Planting and MCMC Sampling from the Potts model

Abstract

We consider the problem of sampling from the ferromagnetic q-state Potts model on the random d-regular graph with parameter β>0. A key difficulty that arises in sampling from the model is the existence of a metastability window (βu,βu') where the distribution has two competing modes, the so-called disordered and ordered phases, causing MCMC-based algorithms to be slow mixing from worst-case initialisations. To this end, Helmuth, Jenssen and Perkins designed a sampling algorithm that works for all β when q is large, using cluster expansion methods; more recently, their analysis technique has been adapted to show that random-cluster dynamics mixes fast when initialised more judiciously. However, a bottleneck behind cluster-expansion arguments is that they inherently only work for large q, whereas it is widely conjectured that sampling is possible for all q,d≥ 3. The only result so far that applies to general q,d≥ 3 is by Blanca and Gheissari who showed that the random-cluster dynamics mixes fast for β<βu. For β>βu, certain correlation phenomena emerge because of the metastability which have been hard to handle, especially for small q and d. Our main contribution is to perform a delicate analysis of the Potts distribution and the random-cluster dynamics that goes beyond the threshold βu. We use planting as the main tool in our proofs, and combine it with the analysis of random-cluster dynamics. We are thus able to show that the random-cluster dynamics initialised from all-out mixes fast for all integers q,d≥ 3 beyond the uniqueness threshold βu; our analysis works all the way up to the threshold βc∈ (βu,βu') where the dominant mode switches from disordered to ordered. We also obtain an algorithm in the ordered regime β>βc that refines significantly the range of q,d.

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