Near-Optimal Lower Bounds on One-Bit Compressed Sensing of Approximately Sparse Signals

Abstract

This paper provides the first near-optimal lower bounds for one-bit compressed sensing of approximately sparse signals lying in a scaled 1 ball, which is a commonly adopted relaxation of the exactly k-sparse assumption. In prior works, the best known upper bounds on uniform Euclidean error are of order O((k/m)1/3), where m is the number of measurements. Under sub-Gaussian matrices, we establish nearly matching lower bounds for both the canonical one-bit compressed sensing model and the uniformly dithered model. Our argument is to first embed a small Euclidean ball into the signal set, which is straightforward for the dithered model but relies on a lifting map for the canonical model, and then construct two signals in this small ball that are separated in Euclidean distance by at least (k/m)1/3 (up to logarithmic factor) but are indistinguishable from the binary measurements. Moreover, our argument extends to approximately sparse signals that live in a properly scaled q ball (q∈ [0,1]), yielding a lower bound Ω((k/m)2-q2+q) that smoothly bridges the cases of exact sparsity (q=0) and 1 sparsity (q=1). Finally, we discuss the extensions of our lower bounds to sub-Weibull matrices, adversarial bit flipping, matrix recovery, and characterize the transition to the non-sparse case.

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