Approximate Support Recovery using Codes for Unsourced Multiple Access

Abstract

We consider the approximate support recovery (ASR) task of inferring the support of a K-sparse vector x ∈ Rn from m noisy measurements. We examine the case where n is large, which precludes the application of standard compressed sensing solvers, thereby necessitating solutions with lower complexity. We design a scheme for ASR by leveraging techniques developed for unsourced multiple access. We present two decoding algorithms with computational complexities O(K2 n+K n n) and O(K3 +K2 n+ K n n) per iteration, respectively. When K n, this is much lower than the complexity of approximate message passing with a minimum mean squared error denoiser% (AMP-MMSE) ,which requires O(mn) operations per iteration. This gain comes at a slight performance cost. Our findings suggest that notions from multiple access %such as spreading, matched filter receivers and codes can play an important role in the design of measurement schemes for ASR.