L2/L2-foreach sparse recovery with low risk

Abstract

In this paper, we consider the "foreach" sparse recovery problem with failure probability p. The goal of which is to design a distribution over m × N matrices and a decoding algorithm such that for every ∈N, we have the following error guarantee with probability at least 1-p \[\|-()\|2 C\|-k\|2,\] where C is a constant (ideally arbitrarily close to 1) and k is the best k-sparse approximation of . Much of the sparse recovery or compressive sensing literature has focused on the case of either p = 0 or p = (1). We initiate the study of this problem for the entire range of failure probability. Our two main results are as follows: enumerate We prove a lower bound on m, the number measurements, of (k(n/k)+(1/p)) for 2-(N) p <1. Cohen, Dahmen, and DeVore CDD2007:NearOptimall2l2 prove that this bound is tight. We prove nearly matching upper bounds for sub-linear time decoding. Previous such results addressed only p = (1). enumerate Our results and techniques lead to the following corollaries: (i) the first ever sub-linear time decoding "forall" sparse recovery system that requires a γN extra factor (for some γ<1) over the optimal O(k(N/k)) number of measurements, and (ii) extensions of Gilbert et al. GHRSW12:SimpleSignals results for information-theoretically bounded adversaries.