Optimization of the Sherrington-Kirkpatrick Hamiltonian

Abstract

Let A∈ Rn× n be a symmetric random matrix with independent and identically distributed Gaussian entries above the diagonal. We consider the problem of maximizing σ, A σ over binary vectors σ∈\+1,-1\n. In the language of statistical physics, this amounts to finding the ground state of the Sherrington-Kirkpatrick model of spin glasses. The asymptotic value of this optimization problem was characterized by Parisi via a celebrated variational principle, subsequently proved by Talagrand. We give an algorithm that, for any >0, outputs σ*∈\-1,+1\n such that σ*, A σ* is at least (1-) of the optimum value, with probability converging to one as n∞. The algorithm's time complexity is C()\, n2. It is a message-passing algorithm, but the specific structure of its update rules is new. As a side result, we prove that, at (low) non-zero temperature, the algorithm constructs approximate solutions of the Thouless-Anderson-Palmer equations.