Algorithms for the ferromagnetic Potts model on expanders
Abstract
We give algorithms for approximating the partition function of the ferromagnetic -color Potts model on graphs of maximum degree . Our primary contribution is a fully polynomial-time approximation scheme for -regular graphs with an expansion condition at low temperatures (that is, bounded away from the order-disorder threshold). The expansion condition is much weaker than in previous works; for example, the expansion exhibited by the hypercube suffices. The main improvements come from a significantly sharper analysis of standard polymer models; we use extremal graph theory and applications of Karger's algorithm to count cuts that may be of independent interest. It is \#BIS-hard to approximate the partition function at low temperatures on bounded-degree graphs, so our algorithm can be seen as evidence that hard instances of \#BIS are rare. We also obtain efficient algorithms in the Gibbs uniqueness region for bounded-degree graphs. While our high temperature proof follows more standard polymer model analysis, our result holds in the largest known range of parameters and .
Cite
@article{arxiv.2204.01923,
title = {Algorithms for the ferromagnetic Potts model on expanders},
author = {Charlie Carlson and Ewan Davies and Nicolas Fraiman and Alexandra Kolla and Aditya Potukuchi and Corrine Yap},
journal= {arXiv preprint arXiv:2204.01923},
year = {2024}
}
Comments
v3: 30 pages, minor revisions incorporating referee comments, to appear in Combinatorics, Probability, and Computing; extended abstract of an earlier version appeared in FOCS