Empirical Chaos Processes and Blind Deconvolution

Abstract

This paper investigates conditions under which certain kinds of systems of bilinear equations have a unique structured solution. In particular, we look at when we can recover vectors w,q from observations of the form \[ y = <w,b><c,q>, = 1,…,L, \] where b,c are known. We show that if w∈CM1 and q∈CM2 are sparse, with no more than K and N nonzero entries, respectively, and the b,c are generic, selected as independent Gaussian random vectors, then w,q are uniquely determined from \[ L ≥ Const· (K+N)5(M1M2) \] such equations with high probability. The key ingredient in our analysis is a uniform probabilistic bound on how far a random process of the form \[Z(X) = Σ=1L|b*Xc|2 \] deviates from its mean over a set of structured matrices X∈X. As both b and c are random, this is a specialized type of 4th order chaos; we refer to Z(X) as an empirical chaos process. Bounding this process yields a set of general conditions for when the map X→ \b*Xc\=1L is a restricted isometry over the set of matrices X. The conditions are stated in terms of general geometric properties of the set X, and are explicitly computed for the case where X is the set of matrices that are simultaneously sparse and low rank.