On Approximations of the PSD Cone by a Polynomial Number of Smaller-sized PSD Cones

Abstract

We study the problem of approximating the cone of positive semidefinite (PSD) matrices with a cone that can be described by smaller-sized PSD constraints. Specifically, we ask the question: "how closely can we approximate the set of unit-trace n × n PSD matrices, denoted by D, using at most N number of k × k PSD constraints?" In this paper, we prove lower bounds on N to achieve a good approximation of D by considering two constructions of an approximating set. First, we consider the unit-trace n × n symmetric matrices that are PSD when restricted to a fixed set of k-dimensional subspaces in RRn. We prove that if this set is a good approximation of D, then the number of subspaces must be at least exponentially large in n for any k = o(n). % Second, we show that any set S that approximates D within a constant approximation ratio must have superpolynomial S+k-extension complexity. To be more precise, if S is a constant factor approximation of D, then S must have S+k-extension complexity at least ( C · \ n, n/k \) where C is some absolute constant. In addition, we show that any set S such that D ⊂eq S and the Gaussian width of D is at most a constant times larger than the Gaussian width of D must have S+k-extension complexity at least ( C · \ n1/3, n/k \). These results imply that the cone of n × n PSD matrices cannot be approximated by a polynomial number of k × k PSD constraints for any k = o(n / 2 n). These results generalize the recent work of Fawzi on the hardness of polyhedral approximations of S+n, which corresponds to the special case with k=1.