Operator Theory Advances and Applications Vol. 96 Editor: I. Gohberg Editorial Office: T. Kailath (Stanford) School of Mathematical H.G. Kaper (Argonne) Sciences S.T. Kuroda (Tokyo) Tel Aviv University P. Lancaster (Calgary) Ramat Aviv, Israel L.E. Lerer (Haifa) E. Meister (Darmstadt) Editorial Board: B. Mityagin (Columbus) J. Arazy (Haifa) V. V. Peller (Manhattan, Kansas) A. Atzmon (Tel Aviv) J. D. Pincus (Stony Brook) J. A. Ball (Blackburg) M. Rosenblum (Charlottesville) A. Ben-Artzi (Tel Aviv) J. Rovnyak (Charlottesville) H. Bercovici (Bloomington) D. E. Sarason (Berkeley) A. Bottcher (Chemnitz) H. Upmeier (Marburg) L. de Branges (West Lafayette) S. M. Verduyn-Lunel (Amsterdam) K. Clancey (Athens, USA) D. Voiculescu (Berkeley) L. A. Coburn (Buffalo) H. Widom (Santa Cruz) K. R. Davidson (Waterloo, Ontario) D. Xia (Nashville) R. G. Douglas (Stony Brook) D. Yafaev (Rennes) H. Dym (Rehovot) A. Dynin (Columbus) P. A. Fillmore (Halifax) Honorary and Advisory C. Foias (Bloomington) Editorial Board: P. A. Fuhrmann (Beer Sheva) P. R. Halmos (Santa Clara) S. Goldberg (College Park) T. Kato (Berkeley) B. Gramsch (Mainz) P. D. Lax (New York) G. Heinig (Chemnitz) M. S. Livsic (Beer Sheva) J. A. Helton (La Jolla) R. Phillips (Stanford) M.A. Kaashoek (Amsterdam) B. Sz.-Nagy (Szeged) Schur Functions, Operator Colligations, and Reproducing Kernel Pontryagin Spaces Daniel Alpay Aad Dijksma James Rovnyak Hendrik de Snoo Springer Basel AG Authors: Daniel Alpay James Rovnyak Department of Mathematics Department of Mathematics Ben-Gurion University of the Negev University of Virginia P.O.Box 653 Charlottesville, VA 22903-3199 84105 Beer-Sheva USA Israel e-mail: [email protected] e-mail: [email protected] AadDijksma Hendrik de Snoo Department of Mathematics Department of Mathematics University of Groningen University of Groningen P.O.Box 800 P.O.Box 800 9700 A V Groningen 9700 A V Groningen The Ne therlands The Netherlands e-mail: [email protected] e-mail: [email protected] 1991 Mathematics Subject Classification 47A48, 47B50 (primary), 46C20, 46E22, 47A45 (secondary) A CIP catalogue record for this book is available from the Library ofCongress, Washington D.C., USA Deutsche Bibliothek Cataloging-in-Publication Data Schur functions, operator colligations and reproducing kernel Pontryagin spaces I Daniel Alpay ... - Basel ; Boston; Berlin: B irkhiiuser, 1997 (Operator theory ; VoI. 96) ISBN 978-3-0348-9823-2 ISBN 978-3-0348-8908-7 (eBook) DOI 10.1007/978-3-0348-8908-7 This work is subject to copyright. AII rights are reserved, whether the whole or part of the material is concerned, specifically the rights of translation, reprinting, re-use of illustrations, recitation, broadcasting, reproduction on microfilms or in other ways, and storage in data banks. For any kind of use permission of the copyright owner must be obtained. © 1997 Springer Basel AG Originally published by Birkhiiuser Verlag in 1997 Softcover reprint ofthe hardcover 1s t edition 1997 Printed on acid-free paper produced from chlorine-free pulp. TCF 00 Cover design: Heinz Hiltbrunner, Basel ISBN 978-3-0348-9823-2 987654321 Dedicated to Heinz Langer on the occasion of his 60-th birthday, in appreciation, admiration, and amity. CONTENTS Introduction ........................................................... IX Chapter 1: Pontryagin Spaces and Operator Colligations 1.1 Reproducing kernel Pontryagin spaces ............................. 1 1.2 Operator colligations .............................................. 13 1.3 Julia operators and contractions ................................... 19 1.4 Extension of densely defined linear relations ....................... 27 1.5 Complementation and reproducing kernels A. Complementation in the sense of de Branges ................... . 31 B. Applications to reproducing kernel Pontryagin spaces 36 Chapter 2: Schur Functions and their Canonical Realizations 2.1 Pontryagin spaces Sj(S), Sj(S), and :!J(S) .......................... 41 2.2 Canonical coisometric and isometric realizations ................... 49 2.3 Canonical unitary realization ...................................... 54 2.4 Unitary dilations of coisometric and isometric colligations. . . . . . . . . . . 62 2.5 Classes S",(J, cB) A. Definition and basic properties ................................. 68 B. Conform ally invariant view ..................................... 71 C. Application to factorization of operator-valued functions ........ 79 D. A non-holomorphic kernel .... '" ... ... ... ... ... .. . .. .. . .. . . . .. . 82 Chapter 3: The State Spaces 3.1 Invariance under difference quotients .............................. 83 3.2 Spaces Sj(S) ....................................................... 88 3.3 Spaces Sj (S) ....................................................... 99 3.4 Spaces :!J(S) ...................................................... 106 viii CONTENTS 3.5 Examples and miscellaneous results A. Rational unitary functions ...................................... 113 B. Symmetry in the state spaces ................................... 119 C. Some consequences of Leech's theorem.......................... 122 D. The scalar case: 8(z) E $)(8) if and only if 8(z) E $)(8) ......... 127 Chapter 4: Structural Properties 4.1 Factorization and invariant subspaces A. Inclusion of spaces $)(8) ........................................ 129 B. Inclusion of spaces 1'(8) ........................................ 138 4.2 KreIn-Langer factorization A. Existence and properties....................................... 141 B. Strongly regular representations ................................ 150 4.3 The Potapov-Ginzburg transform .................................. 155 4.4 Applications to the realization theory A. KreIn space inner and outer spaces ~ and ~ .................... 163 B. Other base points .............................................. 174 C. Examples ...................................................... 177 4.5 Canonical models ................................................. 179 Epilogue: Open Questions and Directions for Further Work............. 185 Appendix: Some Finite-Dimensional Spaces............................. 191 Notes.................................................................. 203 References ............................................................. 211 Notation Index......................................................... 221 Author Index .......................................................... 223 Subject Index .......................................................... 225 INTRODUCTION The Schur class in complex analysis is the set of holomorphic functions which are defined and bounded by one on the unit disk. It occurs prominently in interpolation theory and invariant subspace theory as well as in applications areas. Certain kernels induced by a given Schur function recur frequently. They are reproducing kernels for functional Hilbert spaces, which today we understand to be state spaces for canonical coisometric, isometric, and unitary colligations whose characteristic functions coincide with the given Schur function. Operator generalizations of the Schur class consist of functions 8 (z) defined on a subregion D(8) of the unit disk containing the origin whose values are operators in £(J, Qj) for some Hilbert, Pontryagin, or KreIn spaces J and Qj. We associate with such functions 8 (z) the three kernels _ 1-8(z)8(w)* K ( ) s w, z - 1 - , -zw K-( ) _ 1 - 8(z)8(w)* s W,z - 1 - , -zw 8(z) - ~(w) ) Ks(w,z) z-w ( , Ds(w, z) = 8(z) _ ~(w) Ks(w, z) z-w where 8(z) = 8(z)* and 1 denotes either the scalar unit or an identity opera tor, depending on context. When these kernels are nonnegative, they are repro ducing kernels for Hilbert spaces 5)(8), 5)(8), 1)(8) of vector-valued functions. The spaces appear in a canonical model for contraction operators given by L. de Branges and J. Rovnyak in the case that J and Qj are Hilbert spaces. More generally, we use the hypothesis that the three kernels have negative squares /'l, for some nonnegative integer In this case, we say that 8 (z) belongs to the gen /'l,. eralized Schur class S",(J, Qj). According to a theory founded by L. Schwartz and P. Sorjonen, spaces 5)(8), 5)(8), 1)(8) still exist but now as Pontryagin spaces having the negative index It should be noted that indefiniteness enters the /'l,. subject also in another way, namely, when J and Qj are not Hilbert spaces but Pontryagin or KreIn spaces, a situation pioneered by V. P. Potapov in the matrix case. The indefinite cases have been studied in a number of places, notably in a series of papers by M. G. KreIn and H. Langer and in more recent works by L. de Branges. The KreIn-Langer theory assumes that the spaces J and Qj are Hilbert spaces and is motivated by spectral theory, classical representations of x INTRODUCTION resolvents, and function-theoretic questions. The theory of de Branges adopts a systems viewpoint and uses a notion.of complementation to make the key constructions. Although many elegant results are obtained in these and other sources in the literature, the indefinite theory overall is less complete than the Hilbert space cases. The purpose of this work is to present a theory of the generalized Schur classes SK(~' Q;) in typical indefinite situations. Our main tool is a representation of the spaces jj(8), jj(S), 1)(8) as the state spaces of canonical coisometric, iso metric, and unitary colligations. The spaces ~ and Q; are allowed to be indefinite, but in most of the results it is assumed that they are Pontryagin spaces having the same negative index. However, we make no assumptions on the positive in dices of ~ and Q;, and so our notion of generalized Schur function permits 8(z) to have a "rectangular" form. The main results can be interpreted for matrix or scalar-valued functions. Our methods combine the theory of linear relations, reproducing kernel Pontryagin spaces, and abstract operator theory. This ap proach contains elements of the KreIn-Langer and de Branges viewpoints but is different from both. When all of the spaces ~ and Q; and jj(8), jj(S), 1)(8) are Hilbert spaces, our account is an exposition of known results in a setting of colligations and realization theory. The Hilbert space case in turn guides the indefinite theory. In brief outline: • Chapter 1 is devoted to preliminary notions concerning reproducing kernel Pontryagin spaces, linear relations, and complementation. • In Chapter 2 we make the main construction of canonical colligations and introduce the generalized Schur classes SK(J, Q;). • Chapter 3 details the properties of the state spaces and gives examples, which include rational unitary functions. • In Chapter 4 we explore the relationship between invariant subspaces and factorization and obtain information for the indefinite case from the Hilbert space case by means of the Potapov-Ginzburg transform. The main trans formations in state spaces are used to construct canonical models. • In an epilogue we note some questions that are left unresolved and possible areas for future development. • An appendix derives properties of finite-dimensional spaces which illustrate the theory and are used in our derivation of the KreIn-Langer factorization in Chapter 4. As to our motivation to produce this work, chiefly it seems a natural exten sion of existing theories. At the same time, we note that there is much current interest in indefinite inner products in interpolation problems, systems theory, model theory, and even univalent functions. It is well known that such problems INTRODUCTION xi present essential new difficulties beyond the Hilbert space case, and many issues are unresolved at this time. The main conclusion of this work is that the colliga tion and state space structures associated with generalized Schur functions are well behaved in the indefinite case. It is hoped that this might prove useful in the pursuit of the open problems in the indefinite case. The approach developed here was announced in Alpay, Dijksma, Rovnyak, and de Snoo [1996]. An expository account for scalar-valued functions is given in Alpay, Dijksma, Rovnyak, and de Snoo [1997]. Acknowledgements The Ben-Gurion University of the Negev, University of Groningen, and University of Virginia supported exchange visits of the co-authors over the years during which this work was carried out. James Rovnyak was Dozor Visiting Professor at the Ben-Gurion University of the Negev in the summer of 1996, and he was supported by the National Science Foundation under the grant DMS- 9501304 and at the Mathematical Sciences Research Institute (Berkeley) under the grant DMS-9022140.