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Laurent Series and their Padé Approximations PDF

277 Pages·1987·9.6 MB·English
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OT27: Operator Theory: Advances and Applications Vol. 27 Editor: I. Gohberg Tel Aviv University Ramat-A viv, Israel Editorial Office School of Mathematical Sciences Tel Aviv University Ramat-A viv, Israel Editorial Board A. Atzmon (Tel-Aviv) M. A. Kaashoek (Amsterdam) J. A. Ball (Blacksburg) T. Kailath (Stanford) L. de Branges (West Lafayette) H. G. Kaper (Argonne) K Clancey (Athens, USA) S. T. Kuroda (Tokyo) L. A. Coburn (Buffalo) P. Lancaster (Calgary) R. G. Douglas (Stony Brook) L. E. Lerer (Haifa) H. Dym (Rehovot) M. S. Livsic (Beer Sheva) A. Dynin (Columbus) E. Meister (Darmstadt) P. A. Fillmore (Halifax) B. Mityagin (Columbus) C. Foias (Bloomington) J. D. Pincus (Stony Brook) P. A. Fuhrmann (Beer Sheva) M. Rosenblum (Charlottesville) S. Goldberg (College Park) J. Rovnyak (Charlottesville) B. Gramsch (Mainz) D. E. Sarason (Berkeley) J. A. Helton (La Jolla) H. Widom (Santa Cruz) D. Herrero (Tempe) D. Xia (Nashville) Honorary and Advisory Editorial Board P. R. Halmos (Santa Clara) R. Phillips (Stanford) T. Kato (Berkeley) B. Sz.-Nagy (Szeged) S. G. Mikhlin (Leningrad) Birkhauser Verlag Basel . Boston Adhemar Bultheel Laurent Series and their Pade Approximations 1987 Birkhauser Verlag Basel· Boston Author's Address: Adhemar Bultheel K. U. Leuven Dept. Computer Science Celestijnenlaan 200A 3030 Leuven-Heverlee Belgium Library of Congress Cataloging in Publication Data Bultheel, Adhemar: Laurent series and the Pade approximations. (Operator theory, advances and applications ; vol. 27) Bibliography: p. Includes index. 1. Laurent series. 2. Pade approximant. I. Title. II. Series: Operator theory, advances and applications ; v. 27. QA331.B795 1987 515 87-24297 ISBN-13: 978-3-0348-9988-8 e-ISBN-13: 978-3-0348-9306-0 DOl: 10.1007/978-3-0348-9306-0 CIP-Kurztitelaufnahme der Deutschen Bibliothek Bultheel, Adhemar: Laurent series and their Pade approximations / Adhemar Bultheel. - Basel; Boston: Birkhauser, 1987. (Operator theory; Vol. 27) NE:GT All rights reserved. No part of this publication may be reproduced, stored in a retrieval system, or transmitted in any form or by any means, electronic, mechanical, photocopying, recording or otherwise, without the prior permission of the copyright owner. © 1987 BirkhauserVeriag Basel CONTENTS Preface ix 2. Introduction 1 2.1 Classical Pade approximation 1 2.2 Toeplitz and Hankel systems 2 2.3 Continued fractions 3 2.4 Orthogonal polynomials 4 2.5 Rhombus algorithms and convergence 5 2.6 Block structure 5 2.7 Laurent-Pade approximants 6 2.8 The projection method 7 2.9 Applicati.o ns 7 2.10 Outline 10 3. Moebius transforms, continued fractions and Pade approximants • 11 3.1 Moebius transforms 11 3.2 Flow graphs 14 3.3 Continued fractions (CF) 18 3.4 Formal series • 22 3.5 Pade approximants • 24 . 4. Two algorithms 29 4.1 Algorithm 1 29 4.2 Algorithm 2 32 5. All kinds of Pade Approximants 37 5.1 Pade approximants • 37 5.2 Laurent-Pade approximants 39 5.3 Two-point Pade approximants • 43 6. Continued fractions 47 6.1 General observations 47 6.2 Some special cases 49 7. Moebius transforms 55 7.1 General observations 55 7.2 Some special cases 57 8. Rhombus algorithms 65 vi CONTENTS . . . . . . . 8.1 The ab parameters (sawtooth path) • . . . . . . . . 65 8.2 The FG parameters (row path) 72 8.3 A staircase path. • • • • • • • • • 73 8.4 po paramaters (diagonal path) •••••••••••• 75 8.5 Some dual results • • • • • • • • • • • • • • • 77 8.6 Relation with classical algorithms • • • • • • • • • • • 81 9. Biorthogonal polynomials, quadrature and reproducing kernels • • • • • • • • • • • • • 83 9.1 Biorthogonal polynomials • • • • • • • • • • • • 83 9.2 Interpolatory quadrature methods • • • • • • • • • • • 90 9.3 Reproducing kernels • • • • • • • • • • 94 9.4 Other orthogonality relations • • • • • • • • • • • 98 10. Determinant expressions and matrix interpretations • • • • • 103 10.1 Determinant expressions. • 103 10.2 Matrix interpretations ••••••••••••• 112 10.2.1 Toeplitz matrices. 112 10.2.2 Hankel matrices • • 122 10.2.3 Tridiagonal matrices 127 11. Symmetry Properties • • • • • • 132 = 11.1 Symmetry for F(z) and F(z) F(1/ z) • • 132 11.2 Symmetry for F (z) and G (z) = 1/F (z) • • 136 12. Block structures. • • • • • • • • • • • • 141 12.1 Pade forms, Laurent-Pade forms and two-point Pade forms • • • • • • • • • • • • • • • • . . . 141 12.2 The T-tab1e • • • • • • • • • • • • • • 143 12.3 The Pade, Laurent-Pade, and two-point Pade tables 149 13. Meromorphic functions and asymptotic behaviour. • • • • 155 13.1 The function F(z) • • • • • • • • • • • • • •• 155 13.2 Asymptotics for finite Toeplitz determinants ••••• 156 13.3 Asymptotics for infinite Toeplitz determinants • • • • • •• 159 13.4 Consequences for the T-tab1e • • • • • • • •• 163 14. Montessus de Ballore theorem for Laure.n t-.Pa.d e .. . . . . . approximants. • • • • • • 167 14.1 Semi infinite Laurent series • 167 14.2 Bi-infinite Laurent series • 170 . . . . . 15. Determination of poles . . . 173 15.1 Rutishauser polynomials of type 1 and type 2 . . . 173 15.2 Rutishauser polynomials of type 3 . . 179 15.3 Rutishauser polynomials and Laurent series • • 181 CONTENTS vii 15.4 Convergence of parameters • 183 16. Determination of zeros 187 16.1 Dual Rutishauser polynomials and semi-infinite series 187 16.2 From semi-infinite to bi-infinite series 189 16.3 Convergence of parameters • 193 17. Convergence in a row of the Laurent-Pade table 195 17.1 Toeplitz operators and the projection method 197 17.2 Convergence of the denominator 199 17.3 Convergence of the numerator • 203 18. The positive definite case and applications • 207 18.1 Function classes • 207 18.2 Connection with the previous results 212 18.3 Stochastic processes and systems • 219 18.4 Loss1ess inverse scattering and transmission lines 224 18.5 Laurent-Pade approximation and ARMA-filtering • 230 18.6 Concluding remarks 231 19. Examples 233 19.1 Example 1 • 233 19.2 Example 2 • 248 19.3 Example 3 • 253 References 257 List of symbols 263 Subject index 271 PREFACE The Pade approximation problem is, roughly speaking, the local approximation of analytic or meromorphic functions by rational ones. It is known to be important to solve a large scale of problems in numerical analysis, linear system theory, stochastics and other fields. There exists a vast literature on the classical Pade problem. However, these papers mostly treat the problem for functions analytic at 0 or, in a purely algebraic sense, they treat the approximation of formal power series. For certain problems however, the Pade approximation problem for formal Laurent series, rather than for formal power series seems to be a more natural basis. In this monograph, the problem of Laurent-Pade approximation is central. In this problem a ratio of two Laurent polynomials in sought which approximates the two directions of the Laurent series simultaneously. As a side result the two-point Pade approximation problem can be solved. In that case, two series are approximated, one is a power series in z and the other is a power series in z-l. So we can approximate two, not necessarily different functions one at zero and the other at infinity. To connect this problem to the previous one, we just have to glue the two series together to get a formal Laurent series. When the classical definition of Pade approximation is applied to a Laurent series instead of a power series, we get a numerator which is a polynomial plus infinitely many negative powers of z which are generated by the terms with negative powers in the Laurent series. Thus if the Laurent series has no negative powes of z, i.e. when it becomes a power series, the classical Pade approximant appears as a special case. The first part of this volume (up to chapter 11) is purely algebraic. Three types of recursive algorithms are presented to find the solutions of the three types of Pade problems mentioned above. The first one is in principle the Trench-Zohar algorithm for Toeplitz matrix inversion. The second one is a nonsymmetric version of the Schur algorithm for deciding whether a function is a Schur function. Both these algorithms are based on a "Toeplitz approach", which means that Toeplitz matrices are a basic working tool, whereas the algorithms commonly used in the classical Pade literature (Euclid, Routh, Kronecker a.o) are x more "Hankel minded". A third type of algorithm is of rhombus type and this is essentially the Rutishauser qd algorithm from numerical analysis. From the engineering literature, the flow graph representation of electrical networks is used to represent the algorithms. This will be most useful in getting a visualization of the computational flow. The recurrences of the algorithms can often be interpreted as recurrences associated with continued fractions and formal orthogonal polynomials. These interpretations are also treated to some extend, including reproducing kernels and Christoffel-Darboux-type formulas. When the algorithms are used in a linear algebra context, formulas will be found for Toeplitz and Hankel matrix inversion and triangular factorization. Finally, the block structure of the classical Pade table will be extended to describe the blocks of Laurent-Pade and two-point Pade tables. The second part of the volume is analytic in nature. The Pade approximation problem is considered for meromorphic in C \ {oJ functions. Classical and more recent results on the asymptotic behaviour of Hankel and Toeplitz determinants and the projection method are used for proving convergence in columns and rows of Pade tables. In classical Pade theory the convergence of columns is well established. and the convergence of the rows can be obtained. from a simple duality principle. For the Laurent-Pade problem, convergence of the columns is essentially the same as in the classical case. For the row convergence however, some new methods had to be used, and it is one of the most important results of this monograph. From these convergence results it is derived how the poles and zeros of a meromorphic function given by a Laurent series can be computed. The computation of poles is related to column convergence and the computation of zeros is related to row convergence. Chapter l7 contains some interpretation of the Pade approximation problem in other theories like Caratheooory and Schur function classes, Szego polynomials orthogonal on the unit circle, prediction theory and inverse scattering. My interest in the last topics was the inital motivation for writing this monograph. Therefore it is my sincere hope that this text will not only be appreciated by specialists in Pade approximation, continued fractions, orthogonal polynomials and Toeplitz matrices but also by people with a more applied mathematical background e.g. from stochastic processes, time series analysis, signal processing, linear systems theory or inverse scattering. I realize that it will take some time for the reader who is not familiar with the subject to get accustomed to the large number of different types of polynomials, series and parameters. To help him, a quick reference of the most important formulas is included on a separate card which can be taken along as a bookmarker.

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The Pade approximation problem is, roughly speaking, the local approximation of analytic or meromorphic functions by rational ones. It is known to be important to solve a large scale of problems in numerical analysis, linear system theory, stochastics and other fields. There exists a vast literature
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