Circuit Lower Bounds for the p-Spin Optimization Problem

Abstract

We consider the problem of finding a near ground state of a p-spin model with Rademacher couplings by means of a low-depth circuit. As a direct extension of the authors' recent work [Gamarnik, Jagannath, Wein 2020], we establish that any poly-size n-output circuit that produces a spin assignment with objective value within a certain constant factor of optimality, must have depth at least n/(2 n) as n grows. This is stronger than the known state of the art bounds of the form ( n/(k(n) n)) for similar combinatorial optimization problems, where k(n) depends on the optimality value. For example, for the largest clique problem k(n) corresponds to the square of the size of the clique [Rossman 2010]. At the same time our results are not quite comparable since in our case the circuits are required to produce a solution itself rather than solving the associated decision problem. As in our earlier work, the approach is based on the overlap gap property (OGP) exhibited by random p-spin models, but the derivation of the circuit lower bound relies further on standard facts from Fourier analysis on the Boolean cube, in particular the Linial-Mansour-Nisan Theorem. To the best of our knowledge, this is the first instance when methods from spin glass theory have ramifications for circuit complexity.