Sharp Poincar\'e and log-Sobolev inequalities for the switch chain on regular bipartite graphs

Abstract

Consider the switch chain on the set of d-regular bipartite graphs on n vertices with 3≤ d≤ nc, for a small universal constant c>0. We prove that the chain satisfies a Poincar\'e inequality with a constant of order O(nd); moreover, when d is fixed, we establish a log-Sobolev inequality for the chain with a constant of order Od(n n). We show that both results are optimal. The Poincar\'e inequality implies that in the regime 3≤ d≤ nc the mixing time of the switch chain is at most O((nd)2 (nd)), improving on the previously known bound O((nd)13 (nd)) due to Kannan, Tetali and Vempala and O(n7d18 (nd)) obtained by Dyer et al. The log-Sobolev inequality that we establish for constant d implies a bound O(n2 n) on the mixing time of the chain which, up to the n factor, captures a conjectured optimal bound. Our proof strategy relies on building, for any fixed function on the set of d-regular bipartite simple graphs, an appropriate extension to a function on the set of multigraphs given by the configuration model. We then establish a comparison procedure with the well studied random transposition model in order to obtain the corresponding functional inequalities. While our method falls into a rich class of comparison techniques for Markov chains on different state spaces, the crucial feature of the method - dealing with chains with a large distortion between their stationary measures - is a novel addition to the theory.