Unknown sparsity in compressed sensing: Denoising and inference

Abstract

The theory of Compressed Sensing (CS) asserts that an unknown signal x∈Rp can be accurately recovered from an underdetermined set of n linear measurements with n p, provided that x is sufficiently sparse. However, in applications, the degree of sparsity \|x\|0 is typically unknown, and the problem of directly estimating \|x\|0 has been a longstanding gap between theory and practice. A closely related issue is that \|x\|0 is a highly idealized measure of sparsity, and for real signals with entries not equal to 0, the value \|x\|0=p is not a useful description of compressibility. In our previous conference paper [Lop13] that examined these problems, we considered an alternative measure of "soft" sparsity, \|x\|12/\|x\|22, and designed a procedure to estimate \|x\|12/\|x\|22 that does not rely on sparsity assumptions. The present work offers a new deconvolution-based method for estimating unknown sparsity, which has wider applicability and sharper theoretical guarantees. In particular, we introduce a family of entropy-based sparsity measures sq(x):=(\|x\|q\|x\|1)q1-q parameterized by q∈[0,∞]. This family interpolates between \|x\|0=s0(x) and \|x\|12/\|x\|22=s2(x) as q ranges over [0,2]. For any q∈ (0,2]\1\, we propose an estimator sq(x) whose relative error converges at the dimension-free rate of 1/n, even when p/n∞. Our main results also describe the limiting distribution of sq(x), as well as some connections to Basis Pursuit Denosing, the Lasso, deterministic measurement matrices, and inference problems in CS.