Gibbs conditioning, atypical consensus and splitting Gibbs measures on random regular graphs
Abstract
Given n independent Bernoulli(p) random variables Xi, i = 1, ..., n, representing the opinions of individuals connected by an underlying random k-regular graph Gn on 1, ..., n, we show that when conditioned on an atypical empirical consensus, which is the normalized sum of Xi Xj over neighboring vertices i, j, the joint distribution of the random variables converges, as n goes to infinity, to an Ising measure on the infinite k-regular tree Tk with a specific external field that depends only on the bias parameter p, and a temperature that depends on both p and the atypical consensus value. In particular, we show that conditional on the empirical consensus being smaller (respy, larger) than typical, the limit is a translation-invariant splitting (TIS) antiferromagnetic (respy, ferromagnetic) Ising measure on Tk. Moreover, if the bias is zero, then there is a phase transition: when the consensus exceeds k/(k-1), the conditional limits could be either the plus or minus boundary condition Ising measures. Furthermore, when Xi, i = 1, ..., n, are i.i.d. on a finite space, we show that when conditioned on an atypical value of the scaled sum of h(Xi, Xj) over neighboring vertices i and j, for any symmetric edge potential h, the limiting joint distribution of Xi lies in the set of (possibly degenerate) TIS Gibbs measures on Tk. The proofs leverage a tractable form of the large deviation rate function for component empirical measures of random regular graphs with i.i.d. marks and Gibbs conditioning principles, and entail careful analyses of associated non-convex constrained optimization problems. As a by-product of our results, we also obtain an (asymptotic) analog of the maximum entropy principle for Gibbs measures on random regular graphs.
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