r-local sensing: Improved algorithm and applications
Abstract
The unlabeled sensing problem is to solve a noisy linear system of equations under unknown permutation of the measurements. We study a particular case of the problem where the permutations are restricted to be r-local, i.e. the permutation matrix is block diagonal with r x r blocks. Assuming a Gaussian measurement matrix, we argue that the r-local permutation model is more challenging compared to a recent sparse permutation model. We propose a proximal alternating minimization algorithm for the general unlabeled sensing problem that provably converges to a first order stationary point. Applied to the r-local model, we show that the resulting algorithm is efficient. We validate the algorithm on synthetic and real datasets. We also formulate the 1-d unassigned distance geometry problem as an unlabeled sensing problem with a structured measurement matrix.
Keywords
Cite
@article{arxiv.2110.14034,
title = {r-local sensing: Improved algorithm and applications},
author = {Ahmed Ali Abbasi and Abiy Tasissa and Shuchin Aeron},
journal= {arXiv preprint arXiv:2110.14034},
year = {2022}
}