Matrix Biorthogonal Polynomials: eigenvalue problems and non-Abelian discrete Painlev\'e equations

TL;DR

This paper develops a Riemann-Hilbert approach to matrix biorthogonal polynomials, deriving differential and difference equations, including non-Abelian extensions of Painlevé equations, with applications to eigenvalue problems.

Contribution

It introduces new non-Abelian matrix extensions of discrete Painlevé equations and applies Riemann-Hilbert methods to analyze matrix biorthogonal polynomials.

Findings

Derived Sylvester systems of differential equations for matrix orthogonal polynomials.

Established non-Abelian extensions of discrete Painlevé I equations.

Explored eigenvalue problems for matrix differential operators.

Abstract

In this paper we use the Riemann-Hilbert problem, with jumps supported on appropriate curves in the complex plane, for matrix biorthogonal polynomials and apply it to find Sylvester systems of differential equations for the orthogonal polynomials and its second kind functions as well. For this aim, Sylvester type differential Pearson equations for the matrix of weights are shown to be instrumental. Several applications are given, in order of increasing complexity. First, a general discussion of non-Abelian Hermite biorthogonal polynomials in the real line, understood as those whose matrix of weights is a solution of a Sylvester type Pearson equation with coefficients first order matrix polynomials, is given. All these is applied to the discussion of possible scenarios leading to eigenvalue problems for second order linear differential operators with matrix eigenvalues. Nonlinear matrix difference equations are discussed next. Firstly, for the general Hermite situation a general non linear relation (non trivial because the non commutativity features of the setting) for the recursion coefficients is gotten. In the next case of higher difficulty, degree two polynomials are allowed in the Pearson equation, but the discussion is simplified by considering only a left Pearson equation. In the case, the support of the measure is on an appropriate branch of an hyperbola. The recursion coefficients are shown to fulfill a non-Abelian extension of the alternate discrete Painlev\'e I equation. Finally, a discussion is given for the case of degree three polynomials as coefficients in the left Pearson equation characterizing the matrix of weights. However, for simplicity only odd polynomials are allowed. In this case, a new and more general matrix extension of the discrete Painlev\'e I equation is found.