Hyperbolic Relaxation of k-Locally Positive Semidefinite Matrices

Abstract

A successful computational approach for solving large-scale positive semidefinite (PSD) programs is to enforce PSD-ness on only a collection of submatrices. For our study, we let Sn,k be the convex cone of n× n symmetric matrices where all k× k principal submatrices are PSD. We call a matrix in this k-locally PSD. In order to compare Sn,k to the of PSD matrices, we study eigenvalues of k-locally PSD matrices. The key insight in this paper is that there is a convex cone H(ekn) so that if X ∈ Sn,k, then the vector of eigenvalues of X is contained in H(ekn). The cone H(ekn) is the hyperbolicity cone of the elementary symmetric polynomial ekn (where ekn(x) = ΣS ⊂eq [n] : |S| = k Πi ∈ S xi) with respect to the all ones vector. Using this insight, we are able to improve previously known upper bounds on the Frobenius distance between matrices in Sn,k and PSD matrices. We also study the quality of the convex relaxation H(enk). We first show that this relaxation is tight for the case of k = n -1, that is, for every vector in H(enn -1) there exists a matrix in Sn, n -1 whose eigenvalues are equal to the components of the vector. We then prove a structure theorem on nonsingular matrices in Sn,k all of whose k× k principal minors are zero, which we believe is of independent interest. %We then prove a structure theorem that precisely characterizes the non-singular matrices in Sn,k whose vector of eigenvalues belongs to the boundary of H(enk). This result shows shows that for 1< k < n -1 "large parts" of the boundary of H(ekn) do not intersect with the eigenvalues of matrices in Sn,k.