HE EXPONENTIAL OF QUASI BLOCK-TOEPLITZ MATRICES

doi:10.1007/s10473-022-0312-8

摘要/Abstract

摘要： The matrix Wiener algebra, $\mathcal{W}_N:=\mathrm{M}_{N} (\mathcal{W})$ of order $N>0$, is the matrix algebra formed by $N \times N$ matrices whose entries belong to the classical Wiener algebra $\mathcal{W}$ of functions with absolutely convergent Fourier series. A block-Toeplitz matrix $T(a)=[A_{i,j}]_{i,j \geq 0}$ is a block semi-infinite matrix such that its blocks $A_{i,j}$ are finite matrices of order $N$, $A_{i,j}=A_{r,s}$ whenever $i-j=r-s$ and its entries are the coefficients of the Fourier expansion of the generator $a:\mathbb{T} \rightarrow \mathrm{M}_{N} (\mathbb{C})$. Such a matrix can be regarded as a bounded linear operator acting on the direct sum of $N$ copies of $L^2(\mathbb{T})$. We show that $\exp(T(a))$ differes from $T(\exp(a))$ only in a compact operator with a known bound on its norm. In fact, we prove a slightly more general result: for every entire function $f$ and for every compact operator $E$, there exists a compact operator $F$ such that $f(T(a)+E)=T(f(a))+F$. We call these $T(a)+E's$ matrices, the quasi block-Toeplitz matrices, and we show that via a computation-friendly norm, they form a Banach algebra. Our results generalize and are motivated by some recent results of Dario Andrea Bini, Stefano Massei and Beatrice Meini.

关键词: Toeplitz matrix, infinite matrix, block matrix, exponential, functional calculus

Abstract: The matrix Wiener algebra, $\mathcal{W}_N:=\mathrm{M}_{N} (\mathcal{W})$ of order $N>0$, is the matrix algebra formed by $N \times N$ matrices whose entries belong to the classical Wiener algebra $\mathcal{W}$ of functions with absolutely convergent Fourier series. A block-Toeplitz matrix $T(a)=[A_{i,j}]_{i,j \geq 0}$ is a block semi-infinite matrix such that its blocks $A_{i,j}$ are finite matrices of order $N$, $A_{i,j}=A_{r,s}$ whenever $i-j=r-s$ and its entries are the coefficients of the Fourier expansion of the generator $a:\mathbb{T} \rightarrow \mathrm{M}_{N} (\mathbb{C})$. Such a matrix can be regarded as a bounded linear operator acting on the direct sum of $N$ copies of $L^2(\mathbb{T})$. We show that $\exp(T(a))$ differes from $T(\exp(a))$ only in a compact operator with a known bound on its norm. In fact, we prove a slightly more general result: for every entire function $f$ and for every compact operator $E$, there exists a compact operator $F$ such that $f(T(a)+E)=T(f(a))+F$. We call these $T(a)+E's$ matrices, the quasi block-Toeplitz matrices, and we show that via a computation-friendly norm, they form a Banach algebra. Our results generalize and are motivated by some recent results of Dario Andrea Bini, Stefano Massei and Beatrice Meini.

Key words: Toeplitz matrix, infinite matrix, block matrix, exponential, functional calculus

中图分类号:

15A16

Elahe BOLOURCHIAN, Bijan Ahmadi KAKAVANDI. HE EXPONENTIAL OF QUASI BLOCK-TOEPLITZ MATRICES[J]. 数学物理学报, 2022, 42(3): 1018-1034.

Elahe BOLOURCHIAN, Bijan Ahmadi KAKAVANDI. HE EXPONENTIAL OF QUASI BLOCK-TOEPLITZ MATRICES[J]. Acta mathematica scientia,Series A, 2022, 42(3): 1018-1034.

参考文献 32

[1]	Baker A. Matrix groups:An introduction to Lie group theory. London:Springer-Verlag, 2002
[2]	Barbarino G, Garoni C, Serra-Capizzano S. Block generalized locally Toeplitz sequences:theory and applications in the unidimensional case. Electronic Transactions on Numerical Analysis, 2020, 53:28-112
[3]	Barbarino G, Garoni C, Serra-Capizzano S. Block generalized locally Toeplitz sequences:theory and applications in the multidimensional case. Electronic Transactions on Numerical Analysis, 2020, 53:113-216
[4]	Bini D A, Dendievel S, Latouche G, Meini B. Computing the exponential of large block-triangular block-Toeplitz matrices encountered in fluid queues. Linear Algebra and its Applications, 2016, 502:387-419
[5]	Bini D A, Massei S, Meini B. On functions of quasi-Toeplitz matrices (Russian); translated from Matematicheskii Sbornik, 2017, 208(11):56-74
[6]	Bini D A, Massei S, Meini B. Semi-infinite quasi-Toeplitz matrices with applications to QBD stochastic processes. Mathematics of Computation, 2018, 87(314):2811-2830
[7]	Bini D A, Massei S, Robol L. Quasi-Toeplitz matrix arithmetic:a MATLAB toolbox. Numerical Algorithms, 2019, 81(2):741-769
[8]	Bini D A, Meini B. On the exponential of semi-infinite quasi Toeplitz matrices. Numerische Mathematik, 2019, 141(2):319-351
[9]	Bonsall F F, Duncan J. Complete Normed Algebras. New York:Springer-Verlag, 1973
[10]	Böttcher A, Grusky S M. Spectral properties of banded Toeplitz matrices. Philadelphia:Society for Industrial and Applied Mathematics (SIAM), 2005
[11]	Böttcher A, Silbermann B. Analysis of Toeplitz operators. Second Edition. Prepared jointly with Alexie Karlovich, Springer Monographs in Mathematics. Berlin:Springer-Verlag, 2006
[12]	Böttcher A, Silbermann B. Introduction to large truncated Toeplitz matrices. Universitext. New York:Springer-Verlag, 1999
[13]	Dehghan M. Fully implicit finite differences methods for two-dimensional diffusion with a non-local boundary condition. Journal of Computational and Applied Mathematics, 1999, 106(2):255-269
[14]	Dudgeon D E, Mersereau R M. Multidimensional Digital Signal Processing. 2nd edition. Prentice-Hall Signal Processing Series, 1995
[15]	Ehrhart T, Van der Mee C, Rodman L, Spitkovsky I. Factorization in weighted Wiener matrix algebra on linearly ordered Abelian groups. Integral Equations and Operator Theory, 2007, 58:65-86
[16]	Garoni C, Serra-Capizzano S. Block generalized locally Toeplitz sequences:the case of matrix functions and an engineering application. The Electronic Journal of Linear Algebra, 2019, 35:204-222
[17]	Garoni C, Serra-Capizzano S. Generalized Locally Toeplitz Sequences:Theory and Applications. Vol I. Cham:Springer, 2017
[18]	Garoni C, Serra-Capizzano S. Generalized Locally Toeplitz Sequences:Theory and Applications. Vol II. Cham:Springer, 2018
[19]	Gutiérrez-Gutiérrez J, Crespo P M, Böttcher A. Functions of the banded Hermitian block Toeplitz matrices in signal processing. Linear Algebra and its Applications, 2007, 422(2/3):788-807
[20]	Grenander U, Szegö G. Toeplitz forms and their applications. New York:Chelsea Publishing Co, 1984
[21]	Henrici P. Applied and Computational Complex Analysis. Vol 1. New York:John Wiley & Sons, 1974
[22]	Higham N J. Function of matrices:theory and computational. Philadelphia:Society for Industrial and Applied Mathematics (SIAM), 2008
[23]	Horn R A, Johnson C R. Matrix analysis. Cambridge:Cambridge University Press, 2013
[24]	Jeuris B, Vandebril R. The Kaähler mean of block-Toeplitz matrices with Toeplitz structured blocks. SIAM Journal on Matrix Analysis and Applications, 2016, 37(3):1151-1175
[25]	Khan M A, Timotin D. Algebras of block Toeplitz matrices with commuting entries. Linear and Multilinear Algebra, 2019. https://doi.org/10.1080/03081087.2019.1693955
[26]	Kreyszig E. Introductory functional analysis with applications. New York:John Wiley & Sons, Inc, 1989
[27]	Lee S T, Liu X, Sun H-W. Fast exponential time integration scheme for option pricing with jumps. Numerical Linear Algebra with Applications, 2012, 19(1):87-101
[28]	Lee S T, Pang H-K, Sun H-W. Shift-invert Arnoldi approximation to the Toeplitz matrix exponential. SIAM Journal on Scientific Computing, 2010, 32(2):774-792
[29]	Moler C, Van Loan C. Nineteen dubious ways to compute the exponential of a matrix, twenty-five years later. SIAM Review, 2003, 45(1):3-49
[30]	Nielsen F, Bhatia R. Matrix information geometry. Heidelberg:Springer, 2013
[31]	Rudin W. Functional Analysis. Second Edition. New York:McGraw-Hill, Inc, 1991
[32]	Rudin W. Principles of Mathematical Analysis. Third Edition. New York:McGraw-Hill Book Co, 1976