Sparse Signal Recovery from Quadratic Measurements via Convex Programming

Abstract

In this paper we consider a system of quadratic equations |<zj, x>|2 = bj, j = 1, ..., m, where x in Rn is unknown while normal random vectors zj in Rn and quadratic measurements bj in R are known. The system is assumed to be underdetermined, i.e., m < n. We prove that if there exists a sparse solution x, i.e., at most k components of x are non-zero, then by solving a convex optimization program, we can solve for x up to a multiplicative constant with high probability, provided that k <= O((m/log n)(1/2)). On the other hand, we prove that k <= O(log n (m)(1/2)) is necessary for a class of naive convex relaxations to be exact.