Constructing Orthogonal Rational Function Vectors with an application in Rational Approximation
Abstract
We present two algorithms for constructing orthonormal bases of rational function vectors with respect to a discrete inner product, and discuss how to use them for a rational approximation problem. Building on the pencil-based formulation of the inverse generalized eigenvalue problem by Van Buggenhout et al. (2022), we extend it to rational vectors of arbitrary length , where the recurrence relations are represented by a pair of -Hessenberg matrices, i.e., matrices with possibly nonzero subdiagonals. An updating algorithm based on similarity transformations using rotations and a Krylov-type algorithm related to the rational Arnoldi method are derived. The performance is demonstrated on the rational approximation of on , where the optimal lightning + polynomial convergence rate of Herremans, Huybrechs, and Trefethen (2023) is successfully recovered. This illustrates the robustness of the proposed methods for handling exponentially clustered poles near singularities.
Cite
@article{arxiv.2601.11317,
title = {Constructing Orthogonal Rational Function Vectors with an application in Rational Approximation},
author = {Robbe Vermeiren},
journal= {arXiv preprint arXiv:2601.11317},
year = {2026}
}
Comments
19 pages