ( 6 . 8 ) i s
this transformation i t s e l f * Therefore, i t maps the 1-neighbourhood of the zero matrix function onto i t s e l f (and not only into i t s e l f as mentioned above)» Moreover, i t is a one-to-one mapping. Setting I, s I + si ,
X1 = ( I - eX)' ,
from ( 6 . 8 ) we observe that, f o r a r b i -
trary s < 1 , the transformation
X, = (1 - e'XA)'1-1 maps the e-neighbourhood of the identity matrix function one-to-one onto i t s e l f . At the same time, Theorem 3«?' and Corollary 3«6 imply that the matrix function
X1
i s «-factorable in
indices i f and only i f the matrix function with zero partial indices. Thus, f o r some
Y*
Lp
with zero partial
i s «-factorable in
L
q.
e < 1 , the ©^neighbourhood
of the identity matrix function consists completely of matrix functions which are «-factorable in
Lp
with zero partial indices f o r
i f and only i f they possess this property f o r the evident relation
6r
Q(r)
< 1
r = p
r = q . This aa well as
(which i s true f o r a l l
r €(1,»))
imply assertion 2) of the lemma. 3)
Now we consider the
function
6„ p,a_(r)-neighbourhood of the identity matrix
I . According to assertion 2 ) , every matrix function
G from
this neighbourhood i s «-factorable with zero partial indices not only in
LJT
but also in
function
L*A . Owing to Theorem 3«9 and 2.2, the matrix
G is «-factorable with zero partial indices in a l l
Lr
with
r € Ap . Hence, the 6p^a(r)-neighbourhood of the identity matrix function is a part of i t s 6 r
n (T)-neighbourhood,
i.e.
a(r)
< 6p
n(r)
( r € A^) . Since, f o r a l l p €(1,co) , the interval A contains the point r = 2 , we deduce that the l a s t of the relations to be proved i s also correct. THEOREM — — 6.6.
= Let the matrix functions
G and
X.+ € L00
be such that (6.9)
Then» 1)
if
X+ € M+ ,
and, f o r a l l 226
6 L* , X_ € L~ , lT 1 €
r e A^ , the partial iv-indices of
, then
Ap c
«(G)
G are non-negative,
2)
if
X+ €
, ^
and, for all Proof»
€
|/(t) « l k d • d ^ The function ty does not vanish on T . Indeed, i f Yt ^ Yt
then, by assumption, the eigenvalues of of
At
d
and A^ k
a . e . on
Yt
d
n k
¥ &«
^ i n t ek r s e c t i o n F(*t_) l i e in the
•
Therefore,
A+. fl A+. i 0 • Since neither of the disks A+. and A. td td Tc k contains zero, then the interval connecting t h e i r centres z- and z,_K d does not contadn zero e i t h e r . Consequently, zero does not belong to the interval
•
Now we are going to show t h a t the matrix function G^ = \|/F s a t i s f i e s « o the condition ( 6 . 6 ) . For t h i s purpose, note t h a t , i f the eigenvalues of
F(t)
Zj. F ( t )
l i e in the disk l i e in the disk
6 s sin a/2 At
and d matrices
A+. , then the eigenvalues of the matrix d AQ with centre a t the point 1 and radius
( > sin a H / 2 ) . I f the eigenvalues of
F(t)
l i e both in
At
, then we recognize t h a t the eigenvalues of both the * Z j ^ F ( t ) and z ^ F ( t ) l i e in AQ and, t h e r e f o r e , also of a l l 231
matrices of the form the matrix
GQ(t)
£F(t)
l i e in
with AQ
£ €
a . e . on
. Hence, the eigenvalues of T , and those of
the disk
{zs|z| < 6} . Taking into account that
matrices
I - GQ(t)
are normal together with
I - GQ(t)
6 < 6_ n ( r ) P, Q
in
and the
F ( t ) , we find that
condition ( 6 . 6 ) i s f u l f i l l e d . In view of statement 3) of Lemma 6.2, the matrix function factorable in
Lr
for all
r € Ap
F
is 4-
and i t s p a r t i a l indices are equal
to zero. Applying now Lemma 6.3 with matrix function
GQ
X = ^
, we conclude that the
i s also ^-factorable in
L p , r € A^ and i t s p a r t i a l
indices axe equal to each other and to the index of the function Thus Theorem 6.10 i s proved. COROLLARY 6.4.
=
Leb the matrix
U(t)
more, suppose that, f o r any point arc
Y-fc ( 3 t )
of the contour
r
be unitary a . e . on
and a sector
v < 2 arcsin 6 P »na( r )
of the matrices
l i e in
interval
A^
S^
U
S^. with vertex at the
such that a l l eigenvalues
f o r almost a l l
t € y^ . Then the
i s e n t i r e l y contained in some component of the domain
of § - f a c t o r a b i l i t y of the matrix function indices of
T . Further-
t € T , we are able to indicate an
origin of apex angle U(t)
x •
U
and a l l p a r t i a l p -
are equal to each other.
In f a c t , a unitary matrix i s a normal matrix the eigenvalues of which have absolute value 1. Therefore, the f a c t that the eigenvalues of the matrices
U ( t ) , t € y^
in the intersection
l i e in the sector
implies that they l i e
of this sector with the unit c i r c l e . I t r e -
mains to note that the arc scribed in the sector
S^
may be included into a disk
A^
in-
S^. . A f t e r that, Theorem 6.10 w i l l be applied, s
The normality condition occurring in Theorem 6.10 i s very i n c i s i v e . Thus, we t r y to f i n d an analogue of these propositions related to matrix functions which do not necessarily take normal values. In looking f o r such an analogue, the following considerations are useful. The eigenvalues of the normal matrix
G(t)
belong to some disk i f and
only i f the convex hull of the set of eigenvalues of
G(t)
belongs to
this disk. I t i s well-known that the convex hull of the s e t of eigen-
232
values of the normal matrix H(A) = {
E
A = (a^)? coincides with the s e t -L» J— I
a i 1 5 j 1 « £ I g J * = 1} .
(6.10)
However, formula ( 6 . 1 0 ) continues to make sense f o r a matrix
A not
necessarily normal. DEFINITION 6 . 2 .
'¿'he s e t
H(A)
HausdorfC s e t ) of the matrix For any matrix
A , H(A)
i s called the numerical domain (or
A .
i s a convex compact subset of the complex
plane containing a l l eigenvalues of the matrix
A (GLAZMAN, LYUBICH
[ 1 ] , MARCUS, MING [ 1 ] ) . I t i s quite natural to suspect that there e x i s t s u f f i c i e n t conditions of $ - f a c t o r a b i l i t y of the matrix function
G and estimates f o r i t s
p a r t i a l indices formulated in terms of H(G). DEFINITION 6 . 3 .
By
d(A)
part of points from
we denote the smallest value of the real
H(A) .
I t i s well-known ( c f . MARCUS, MINC [ 1 ] ) t h a t d(A) value of the Hermitian matrix LEMMA 6.4» tion
Then for Proof.
i s the smallest eigen
Re A = tj(A+A*).
Assume the matrix function
G f 1M
to s a t i s f y the condi-
ess i n f d(G(t)) > l/l-M ( r ) ||G|| . p , a ter Ap £ $(G)
and a l l p a r t i a l r - i n d i c e s of
(6.11) G are equal to zero
r € Ap . We shall show that the matrix function
matrix function
GQ
G d i f f e r s from the
satisfying inequality ( 6 . 6 ) only by a constant 2
multiplier
p. > 0 . For t h i s purpose, using the equation ||a|| = ||AA*||
and choosing the point
t e r
a r b i t r a r i l y , we write
||l-nG(t)||a =
= ||(I-uG(t))(l-RG(tJ»|| = ||I+|i a G(t)G(t)* - 2H Re G(t)|| . Inside the noim sign we have obtained a Hermitian non-negative matrix N the norm of which, as well-known, i s the maximum of the quantity taken over a l l vectors
x
of the unit sphere. Since
(Nx,x
( l x , x ) = ||x||l = 1
(H*G(t)G(t)*x,x) = n*||G(t)*x||* < u'||G(t)*P = H2l|G(t)||*
and 233
(-2H Re G ( t ) x , x ) s -2n(He G ( t ) x , x ) < -2ud(G(t)) , we deduce Hl-UGCtJH* < 1 + |i«||G(-b)||a - 2|id(G(t)) . Therefore, the inequality ||I-jiG(t)||* < 1 + (x*f|G||* - 2(i ess inf d ( G ( t ) ) holds a.e. on r . ~ t€r Choosing u = ||G||~2 ess iaf d ( G ( t ) ) , we obtain that t€r ||I-|iG(t)||a < 1 - ||G|f2 ess i a f d ( g ( t ) ) a.e. on T. Thus, due to condi~ ter tion (6.11), ||I-HG|| < 6 p j a ( r ) . From this and assertion 3) of Lemma 6.2 we conclude the $-factorability in
L r , r € Ap , of the matrix function
(iG . Moreover, we see that i t s partial r-indices are equal to zero. Clearly, the i n i t i a l matrix function
G i s , together with
jiG , also
^-factorable and the tuples of partial indices of these matrix functions coincide.
=
Acting as in the proof of Theorem 6.10, from Lemma 6.4- one can get the following result. THtSORBM 6.11. every point line
Let the matrix function
G € L„ 00 be such that,* f o r t € T , there exist an arc Y-fc ( * t ) aQ d a straight
1+. whose distance from zero i s greater than «
and which has the property« f o r almost a l l HCGi'O)
T €
||G|| l / l - ^ TQc F ) P> , the set
separated from zero by the straight line
matrix function
G i s ^-factorable in
Lp
for
r € Ap
. Then the and a l l i t s
partial indices coincide. Supposing, in addition, that the contour
r
satisfies the Lyapunov
condition, we are able to strengthen Lemma 6.4. To this end, we need the following result related to factorization of positive functions. LEMMA 6.5.
be a function given on the Lyapunov contour r +1 which takes only non-negative values and f o r which of" 6 L . Then +1 +T there exists a representation a = a + a_ with a~ € L^ , a_ 6 L~ .
Proof. a = a ot
Let
We set
a
a + = exp(P In a ) , a_ = exp(Q In a ) . Evidently,
and the function
degenerate in «
a
(a
, respectively) i s analytic and non-
~+1
(J> ) . A i s o , |a~ ( z ) | = exp(+ Re(P In a ) ( z ) ) .
Furthermore, i f we prove that Re(P In a ) i s a function bounded in Z>+, ±1 + then the inclusion a + € Lro w i l l be proved.
234
We have (P l a « ) ( « ) » s i r
/ la «(t) g -
,
r so that |Re(P l a a ) ( z ) | = &
/ l o « ( t ) 1» g - |
Re(Ax,x) > d(A)||x||z, on t h e other hand, which implies ||Ax|| > d(A)||x||. Hence A i s < d(A)~1.
^ - f a c t o r i z a t i o n i s a l r e a d y w e l l u n d e r s t o o d . This allows f o r making more p r e c i s e t h e r e s u l t s on t h e v a l u e s of p a r t i a l F i r s t of a l l , suppose t h a t
G € L* + C
indices.
(L~ + C) . According t o Theorem
5 . 2 , from t h e S - f a c t o r a b i l i t y of such a m a t r i x f u n c t i o n i n some we deduce t h e $ - f a c t o r a b i l i t y i n a l l
Lp
L p , 1 < p < » , moreover, w i t h
t h e same t u p l e of p a r t i a l i n d i c e s . Hence, i n t h e f o r m u l a t i o n s of Theorems 6.6 - 6.11' and Lemmas 6.4-, 6.4-' we may r e p l a c e maximal value
62
a
( r ) » which w i l l be denoted by
p , n•(r)
by i t s
6 Q ( r ) , and claim
t h e e x i s t e n c e of a ^ - f a c t o r i z a t i o n w i t h n o n - n e g a t i v e
(non-positive,
c o i n c i d i n g , e t c . ) p a r t i a l i n d i c e s i r r e s p e c t i v e of the p a r a m e t e r v a l u e p . In a d d i t i o n , Theorems 6 . 6 - 6 . 9 can be s i m p l i f i e d as f o l l o w s : i f G € L* + 0 , then i n a s s e r t i o n 2 ) of Theorems 6 . 6 and 6 . 9 t h e r e q u i r e —1 + ment that
X+ € M^ 1
X7 €
can be o m i t t e d , and i n Theorems 6 . 7 and 6 . 8 - t h e demand . If
G € L~ + 0 , t h e n i n a s s e r t i o n 1 ) of Theorems 6 . 6
and 6 . 9 we may cancel t h e requirement and 6 . 8 - t h e demand
X ^ e M~ , but i n Theorems 6 . 7
X ^ e M~ . 1
00
Now we a r e going t o s t a t e t h e e x a c t f o r m u l a t i o n and t o conduct t h e proof of t h e r e s t a t e d a s s e r t i o n 1 )' of Theorem 6 . 6 i n t h e c a s e
G 6 L~0 0 + 0 .
The o t h e r v a r i a n t s can be considered a n a l o g o u s l y , which i s l e f t t o t h e interested reader. THEOREM 6 . 1 2 .
Suppose t h a t
G € L~ + C ,
X+ €
t h e c o n d i t i o n s : 1 ) ||I-X + GXj| < 6 a ( r ) , 2 ) Then ( i )
1
partial Proof.
(1 < p < oo)
G admits a i - f a c t o r i z a - »
w i t h a n o n - n e g a t i v e t u p l e of
indices. X_ 6 L~
The r e l a t i o n
operator
implies t h a t
PX_Q = 0 . Moreover, t h e
PGQ i s compact by Lemma 5 . 1 . Consequently, P + X+GX_Q = (P+X+Q)(P+GQ)(P+X_G) + T ,
where
T
satisfy
L+ .
X~ e M~ , ( i i ) t h e m a t r i x f u n c t i o n
t i o n i n a l l spaces
, X_ 6 L~
(6.12)
i s compact.
From c o n d i t i o n 1 ) of t h e theorem we conclude t h e i n v e r t i b i l i t y of t h e operator
P+X+GX_Q
i n t h e space
L ° , and from c o n d i t i o n 2 ) and Theorem
5 . 2 we g e t t h e Fredholmness of t h e o p e r a t o r
P+X+Q
(in all
spaces 237
Therefore, equation (6.12) and Theorem 1.9 imply the Fredholmness of the product
(P+GQ)(P+X_Q) in the space L? . In turn, from the Fred-
holmaess of this product and the same Theorem 1.9 there follows that P+GQ
is a $_-operator.
Due to Corollary 5.1, if P+GQ the operator P+GQ of the product
is a $_-operator and
G € L~ + C , then
is Fredholm. In this case the second factor P+X_Q
(P+GQ)(P+X_Q) will also be Fredholm. Since
then, in virtue of Theorem 3»15', we may conclude that
X_ € L~ ,
iT^C M~ . In
this way, assertion (i) has been proved. As soon as this condition is fulfilled, we can apply assertion 1) of Theorem 6.6, according to which the partial 2-indices of the matrix function
G
are non-negative
(the $-factorability of this matrix function in L a FredholmnesB of the operator P+GQ
just proved). The result obtained
can be transferred to all parameter values beginning of the section.
results from the
p , as was mentioned at the
s
If the considered matrix function
G
is continuous, then we can apply
the strengthenings of Theorems 6.6 - 6.11 for the case well as for the case
G € L* + C
as
G € L~ + 0 mentioned at the beginning of the
section. In the case of a continuous matrix function
G , a particularly
clear form can be given to Theorem 6.11. DEFINITION 6.3. By
h(A) we denote the distance from the numerical
domain of matrix A
to zero. The matrix A will be called strictly
non-degenerate, if
h(A) > 0 , i.e. if
H(A) does not contain zero.
This definition is justified by the fact that a strictly non-degenerate matrix is clearly non-degenerate. THEOREM 6.13. all
t e
If the matrix function
is continuous and, for
r, h(G(t)) >
Vl-6£(r) ||G(t)|| ,
then all the partial indices of Proof.
G
The continuity of
G
G
(6.13)
are equal to each other.
implies the continuity of the function
a(t) = ||G(t)|| . In accordance with inequality (6.13) this function does not vanish. 238
From relation (6.13) we deduce an analogous relation f o r the matrix function
F = a~1G . In addition, f o r a l l
Consequently, f o r a l l
t € T , we have
||F(t)|| = 1.
t € r ,
h ( F ( t ) ) > V l " 6 £ ( r ) ||F|| . The closed convex set which we denote by Let
H(F(t))
(6.14)
contains a unique point nearest to zero
z ( t ) . Due to inequality (6.14),
z(t) ^ 0 •
be the straight l i n e passing through the point
^ ( h ( F ( t ) ) + V l - 6 * ( r ) ||f|| ) z ( t )
and orthogonal to the radius vector of
this point. U t i l i z i n g inequality (6.14) again, we find that distance to zero greater than H(F(t)) where
V 1 - 6 ^ 1 " ) ||F|| and separates the set
from zero. Since the matrix functions
nuous, the straight l i n e T
F
and
G are contiH(F(T))
,
t .
Summarizing, f o r the matrix function indices of
F
separates from zero a l l sets
i s s u f f i c i e n t l y close to
6.11 are f u l f i l l e d ( f o r
has a
F , the assumptions of Theorem
p = 2 ) . In view of this theorem, the p a r t i a l
are equal to each other. Applying Lemma 6.3
we observe that the partial indices of which proves Theorem 6.13.
for
x = «
G are also equal to each other
=
For the total index of a continuous matrix function, Ivluskhelishvili's formula i s true. Therefore, i t i s not hard to evaluate the partial indices of a matrix function
G which meets the assumptions of Theorem
6.13« each of them i s equal to 2jj{arg det G ( t ) } r
de'b G ( ' b ) } r
("thus, ' b l i e value
automatically proves to be d i v i s i b l e by
n ) . Notioe
however, that in the suppositions of Theorem 6.13 the values of the p a r t i a l indices of
G are closely connected with the behaviour of i t s
numerical domain. To illuminate this connection, we f i r s t remark that the index of a function
i|r continuous on
r i s uniquely defined by the
condition \|/(t) € H ( G ( t ) ) . In f a c t , i f
i s any other function continuous on
this condition, then, f o r every = W("t) + ( 1 - X ) t 0 ( t )
(6.15) r
and s a t i s f y i n g
X ^[0,1] , the function tyj^(t) =
i s continuous and f u l f i l s condition (6.15),
239
therefore, i t does not vanish on
T . ^he mapping
X -»
0(r) . Conse-
interval [ 0 , 1 ] continuously into the functional space quently, the indices of a l l functions indices of
>|/Q and
maps the
coincide. Especially, the
\|/1 = ty are the same.
I t i s quite natural to c a l l the common value of the indices of a l l functions
\|/ continuous on
T
and satisfying condition (6.15) the winding
number Q± the numerical domain around zero. The partial indices of
G
coincide with precisely this number as soon as Theorem 6.13 applies. Indeed, the function ty may be chosen in such a way that the matrix function
ty~1(t)||G(t)||~^
s u f f i c e s to set, e . g . , F
s a t i s f i e s the hypothesis of Lemma 6.4 ( i t = z ( t ) ) . But then the partial indices of
are equal to zero, and, as follows from Lemma 6.3, the partial indi-
ces of
G coincide with the index of the function
, i . e . , with the
winding number of rotations of the numerical domain around zero. Olearly, the remark made at the end of the previous section can be applied to Theorem 6.13 in f u l l . Thus, not only the l e f t but also the right indices of an arbitrary matrix function
G satisfying the condi-
tions of this theorem coincide with the winding number of the numerical domain around zero. 6.6.
ON THE STABILITY OP THE FACTORIZATION FACTORS G+
Up to now, the question of s t a b i l i t y of the factors
G+
from the
^-factorization ( 2 . 1 ) of the matrix function «•
L P
has not been
G in
studied in f u l l d e t a i l . Hence, we r e s t r i c t ourselves to the explanation of results associated with the factorization problem in .a (C,R)-algebra ft • Following the agreement at the beginning of the chapter, instead of "factorization in ft" we shall simply write " f a c t o r i z a t i o n " , under "norm" we shall understand the norm in
A , etc.
Closeness of the factorization factors
G+
and
F.+
of the matrix function G
of the matrix function F(t) = F+(t) A,(t)F_(t)
(6.16)
i s characterized by the quantities l|G+-F+H • H G - - p J » H ^ - ^ l l 240
. ll€ 1 -iC 1 ll
(6.17)
THEOEM 6.14.
Let
G be a certain matrix function admitting a f a c -
t o r i z a t i o n ( 2 . 1 ) . Then there exists a
6 > 0
such that, i f ||G-F|| < 6,
(6.16) i s a f a c t o r i z a t i o n of the matrix function of the values ( 6 . 1 7 ) i s smaller than Proof. Since
F
and at l e a s t one
6 , then A i = A .
For the sake of definiteness, l e t
||G-F|| < 6
and ||G~1-F~1||< 6.
G+ A - F + A i = GG~1-FF21 = G(g3 1 -F~ 1 ) + (G-F)F2 1 , then l|G + A-F + Aill < l|G||l|G:1-F:1||+||G-F||||r1|| < 6(iigii + P : 1 ! ! ) < 6(I|G|I + IIG:1-iC1|l • l|Gl1||) < 6(iiqh + IIG:1II + &)
so that the d i f f e r e n c e of corresponding columns of the matrix functions G + A and
F+A1
can be made a r b i t r a r i l y small, i f
6
i s chosen in a
suitable manner. Consequently, i f we choose 6 small enough, then the norm of the vector K(1)_x. J can also be made a r b i t r a r i l y small, where function g . - f . t J g., u u XJ . Then
" * « ) T~1dT . Letting
6 - . 0 , the r i g h t -
hand side becomes a r b i t r a r i l y small and the l e f t one does not depend on
6 . Consequently,
function
G+
g ^ ( 0 ) = 0 , which i s impossible, as the matrix o i s non-degenerate in 31 * . The contradiction obtained
shows that, f o r s u f f i c i e n t l y small for
6
6 , x ^ 1 ) < x^ , j=1
small enough, the t o t a l indices of
clude that
G
and
F
• Since, agree, we con-
x^"1) = x.. , ¡j=1,...,n , which proves Theorem 6.14.
s
In t h i s way, f o r close matrix functions with d i f f e r e n t tuples of partia). indices, the f a c t o r i z a t i o n factors
G c a n n o t be too c l o s e . I t turns
out that the converse statement, the formulation of which must somewhat, be strengthened because of the lack of uniqueness of the f a c t o r s
G+ ,
i s also true. THBOBEM 6.15.
Let
we can s p e c i f y a
G be a factorable matrix function. For any e > 0, 6 > 0
such that, i f
||F-G|| < 6
and the p a r t i a l
241
indices of the matrix function of the matrix function
P
coincide with the partial indices
G , then, for every factorization of
there can be found a factorization of in (6.17) are smaller than
F
G ,
for which any of the values
e .
In order to prove this theorem, first of all remark that
||F+-G+|| =
= IIF(F:1-G:1) A~ 1 + (F-^)G:1 A- 1 U < (iifiiiif:1-G:iII+IIG:iIIIIF^II)II7\-iH . Thus, it can be guaranteed that the quantity —1 as
||F-G|| and
||F+-G+||
is small as soon
||P_ -G_ || are small. Since in every Banach algebra the
operation of taking the inverse element is continuous for fixed 1
1
||i'~ -G~ || will be small, if smallness of
G ,
||F+-G+|| is small. Analogously, —i —1 the
||F_-Gj| results form the smallness of
-G_ || .
In summary, it suffices to prove a simplified form of Theorem 6.15 in mm'X —1
which it is only stated that
||G_
columns of the matrix function
G_
|| < e . We shall show that the may be interpreted as vectors from
_]R
the kernel of an operator of the form
P+Qt
G . The Fredholmness of
such operators results from the following proposition. LEMMA 6.6.
The kernels of the operators
P+GQ
and
T^(G)
have
equal dimensions and the images are closed only simultaneously and have equal codimensions. Lemma 6.6 is close to assertion 1) of Lemma 3.5 with respect to its formulation and way of proving. Thus, its proof is omitted here. We only wish to explain that if and only if
+
x
LBMMA 6.7. Let ces of which are 1)
(= Px) = 0 G
x~€ ker TQ(G) .
be a factorable matrix function the partial indi-
x, > ... > x Q . Then
if
X
(Pt~1 + Qt"*iG)x = 0 |
—/1
G_
is a solution of the (6.18)
is a matrix function which is non-degenerate at least at
one point of
r
(6.18), then
X m a y
factorization of 242
and
the j th column of the matrix function equation
2)
ker(P+GQ) = 0 + ker TQ(G) , i.e., x € ker(P+GQ)
and the 0 th column of which solves the equation
G .
play the role of a right factor in some
Proof. and
Relation (6.18) is equivalent to both equations P t ^ x s 0
Qt""wlGx = 0 • The first of the latter two equations means that
t ^ x €(fl~)a
or, what is the same, x €(ft~)Q ; the second amounts to
saying that
t'^Gx €(ft+)n . If we take
j th column of the matrix function
-1
G_
x = x., , where
x^
, then obviously
is the -
x. €(ft~) •
Moreover,
t~M*Gx. = t^^G. A G x. is the j th column of the matrix u *** *" J
function
G + . Thus, assertion 1) has been proved. Now we proceed to
the proof of 2). If the vector function x. u is the solution of equation (6.18), then, as mentioned above, x. €(fl~) and t- H lG_AG x. €(fl+)a , therefore, we deduce that
tíG
the kernels of the operators
with them, also of the operators
A
F+Qt 1 ~ w íF
and
and
(and, togethe
B ) axe equal. Due to a
theorem from GOHBERG, KRUPHIK [4], p. 170, for any vector ker A
there exists a vector
where the constant
c
y € ker B
from
||x-y|| < c ||A-B|| ,
such that
is determined only by the operator
||A—B|| < ||y||*||t1"Kí||.||G-P|| , for any
x
A • Since
e.. > 0 , one can find a
> 0
such that, for
||G-F|| < 6 . , there exists a vector y. € ker B with u u . Now we form the matrix function Y = (y1 ... y u ) .
||y.-x.|| < o j o
Since the matrix function sufficiently small
(x1 ... x Q ) (=G~ )
e• u , the matrix
least at one point of
Y
is non-singular, for
will also be non-singular at
T . Owing to assertion 2 ) of Lemma 6.7, there
exists a factorization of the matrix function Clearly, for given the inequalities ii j?:1 c
1
p
0 , one can choose ||y-¡-x.|| < e. J
J
J
(3=1,..,, n)
F
such that
e- , 3=1,..,,n imply
F_ = "í"^ such that
||X-Y|| < e , i.e.,
6.
In order to finish the proof of the simplified form of Theorem 6.15» 6 = min{6.i 3=1,...,n} . At the same time, we u have proved Theorem 6.15 in full, = it remains only to set
COROLLARY 6.5»
Assume the matrix function
G
to be factorable and
the tuple of its partial indices to be stable. Then, for every e > 0 there exists a tion
F
6 > 0
such that, for
||F-G|| < 6 , the matrix func-
admits a factorization in which each of the quantities
(6.17) is less then
s .
In fact, if the tuple of partial indices of the matrix function stable, then, for
6 > 0
small enough, the condition
is
and
G
||F-G|| < 6
implies the coincidence of the tuples of partial indices of Thus, Theorem 6.15 can be applied.
G
F
=
In brief, the latter result can be formulated in the following way: If the middle factorization factor A
is stable, then the factors
are also stable. Now vie intend to formulate Theorem 6.15 in terms of sequences.
244
G+
THEOREM 6,15' . Let
iG^}^
be a sequence of matrix functions
admitting a factorizat;ion with, one and the same tuple of partial indices and converging to the matrix function
G
which is also as-
sumed to be factorable and to have the same tuple of partial indices. Then one may choose factorizations manner that
= G^^A G~1
-» G + ,
in such a
(in the norm (5.8), where
G + are factorization factors of G . COROLLARY 6.5*»
Let
be a sequence of matrix functions
which converge to the factorable matrix function
G
with a stable
tuple of partial indices. Then, beginning with some element of the sequence, the conclusion of Corollary 6.5 is valid. For a factorable matrix function all partial indices of which axe equal to each other, Corollary 6.5 can be made more precise. This refinement amounts for stating that the closeness of the factorization factors of close matrix functions
F
and
G may be ensured by the requirement
G_(oo) = F_(co) . Up to now, in the present chapter we have been concerned with the following problems knowing the properties of a given matrix function, determine the properties of matrix functions sufficiently close to it. Now we turn to the "inverse" problem consisting in the determination of the factorization properties for the limit of a sequence of matrix functions, if we know the factorization properties of the terms of this sequence. Theorem 6.5 shows that any factorable matrix function tuple of partial indices a sequence
G with the
may be represented as the limit of
of factorable matrix functions the tuples of
partial indices
C*^^)!? = of which obey the condition J tj I
(*.) ^ ¿J
J
but, in other respect, they are not interconnected or joined with the tuple
(*,) . Vice versa, if the sequence of factorable matrix func-
tions
{G^ J } ^
converges to the factorable matrix function
according to Theorem 6.4, for sufficiently large 0 J— I
y
J
J— *
G , then,
k , the condition
is fulfilled. Finally, the limit of a sequence of 245
factorable matrix functions may not permit any f a c t o r i z a t i o n at a l l » However, we are able to indicate conditions under which the passage to the l i m i t does not go beyond the class of factorable matrix functions and does not influence on the values of p a r t i a l indices. THEOREM 6.16.
Let
{G^}^.«,
be a sequence of factorable matrix
functions converging to the matrix function
G . Then the following
assertions are equivalent: 1)
the f a c t o r i z a t i o n f a c t o r s of the matrix functions
chosen in such a way that || does not depend on 2)
G^^
may be
< M , where the constant
M < oo
k ; G can be factored and a l l matrix functions
the matrix function
G^^ , beginning with some number
k , have one and the same tuple
of p a r t i a l indices which agrees with that of the matrix function Proof.
G .
Suppose that 2 ) i s f u l f i l l e d . Due to Theorem 6.15 1 , the f a c -
t o r i z a t i o n s of {(G|k^)"1}
and
G^^
can be chosen in such a fashion that the sequences
{(G^)-1}
converge ( t o
G~1
and
G~1, r e s p e c t i v e l y ) .
In this case these sequences w i l l be bounded e i t h e r . Thus, 1 ) f o l l o w s from 2 ) . Conversely, l e t 1 ) be v a l i d . As i t was mentioned in the proof of Theorem 5.6, the operator
^ ( G ^ )
i s a regularizer f o r
- 1
considered in
(«")n
. Hence, there e x i s t s an equibounded
sequence of regularizers of the operators
. In accordance
with Theorem 1.11 this means that the l i m i t of the sequence i . e . , the operator operator
Tp(G')
0« (G< k >) , si T^(G) , i s also iredholm. The Fredholmness of the
can be shown in a similar way. With regard to Theorem
5.6, the matrix function
G can be factored. I t s tuple of p a r t i a l
indices w i l l be denoted by certain neighbourhood of
(*.)!?_,. . In virtue of Theorem 6.4, in a o J" ' G we encounter only such matrix functions
(x 1 .) f u l f i l the condition ( k . ) >- ( * ' • ) . J J J Since there e x i s t s only a f i n i t e number of such tuples, one of the
whose tuples of p a r t i a l indices
following two situations always applies: a ) there i s a neighbourhood of
246
G
such that a l l matrix functions
G^^
contained in i t have one
and the same tuple of partial indices ( * J } b) it is possible to (k ) " choose a sequence {G s all terms of which have one and the same tuple of partial indices
(x.,) ± ( x p . (k ) (k ) A (k ) Assume that situation b) applies. As the sequence G = G+ ^ G_ converges to
G
and
(x.) , where
|| A -(&+ k £ J V 1 -A (G^8^)""1!! =
= II(G^ ks) r 1 (G (ks) -G)(G^ ks) )" 1 || < M'llG^-Gll , then the sequence EV = (G.
)
A(G
) "
converges to A if
. Consequently, in any neigh-
bourhood of the matrix function A there exists a matrix function the tuple of partial indices of which is just the same as that of the matrix function G . According to Theorem 6.4, contradiction to the conditions V
(x.) A
a n d(x.)
, and A this is a ^ *
Summarizing, situation a) holds by all means, i.e., assertion 2) is true. The proof of Theorem 6.16 is complete. 6.7.
=
COMMENTS
The question of stability of partial indices was first considered in MANDZHAVIDZE [ 2 ] in connection with the problem of the approximate solution of the Riemann boundary value problem, theorems 6.1 and 6.2 as well as the criterion of stability of partial indices (Theorem 6.3)
were obtained by GOHBjSRG and KBE& [2,3] and BOJABSKI [1], The proof of Theorems 6.1 and 6.2 conducted here is close to the one suggested in MANDZHAVIDZE [ 5 ] . The same applies to the proof of the sufficiency in Theorem 6.3» The proof of the necessity in Theorem 6.3 given above generalizes correspondent arguments from BOJARSKI
[ 1 ] , GOHBERG, KBBiN [3] to the case of matrix functions with unbounded factorization factors. In Section 10.2 of the book OLANCEY, GOHBERG [3] another way of proving the necessity is explained, which is based on the following general result of WIDOM [3] related to perturbations of Fredholm operators: Let
T
be a Fredholm operator in the Banach space
be a subspace of there exists an and a number
[X] A € S
r > 0
such that, for every non-zero such that
f(Ax) 4=
such that, for any
0
X , and let S
x € X,
f € X* ,
• Then there exist
B € S
e 6(0,r) , at least one of
247
the defect numbers of the operator
T + eB
T = P+t~sGQ , S = {AP+B^: A,B 6
application of this result to the caae € L^} , where
s
is equal to zero. The
is an integer strictly included between the smallest
and largest partial index of the matrix function
G , proves the
necessity of condition (6.2) for the stability of partial indices. Theorems 6.4 and 6.5 and Lemma 6.1 are due to GOHBiSRG and KEfiiN [3]. The topological interpretation of Theorems 6.3 - 6.5 is given by the authors under the influence of BOJABSKl's paper [3]. Remark, incidentally, that in this paper there was proved the connectedness of the intersection of the sets functions continuous on r
with the class of matrix ^i"''*1 ^ ^ class of
and of the sets
matrix functions continuous on T
and factorable in
nectedness of the intersection of
C(r) . The con-
and the class of piecewise con-
tinuous matrix function was studied in GLEBOV, DEUNDYAK [1]. Furthermore, the question of connectedness of the sets of the density in Lra
of the set $
$M
themselves as also
of all ^-factorable matrix func-
tions remains to be solved. Theorems 6.6 - 6.13 are obtained by one of the authors (SPITKOVSKl¥ [2,3,5|10]). The idea of transition from the matrix function
G, to
its Cayley transform used in the proof of Lemma 6.2 is borrowed from KBUPNIK, NYAGA [1], where this device was applied to the study of unitary matrix functiona. V
In connection with Lemma 6.3, note that in the article of SPITKOVSKII [9] one can find the description of the class
S
consisting of all
those functions the multiplication by which does not violate the factorability in L^ . It appeared that this class does not depend on p and, being multiplied by a function
x
arbitrary ^-factorable matrix function
6
® » the partial indices of an G
behave precisely as in case
of a continuous function % , i.e., they are shifted by its index. Lemma 6.4 is due to DANILYUK [4,5], its precising for the case of a Lyapunov contour (Lemma 6.41) was obtained by one of the authors (SPITKOVSKII [2]). Lemma 6.5, with the help of which the latter lemma
248
was derived, is well-known for a long time and was already used in SIMOIffiNKO [4], The proof of Lemma 6.5 is borrowed from the book GOKBERG, KRUPNIK [4], In SHELEPOV [1] it was mentioned that, with regard to RADON's [1] results, Lemma 6.5 may be transferred to the case when
T
is a Radon
curve without cusps. Therefore, Theorem 6.11* can also be transferred to this case. Concerning the considerations after Theorem 6.13 related to the values of the partial indices, let us still mention the following. Generally speaking, starting from a matrix function it is not always possible to construct a tuple of j=1,...,n
continuous on
T
G n
and coinciding, for all
continuous on r, functions
A-i(t), ¿J
t e r , with the
tuple of its eigenvalues counted with regard to their algebraic multiplicity (as a matter of fact, in moving along the components of the contour
r , the continuous branches of the solutions of the equation
det(G(t)-\l) = 0
move into another, not necessarily coinciding with
the original ones). But if we do succeed in doing so, then it makes sense to speak about indices of eigenvalues of the matrix funktion t
G.
In GAKHOV's review article [3] among others there was posed the problem of describing all those matrix functions the partial indices of which coincide with the indices of eigenvalues. The complete solution of this problem has not been found yet
The relations
u
€ H(G(t)) ,
however, imply that, under the conditions of Theorem 6.13» the indices of eigenvalues coincide with the winding number of the numerical domain of the matrix function dices of
G
around zero and, thus, with the partial in-
G . In this way, matrix functions satisfying the conditions
of Theorem 6.13 form a certain subclass of the desired set. The application of Theorems 6.6 - 6.13 is impossible without the knowledge
of lower estimates for the values
n
( r ) . Assertion 1 ) of
Le&ma 6.2 allows for replacing the problem of finding such estimates by the problem of evaluating (or obtaining upper estimates for) the norms The problem of the description of all triangular matrix functions - whose partial indices coincide with the indices of the diagonal elements solved in Chapter 4 is a special case of this problem.
249
of operators Q
aad S . la case when the coatour I* is a circle, the
norm of the operator S has been calculated in all spaces
,
1 < p < oo (VERBITSKlí, KRUPNIK [1,2], KRUPNIK [4]). This fact will be used in the next chapter. With our definition of the noun in L®
(see
Section 1.2) the norms of the operators S and Q , generally speaking» depend on n . However, for p = 2 , such a dependence fails to •xiat. In SPITKOVSKlí [3] it was shown that the noma of the operators S
and Q in L»
are connected via the relation
||Q|| = ^(||S||+||8||~'1).
Therefore, the estimates for 6 2 n(r) mentioned in assertion 1) of Lemma 6.2 coincide. Unfortunately, we do not know whether these estimates are exact or not.
It is also unknown, which of these estimates is
the most exact one for p 4= 2 and a contour r
different from the
circle. Theorem 6.15 (on the continuity of the factorization factors for fixed partial indices) is due to SHUBIN [1]. He has also proved there that, if the matrix function G is a k times continuously differentiable (analytic) function of some parameter u
and the partial indices do
not depend on a> , then the factorization factors G +
are also k
times continuously differentiable (analytic) functions of (•) . The factorization of matrix functions depending on a parameter was also examined by NIKOLENKO [1,2]. In NIKOLENKO [1] he derived the stability criterion for partial indices in case when the parameter ranges over even-dimensional spheres or triangulations. In this paper it was furthefr shown that the triple fibre bundle, where
(T x T , p_
H X
T+
) forms a locally trivial
is the class of nxn matrix functions non-
singular and satisfying a Holder condition in 1 " U r and analytic in + 3H~ , is the class of Holder continuous matrix functions with the
h
tuple of partial indices from T x T
into X. _
X
_ k (=(x 1 ,...,h
)) , and p_ is the mapping x acting according to formula p_(P.,P ) = +J M ? +
X
-
t
In NTKQLBNKO [2] it is shown that this fibre bundle is trivial if and only if x1 = ... = x Q . Theorem 6.16 was first formulated in LITVINCHUK, NIKQLAICHUK, SPITK0V8K$I
[1]. 250
A series of papers is devoted to the approximate solution of singular integral equations (and, especially, to the vector-valued Riemann boundary value problem). A systematic explanation of the state of the arts (up to 1978) related to methods of their approximate solution the reader can find in the last chapter of the monograph
PRftSSDORF [1],
Concerning later results, see BABBSHKO [3], DIDENKO [1-3], DIDEHKO, TIKHONENKO [1,2], ZCEiOTAREVSKlf [1], PR&SSDOHF, SCHMIDT [1], SILHERMANN [1]. In MBUNARGIYA [1,2] several cases are examined in which the solution of the vector-valued Riemann boundary value problem with matrix G
+ XG 1
may be found as a series
k=o
, where
J?.[k) are suc-
cessively determined as solutions of Riemann problems with matrix and a free term depending on
GQ
J?^) (j=0,... ,k-1).
Now we focus our attention on another results associated with the stability problem and estimates of partial indices. KRAVCHENKO and v NIKGLAICHUK [1J have obtained formulae for partial indices of secondorder matrix functions such that at least one element of them does not degenerate on
r . These formulae involve the dimension of the kernel
of an integral operator which can be effectively constructed by a given matrix function. CHORIEV [1-3] has studied the relationships between stability of partial indices of sufficiently smooth matrix functions
G
and the validity
of Liouville's theorem for the equation 3U = BU , where
1
z eJ>+ , B(z) = 0
B(z) = £(z)"" a&(z) for
is an extension of the matrix function differentiable in Here
L^ (p > 2)
D(t) = diag[t k+1
GD ''
for
z
, and
into the domain J5+
in the generalized sense.
t k+1 ,t k ,...,t k ]
nulling the total index of
-
is a matrix function an-
G .
In LAX [1] it was established that the property of the partial indices of a matrix function
G
given on the circle to be equal to zero is
equivalent to the solvability of the Dirichlet problem for the differ-
251
eatial equation
= G^G
Gz .
In the author's opinion, the problem of finding estimates for the partial indices and of obtaining effectively verifiable conditions of their stability or non-negativity is still far from being completely solved and any new result towards its solution iH of considerable interest.
252
CHAPTER 7.
FACTORIZATION ON THE CIRCLE
The results of this chapter may be divided into two groups, which are associated with each other in a natural way. The first of them is formed by problems of factorization and ^-factorization on the circle
T
of
Hermitian (in particular, of definite) and unitary matrix functions» The properties in which these matrix functions are peculiar enable for obtaining more complete and exact theorems on factorization. Some of these theorems are useful, especially, for the study of relationships between necessary and exact conditions of factorability, a problem, which was already stated in Chapters 2 and 3» The second group represents essential strengthenings for the space L a ( T ) of a series of important results from the preceding chapter related to ^-factorization with non-negative, non-positive, stable, in particular, with equal partial indices of arbitrary matrix functions + from the classes
Lro , L ^ + C
and
0 . This group of results is based
on the utilization of exact estimates for the norms of the operators S, P,
PGCi, QGP, which hold in
L 2 ( T ) , but aLso on the application
of results of the first group concerning ^-factorization of matrix functions with the algebraic properties mentioned above. In Section 7.1 a definition of factorization specific for the circle T will be introduced, from which we immediately shall obtain the connection between factorizations of the matrix function the matrix function
G*
in
) ,
G
in
Lp(T)
and
q = p/(p-l) , which is of some
significance to what follows. In Section 7.2 we shall be concerned with factorization and 9-factorization of Hermitian matrix functions, where the structure of the factorability domain will be revealed, relations for partial indices will be derived and a necessary condition for the domain of factorability to be non-empty will be established* A representation for a Hemiitian matrix function factorable in
L2(T )
the total index of which is
equal to zero will be described. This representation enables us to
253
estimate the cumber of zero partial indices of a given matrix function G
with the aid of the absolute value of the signature of G .
Section 7»3 is dedicated to the factorization problem in L 2
of those
Hermitian matrix function for which the corresponding quadratic form preserves the sign* (The main result of this section is a theorem which asserts that, for+a positively definite matrix function G , the necessary condition G € L., of its factorability is also sufficient. The proof of this theorem rests upon the claim on the existence of a representation of a positively definite matrix function of a erertain outer matrix function
A
G
and its adjoint
as the product A* • This pro-
position is of independent interest and significance for applications. The aim of Section 7«4 consists in making more precise various results of 6.3 and 6.4. The most general result of this section is the theorem on the existence of a ^-factorization in L^
with coinciding partial
indices for those matrix functions the numerical domain of which may be locally (i.e., for any sufficiently small arc of the contour T ) included into a sector whose apex angle is less than
2it/max(p,q.) •
A special case of this theorem is provided by the assertion that every uniformly positively definite matrix function admits a ^-factorization with zero partial indices. It appears that the factorization factors of such matrix functions are necessarily bounded. This assertion, which is of independent interest (cf. Theorem 5.2 from Section 5.1), allows for reducing in Section 7*5 the problem of $-factorability of an arbitrary matrix function
G € LM
to the same problem for a certain unitary
matrix function. Moreover, this assertion permits us with the help of this reduction to obtain criteria of $-factorability in L a
with non-
negative, non-positive and stable (in particular, zero) partial indices. Hiffls criteria are the conversions (and that even in a stronger form) of corresponding sufficient conditions from 6.3. Thus, for the problem of ^-factorization in L S (T ) they are also necessary. Note that for unitary matriac functions the criterion of existence of a ^-factorization in L a
254
with definite partial indices will be derived from the sophis-
ticated result OQ the calculation of the norms of the Haakel operators PGQ
and
(¿GP , which has important applications beyond the factori-
zation theory for matrix functions either. Furthermore, we intend to specify the results of 7.4 and 7.5 for the case of a matrix function
G
which satisfies certain analytic condi-
tions, mainly for the case of a continuous matrix function
G . This
topic is pursued in Section 7«6. Here, in particular, it is established that the partial indices of a continuous strictly non-singular (i.e., satisfying the condition
0 ^ H(G(t)) ) matrix function
G
are equal
to each other. This result is a strengthening but also a simplification of Theorem 6.13 for the case when the contour
r
is a circle.
Section 7«7 contains information on the history of the subject and comments related to current literature. 7.1.
DEFINITION OF FACTORIZATION ON THE CIRCLE
In the present chapter we deal with the factorization problem in case when the contour T suppose that T
is a circle. Without loss of generality, we may
is the unit circle T = {£ s
= 1} •
In this case complex conjugation realizes a one-to-one correspondence between the classes L~
and L* (= H^) . Indeed, the function
defined in the unit disk belongs to the Hardy class the function ^
H^
f
if and only if
defined outside the unit disk by the equation
¥(£) = f(g"*1) lies in the class E^ , where the boundaxy values of the functions
f
and "i? are connected via the relation £(t) = f(t) .
Redenoting the matrix function and the matrix function
G_
by
we may claim that, in the case
G+
from the representation (2.1) by A
B* , in view of the remark made above, T = T , Definition 2.1 is equivalent
to the following one. DEFINITION 7.1.
A representation G = AAB*
will be called a factorization in
(7.1) of the matrix function
defined on the unit circle, if the matrix functions
A
and
G
B 255
(A-
and
B)
belong to the class
H^ (H^ , q = p/-(p—1))
and .A
i s a diagonal matrix function of the form ( 2 . 2 ) . From Theorems 1.17 and 1.18 i t i s clear that the requirements A-1
€ H^
A € L
are f u l f i l l e d i f and only i f
and
function
A
€ L
i s an outer matrix function 1 5 ,
. A similar assertion i s true f o r the matrix
B .
THEOREM 7.1. in
A
A € H^ ,
Lp
The matrix function
defined on T can be factored
G
i f and only i f the matrix function
L^ . In this case the tuple the tuple
(>1-;) u
)
G*
can be factored in
of p a r t i a l (¡.-indices of
of p a r t i a l p-indices of
G* and
G are connected v i a the
relations Hi = - * n _o+1 ,
j = 1,2,...,n .
In particular, the total q-index of p-index of Proof.
G*
(7.2)
i s opposite to the t o t a l
G .
We introduce the constant matrix
(
0 ...
1 The matrix
T
1
• ' ?..
| •
(7.3)
0
i s both Hermitian and unitary, i . e .
T = T * = T .
Taking these properties into consideration, the expression
G* = B/V*A*,
which i s obtained from ( 7 . 1 ) , may be rewritten in the equivalent form G* = B T ( T A » T ) ( A T ) * . Since
(7.4)
T A * T = U " 1 T = d i a g [ t ~ * n , . . . , t " " H l ] , the representation ( 7 . 1 )
i s a f a c t o r i z a t i o n of the matrix function
G in
equation ( 7 . 4 ) provides a f a c t o r i z a t i o n of
G*
i f and only i f in
L^
( t h e r e f o r e , the
f a c t o r i z a t i o n s e x i s t only simultaneously) and the corresponding p a r t i a l indices of
G
and
G*
are connected by the relations ( 7 . 2 ) , which
proves the theorem. THEOREM 7.1 .
A matrix function
G of class
L^,
defined on T
is
^-factorable in L p i f and only i f the matrix function G* i s fl-fadA nxn matrix function A i s called outer, i f i t s entries belong to - the class D and det A i s an outer function*
256
torable in
L^ • Moreover, the assertions concerning the values of
t o t a l and p a r t i a l indices formulated in Theorem 7.1 continue to be valid. Proof.
I f the matrix function
G i s not f a c t o r a b l e in
owing to the previous theorem, the matrix function able in
G*
i s not f a c t o r -
L^ , which i s consistent with the assertion to be proved. I t
remains to consider the case of a matrix function tored in
, then,
G which can be f a c -
Lp • According to Corollary 3*3 and the definition of
f a c t o r i z a t i o n , the representation ( 7 . 1 ) i s a ^ - f a c t o r i z a t i o n of Lp
i f and only i f the operator
K& = ( B * )
-1
A^QA
-1
K ^ = [(Al)*]"" 1 (TA*T)~ 1 Q(BT)" 1
in
i s bounded in
Lp , and the representation (7.4-) i s a ^ - f a c t o r i z a t i o n of i f f the operator
G
G* in
L^
i s bounded in
.
But the operator K^, = (A*)"" 1 A T^TB -1 =(A*)~ 1 AQB - 1 may be viewed as adjoint ( i n the sense of Definition 1 . 6 ) to the operator (B*)~ Q A A , i f we i d e n t i f y
with the dual of the space
L^
with the aid of the
b i l i n e a r form (f,g)
J g(t)*f(t)|dt| T In virtue oif assertions 2 ) and 3 ) of Lemma 3«3 the operators (B')-1QA'1A-1
=
Kg
and
Eire densely defined and closed. Therefore, a s s e r t i o n 4 )
of the same lemma may be applied, owing to which these operators are bounded only simultaneously. Thus, the operators
Kg
and
Kg*
considered in
L^
and L° , respec-
t i v e l y , are bounded only simultaneously. From here and Theorem 3*8 we deduce the assertion to be proved. COROLLARY 7 . 1 . provided that
=
The matrix functions
G and
G 6 L w , also $ - f a c t o r a b l e ) in
G* L2
are f a c t o r a b l e (and, only simultaneously.
In addition, t h e i r t o t a l 2-indices are opposite and the p a r t i a l indices are connected by r e l a t i o n ( 7 . 2 ) . Corollary 3 . 6 taken together with Theorem 7 . 1 ' leads to the following conclusion. O This can be established j u s t as the corresponding part from the - proof of Lemma 3»4-»
257
COROLLARY 7.2.
The matrix function
G € Lra
(G*)""1
if and only if the matrix function in
is left «-factorable in
L ^ , where the corresponding tuples of partial indices coincide.
Due to Corollary 7.2, a unitary matrix function for which
G(t)* = G(t)~
1
a.e.
on T
)
G
(i.e., a function
is left «-factorable in
if and only if it is right «-factorable in 7.2.
is right «-factorable
Lp
L^ .
FACTORIZATION OF HERMITIAN MATRIX FUNCTIONS
From Theorems 7.1 and 7.11 it is clear that Hermitian matrix functions (i.e. such that
G(t) = G(t)* a.e. on T
) play a special role in the
factorization problem with respect to T . THEOREM 7.2.
Under the mapping
ability (and, if
p -* p/(p-l), the domain of factor-
G € L ^ , then also the domain of $-fac to rability)
of a Hermitian matrix function
G
is transformed into itself. In
addition, for its partial p-indices, the relations H
d
*d
+
H
n-j+1
+
M
n-j+1
+
w
n-j+1
< 0
if
p > 2 ,
= 0
if
P = 2 ,
> 0
if
p < 2
(7.5)
are valid. The assertion of Theorem 7«2 follows from Corollary 7.1 and Theorem 2.1 (on the monotony of partial p-indices). COROLLARY 7.3.
The components of the factorability domain of a
Hermitian matrix function which correspond to positive
(negative)
values of the total index are situated strictly to the left (right) of the point
p = 2 . The component
T (G) , provided that it is not
empty, necessarily contains the point
p = 2 .
Consider the Hermitian matrix function
G
with non-empty factorability
domain. In accordance with Theorem 7.2
G
can be factored in
some since
p > 2 . If (7.1) provides a factorization of G
in
Lp
for
, then,
is Hermitian, equation (7.4-) yields a factorization of this
matrix function in
258
G
L^
L
. According to formulae (2.5)» which express the
connection between factorization factors from different factorizations of one and the same matrix function, we have A = BTH , where
H
(7.6)
is a polynomial matrix function the structure of which is
described in Chapter 2 immediately after formulae (2.5)» In particular, there was also shown that
det
H
is a polynomial whose degree is
equal to the difference of the total indices of G
in the considered
factorizations. In the case under study, thanks to Theorem 7.1 and Corollary 7.3» we may assert that this degree is equal to * (< 0) is the total p-index of
-2x , where
G .
Utilizing equations (7.1) and (7.6), we may represent the matrix function
G
in the form G = BTHAB* .
(7.7)
Consequently, for almost all
t 6 T , the quadratic forms associated
with the matrices
TH(t)A(t)
G(t) and
are congruent. Hence, the
signatures (i.e. the differences of the numbers of positive and negative squaxes of the corresponding quadratic forms) of these matrices also coincide a.e. on T . Since the matrix function
THA
is continuous
on T , its signature is a piecewise constant function of
t
the dis-
continuities of which are contained in the set of zeros of the function det (THA ) = (-1)QtKdet H , i.e. in the set of zeros of the polynomial det H . However, the latter vanishes at no more than
2|x|
points of
the circle T . In this way, the following statement has been proved. THEOREM 7.3. 7X(G) t. e T ,
Let
G
be a Hermitian matrix function. For the set
to be non-empty, it is necessary that there exist points j = 1,...,N
which partition T
into
N < 2|x|
arcs such that
u the signature of the matrix G(t) is constant on a each of them a.e.» COROLLARY 7.4-. For T 0 (G) to be non-empty, it is necessary that the signature of the matrix COROLLARY 7.5. For
G(t) is constant a.e..
T(G)
to be non-empty, it is necessary that
there exists a partition of TP into a finite number of axes such that»' on each of them the signature of the matrix
G(t) is constant a.e..
25S
With the help of Corollary 7*5 one can e a s i l y construct an example of a scalar function taking the values
1
a f a c t o r i z a t i o n in any of the spaces f(t) = 1
if
[V|t-l|]
and
-1
which does not admit
L^ • In particular, one may set
i s even, and
f ( t ) = -1
otherwise.
The conditions found in Theorem 7«3 are not s u f f i c i e n t f o r the domain of f a c t o r a b i l i t y of the matrix function G to be non-empty, even in +1 case we require G € L^ and N = 0 . As an example we consider the matrix function
G(t) = d i a g [ f ( t ) , - f ( t ) ]
, where the function ±1
real-valued, changes i t s sign i n f i n i t e l y many times and all
t € T , the matrix
G(t)
f
f
is
€ L^ . For
i s Hermitian and i t s signature i s equal
to zero. At the same time, the matrix function in question d i f f e r s from the Hermitian matrix function
c :)•
d i a g [ f , f ] , the signature of which
changes i n f i n i t e l y many times, by the constant multiplier Consequently, the f a c t o r a b i l i t y domain of
G i s empty.
Now we intend to consider in more detail an Hermitian matrix function G f o r which the component
T Q (G)
in this case the inclusion indices of
G
k^ > . . . > k., > 0
set
T(G)
2 € T Q (G)
necessarily holds and the p a r t i a l
are connected by relations
p a r t i a l indices of
THEOREM 7»4.
i s not empty. According to CoicLlary 7.3,
(7.5)»
Thus, the tuple of
G i s uniquely determined by the numbers (m > 0 )
of d i f f e r e n t positive indices and t h e i r
Assume that f o r the Hermitian matrix function i s non-empty. Then
G the
G admits a representation in the
form G
where
±1 A0
=
A
OAOAS
(7.8)
.
€ H, , hkn
\
t k l £, A0(t)= \ t"1^' X Il„
260
/
(7.9)
\| ,
J = I
sum i s equal to
and
1. = n-2 0
signature
a
1+
of
and
m E 1-t d=1 3
1
are integers such that t h e i r
and t h e i r d i f f e r e n c e equals the
G .
Before proving the theorem, l e t us remark that by
a
one has to under-
stand that value of the signature which i s taken by the matrix funcG a . e . on T • Because of Corollary 7.4-> such a value e x i s t s .
tion Proof«
Starting with an arbitrary f a c t o r i z a t i o n ( 7 . 1 ) of the matrix
function
G in
L2
and arguing as in the proof of Theorem 7.3» we +1
obtain equation ( 7 . 7 ) in which from one f a c t o r i z a t i o n of structure of
G in
B € Ha L2
and
H
i s a transition matrix
to another. Consequently, the
H i s described by assertion 2 ) of Theorem 2.2. With r e -
gard to relations ( 7 . 5 ) » we deduce the following description of the structure of the matrix function L e t the matrix function as the matrix function
W = TH .
W be partitioned into blocks in the same way A0
defined by equation (7.9)> and l e t these
blocks be numbered in l i n e s and columns by the indices from
-m
to m
from bottom to top and from the l e f t to the r i g h t , r e s p e c t i v e l y . Then: 1)
if
2)
W_ _
3)
if
r < s , then
W,, r , s„ = 0 , i s a constant non-singular matrix,
r > s , then
W_ I ,s
i s a polynomial matrix function such that
the degrees of i t s elements do not exceed formity, s e t
k g = -k —a f o r
s < 0 , and
( f o r the sake of unikQ = 0 ) .
Now we want to show that there exists a polynomial matrix function
¥
with a constant non-zero determinant such that the equation W(t)A(t) = ¥(t)A0(t)v(t)*
(7.10)
is valid. P a r t i t i o n i n g the matrix function as
¥
into blocks in the same manner
W and imposing on i t the additional condition ^•n I® os = 0
f
°r
r+s < 0 ,
(7.11)
261
we get a system which is equivalent to (7.10); t
= V^ »r.-vW V s . v ^ * *
V
•
where the summation on the right-hand side is carried out for v between -s and r , J = I for v 4= 0 Since the matrix function
lying
and J Q = J .
WA is Hermitian, the system (7.12) is trans-
formed into itself after conjugation and changing r
and s with each
other. Consequently, those equations with r < s may be omitted. The remaining equations of the system (7.12) are partitioned into 2m+1 groups, assigning to the j th group those of the equations for which r+s = d (o=0,...,2m) . The zero group consists of the equations w
r r ^ = „ = ^0,0„ 0,0
-r^-r r^* »
.
(7.13)
0,0„ .
For the solvability of the last equation, it is necessary and sufficient to equate the integers 1 +
and 1_ to the number of positive and
negative squares, respectively, of the matrix
j0
. The remaining
equations are always solvable. The solutions of all the equations (7.13) may be chosen in the class of constant matrices. Now we take advantage of the fact that the equations of the j th group involve only those unknown matrices Suppose that, for
_ for which 0 — < r+s — < J• r,s ¡j < 3 0 (< 2m+1) , the equations of the j th group
are solved, where the matrix functions Hr,s already obtained are polynomial with degree of its elements not exceeding k._+k_ r s . Bach equation of the (oq+1) th group may be rewritten in the form k +k » r . s ^ V S . - s *rf-r r*B,r( >* * ' = t+k w (t) S r," J » r ^ W v V v W * • +
J
t
t
The summation on the right-hand side is carried out for v lying between -s+1
and r-1 .
In view of the assumption stipulated the right-hand side of (7.14-) is a, polynomial matrix function the degree of the entries of which are not
262
g r e a t e r than 6®t
k_+k„ . S e t t i n g ¥ _ = 0 f o r s i r , from ( 7 . 1 4 ) we 1 9 S i n the form o f a polynomial m a t r i x f u n c t i o n the degrees o f
r , s„
the e n t r i e s o f which are a l s o l e a s than or equal t o For
k^+kg .
s = r , equation ( 7 . 1 4 ) reads as f o l l o w s ! 2 Re(t t
r
*\
(t)»*
_) »
—k rW (t) Z * r,—r* ' |v| 0 )
In f a c t , i f
t*1 \
\
0
and
A(t)*
,
/
- k , (= k 2 )
are i t s p a r t i a l 2 - i n d i c e s .
x., > 0 , then the mentioned representation exists by
Theorem 7.4-. I f representation
264
1 0
x 1 = 0 , then Theorem 7.4- ensures the existence of the G = AQ ^ ^
® j A* . I t remains only to remark that
7.3.
FACTORIZATION OF DEFINITE MATRIX FUNCTIONS
An important subclass of Hermitian matrix functions are positively (negatively) definite matrix functions, i.e. such that the signature of the matrix
G(t) is equal to
n
(-n) a.e. on T
. Since negatively
definite matrix functions become positively definite after multiplication by -1 , it is sufficient to study only positively definite matrix functions. If a positively definite matrix function is factorable in Lj , then, by Corollary 7.6, all its partial 2-indices are equal to zero. Moreover, 1+ = n
and
1_ = 0 , since only in this case the equation
1+ -
= n
may be guaranteed. Thus, for positively definite matrix functions, the factor A 0
is the unit matrix. Consequently, if a positively definite
matrix function can be factored in L 2 , then it admits also a representation G = AA* with
(7.15)
A-'U H 2 .
The necessary condition for T 0 (G) to be non-empty established in Corollary 7.4- (i.e. of factorability in L,) is fulfilled for a positively definite matrix function. If we complete this condition by the requirements
G
€ L, , which, axe obviously necessary for factorability«
then the obtained collection of conditions proves already to be sufficient. In other words, the following result holds» THEOREM 7.5.
A positively definite matrix function ±1 can be factored in h 2 if and only if G 6 L 1 .
G
defined on T
Theorem 7.5 may be derived as a consequence of a more general result on the representation of a positively definite matrix function
G
in the
form of the product (7.15) of an outer matrix function and its adjoint1). Let us begin with the scalar case. D The reader who is only interested in the problem of ^-factorization of matrix functions from the class L^ may omit all the material up to the end of the present section. The question of S—factorability of positively definite matrix functions of the mentioned class will be solved in 7.4- irrespective of Theorem 7.5.
265
LBMMA 7.1»
Let
representation
g
be a non-negative function defined on T
g(t) = |f(t)|* , where
tion, is possible if and only if tion
f
f
. The
is a certain outer func-
log g ( L 1 . If the desired func-
exists, then it is defined up to a constant multiplier with
absolute value 1. Proof.
Prom Definition 1.12 of an outer function and Theorem 1.15. it g = |f|a
is clear that the relation
holds if and only if
• Since the role of the function
a.e. on T
k
g(t) = k(t)2
in (1.7) may be played
by any non-negative function with summable logarithm, it follows that the condition
log g € L,
is necessary and sufficient for the existence
of the desired representation. If this condition is fulfilled, then the corresponding function defined up to the constant 7.1.
v
f
is
from relation (1.7), which proves Lemma
s
In particular, Lemma 7.1 allows for solving^ the question of factorability
in
L2
of a real-valued function to the very end.
THEOREM 7.6. Let 2 e J(G) 1) 2)
Proof.
be a real-valued scalar function. The inclusion
holds if and only if
€ L, G
G
and
takes values of one and the same sign a.e. The necessity of condition 1) is obvious} the necessity of
condition 2 ) results from Corollary 7.4-. If condition 1) and 2) are satisfied, then ±1 such that Lemma 7.1,
g
G = eg , where
€ L,
and
g = |f|* , where
its inverse to the class factorization of Now let
s
G € L1
G
is a non-negative (a.e.) function
is a constant equal to f
1
or
-1 . Due to
is an outer function belonging with
H 2 . Setting
A = f ,
B = ef , we get a
in L 2 . Thus Theorem 7.6 is proved.
=
be a positively definite matrix function of n th order.
We introduce the Hilbert space ^ (rows) f
g
defined on T
of n-dimensional vector functions
for which the value ^
/ f(e ie )G(e ie )f(e ie )»d© 1 >
All the integrals in the present section are taken over the interval [-m,it] . 266
makes sense and is finite. The scalar product in formula
is defined by the
/ f(eie)G(el6)g(eie)»de . We denote by £
(f,g) =
sure (with respect to the norm in ^ ) of the space L
the clo-
consisting of
all vector functions of the form f(e ie ) = where Let X Q space L Q
? e i k 9 f( k ) , k=o
(7.16)
(k=0,...,Nj N=0,1,...) are constant row vectors. be the closure (again with respect to the nonm in ^ ) of the of those vector functions
Clearly, HoX, Q
and
IiBMMA 7.2. Let
f €L
for which
dim Z |J£0 < n .
G € L1
be a positively definite matrix function of
n th order such that log det G € L., . Then
function. Since
implies that G = |G+|a , where G € L 1 , then ie
i0
From this it is clear that, for all ie
G+
is an outer
G + 6 H a . For an arbitrary function
ie
instead of J f(e )G(e )f(e )de (f,f) =
dim X. | |G+(0)f(0)|1 . Setting
g 6 L Q , we thus obtain the distance from is not less than
1
f,
i6
f = 1-g with
1 2
||1-g||^ = (l-g.l-g) ^ > |G+(0)|. Consequently,
to L Q
(and, therefore, also to the subspace X,
|G+(0)| . Thus, 3tQ
and
Returning to the general case, we denote by
dim( X J A
X.|(e
0)
= 1 •
) > ... > XQ(e "i A
the collection of all eigenvalues of the matrix G(e
J
A
)
) . Since
log X a (e i e ) < 1 | log X 3 (e i e ) = Ja log and
16 n XnCe ) = aJ log det G(e i6 ) 3 0=1
log det G(e ie ) =
E log \ A e i Q ) < log Xn(ei6)+(n-1 )log \,(e ie ) 0 d=i
< log \ n (e i e Hn-1)Xi(e l e ) < log \.(ei6)+(n-1) E \di (e i 6 ) 0=1 = log X a (e i e ) + (n-1)tr G(e ie ) , the conditions
log det G € L i
and
log ^
€ L,
are equivalent for a 267
)
positively definite matrix function JA
G- € L 1 • By '
iA tr G(e ) we denote
the trace * of the matrix G(eAW) . We shall make use of Its summability. Choosing a vector function
f €L
and denoting its j th component by
f • , we have u
/ f(eie)G(eie)f(eie)*d6
(f,f) = ^
* i(ei6)*Q(ei0)f(eie)* d6 = ^ Jf / XQ(eie)|f.,(eie)|de .
> h
The inclusion 1
X Q = |X+|
log X Q € L,
, where 1
inequality
established above permits us to assert that
is an outer function. In addition, due to the ft 1 ft
0
|*+(0)f¿(0)1» .
Hence (f,f)> letting
E U + (o)f 1 (o)|» = |x+(o)|*!|f(o)||a . J
0=1
f = a - g , where
a is a fixed constant vector and
over L q , we find that the distance from |X+(0)|||a|| . Since L Q tor does not belong to
a to g
g
ranges
is not less than
is dense in £ Q , every constant non-zero vec. Consequently,
dim( X|5C0) = n, which
proves Lemma 7.2. = THEOREM 7.7. The matrix function
G
defined on V admits a repre-
sentation G = AA* with an outer matrix function 1) G
A
if and only if
is positively definite,
2) log det S C L ) ( 3) 1 og||G|| € L, . If the indicated representation exists, then the matrix function
A
is defined up to a constant right unitary multiplier. Proof. Assume that G = XX* , where
A = (ajjk)jtk=1
i s 8X1
outer ma-
trix function* Then, for an arbitrary n-dimensional vector x , (G(t)x,x) = (A(t)A(t)*x,x) a HA(t)*xj]» > 0 1
holds a.e. on T , i.e.,
> tr G(e ie ) is the sum of the diagonal elements of G(ei6), where G € L 1 a
266
the matrix function G
is positively definite and condition 1) is ful-
filled. Moreover, from Lemma 7.15 and the relation
det G = |det A|1
we deduce that condition 2) is also satisfied. Purthermore, we denote by values of the matrix
Xi(t) > «.* > ^("O
G(t) at those points
is positively definite. Then
tlie
collection of eigen-
t € T where this matrix
||G(t)|= (Afc^CoKt^Ct)*))1/2 = ^ ^ ( t ) )
= Xi(t) . We have, on the one hand, Xi(t) > (Xi(t)...Xn(t))1^n = (det G(t))1/Q . On the other hand, \.,(t) < X1(t)+...+ X a (t) = tr G(t) =
J i 8 3d ( t ) = ;},Li | a ^ ( t ) | 2 - a* ^ l a d k ( t ) l • T h u a ^ log det G(t) < log||G(t)|| < 2 log n + max log|ajk(t)| 0
a.e. on T
.
With regard to the definition of an outer function each of the functions a ^
belongs to the class D . Therefore, it is either identi-
cally equal to zero or, taken absolutely, coincides with a certain jA outer function. In any case, / logla^j^e
)|d6 < + co and, conse-
i
quently, J max log|a;.j£(e ®)|de < + » . Prom the inequalities obtained for log||G(t^|j and the summability of the function log det G , we thus conclude that log||G|j € L 1 .In this way, condition 3) is also necessary for the existence of a representation (7.15). It is obvious that, replacing in (7.15) the matrix function A by AU, where U
is a constant unitary multiplier, we do not violate equation
(7.15) and do not go beyond the class of outer matrix functions.Vice versa, assume that, besides of the representation (7.15), the equation G s BB* with an outer matrix function B 1
is valid* Then
1
A~ (t)B(t) = (B~ (t)A(t))a.e. on
T .
—"1
The latter equation means that the matrix function
U = A B
is uni-
tary and, in particular, belongs to the class L^ . Moreover, this matrix function is outer along with
A
and
B. Therefore, on the basis
of Theorem 1.18,9 from the condition U € LCO we can conclude that U € H w . To verify that the matrix function U* (= B~1A) lies in the class
^
can be done in a similar way. But then
U € ^
H L~ , so
that, by Theorem 1*28, the matrix function U is constant. Thus B s All , where U is a constant unitary matrix*
269
It remains to prove the existence of a representation (7.15) in case the conditions 1) - 3 ) a-r-e fulfilled. ^Replacing the matrix function by
f
G , where
G
f(t) = ||G(t)|| , we get a summable positively definite
matrix function with summable logarithm of the determinant. If the existence of a representation tion
B
f
G = BB*
will be proved, then setting
function with the property
|f + |
4
with an outer matrix func-
A = Bf + (where
= f
f+
is an outer
existing in view of Lemma 7.1),
we shall obtain a representation (7.15) of the original matrix function
G • Hence, without loss of generality, we may assume the matrix
function
G
to be summable.
If we stipulate the mentioned assumption and use the notations introduced before Lemma 7.2, we observe that, due to this lemma, the orthogonal complement of X
with respect to X
choose an orthonoimal basis bitrary
f eJf and
{» d )J a 1
is n-dimensional. Now we
in
*
0
siQCe)
k = 1,2,... , e l k f € t Q , then for all
/ f(e ie )G(e ie )q. ;j (e ie )»e ikti de = 0 ,
la particular, taking
f = ^
for
^
f € Jt : (7.17)
, we have
/
d (e ie )»e ik8 de = 0 , s 1,...,n{ k s 1,2,... . Changing in the last equation
j
and
1
with each other and passing
to the adjoint, we find that this equation continues to be true also for
k = -1,-2,... . But this means that the measure JA 4 ft "1ftv
j(e
)*d6
is orthogonal to all trigonometric polynomials
vanishing at zero. In its turn, this allows for coacluding that the e > 0
and
outside the disk of radius we conclude that
274
F
are equal t o each other.
tence of a continuous and non-vanishing function where
such that
Y T • Then the i n t e r v a l
nent of the $ - f a c t o r a b i l i t y domain of the matrix function p a r t i a l p - i n d i c e s of
have (*••»)
a^ < 2u/max(p,q) ( q = p / ( p - 1 ) )
H ( F ( T ) ) C ST
with the end points
defined on T
t € T there e x i s t s an arc
, a scalar
a t the o r i g i n of apex angle
P € LCO
H(G(T))
s
a . e . on T
a . e . on T
with centre at
0
. Since
, H(G(T)) l i e s
and in the sector
Sa,
i s l o c a t e d to the r i g h t of the v e r t i c a l l i n e
passing through the point have
(e cos ^ , 0 ) . Consequently, a . e . on T
we
d(G(x)) > e cos oc/2 , so t h a t Theorem 7 . 9 may be applied to the
matrix function +1
M = Re G • Owing t o t h i s theorem,
€ Hw . Denoting
J£ = im G , we obtain
then
N i s Heimitian together with
that
+
N = M~1K(M* )~ 1 . i'he m a t r i x
K . Since
|(K(T)X,^| < t g SJ||M*(T)X|| • . Denoting
the equation
+
G = M + iK = M+M* + iK =
U + ( I + iM^ 1 K(M*)~ 1 >l» = M + (l+iN)M* , where function
M = MM** , where
H(G(T)) C S a ,
M»(T)X
by
y
and using
(K(T)X,X) = (M + (T)N(T)MJ(T)X,X) = (N(-C)y,y) , we f i n d
|(N(T)y,y)| < tg £j||y||1 . This means t h a t the numerical domain o f
the matrix
N(T)
i s s i t u a t e d on the i n t e r v a l
[ - t g Sj, tg Sj]
Consequently, the numerical domain o f t h e m a t r i x on t h e i n t e r v a l which connects the points
I + iN(x)
1 - i « t g Sj
and
This i n t e r v a l l i e s in t h e disk with centre a t the point radius angle
a.e,
onT,
i s located
1+i«tg ^ . ( s e c * £¡,0)
of
s i n ( a / 2 ) / ( c o s I ( o < / 2 ) ) , which i s v i s i b l e from the o r i g i n a t the a
. In addition, the matrix
I + iN(x)
i s obviously normal.
Therefore, Theorem 6 . 1 0 can be applied t o the m a t r i x f u n c t i o n
I + iN .
Due t o t h i s theorem, t h e i n t e r v a l
and
Ap
with the end points
p
q
l i e s e n t i r e l y i n a c e r t a i n component of the domain of $ - f a c t o r a b i l i t y and a l l p a r t i a l i n d i c e s are equal t o each o t h e r . Since the i n t e r v a l passes through the point 2 and the m a t r i x function
I + iN
Ap
has a u n i -
formly p o s i t i v e r e a l p a r t , we may claim t h a t , according t o Theorem 7 . 8 , a l l i t s p a r t i a l 2 - i n d i c e s are equal t o z e r o . Consequently
Ap £ $ 0 ( I + i N j .
Apparently, t h i s implies t h a t
r-indices
of
Ap c $ q ( G )
and a l l p a r t i a l
G , r € Ap , are equal t o z e r o . U t i l i z i n g Lemma 6 . 3 , we conclude
t h a t the i n t e r v a l
Ap l i e s inside a c e r t a i n component of the domain
of $ - f a c t o r a b i l i t y of the m a t r i x function
F
( r € Ap)
=
of
F
are equal t o each o t h e r .
and a l l p a r t i a l r - i n d i c e s
Theorem 7»10 i s an e s s e n t i a l g e n e r a l i z a t i o n of Theorem 6 . 1 0 , the s e c t o r
S^.
contains the disk
A^.
because
and the rigorous requirenent of
normality i s no longer imposed upon the m a t r i x
F(t)
i n Theorem 7 . 1 0 .
Moreover, Theorem 7»10 g e n e r a l i z e s Theorem 6 . 1 1 * , t o o . In f a c t , under the condition of Theorem 6.11 1 , the s e t s separated from zero by the s t r a i g h t l i n e
||F(T)||
H(F(T)) , t € y^
are
which i s d i s t a n t from zerc
275
by more than cos(it/2max(p,q)) . At the same time, these sets are coQoeatrated in the unit disk, as the numerical domain of an arbitrary matrix A lies in the disk with centre at zero and radius ||Aj| . Thus, th This reformulation looks as follows. THEOREM 7.11. Assume the matrix function F of class L^ defined on T to be such that, for every point t € T , there exist an arc Y^ (it) and a straight line
which does not pass through zero
and has the following property« for almost all T € H(F(t)) is separated from zero by is ^-factorable in L t
» "bbe set
. Then the matrix function G
and all its partial 2-indices are equal to
each other. Finally, note that, as also in Section 6.4-, under the conditions of Theorem 7.8 - 7.11, there exists not only a left but also a right frfaotorization of the matric function & (and F) , where the right partial indices coincide with the left ones and with each other. 7.5. DEFINITENESS CRITERIA AND STABILITY OF PARTIAL INDICES OF BOUNDED MEASURABLE MATRIX FUNCTIONS One more circumstance (besides equations (7.19) and Theorem 7.9) thanks to which, ultimately, wt succeed in proving assertions converse to Theorems 6.6 - 6.9 for p = 2 , is the existence of exact formulae for the norms of the operators QGP and PGQ in the case r = T . LEMMA 7.3. Let G be a matrix function from L^ defined on T . The norms of the operators QGP and PGQ in the space L* are calculated by the formulae 276
IIQGPII = ^gLj \\G-H\ , Proof»
llPGQll = ^mig HG-HI .
We shall consider the spaces L^
and L«
(7.20) of oxn matrix func-
tions as Banach spaces the aozm ia which is defined by the formulae ||All, « ¿ j
J
tr(A(eie)A(ei0)*)1/2de
and ||A||, - (Jp / tr A(e ie )A(e i8 )-de) 1 / 2 , respectively. The space dual to L^
may be identified with the space of measurable
essentially bounded matrix functions (supplied with the norm (3*19)) by assigning to the matrix function
G € Lw
the functional
* G (A) = ¡g S tr A(ei0)G(eie)*de .
(7.21)
With regard to the mentioned correspondence the subspace orthogonal complement to the subspace from
H*
The space
H*
H^
is an
of those nxn matrix functions
which vanish at zero* Lt
supplied with the scalar product
(A,B) » J j / tr(A(eie)B(eie)*)d6 becomes a Hilbert space, where for all
A,B € L a ,
||AB||< ||A||,||B||t .
In this way, the set of matrix functions of the form F = AB with
(7.22)
At B«Hj , || Aj| ] , || B|| t < 1
space
H*
lies in the open unit ball of the sub-
of the space L 1 . Let us show that it is dense in this ball.
For this purpose, above all, note that an arbitrary matrix function F € H* , UFlh < 1
for which
log|det F| € L 1
admits a representation
(7.22). Indeed, in this case the matrix function
(FF*)1/2 satisfies
the conditions of Theorem 7-7. Thus, (FF*)1^2 = AA* , where
A € Hi
is
an outer matrix function. Besides, || A||J = j - / tr A(eie)A(ei0)*de = ¡g J tr(F(e ie )F(e ie )*) 1 /2 de = IIFIU < 1 .
277
In order t o s a t i s f y ( 7 . 2 2 ) , we s e t
B = A~1F . Since
IIBit * - i f / t r ( B ( e i e ) B ( e i e ) * ) d e - Jp / tr(A(eier1F(eie)P(eie)»(A(e±e)-)-^e - J f / tr(A(eie)*A(ei6))de - ^
/ tr(A(eie)A(eie)»)d6
- Il*lli < 1 . the matrix function
B
i s situated in the open unit b a l l of the space
L t • Furthermore, since
B
open unit b a l l of the space
i s of c l a s s
D , then i t also l i e s in the
H* • Hence the desired representation has
been constructed. In turn, the s e t of matrix f r a c t i o n s log|det F| < L ,
F € H* , ||F|| ^ < 1
i s dense in the unit b a l l of
f o r which
H* . In f a c t , with the
aid of an a r b i t r a r i l y small perturbation of the matrix function may guarantee t h a t
det F(o) + 0 . Applying now Jensen 1 s inequality
(G0LUZ1N [ 1 ] , PRIVALOV [ 2 ] ) to the function ^
F we
det F(€
, we get
/ log|det F ( e i e ) | d 6 > log|det F(0)| > - « . id
Multiplying the matrix functions
F
and
B
by
e
be seen t h a t the s e t of matrix functions of the form B € Ht , j|A|| i , ||B||, < 1
i s dense in the ball
{F €
Now we intend to show that the norm of the operator coincides with the norm of the functional on
, i t can e a s i l y AB with
A € H^
i ||F|| 4 < 1 } . PGQ in
Lj
defined by formula ( 7 . 2 1 )
Hlf .
By the very d e f i n i t i o n , I I + g U J = s u p { ^ ; t r ( F ( e i 0 ) G ( e i e ) * ) d e « ||F|h < 1 , F € H+} , H1 where
sup
may be taken not over the whole of the unit b a l l , but only
over i t s dense subset consisting of matrix functions of the form with
278
||Fi||* < 1 ( 3 = 1 , 2 ) ,
F, € h£ , F 2 € h7 . At the same time,
F 1 FJ
Jjp/
triF^e^JP^e^me16)')^
=
J
tr(FI(ei8)*G(eie)»F1(eie))de
= h
tr((G(eie)PI(eie))*F1(ei6))de
- f e W
(G(eie)Ft(eie))»P1(eie)de
.
Denoting the columns of the matrix functions ( 3 = 1 , 2 ) , instead of
/
(G(eie)F
t
F^
by
(el8))»F,(eie)de
we may write the
matrix- the ( i , k ) th entry of which i s the s c a l a r product ( i n and
L ? ) of
Gf^2^ . Therefore
J j tr / (G(eie)FI(ei0)/F1(eie)de =
The condition
||3?J|a < 1
(f^.Gft2))
i s equivalent to the inequality
J
,2 iif£dV < 1 * * k=1
£
(3=1,2).
Thus, i t only remains to note t h a t , under the conditions h
Z o4dV < ICssi sup E
Summarizing,
1
(3=1,2) , PGQf^.2^)
||PGQ|| =
4 l ) € ( H t ) a , 4 2 > 6 ( & T ) a , the value
i s equal t o ||PGQ|| . H1
. An a r b i t r a r y extension of the functional
t g l j . ^o the whole space L 1 i s of the form ^ a ^ & ( F ) = • ( , ( ? ) f o r a l l P 6 Ht , then G-G* € with
T € H~ . Conversely, f o r any
. Besides, since 1
, i.e.,
T € H~ , the functional
G1 = G-T i s
an extension of the functional
t ( j l » + * Using the f a c t t h a t in extending H1 a functional the norm does not decrease, we recognize t h a t
||PGQ|| < ll+g.jll = ||G-T|| f o r a l l
Y € H~ . At the same time, due to the
Hahn-Baaach theorem, there e x i s t s an extension which preserves the norm. This proves the second of the formulae ( 7 . 2 0 ) . J t i l i z i n g the f a o t that nQGPQ - llPG'Gfl a
QGP i s an operator a d j o i n t to
PG*Q , so t h a t
migHG*-Y|| = m±5l|G*-X»|] = mij||G-Xj| , KH» XeHoo
YCHte
279
the f i r s t formula may be readQy derived from the second one. Thus, the proof of Lemma 7*3 i s complete.
=
The criterion of non-negativity (non-positivity) of partial 2-indices, f i r s t of a l l , w i l l be proved f o r unitary matrix functions. Above a l l , this i s caused by the fact that the proof of the corresponding c r i t e r ion f o r arbitraiy matrix functions employs the statement related to unitary matrix functions as an auxiliary result. However, there are, in addition, two more important reasonst 1 ) f o r unitary matrix functions the definiteness criterion f o r partial indices can be formulated in the most transparent form, revealing the relationships between the structure of the set of partial indices and the approximation properties of matrix functions, and 2 ) matrix functions occurring in applied problems are often unitary (see, f o r instance, KREIN, MSLIK-1DAMXAN (1 ] , TROITSKli [ 1 ] ) . THEOREM 7.12. The operator
U be a unitary matrix function defined on T
Let
P + UQ i s invertible from the right ( l e f t ) in
i f and only i f there exists a matrix function
X € H^
(H~)
•
L? such
that ||U - Xl| < 1 • Proof.
(7.23)
Owing to assertion 1 ) of Lemma 3»5» the operator
P + UQ
invertible from the right only simultaneously with the operator
is T Q (U) H /
which, in turn, i s invertible from the right only simultaneously with the operator
P + QUQ . The l a t t e r is invertible from the right i f and
only i f the operator (P+QUQXP+QUQ)«1 = (P+QUQ)(P+QU*Q) = P+QUQJJ«Q = P+QUU»Q-QUFU*Q = P+Q-(QUP)(PU*Q) = I-(QUP)(QUP)* i s invertible
1 >.
Since
||QUP|| < ||U|| = 1 , then f o r the i n v e r t i b i l i t y
of this operator, i t i s necessary and s u f f i c i e n t that
||QUP|| < 1 .
I t remains to apply the f i r s t of the formulae (7*20). The case of i n v e r t i b i l i t y from the l e f t can be regarded analogously. Thus Theorem 7.12 i s proved, 1>
s
Here we used the f a c t that a linear bounded operator T acting in a; Hilbert space i s invertible from the right i f and only i f the opei>ator TT* i s invertible.
280
THEOREM 7.13«
Assume t h a t
U i s a unitary matrix function defined
on T . Then the following assertions are equivalent! 1)
U i s « - f a c t o r a b l e in
Lt
and a l l i t s p a r t i a l indices are non-
negative (non-positive), 2)
there e x i s t s a matrix function
(l£) 3)
and and
of
JT 1 € M*
Y € HQ ( l £ )
such t h a t
Y~1€ H~
U coincides with the number o f
det X inside the unit disk and with the number of poles
det Y
Proof.
such t h a t
||U-Y|| < 1 .
In t h i s case the t o t a l index of zeros of
(H~)
||U-X|| < 1 ,
there e x i s t s a matrix function
(H+)
X 6 H*
outside i t .
We shall conduct the proof f o r the case of non-negative p a r t i a l
i n d i c e s . Since, f o r any matrix function
X € Lw ,
IIU - X|| = ||I - XII*|| ,
(7.24)
then the inequality ( 7 . 2 3 ) guarantees the a p p l i c a b i l i t y of assertion 2 ) from Theorem 6 . 6 to the matrix function
U* (with
X+ = X , X_ = I ) ,
according to which t h i s matrix function i s ^ - f a c t o r a b l e in
L2
and i t s
p a r t i a l indices are non-positive. In view of Corollary 7 . 1 , from here we deduce the $ - f a c t o r a b i l i t y in
Lx
of the matrix function
U as well
as the non-negativity of i t s p a r t i a l i n d i c e s . Thus, 2 ) implies 1 ) . Now we are going to prove that 1 ) implies 2 ) . From the 5—factorability of the matrix function
U and the non-negativity of i t s p a r t i a l indices
we conclude t h a t the operator
P + UQ i s i n v e r t i b l e from the r i g h t
(Corollary 3 . 8 ) . By Theorem 7 . 1 2 , there e x i s t s a matrix function s a t i s f y i n g the inequality ( 7 . 2 3 ) . We want to show t h a t c a l c u l a t e the t o t a l index of equation
T e (XU*) = QXU*L * fo)
which holds because of ( 7 . 2 4 ) , the operator operator
X^e M*
X6H* and
U . To t h i s end, we shall employ the n
= WD«|
(H a ) a
+ QXFU*| . = T g (X)T 0 (U*) (H,)a * ^ '
QXP a 0 . As follows from r e l a t i o n s ( 7 . 2 3 ) and TQ(XU)
TQ(U') = T^(U)*
i s i n v e r t i b l e . Due to Corollary 1 . 2 , the
i s Predholm simultaneously with the operator
JEQ(U) . Consequently (see Theorem 1 . 9 ) » the operator Predholm and i t s index i s opposite to the index of
T^(X) TQ(U*)
i s also and, thus, 281
coincides with the index of the operator Theorem 3*15 we conclude from the tion of
X € H*
that
X" 1 « M*
det
X
of the matrix func-
fl-faotorability
and, due to Theorem 2.6, the t o t a l index
X ( i . e . , the index of the operator
of zeros of
. On the strength of
T ^ ( X ) ) coincides with the numbeir
in the unit disk. Thus, the equivalence of as-
sertions 1 ) and 2 ) as well as the v a l i d i t y of one of the formulae f o r the total index
TJ have been proved. The equivalence of assertions 1 )
and 3 ) and the Becond formula f o r the t o t a l index can be established in a similar way. OORfir.T.ABY 7.10. on T 1)
s Assume
U
to be a unitary matrix function defined
. The following assertions are equivalent! U is
fr-factorable.in
La
and a l l i t s p a r t i a l indices are equal
to zero, 2)
there e x i s t s a matrix function
and 3)
15
such that
X €
such that
H*
|JX-Ui| < 1 , there e x i s t s a matrix function
and
||X-U|| < 1 .
The transition from unitary matrix functions to arbitrary matrix functions of class
Lm
may be accomplished with the aid of the following
auxiliary r e s u l t » LEMMA 7.4-. Let the matrix function G given on T s a t i s f y the con±1 dition G 6 L m . Then i t can be represented in the form G = AU ,
(7.25)
but also as G = VB* , +1 +1 A , B € H00 and the matrix functions
where
(7.25') U
and
V
are uni-
tary. Proof.
The matrix functions
GG*
and
Theorem 7.9. Therefore, the equations +1
A~
+1
, B~ € H^
are v a l i d . Setting
G*G meet the conditions of GG* = AA* , G*G = BB*
U = A
-
G , V = G(B*)
with
, we may
guarantee that relations (7.25) and (7.25 1 ) are f u l f i l l e d . Thus we are only obliged to check that the matrix functions 282
U and
V
are unitary«
U(t)U(t)* = A ( t ) - 1 G ( t ) G ( t ) n A ( t ) T 1 = A ( t ) - 1 A ( t ) A ( t ) » ( A ( t ) T 1 = I a.e. on T
. The unitarity of the matrix
verified.
=
V(t)
can analogously be
Equations (7.25) and (7.25 1 ) mean that the matrix functions V
G, U
and
are factorable (S-factorable) only simultaneously, where the tuples
of their partial indices coincide. Now, finally, we are prepared for proving the existence criterion for a
factorization in THEOItEM 7.14-.
L2
with definite partial indices*
For a matrix function
G € L^
defined on T
, the
following statements are equivalent« 1)
2 € «(G)
2)
there exists a matrix function and
3)
and all partial indices of
and G
X_ € H~
such that
XT 1 « M~
X + € M*
such that
H*
|| I—X+G|| < 1 , = Y+Gq , where
a.e. on T 5)
are non-negative,
||I-GX_|| < 1 ,
there exists a matrix function
4)
G
,
G = GqY_ , where a.e. on
Y++ € E* , Y; 1 € M+ , d(G Q (t)) > d > 0 00 ' Y_ € M~ , Y ^ C l £
, d(G Q (t)) > d > 0
T .
If these conditions hold, then the total index of the matrix funcG
tion
coincides with the number of poles of
number of zeros of ber auf zeros of
det Y + det X_
det X +
and with the
in the unit disk, but also with the numdet Y_
and the number of poles of
outside)
the unit disk. Proof.
The implications 2 ) ==> 1 ) and 3) ==> 1 ) are special cases of
statement 1 ) from Theorem 6.6. If 1 ) is fulfilled, then due to Corollary 3.4,
G
function with
G
€ L ^ . Thus, Lemma 7.4 can be applied. The unitary matrix V
defined in this lemma is S-factorable in
Lt
together
and its partial indices are non-negative. According to Theorem
7.13, there exists a matrix function ||V-X|| < 1 . Setting
X €
X_ = (XB"""1)» , where
such that B
M*
and
is the matrix function
283
from representation (7.25 1 ) , we get
I_6 ^
f
j T ' U M~
and
|I- 2 ) . In order to v e r i f y the implication 1 ) ==> 3 ) , we introduce the matrix function
U
from representation (7,25)
such that we s e t
t
||U-Y|| < 1
X+ = I » A ~ 1 . Then
and a matrix function
Y € M~
e x i s t i n g by Theorem 7.13« Furthermore,
X+ €M+ , J^1 => A(Y*)~ 1 €
and
||I-X+G|| = ||I-T*A-1AU|| - || I—T*U|| = ||U*-Y*|| » ||U-Y|| < 1 . In t h i s way, we have checked that statements 1 ) , 2 ) and 3 ) are equival e n t * Now we want to show the equivalence of assertions 2 ) and 5 ) . I f 2 ) i s t r u e , then the matrix function real p a r t , because Setting
has a uniformly p o s i t i v e
Re(GX_x,x) = ( x , x ) - R e ( ( l - G X _ ) x , x ) > (1-||I-GXj| )||x||a.
Y_ = ST1 , we conclude that 2 ) = > 5 ) . Conversely, i f 5 ) i s
f u l f i l l e d , then the condition where
GX_
||I-GXj| < 1
is satisfied for
X_ = iilT 1 ,
i s some p p s i t i v e constant (concerning the choice of n, see
the proof of Lemma 6 . 4 ) . Thus, 2 ) ==> 5 ) . The implication 3 ) ==> 4 ) can be v e r i f i e d analogously. The formulae f o r the t o t a l index established in the theorem can be proved
i a just the same way as i n Theorem 7*13* Thus, the proof of theorem
7.14 i s complete. COROLLARY 7.11.
= For the matrix function
G € L^
given on T
, the
f o l l o w i n g statement are equivalent: 1)
2 € ®(G)
and a l l p a r t i a l indices of
2 ')
there i s a matrix function
X.+ € 0 H* 0
G
are equal t o zero,
such that
+ 0H*0
and
H~
and
||I-X+G|| < 1 , 3)
there i s a matrix function
4)
G = Y + G q , where
TQ 6
5)
G = G0Y_ , where
+1 lT €
III-GXJ < 1 ,
+1
.
X_€ H^
such that
, d(GQ(t)) > d > 0
a . e . on T
,
, d(GQ(t)) > d > 0
a . e . on T
.
In t h i s way, statemenifll) and 3 ) of Theorem 6.6 as well as Lemma 6.4 admit an inversion f o r the f a c t o r i z a t i o n problem in
284
L»
on IT
.
Apparently, the correctness of the inversion of Theorem 6 . 7 - 6 . 9 and of the remaining statements of Theorem 6 . 6 may be proved in a s i m i l a r manner. In t h i s case one of the matrix functions by which the matrix function
G in the formulations of the indicated theorems i s m u l t i -
plied may be chosen to be the i d e n t i t y . In summary, f o r the ^ - f a c t o r i z a t i o n problem in the space
La
on T we
have derived c r i t e r i a of non-negativity, non-positivity, and equality to zero of p a r t i a l i n d i c e s . In view of i t s p a r t i c u l a r importance we no» s t i l l want to formulate the c r i t e r i o n of s t a b i l i t y . THEOREM 7 . 1 5 . able in
Ii«
The matrix function
7.6.
given on T
is «-factor-
with a stable tuple of p a r t i a l indices i f and only i f +
one can find an integer IT
G € Lw
and
k
and matrix functions
|| I - t ' ^ X j < 1 ,
X+ € H^ such t h a t
|| I-t" k ~ 1 X + G|| < 1 .
ON PARTIAL INDICES OF CONTINUOUS MATRIX FUNCTIONS
In Chapter + 6 we have already used the f a c t that the additional assumpt i o n G € L~ + C excludes the dependence o f the 8 - f a c t o r a b i l i t y property and the values of p a r t i a l indices on the parameter value +
In t h i s way, f o r
p .
G € L~ + C , Theorems 7 . 1 4 , 7.15 and Corollary 7.11
proved above f o r the f a c t o r i z a t i o n in
Lt
pass into c r i t e r i a o f non-
negativity, s t a b i l i t y and equality to zero of p a r t i a l indices r e l a t e d to f a c t o r i z a t i o n in a r b i t r a r y
, 1 < p < a> . In p a r t i c u l a r ,
remark applies to continuous matrix functions
this
G .
Supposing the requirement of f a c t o r a b i l i t y in C (which i s stronger ±1 than the condition G~ € C) to be f u l f i l l e d , i t seems t h a t we may go even f u r t h e r . Namely, one can claim that the conditions of non-negativ^i t y ( n o n - p o s i t i v i t y , equality to zero, s t a b i l i t y ) of p a r t i a l indices mentioned in Section 6 . 5 will remain necessary even in case the additional demand of r a t i o n a l i t y i s imposed upon the matrix functions X+ , I +
involved in them. I t should be noted t h a t in t h i s case the
proof of necessity i s not based on the sophisticated Lemma 7.3» Now we are going to present the exact formulation and the proof f o r the s i t u a tion whan the p a r t i a l indices are equal to zero. 285
THEOREM 7.16.
Assume the matrix function
factorable in
0
G
defined on T to be
and all of its partial indices to be equal to zero.
Then there can be found polynomial matrix functions
X1
and
X,
whose zeros of the determinant lie outside the unit disk and such that ||I - X1G|| < 1 Proof.
, ||I - GXJ|| < 1 .
(7.26)
By assumption, the factorization of the matrix function
of the form functions
G = AB* , where —1
Y., = jiBA
and
+1
A-
+1
,B € 0 —1
Y 2 = nAB
also belong to
inequalities
0
and are non-
|X ^ 0 . Since
I - Y,G = I - jiBB* , IQ - GY? Q= I - HAA* , then choosing — (0, min{||A||
is
. Therefore, the matrix +
degenerate in the unit disk for arbitrarily chosen
interval
G
Ji from the
,||B|| }) , we may ensure the validity of the
||I-Y.,G|| < 1 , ||I-y
matrix polynomials with arbitrary degree of accuracy. Choosing as matrix polynomials sufficiently close to
Y^
2
we
ij g
may guarantee both
the validity of inequality (7.26) and the non-degeneracy of
^ 2
the unit disk, which proves Theorem 7.16. s Finally, we intend to present a proposition which is obtained from Theorem 7.11 under the additional requirement of continuity of the matrix function THEOREM 7.17.
G . The partial indices of a continuous strictly non-
degenerate matrix function are equal to each other. Proof.
With regard to Definition 6.3 the condition
fulfilled for all
t € T . Owing to the convexity of the numerical do-
main, we may claim that there exists a straight line H(G(t)) from zero. As the matrix function straight line with
T
l^
0 $ H(G(t)) is
G
separating
is continuous, the
will separate from zero also all the sets
close enough to
H(G(t))
t . In this way, the conditions of Theorem
7.11 are satisfied. Due to this theorem, the partial indices of
G
(coinciding with its partial 2-indices) axe equal to each other, which proves Theorem 7.17«
286
=
COROLLARY 7.12. and for a l l trum of
Suppose the matrix function G i s continuous on T
t €f
G(t)
G(t)
i s normal,and the convex hull of the spec-
does not contain zero* Then the p a r t i a l indices of G
are equal to each other* The assertion of the corollary i s correct, because the numerical domain of a normal matrix coincides with the convex hull of the spectrum. In particular, i f all
G i s a unitary matrix function, then
G(t)
i s , for
t € T , a normal matrix with a spectrum concentrated on the unit
c i r c l e . Therefore the following statement i s true. OORnr.T.ARY 7.13.
If
U i s a unitary matrix function continuous onT
whose eigenvalues, for any t € T ,
axe concentrated on an arc of the
circle the end points of which are seen at an angle l e s s than it , then a l l p a r t i a l indices of COROLLARY 7.14-.
U coincide.
Assume G to be a continuous second-order matrix
function given on T , where, for a l l with eigenvalues
Xi(t)
p a r t i a l indices of
t € T , G(t)
i s a normal matrix
and X»(t) • For the coincidence of the
G , i t i s s u f f i c i e n t for the quotient X 1 ( t ) / X a ( t )
to be non-negative for any t € T . Indeed, the numerical domain of the matrix function G(t) val with the end points *i(iO/Xi(t)
Xi(t)
i s an inter-
and XaC*) • The condition imposed on
dust means that this interval does not contain the zero
point. Incidentally, the structure of the numerical domain for second-order matrices can be easily described, even i f they f a i l to be normal (HALMOS [ 1 ] ) . Namely, i f
A.,
and
are eigenvalues of the second-
order matrix
and x a
are normed eigenvectors associated
A and x 1
with them, then H(A)
i s an e l l i p s e with focuses
and \ a
and a
large axis U1-X2I 0-|(*i,x.)|«)V2 if
'
\ i + \ 2 , and a disk of radius
A-M || and centre
\ , if
\ 1 = \ 2 = \ . From this we derive the next r e s u l t . 287
SORQLLARY 7.15. Let
G
be a continuous second-order matrix func-
tion* Furthermore, assume that values of the matrix
G(t)
and
Xi(t) x,(t)
and
X 2 (t)
and
are the eigen-
x a (t)
the normed eigen-
vectors associated with them. The following condition is sufficient for the coincidence of partial indices of
G s
M t ) | + |X.(t)| > |Xi(t)-Xa(t)|(1-|x1(t)>x2(t))|»r'l/2 must hold at those points
t € T at which
\.|(t) ^ X 2 (t) , and
2|X(t)| > ||G(t) - X(t)I|| is vaLid at those points
t € T at which
Xi(t) = X a (t) (= \(t)).
In connection with Corollary 7.14- the following example is of some significance. Let G(t) - J
where
k > 0
The matrix
is integer.
G(t)
is simultaneously Hermitian and unitary, its eigen-
values do not depend on
t
and are equal to
Xi(t) = 1
and
X»(t)= -1.
At the same time,
«< x*:')(:
so that the partial indices of
G
are equal to
k
and
-k • For
k = o,
they coincide, although the assumption of Corollary 7.14- is not fulfilled} for
k > 0 , the partial indices of the matrix function
G
do
not coincide. Thus, the sufficient condition for coincidence of partial indices established in Corollary 7.14- is essential but not necessary. 7,7, COMMENTS The relationship between factorizations of the matrix functions
G
and
G* in case of Holder matrix functions mentioned in Theorems 7*1 and 7.11 was established by SHMUL'YAN [2]. Relation (7.5) from Theorem 7.2 for the same case was also proved by him.
288
Theorem 7.3 and i t s C o r o l l a r y 7.5 are g i v e n i n SPIIKOVSKII [ 6 ] , Theorem 7.4- and C o r o l l a r y 7 . 8 f o r the case of matrix f u n c t i o n s w i t h Holder elements were proved in NIKQLAICHUK, SPITKOVSKII [ 1 , 2 ] | i n SPITKOVSKli [ 7 ] they were extended t o the general case. A s p e c i a l kind o f f a c t o r i z a t i o n of Hermitian matrix functions with z e r o p a r t i a l
indices
i s presented in SHMUL'YAN [ 2 ] . C o r o l l a r y 7.6 i s also proved t h e r e . Theorem 7.4- may be used f o r the c l a s s i f i c a t i o n of s h i f t s in a space with i n d e f i n i t e metric i n case of a f i n i t e - d i m e n s i o n a l i s o t r o p i c subspace (concerning t h i s matter, see the note of one of the authors i n the review R e f e r a t i v n y i Zhurnal Matematika 1983, 3B, 1001 of the a r t i c l e BALL, HELTON [ 1 ] , where the inverse way of reasoning was gone: Theorem 7.6 was deduced from r e s u l t s r e l a t e d t o s h i f t c l a s s i f i c a t i o n ) . A $ - f a c t o r a b i l i t y c r i t e r i o n in
L2
as w e l l as a method f o r constructing
a f a c t o r i z a t i o n and c a l c u l a t i n g p a r t i a l i n d i c e s o f a Hennitian secondorder matrix f u n c t i o n with negative determinant and d e f i n i t e diagonal elements are described in LITVINCHUK, SPITKOVSKli [ 1 , 2 ] . In p a r t i c u l a r , i n these papers i t i s established t h a t the general case of such a matrix f u n c t i o n can be reduced to the study of a matrix f u n c t i o n o f the kind
(
|u| 4 -1
m \ I
In t h i s case the matrix f u n c t i o n Q
(» € L j
.
i s ^ - f a c t o r a b l e i f and only i f
does not belong t o the l i m i t spectrum of the operator (H() ( i . e . as an eigenvalue of
1
1
as an s-number
H(w)H(»)*).
The proof scheme of Theorem 7.4- given here was used by DIDKMO and CHEENBTSKli [ 1 ] in studying the f a c t o r i z a t i o n problem f o r orthogonal matrix f u n c t i o n s . Namely, in t h i s a r t i c l e i t i s shown t h a t , f o r a Holder orthogonal matrix function
G , equations ( 7 . 5 ) are f u l f i l l e d
and there always exists a factorization ( 2 . 1 ) subjected to the a d d i t i o n a l conditions tion
= G_G^ = T , where
T
i s the matrix d e f i n e d by eques-
(7.3). 289
Lemma 7.1 i s a r e s u l t of SZEGB ( s e e , e . g . , HOFFMAN [ 1 ] ) obtained by him as a generalization of the i e j e r - R i e s z lemma which asserts that any trigonometric polynomial non-negative on T coincides with the square of the modulus of some algebraic polynomial. Lemma 7.2 and Theorem 7,7 are reformulations of an important proposition from the theory of stochastic processes ( s e e , f o r example, HOZANOV [ 1 ] ) . The extension of this statement to the s e c t o r i a l case and the history of the problem can be found i n KBeIN, SPITKOVSKII [ 1 , 2 ] . In the a r t i c l e KBEIN, SPITKOVSKll [ 3 ] the results of the papers just mentioned, in p a r t i c u l a r , the theorems on f a c t o r i z a t i o n of s e c t o r i a l matrix functions were applied f o r obtaining generalizations of the Szego l i m i t theorem. In turn, these generalizations can be used f o r the discussion of some problems of s t a t i s t i c a l physics in a similar manner as the corresponding results f o r the scalar case were used in VLADIMIROV, VOLOVICH [ 1 , 2 ] . We would l i k e to remark that methods and results of f a c t o r i z a t i o n theory have been used f o r extending the Szego l i m i t theorem before the paper of KHEIN, SPITKOVSKII [ 3 ] , t o o . L e t us r e f e r , f o r instance, to one result from WIDOM [ 3 ] due to which, f o r a matrix function class
G^
-
lim exp — C"*1 2it o
log det G ( e i 6 ) d 6 . e
are the values of the harmonic continuation of
c i r c l e with radius Toeplitz matrix Gj
from the
H^ + 0 , the l e f t and r i g h t p a r t i a l indices are equal t o zero,
lim n -» oo Here
F
Q (< 1)
(G.
of the matrix function
and
G on the
i s the determinant of the block-
constructed by the Fourier c o e f f i c i e n t s G .
In case of a contracting p o s i t i v e l y d e f i n i t e matrix function
G , the
material of Oh. 5 of the book SZ.-NAGY, FOIAS [ 1 ] i s also related to Theorem 7.7. The special kind ( 7 . 1 5 ) of f a c t o r i z a t i o n of a p o s i t i v e l y d e f i n i t e matrix function s a t i s f y i n g a Holder condition was established by SHMDL'YAN [ 1 ] . Theorems 7.5 and 7.9 are e x p l i c i t l y formulated (as c o r o l l a r i e s of more general propositions) in SPITKOVSKli [ 2 ] , however, as a matter of f a c t , they were known even e a r l i e r .
290
The boundedneaa of the factorization factors of a positively definite matrix function proved in Theorem 7*9 generalizes ( f o r r • T ) the r e sult of Lemma 6.5 from the scalar case. In Chapter 6 the proposition which stated that the multiplication by a positive function t i b l e in
L^
a
inver-
does not go beyond the class of $-factorable matrix func-
tions was easily derived from this lemma. The l a t t e r result, however, cannot be transferred to the case of a positively definite matrix function
G , even i f
T = T » in the paper of KRUPNIK and ROZENBERG [1 ] i t
was proved that there exist piecewise continuous 2x2 matrix functions and
B such that
A ia ^-factorable in
d e f i n i t e , but the product
A
L^, B i s uniformly positively
AB f a i l s to be ^-factorable in
L p . An
example of two uniformly positively definite piecewiae continuous matrix functions of second order the product of which i s not ^-factorable in L a was constructed by one of the authors in SPITKOVSKIÏ [ 4 ] , Theorem 7.8 i s due to SIMONENKO [ 4 ] . The equality to zero of the partial indices of a matrix function factorable in
0 and with uniformly posi-
tive real part was shown by GOHBERG and KREIN [ 3 ] . The factorability in L2
and the equality to zero of the partial indices of matrix functions
of the type
I + F
with
||F|| < 1 were established by WIENER and MASANI
[ 1 ] . Notice that every matrix function with a uniformly positive real part may be transformed into the type just mentioned via multiplication by a positive constant. In connection with Theorem 7,3 we also note that on every connected r e c t i f i a b l e closed contour different from the circle there exists a rational matrix function with uniformly positive real part and non-zero partial indices (VIROZUB, MATSAEV [ 1 ] ) . Such matrix functions exist even for
ns 2
(MARKUS, MATSAEV [ 2 ] ) .
Theorem 7.10 has been proved by one of the authors (SPITKOVSKIÏ [ 1 0 ] ) . A slightly different formulation of this theorem ia given in SPITKOVSKIÏ [ 5 ] » In case of unitary matrix functions Theorem 7.10 changes over into a reault of KRUPNIK, NYAGA [1] (see also KRUPNIK [ 4 ] ) coinciding with thé reformulation of Corollary 6.4, where equations (7.19) are taken into
291
account. This theorem also covers the factorability criterion of a matrix function
G
with zero partial indices which is discussed in
VERBITSKlï, KRUPNIK [2], Furthermore, notice that the questions of Fredholmness, index and one-sided invertibility of the operator Tf(s) = sf(s) + S ^ l
J
dt
which was examined by another method in FAOUR NAZIH [1] (concerning this topic, see the note of one of the authors in the review Referativnyï Zhurnal,Matematika 1980, 10 B, 674 of the paper in question) may be studied with the aid of Theorem 7.10. The factorization problem of locally sectorial (i.e. satisfying the condition H(F(t)) c s t
(x e Yt)
of
speaking, unbounded matrix functions
Theorem 7.10) but, generally
V F was studied in SPITKOVSKII [7J.
In this paper the notion of canonical factorization was introduced. »
On the one hand, it generalizes the corresponding notion from KREIN, SPITKOVSKII [1,2] (especially, the representation of a positively definite matrix function as the product of an outer matrix function and its conjugate) and, on the other hand, the notion of factorization in L2
with coinciding partial indices. Moreover, it is shown there thatt
for locally sectorial matrix functions, a canonical factorization is determined up to constant multipliers. In connection with this it should be mentioned that till now a definition of factorization on the circle which comprehends in a certain sense both factorization in L^ and representations of the fonn (7.15) and is unique in the sense that it could be reconstructed by the factor A with the same degree of arbitrariness of a factorization in L^
has not been found yet.
F;>om our point of view, the problem of finding such a definition is very important for the needs of a logically well-composed structure of factorization theory. Theorem 7.11 in the scalar case was proved by DOUGLAS, and WE3QM [1J. In this case the conditions of Theorem 7.11 may be formulated in a more elegant fashion. Namely, the function Theorem 7.11 (for 292
F
satisfies the conditions of
n = 1) if and only if the convex hull of thé set of
its essential limits at every point
t € T does not contain zero. With
this in mind, in the paper DOUGLAS, WIDOM [1] there was posed the following problem* Is the condition of non-degeneracy at every point t € T
of all matrices from the convex hull of the essential limits of
a matrix function rability of
F
(e L^) given on T
F
in L a
sufficient for the $-facto-
with zero partial indices? This question was
positively answered by GLANGSX [1] under the additional supposition that, at every point
t € T , the matrix function
F
has no more than
two limits. In the general case the answer to this question is negative» In the article functions
F
AZOFF, CLANCEY [1]
one can find examples of matrix
satisfying the Douglas-Widom demands, but whose partial
2-indices are not equal to zero. Moreover, there are cited examples of matrix functions factorable in L 2
F
satisfying these demands, but in general being not at all.
v
__
Lemma 7.3 for the scalar case was proved in ADAMYAN, AEOV, KBEIN [1], DUKHOVNYI [1] and for the matrix case (and the case of an operator function, which we do not touch upon) in ADAMYAN, AEOV, KEffifN [2], NEHABI [1]. The main ideas of the proof described here are borrowed from ADAMYAN, AEOV, KREiN [1], POUSSON [1], In the present book we do not mention the following sophisticated question naturally arising in connection with Lemma 7.3s Under which conditions is the matrix function
XQ
(Yq, respectively) on which the minimum in (7.20) is attained
unitary and to which degree are the properties in which the matrix function
G
is peculiar acquired by the matrix function
G - XQ
(G - Y ) ? It appears that the last question is closely related to the properties of the factorization factors of
G ; concerning this subject,
see the paper ADAMYAN, AEOV, KEEIN [1] quoted above. In this connection we still refer to another paper
(SILBEBMjmN [1]),
that the best approximation of a function but one points
t € T
G
where it is shown
(€ L M )
analytic at all
can be everywhere discontinuous. In this way,
the local principle does not work here. Theorem 7.12 in the scalar case was proved by LEE and SABASON [*l] Theorems 7.13 and 7.14 in the scalar case were established by WIDOM [1] 293
and DEVTNATZ [1], and in the matrix aase but for zero partial indices by POUSSON [1] and RABINDRANATHAN [1] (in other words, in the latter two papers Corollaries 7.10 and 7*11 were shown). In a general form Theorems 7.13 - 7.15 were presented by one of the authors (SPITKOVSKII [2,10]). The device of transition to a unitary matrix function described in Lemma 7.4 was suggested by RABINDRANATHAN [1]. In the paper SPITKOVSKli [6] a modification of the Rabindranathan method was proposed which consists in the multiplication of the studied matrix function 1
A**'
on the left and by
- 1
(B*) '
on the right, where
outer matrix functions from the representations
A
and
G
by
B
are
2
and
AA* = (GG*)^
1 2
BB* = (G*G)' ^ . In particular, on such a multiplication Hennitian matrix functions change into matrix functions which are Hermitian and unitary simultaneously (applying a notion usual in matrix theory, such matrix functions are called J -matrix functions). There are two situations in which the factorization problem for J -matrix functions can be solved trivially. This is the scalar case, where we simply deal with a function having the values
+ 1 , and the definite case, in which an
J-matrix function may be reduced to a constant one which equals
-T or
- 1 . On the strength of this simple consideration in SPITKOVSKli [6] a generalization of Theorem 7.6 to the case
p + 2
is proved. Moreover,
it is clarified that the requirement for the total index to be equal to zero can be omitted in Corollary 7.9» Incidentally, Theorem 7.6 and Corollary 7*9 themselves, as far as the authors know, have not been published previously. We intend to note that for an arbitrary J -matrix function, certainly, there exists a criterion for the partial indices to be equal to zero formulated in terms of the behaviour (dependence on
t) of the subspace
of its invariant vectors, since the matrix function itself may be reconstructed uniquely by this subspace. One sufficient condition of this type is presented in the article SPITKOVSKli [6]. Unfortunately, a criterion itself has not been obtained yet.
29^
In connection with the theory of canonical d i f f e r e n t i a l equations the f a c t o r i z a t i o n of unitary matrix functions defined on the real l i n e has been studied by KREIN and IvlELIK-ADAMYAN [ 1 , 2 ] . Among other results they proved, in p r i n c i p l e , that, f o r a given matrix function can f i n d a matrix function
Y 6 H~
such that
X + Y
X € H* , one
i s unitary almost
everywhere on T and has zero parti-al indices i f and only i f A procedure of finding the matrix function f i n e d by
||PXQ|| < 1 .
Y , which i s uniquely de-
X , i s also described there.
Concerning other work dedicated to the s p e c i f i c character of f a c t o r i z a tion of matrix functions having one or another additional algebraic property, we mention the a r t i c l e of EEINSTEIN, SHAMASH [ 1 ] , In t h i s paper afl algorithm f o r constructing a f a c t o r i z a t i o n of the form G ( s ) = X(s)X* ( - s ) real l i n e with
f o r a rational matrix function
G(s) = G1(-s) , G ( i s ) > 0
G considered on the
i s presented.
Theorem 7.16 was proved in SPITKOVSKII [ 1 0 ] , c f . also SPITKOVSKlf [ 2 , 3 ] } Theorem 7.17 and i t s Corollaries 7.12 - 7.15 are borrowed from SPITKOVSKli [ 1 ] , wheras the example inserted a f t e r Corollary 7.15 i s taken from SHMUL'YAH [ 1 ] . In terms of Toeplitz operators ( i . e . operators of the form theory of the f a c t o r i z a t i o n problem in
L2
Tp(G)) the
on the c i r c l e f o r the scalar
case i s explained in detail in Ch. 7 of the book DOUGLAS [ 2 ]
In
particular, in the book just mentioned one can f i n d an interesting r e sult on the connectivity of the spectrum of the operator arbitrary
5 £ L ffl
T^(G)
for
obtained by WIDOM [ 2 ] as well as an analogue of t h i s
result f o r the case of an essential spectrum. When diagonal matrix functions were f i r s t dealt with, we already noticed that the property of the spectrum and the essential spectrum just mentioned disappears in passing over to the matrix case. In the examples known to the authors the number of connected components of the ( e s s e n t i a l ) spectrum does not exceed the order of the matrix. I t i s of some i n t e r e s t to find out whether this law remains true f o r a l l matrix functions from 1>
L00 „ .
See also the monographs HALMOS, SUNDER [ 1 ] and BOUCHER,S3LBERMANN [ 1 ] .
295
CHAPTER 8.
CONDITIONS OF «-FACTORABILITY IN TH3 SPACE L . CRITERION OF S-FACTORABILITY IN MEASURABLE MATRIX FUNCTIONS
OF BOUNDED
la this comparatively small chapter we shall be concerned with classes of matrix functions from
L CO
^-factorable in the spaces
defined on a contour of class
and
Lp(r) , where we pursue the aim to select
such classes which are as wide as possible. For the construction of classes of matrix functions from the classes studies previously in Chapters 5, 6 and 7 which admit a ^-factorization we shall use the e-local principle (Theorem 3.22) and the properties of a matrix function F € L
to preserve $-factorability on multiplication by a matrix func-
±
tion from the classes
L^ + C
(Theorem 5.5)» As a matter of fact, this
general approach forced us from the very start to give up any attempts to obtain, simultaneously with conditions of $-factorability, any conclusions about the values of partial indices. The conditions of factorability in
L^
derived below are sufficient. However, for
in case of a Lyapunov contour
p = 2
r , we are also able to substantiate
their necessity. A criterion of 4-factorability of a matrix function G from
Jjm
in the spaces
with
p ^ 2
fails to be known hitherto.
Now we intend to describe the contents of the present chapter in more detail. Section 8.1 is of auxiliary character. On the basis of the e-local principle the operation of transition from a certain class of matrix functions from
L^
to a wider class
H
A
preserving the
property of $-factorability is introduced in it. In addition, in 8.1 properties and estimates for the radius
n (T)
of the largest
neighbourhood of a unitary matrix function entirely consisting of matrix functions which are ^-factorable in
will be established.
The preliminary results are used in Section 8.2 in order to formulate a sufficient condition of $-factorability in
L^ .
This condition consists in the membership of the matrix function the class tions
296
F
B^ a ( r ) from
L
G
to
which is constructed by some class of matrix funcwith the help of the method described in 8.1 and is
determined by one of the conditions ensuring ^ - f a c t o r a b i l i t y of in
Lp • In case of a Lyapunov contour
the class
B (r) x^ 9
I*
can be weakened. I f G € Bg
contour, then the condition
the conditions determining
p = 2
Q(r)
F
and
T
i s a Lyapunov
proves to be an exact condi-
t i o n of 4 - f a c t o r a b i l i t y . This r e s u l t i s explained in Section 8.3« Comments on current l i t e r a t u r e are given in 8 . 4 . 8.1.
AUXILIARY RESULTS
DEFINITION 8 . 1 .
Let
A
be a certain class of matrix functions from
L^ . The class of a l l matrix functions requirements w i l l be denoted by e x i s t matrix functions i,t€
-0
G
2)
the matrix functions
+
0
»
EV t € A
at the point
i^t
6
L
G
»
+
and
G
s a t i s f y i n g the f o l l o w i n g
: f o r every point and 0
G^ t € L0„0 +, +.
such that
• G+
^
are s - l o c a l l y equivalent
t ,
I t i s c l e a r by the very d e f i n i t i o n that the class The operation
of t r a n s i t i o n from
choosing the class
B = "2
the class
t € T , there
A
to
K
li
contains
A .
i s idempotents
as the i n i t i a l one and constructing by i t
, we see that i t does not contain any new matrix functions
( i n comparison with The operation
"X), i . e .
2 = "X .
i s of i n t e r e s t f o r us, since i t does not v i o l a t e
the $ - f a c t o r a b i l i t y of a matrix f u n c t i o n . To be more exact, the f o l l o w ing r e s u l t holds. TH-SORKiii 8.1. and
Assume
A
to be an a r b i t r a r y subclass of the class
L^
U (C (1,OO)) a set l y i n g in a c e r t a i n component of the $ - f a c t o -
r a b i l i t y domain of every matrix function from
A . Then
U
i s a sub-
set of some component of the $ - f a c t o r a b i l i t y domain of a l l matrix functions from class
H. .
In case of a one-point set $ - f a c t o r a b i l i t y in 4 — f a c t o r a b i l i t y in
Lp L
U (U = { p } )
Theorem 8.1 simply means that
of a l l matrix functions of the class of the matrix functions of the class
A implies "X .
297
Proof.
Starting from the matrix function
we reconstruct the matrix functions
G € TL and
G+ ^
and the point t € T t involved in Defini-
tion 8.1. Let
p
be any point of the set
is ^-factorable in tion
L^
8180
t 6 r , the matrix functions the point
F^ (€A)
and, according to Theorem 5« , the matrix funcia
Gt = G+
U . Then the matrix function
^-iao'torable in G
and
G^
• Since, for all
are s-locally equivalent at
t , Theorem 3.22 enables us to make a conclusion about
faotorability of the matrix function
G
in
In this way, we have verified that the set $-factorability of every matrix function
L^ . lies in the domain of
U G
from the class
A . Now
we are still obliged to prove that this set belongs entirely to one component of the S-factorability domain, i.e., for any (Pi < P») , the total p i - and p t -indices of
G
p ctg(u/2 max(p,q)) . Since the value |s| a as also 6' Q ( r ) Ti Tj *i p p D Thus, f o r the case of a c i r c l e , the inequalities in relations ( 8 . 1 ) and ( 8 . 2 ) become equalities. 303
i s one and the same f o r a l l smooth contours, i t s u f f i c e s to v e r i f y the opposite inequality f o r
r = T • But in t h i s case the inequality
|s|
n < c t g ( n / 2 max(p,q)) P i s completely proved. =
r e s u l t s from r e l a t i o n ( 7 . 1 8 ) . Thus Lemma 8 . 3
L
Remark t h a t , f o r any contour
r
of c l a s s
, proposition 1 ) of Lemma
6 . 2 along with inequality ( 8 . 2 ) enable ufi to claim that 6
p
—sia('n:/max(Pi^)) •
quantities class
t h i s way, f o r smooth contours, the
I a
a t t a i n the l a r g e s t possible value f o r contours of
Q (r)
. Clearly, at the same time the value
L
l e s t of a l l possible values. 8.2.
SUFFICIENT CONDITIONS OP
DEFINITION 8.3« functions
r
Q
takes the smal-
P
FACTORABILITT
To the c l a s s
G given on
|s|
B^
Q
( r ) we assigns those nxn matrix
f o r which, f o r every point
t € r , one
can specify an arc y t containing + _ + i t as well as matrix functions 5 +. ,TJ i. £ l o"o + 0 such that G. + € L„co + C and,* f o r P+. TJ = G.+ ,+«GG +w, * a t l e a s t one of the following r e l a t i o n s i s f u l f i l l e d » 1)
ess sup||I-It(T)|| < 6'
2)
ess i n f d ( F t ( r ) ) > Tey t *
3)
the s e t
(r) ,
Vl-(6'n(r))» ess P» n
sup||Ft(T)|| ,, xeY t
U H(Ft(x)) ess sup||Ft(T)|| T€y t
i s separated from zero by
a s t r a i g h t l i n e whose distance to zero i s greater than
4)
there e x i s t s a disk
angle
a^ < 2 arcsin
the matrix
F^.(t)
which i s v i s i b l e from the origin a t an a (r)
and such that almost everywhere on
i s normal and t h e i r eigenvalues are located in A^..
I t turns out that a l l matrix functions from the c l a s s ^ - f a c t o r a b l e in THEOREM 8 . 2 .
B p a (r)
are
L^ . Moreover, the following r e s u l t i s t r u e . The interval
Ap i s completely contained in a c e r t a i n
component of the domain of $ - f a c t o r a b i l i t y of any matrix function from the c l a s s
304
B
Q (r)
.
Proof«
Godsicier t h e c l a s s
A
of those matrix functions
(= F)
for
which a t l e a s t one o f t h e r e q u i r e m e n t s 1 ) - 4 ) o f D e f i n i t i o n 8 , 3 i s filled, contour
and t h a t on t h e c u r v e r • Evidently,
y^
the c l a s s
c o i n c i d i n g w i t h t h e whole o f H
c o n s t r u c t e d by
w i t h D e f i n i t i o n 8 . 1 c o i n c i d e s with t h e c l a s s
A
in
ful-
the
accordance
. With r e g a r d t o
Theorem 8 . 1 i t i s p o s s i b l e t o c o n c l u d e t h a t Theorem 8 . 2 w i l l be proved a s soon as we e s t a b l i s h t h e c o r r e c t n e s s o f i t s p r o p o s i t i o n w i t h r e s p e c t t o m a t r i x f u n c t i o n s from t h e c l a s s
A •
However, t h e $ - f a c t o r a b i l i t y with one and t h e same t o t a l i n d e x i n L r ( r e Ap)
o f an a r b i t r a r y m a t r i x f u n c t i o n
of Definition 8.3 f o r the values
a
(r)
yt = r
F
all
satisfying condition
r e s u l t s d i r e c t l y from D e f i n i t i o n 8 . 2
and i n e q u a l i t y ( 8 . 4 ) . The c a s e when
F
1)
of
satisfies
one o f t h e c o n d i t i o n s 2 ) - 4 ) o f D e f i n i t i o n 8 . 3 can be reduced t o t h e p r e v i o u s one by methods used i n t h e arguments o f Lemma 6 . 4 , 6 . 1 1 and 6 . 1 0 , r e s p e c t i v e l y . Thus Theorem 8 . 2 i s p r o v e d .
Theorems
=
S t i l l p r e s e r v i n g t h e c l a i m o f Theorem 8 . 2 , i n c a s e o f a smooth c o n t o u r r one can weaken t h e r e s t r i c t i o n s on t h e c l a s s
BpjD(r)
to a certain
d e g r e e . Namely, c o n d i t i o n s 1 ) - 4 ) from D e f i n i t i o n 8 . 3 r e l a t e d t o a Lyapunov c o n t o u r
r
w i l l be r e p l a c e d by t h e
1 )
e s s 8up||I-F t (T)|| < s i n ( i t / m a x ( p , q ) ) T€ Yt
2' )
d ( F t ( T ) ) > ||Ft(T)||cos(u/max(p, to be a
bounded by
r.
According to proposition 1 ) of Theorem 3*21, the matrix function G given on
r
function
G • u> given on T
of
G • u
form
i s ^-factorable in
in
Lt
La
only simultaneously with the matrix
• By what was proved above, $ - f a c t o r a b i l i t y
means that i t i s possible to represent i t in the +1
G • 0» a ^ ( q ) i where
A - e M*(TT)
and
G ^
i s a matrix func-
tion with a uniformly positive real part. From the l a s t +1equation we obtain that
G = (A • a»"1 ) ( G ( 0 ) • 1 , in SPITKOVSKII [ 2 ] .
Prom Theorem 8 . 3 , applied to the s c a l a r case, the following proposit i o n obtained by SIMONENKO [ 4 , 6 ] r e s u l t s . L e t
r
be a smooth contour
(which, f o r the sake of s i m p l i c i t y , i s assumed t o be connected). To the class
Sp(r)
we
assign those functions
represented in the form +1 integer,
h
certain
€ L^ , |arg h ( t ) | < a
Sp(r)
value (equal to
given on
f ( t ) = ^ ( t ^ ^ C t ) , where
a < 2u/max(p,q)
the c l a s s
f
and
r
which can be
O LEE [ 1 ] has d i s c u s s e d the c a s e G€E^+C, where t h e a l g e b r a ^ [ G ] was defined as g e n e r a t e d by H^ and G| i t was claimed t h a t the demand G - 1 e H j G ] i s e q u i v a l e n t t o t h e 4 - f a c t o r a b i l i t y o f the f u n c t i o n G. Howe v e r , i n t h e p r o o f o f t h e n e c e s s i t y the c o n d i t i o n G e ^ + C was not used, but the a u f f i c i e n c e i s a simple consequence o f Theorem 5 . 2 which does not need any a d d i t i o n a l arguments.
313
f i n a l l y , we intend to note that the class of smooth, contours, apparently, does not seem to be the most general olass for which Theorems 8.3, 8*4- and Corollary 8.1 remain valid. The problem of extending this class i s of some significance.
314
CHAPTER 9.
THE GENERALIZED RIEMANN BOUNDARY VALUE PROBLEM
The generalized Riemann boundary value problem (also known as the Markushevich problem or the general boundary value problem of linear conjugation) on the unit circle T consists in the determination of functions
J/~)dt . bt*\J/+ - v|/~ = a*|/+ » we may rewrite
the right-hand
side i n the following manner: J a " 1 t ~ 2 ( c a t V - ca*|/+)dt = / o\|/+dt T T
/ c\J/+t~2dt . T
Since the contour under consideration i s the unit c i r c l e , we have oFE = - t
dt , so t h a t we f i n a l l y get«
/ 8 T
W
/
dt = 2 Re / o ( t > + ( t ) d t T
.
Thus, condition ( 9 . 6 ) coincides p r e c i s e l y with the condition o f orthogonality of
g
to the "+"-components o f the solutions of the homo-
geneous problem (9.4-). Therefore, i t i s necessary f o r the s o l v a b i l i t y of problem ( 9 . 1 ) . Now, l e t the function
c (e L p )
s a t i s f y the condition ( 9 . 6 ) . Then in
\
„ (c - be a " 1 g =I ^ * I there \t 1 a c / belonging to the Image of problem ( 9 « 4 ) .
every neighbourhood of the vector function e x i s t s a veotor function The vector function
1
~(
£
f = £i = I
AI
belongs to the image of problem
( 9 . 2 ) . With regard to Lemma 9 . 1 , the function
^(f1+Ta)
l i e s in the
;
image of problem (9»1)• Due to the closeness of the vector functions g
and 3? i t i s possible to make the vector functions
and c
£t = f
Ag =
as close as desired and, consequently, also the functions
and ^ ( f 1 + f a ) . Hence, the image of problem ( 9 . 1 ) i s dense in the subspace generated by conditions ( 9 . 6 ) , which proves Lemma 9 . 2 .
= 321
COROLLARY 9.3»
The codimension
l'
of the closure of the image of
problem (9.1) (over the field of real numbers) agrees with the codimension of the closure of the image of problem (9.4-) (over the complex field). Indeed, Lemma 9*2 demonstrates that the number
l'
coincides with the
number of linearly independent (over the field of real numbers) solutions of the homogeneous problem (9.11)» which, according to Corollary 9*2, is equal to the dimension (over the complex field) of the kernel of problem (9*2*)• It remains to use the coincidence of the kernels of problems (9.21 ) and (9.41 ). Now we are going to formulate the main theorem of the present section. THEOREM 9.2. Iredholm in
The generalized Riemann boundary value problem (9.1) is Lp
iff
1)
condition (9.3) is fulfilled,
2)
the matrix function in
G
defined by equation (9»5) is ^-factorable
Lp .
If the conditions 1 ) and 2 ) are satisfied, then the index of problem (9.1) coincides with the total index of
G , the number
1
of
linearly independent solutions of the homogeneous problem is equal to the sum of positive partial indices, whereas the number l 1
of solva-
bility conditions for the inhomogeneous problem is opposite to the sum of negative partial indices. Proof.
The necessity of condition 1 ) for the Fredholmness of problem
(9.1) has been stated by Theorem 9.1» If this condition is satisfied, then, owing to Corollaries 9.1 - 9.3, problem (9.1) is Predholm only simultaneously with problem (9.4). Thanks to Theorem 3.16, the Fredholmness of problem (9.4) is equivalent to the S-factorability of the matrix function
G .
According to Corollary 9.2, the number
1
coincides with the dimension
of the kernel of problem (9»4), i« e * with the sum of positive partial indices of
G
(by Theorem 3.16). The formula for
l1
is established
on the strength of Corollary 9.3. Now, from the formulae for
322
1
and
1
i t i s not hard to obtain the formula f o r the index of problem ( 9 * 1 ) . Hence, Theorem 9*2 i s proved.
'=
We would l i k e to mention t h a t the formulae f o r written in t h e following manners L e t dices of the matrix function 1 a max{0,H,+K t } , 1 = x, ,
l1
and
and x ,
1*
can be
be the p a r t i a l i n -
G . Then
l ' = maxiO,-*.,-*,} , i f
= - Kt ,
DEFINITION 9«1.
k,
1
if
nixt > 0 }
x 0 , then, due to formulae (9*7), the numbers
1
and
l'
are defined uniquely by the t o t a l index of the matrix function ( 9 . 5 ) . Therefore, they remain unchanged under small perturbations o f the c o efficients
a
and
b • Thus, the condition
x.,x a > 0
( a l l the more,
the condition of s t a b i l i t y of problem ( 9 * 1 • ) ) i s s u f f i c i e n t f o r the s t a b i l i t y of the numbers
1
and
l'.
The next statement, which often proves to be useful in the study of problem ( 9 . 1 ) , r e s u l t s d i r e c t l y from Theorem 9»2. THEOREM 9*3« ( 9 . 1 ) by
The substitution
b - q> with
of the c o e f f i c i e n t
b
in problem
cp € H^ + C does not influence neither on the
Fredholmness of the problem not on the value of i t s index. I f t
t) < 1 < n+N , hold. Here
N > |h|
(9.111)
N i s the number of zeros ( t a k i n g i n t o account t h e i r i},- q>,
in
.
We r e p r e s e n t the matrix f u n c t i o n ( 9 . 9 ) i n t h e fouu J G
Here
N < |w| ,
l ' = 1-2« , i f
m u l t i p l i c i t y ) of the f u n c t i o n Proof.
if
o = l9i - »«I 1
9 1 a ^h/Xi ,
Wl
\~Xa
() < |n| ,
?(q>) > |h|
are fulfilled. Here
P(tp) 'is the number of poles (counting their multiplicity) of
the function
q> in
»
Corollary 9.5 follows immediately from Theorem 9*^ by setting and taking as
(t) = 0
+
( t M^
have no
, coincide (with referenoe to the multiplicity)
327
at no more than
|x|
points and s a t i s f y the conditions (9*12) and
( 9 . 1 3 ) . Then problem ( 9 . 1 ) i s Fredholm and the numbers
1
and
l'
of this problem are stable* Let us emphasize a s u f f i c i e n t condition f o r s t a b i l i t y of problem ( 9 . 1 ) « THEOREM 9.5. poles in
Assume that the functions
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