Go to OpenReview Archive homepageCutoff and Metastability for the homogeneous Block Mean-field Potts model
Abstract: In this paper, we study the Potts model on a general graph whose vertices are partitioned into $m$ blocks of the same size. The interaction between two spins depends only on whether they belong to the same block or not. We denote the interaction coefficients for the spins at the different blocks and the same block by $a, b$, respectively. We show that $J=(b+(m-1)a) / m$ plays the role of the effective interaction coefficient of the overall system. In Curie-Weiss-Potts model with $a=0, \ b=1, \ \textnormal{and} \ m=1$, critical phase transition appears at the inverse-temperature $\beta_c$, and mixing transition occurs at $\beta_s$. Generalizing this fact to our model, we explicitly find the critical inverse temperatures $\beta_c/J, \ \beta_s/J$ for the phase transition and mixing, respectively. Enhancing the aggregate path coupling, we prove in a high-temperature regime $\beta<\beta_s/J$, a cutoff occurs at time $\large[2(1-2\beta J/q)\large]^{-1}n \log n$ with window size $n$. Moreover, metastability deduces the exponential mixing in the low-temperature regime $\beta> \beta_s/J$. These results first show the cutoff of the block Potts model and suggest a novel extension of the aggregate path coupling.
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