Unlabeled Compressed Sensing from Multiple Measurement Vectors
Abstract
This paper introduces an algorithmic solution to a broader class of unlabeled sensing problems with multiple measurement vectors (MMV). The goal is to recover an unknown structured signal matrix, , from its noisy linear observation matrix, , whose rows are further randomly shuffled by an unknown permutation matrix . A new Bayes-optimal unlabeled compressed sensing (UCS) recovery algorithm is developed from the bilinear approximate message passing (Bi-VAMP) framework using non-separable and coupled priors on the rows and columns of the permutation matrix . In particular, standard unlabeled sensing is a special case of the proposed framework, and UCS further generalizes it by neither assuming a partially shuffled signal matrix nor a small-sized permutation matrix . For the sake of theoretical performance prediction, we also conduct a state evolution (SE) analysis of the proposed algorithm and show its consistency with the asymptotic empirical mean-squared error (MSE). Numerical results demonstrate the effectiveness of the proposed UCS algorithm and its advantage over state-of-the-art baseline approaches in various applications. We also numerically examine the phase transition diagrams of UCS, thereby characterizing the detectability region as a function of the signal-to-noise ratio (SNR).
Cite
@article{arxiv.2406.08290,
title = {Unlabeled Compressed Sensing from Multiple Measurement Vectors},
author = {Mohamed Akrout and Amine Mezghani and Faouzi Bellili},
journal= {arXiv preprint arXiv:2406.08290},
year = {2024}
}