Sampling from the Gibbs measure of the continuous random energy model and the hardness threshold

Abstract

The continuous random energy model (CREM) is a toy model of disordered systems introduced by Bovier and Kurkova in 2004 based on previous work by Derrida and Spohn in the 80s. In a recent paper by Addario-Berry and Maillard, they raised the following question: what is the threshold βG, at which sampling approximately the Gibbs measure at any inverse temperature β>βG becomes algorithmically hard? Here, sampling approximately means that the Kullback--Leibler divergence from the output law of the algorithm to the Gibbs measure is of order o(N) with probability approaching 1, as N→∞, and algorithmically hard means that the running time, the numbers of vertices queries by the algorithms, is beyond of polynomial order. The present work shows that when the covariance function A of the CREM is concave, for all β>0, a recursive sampling algorithm on a renormalized tree approximates the Gibbs measure with running time of order O(N1+). For A non-concave, the present work exhibits a threshold βG<∞ such that the following hardness transition occurs: a) For every β≤ βG, the recursive sampling algorithm approximates the Gibbs measure with running time of order O(N1+). b) For every β>βG, a hardness result is established for a large class of algorithms. Namely, for any algorithm from this class that samples the Gibbs measure approximately, there exists z>0 such that the running time of this algorithm is at least ezN with probability approaching 1. In other words, it is impossible to sample approximately in polynomial-time the Gibbs measure in this regime. Additionally, we provide a lower bound of the free energy of the CREM that could hold its own value.