Spatial Mixing and Non-local Markov chains
Abstract
We consider spin systems with nearest-neighbor interactions on an -vertex -dimensional cube of the integer lattice graph . We study the effects that exponential decay with distance of spin correlations, specifically the strong spatial mixing condition (SSM), has on the rate of convergence to equilibrium distribution of non-local Markov chains. We prove that SSM implies mixing of a block dynamics whose steps can be implemented efficiently. We then develop a methodology, consisting of several new comparison inequalities concerning various block dynamics, that allow us to extend this result to other non-local dynamics. As a first application of our method we prove that, if SSM holds, then the relaxation time (i.e., the inverse spectral gap) of general block dynamics is , where is the number of blocks. A second application of our technology concerns the Swendsen-Wang dynamics for the ferromagnetic Ising and Potts models. We show that SSM implies an bound for the relaxation time. As a by-product of this implication we observe that the relaxation time of the Swendsen-Wang dynamics in square boxes of is throughout the subcritical regime of the -state Potts model, for all . We also prove that for monotone spin systems SSM implies that the mixing time of systematic scan dynamics is . Systematic scan dynamics are widely employed in practice but have proved hard to analyze. Our proofs use a variety of techniques for the analysis of Markov chains including coupling, functional analysis and linear algebra.
Cite
@article{arxiv.1708.01513,
title = {Spatial Mixing and Non-local Markov chains},
author = {Antonio Blanca and Pietro Caputo and Alistair Sinclair and Eric Vigoda},
journal= {arXiv preprint arXiv:1708.01513},
year = {2017}
}