Swendsen-Wang Algorithm on the Mean-Field Potts Model

Abstract

We study the q-state ferromagnetic Potts model on the n-vertex complete graph known as the mean-field (Curie-Weiss) model. We analyze the Swendsen-Wang algorithm which is a Markov chain that utilizes the random cluster representation for the ferromagnetic Potts model to recolor large sets of vertices in one step and potentially overcomes obstacles that inhibit single-site Glauber dynamics. Long et al. studied the case q=2, the Swendsen-Wang algorithm for the mean-field ferromagnetic Ising model, and showed that the mixing time satisfies: (i) (1) for β<βc, (ii) (n1/4) for β=βc, (iii) ( n) for β>βc, where βc is the critical temperature for the ordered/disordered phase transition. In contrast, for q≥ 3 there are two critical temperatures 0<βu<βrc that are relevant. We prove that the mixing time of the Swendsen-Wang algorithm for the ferromagnetic Potts model on the n-vertex complete graph satisfies: (i) (1) for β<βu, (ii) (n1/3) for β=βu, (iii) (n(1)) for βu<β<βrc, and (iv) (n) for β≥βrc. These results complement refined results of Cuff et al. on the mixing time of the Glauber dynamics for the ferromagnetic Potts model.