Submodular maximization and its generalization through an intersection cut lens

Abstract

We study a mixed-integer set S:=\(x,t) ∈ \0,1\n × R: f(x) t\ arising in the submodular maximization problem, where f is a submodular function defined over \0,1\n. We use intersection cuts to tighten a polyhedral outer approximation of S. We construct a continuous extension F of f, which is convex and defined over the entire space Rn. We show that the epigraph of F is an S-free set, and characterize maximal S-free sets including the epigraph. We propose a hybrid discrete Newton algorithm to compute an intersection cut efficiently and exactly. Our results are generalized to the hypograph or the superlevel set of a submodular-supermodular function, which is a model for discrete nonconvexity. A consequence of these results is intersection cuts for Boolean multilinear constraints. We evaluate our techniques on max cut, pseudo Boolean maximization, and Bayesian D-optimal design problems within a MIP solver.