On the exponent of several classes of oscillatory matrices

Yoram Zarai; Michael Margaliot

doi:https://doi.org/10.1016/j.laa.2020.09.021

On the exponent of several classes of oscillatory matrices

Yoram Zarai, Michael Margaliot

Tel Aviv University

Research output: Contribution to journal › Article › peer-review

Abstract

Oscillatory matrices were introduced in the seminal work of Gantmacher and Krein. An n×n matrix A is called oscillatory if all its minors are nonnegative and there exists a positive integer k such that all minors of A^k are positive. The smallest k for which this holds is called the exponent of the oscillatory matrix A. Gantmacher and Krein showed that the exponent is always smaller than or equal to n−1. An important and nontrivial problem is to determine the exact value of the exponent. Here we use the successive elementary bidiagonal factorization of oscillatory matrices, and its graph-theoretic representation, to derive an explicit expression for the exponent of several classes of oscillatory matrices, and a nontrivial upper-bound on the exponent for several other classes.

Original language	English
Pages (from-to)	363-386
Number of pages	24
Journal	Linear Algebra and Its Applications
Volume	608
DOIs	https://doi.org/10.1016/j.laa.2020.09.021
State	Published - 1 Jan 2021

Keywords

Exponent of oscillatory matrices
Planar network
Successive elementary factorization
Totally nonnegative matrices
Totally positive matrices

All Science Journal Classification (ASJC) codes

Algebra and Number Theory
Numerical Analysis
Geometry and Topology
Discrete Mathematics and Combinatorics

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Cite this

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title = "On the exponent of several classes of oscillatory matrices",

abstract = "Oscillatory matrices were introduced in the seminal work of Gantmacher and Krein. An n×n matrix A is called oscillatory if all its minors are nonnegative and there exists a positive integer k such that all minors of Ak are positive. The smallest k for which this holds is called the exponent of the oscillatory matrix A. Gantmacher and Krein showed that the exponent is always smaller than or equal to n−1. An important and nontrivial problem is to determine the exact value of the exponent. Here we use the successive elementary bidiagonal factorization of oscillatory matrices, and its graph-theoretic representation, to derive an explicit expression for the exponent of several classes of oscillatory matrices, and a nontrivial upper-bound on the exponent for several other classes.",

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T1 - On the exponent of several classes of oscillatory matrices

AU - Zarai, Yoram

AU - Margaliot, Michael

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N2 - Oscillatory matrices were introduced in the seminal work of Gantmacher and Krein. An n×n matrix A is called oscillatory if all its minors are nonnegative and there exists a positive integer k such that all minors of Ak are positive. The smallest k for which this holds is called the exponent of the oscillatory matrix A. Gantmacher and Krein showed that the exponent is always smaller than or equal to n−1. An important and nontrivial problem is to determine the exact value of the exponent. Here we use the successive elementary bidiagonal factorization of oscillatory matrices, and its graph-theoretic representation, to derive an explicit expression for the exponent of several classes of oscillatory matrices, and a nontrivial upper-bound on the exponent for several other classes.

AB - Oscillatory matrices were introduced in the seminal work of Gantmacher and Krein. An n×n matrix A is called oscillatory if all its minors are nonnegative and there exists a positive integer k such that all minors of Ak are positive. The smallest k for which this holds is called the exponent of the oscillatory matrix A. Gantmacher and Krein showed that the exponent is always smaller than or equal to n−1. An important and nontrivial problem is to determine the exact value of the exponent. Here we use the successive elementary bidiagonal factorization of oscillatory matrices, and its graph-theoretic representation, to derive an explicit expression for the exponent of several classes of oscillatory matrices, and a nontrivial upper-bound on the exponent for several other classes.

KW - Exponent of oscillatory matrices

KW - Planar network

KW - Successive elementary factorization

KW - Totally nonnegative matrices

KW - Totally positive matrices

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U2 - https://doi.org/10.1016/j.laa.2020.09.021

DO - https://doi.org/10.1016/j.laa.2020.09.021

M3 - مقالة

SN - 0024-3795

VL - 608

SP - 363

EP - 386

JO - Linear Algebra and Its Applications

JF - Linear Algebra and Its Applications

ER -

On the exponent of several classes of oscillatory matrices

Abstract

Keywords

All Science Journal Classification (ASJC) codes

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