Optimization of Mean-field Spin Glasses

Abstract

Mean-field spin glasses are families of random energy functions (Hamiltonians) on high-dimensional product spaces. In this paper we consider the case of Ising mixed p-spin models, namely Hamiltonians HN:N R on the Hamming hypercube N = \ 1\N, which are defined by the property that \HN( σ)\ σ∈ N is a centered Gaussian process with covariance E\HN( σ1)HN( σ2)\ depending only on the scalar product σ1, σ2. The asymptotic value of the optimum σ∈ NHN( σ) was characterized in terms of a variational principle known as the Parisi formula, first proved by Talagrand and, in a more general setting, by Panchenko. The structure of superlevel sets is extremely rich and has been studied by a number of authors. Here we ask whether a near optimal configuration σ can be computed in polynomial time. We develop a message passing algorithm whose complexity per-iteration is of the same order as the complexity of evaluating the gradient of HN, and characterize the typical energy value it achieves. When the p-spin model HN satisfies a certain no-overlap gap assumption, for any >0, the algorithm outputs σ∈N such that HN( σ) (1-) σ' HN( σ'), with high probability. The number of iterations is bounded in N and depends uniquely on . More generally, regardless of whether the no-overlap gap assumption holds, the energy achieved is given by an extended variational principle, which generalizes the Parisi formula.