Rational approximation of Euler's constant using multiple orthogonal polynomials
Abstract
We construct new rational approximants of Euler's constant that improve those of Aptekarev et al. (2007) and Rivoal (2009). The approximants are given in terms of certain (mixed type) multiple orthogonal polynomials associated with the exponential integral. The dual family of multiple orthogonal polynomials leads to new rational approximants of the Gompertz constant that improve those of Aptekarev et al. (2007). Our approach is motivated by the fact that we can reformulate Rivoal's construction in terms of type I multiple Laguerre polynomials of the first kind by making use of the underlying Riemann-Hilbert problem. As a consequence, we can drastically simplify Rivoal's approach, which allows us to study the Diophantine and asymptotic properties of the approximants more easily.
Cite
@article{arxiv.2404.09799,
title = {Rational approximation of Euler's constant using multiple orthogonal polynomials},
author = {Thomas Wolfs and Walter Van Assche},
journal= {arXiv preprint arXiv:2404.09799},
year = {2025}
}
Comments
23 pages. v2: added some references to other known constructions. v3: simplified the idea behind the overall quality of rational approximants, clarified parts of the proof of Proposition 3.2 and streamlined some notation