English

Orthogonal Polynomials, Asymptotics and Heun Equations

Classical Analysis and ODEs 2020-01-08 v1 Mathematical Physics math.MP

Abstract

The Painlev\'{e} equations arise from the study of Hankel determinants generated by moment matrices, whose weights are expressed as the product of ``classical" weights multiplied by suitable ``deformation factors", usually dependent on a ``time variable'' tt. From ladder operators one finds second order linear ordinary differential equations for associated orthogonal polynomials with coefficients being rational functions. The Painlev\'e and related functions appear as the residues of these rational functions. We will be interested in the situation when nn, the order of the Hankel matrix and also the degree of the polynomials Pn(x)P_n(x) orthogonal with respect to the deformed weights, gets large. We show that the second order linear differential equations satisfied by Pn(x)P_n(x) are particular cases of Heun equations when nn is large. In some sense, monic orthogonal polynomials generated by deformed weights mentioned below are solutions of a variety of Heun equa\-tions. Heun equations are of considerable importance in mathematical physics and in the special cases they degenerate to the hypergeometric and confluent hypergeometric equations. In this paper we look at three type of weights: the Jacobi type, which are are supported (0,1](0,1] the Laguerre type and the weights deformed by the indicator function of (a,b)(a,b) χ(a,b)\chi_{(a,b)} and the step function θ(x)\theta(x).

Keywords

Cite

@article{arxiv.1905.04869,
  title  = {Orthogonal Polynomials, Asymptotics and Heun Equations},
  author = {Yang Chen and Galina Filipuk and Longjun Zhan},
  journal= {arXiv preprint arXiv:1905.04869},
  year   = {2020}
}
R2 v1 2026-06-23T09:04:22.191Z