English

Swendsen-Wang Algorithm on the Mean-Field Potts Model

Discrete Mathematics 2017-11-27 v4 Statistical Mechanics Mathematical Physics math.MP Probability

Abstract

We study the qq-state ferromagnetic Potts model on the nn-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=2q=2, the Swendsen-Wang algorithm for the mean-field ferromagnetic Ising model, and showed that the mixing time satisfies: (i) Θ(1)\Theta(1) for β<βc\beta<\beta_c, (ii) Θ(n1/4)\Theta(n^{1/4}) for β=βc\beta=\beta_c, (iii) Θ(logn)\Theta(\log n) for β>βc\beta>\beta_c, where βc\beta_c is the critical temperature for the ordered/disordered phase transition. In contrast, for q3q\geq 3 there are two critical temperatures 0<βu<βrc0<\beta_u<\beta_{rc} that are relevant. We prove that the mixing time of the Swendsen-Wang algorithm for the ferromagnetic Potts model on the nn-vertex complete graph satisfies: (i) Θ(1)\Theta(1) for β<βu\beta<\beta_u, (ii) Θ(n1/3)\Theta(n^{1/3}) for β=βu\beta=\beta_u, (iii) exp(nΩ(1))\exp(n^{\Omega(1)}) for βu<β<βrc\beta_u<\beta<\beta_{rc}, and (iv) Θ(logn)\Theta(\log{n}) for ββrc\beta\geq\beta_{rc}. These results complement refined results of Cuff et al. on the mixing time of the Glauber dynamics for the ferromagnetic Potts model.

Cite

@article{arxiv.1502.06593,
  title  = {Swendsen-Wang Algorithm on the Mean-Field Potts Model},
  author = {Andreas Galanis and Daniel Stefankovic and Eric Vigoda},
  journal= {arXiv preprint arXiv:1502.06593},
  year   = {2017}
}

Comments

To appear in Random Structures & Algorithms

R2 v1 2026-06-22T08:35:57.168Z