Fast Algorithms for Discrete Differential Equations
Abstract
Discrete Differential Equations (DDEs) are functional equations that relate polynomially a power series in with polynomial coefficients in a "catalytic" variable and the specializations, say at , of and of some of its partial derivatives in . DDEs occur frequently in combinatorics, especially in map enumeration. If a DDE is of fixed-point type then its solution is unique, and a general result by Popescu (1986) implies that is an algebraic power series. Constructive proofs of algebraicity for solutions of fixed-point type DDEs were proposed by Bousquet-M\'elou and Jehanne (2006). Bostan et. al (2022) initiated a systematic algorithmic study of such DDEs of order 1. We generalize this study to DDEs of arbitrary order. First, we propose nontrivial extensions of algorithms based on polynomial elimination and on the guess-and-prove paradigm. Second, we design two brand-new algorithms that exploit the special structure of the underlying polynomial systems. Last, but not least, we report on implementations that are able to solve highly challenging DDEs with a combinatorial origin.
Cite
@article{arxiv.2302.06203,
title = {Fast Algorithms for Discrete Differential Equations},
author = {Alin Bostan and Hadrien Notarantonio and Mohab Safey El Din},
journal= {arXiv preprint arXiv:2302.06203},
year = {2023}
}
Comments
11 pages, revised version