One-Bit Compressed Sensing via One-Shot Hard Thresholding
Abstract
This paper concerns the problem of 1-bit compressed sensing, where the goal is to estimate a sparse signal from a few of its binary measurements. We study a non-convex sparsity-constrained program and present a novel and concise analysis that moves away from the widely used notion of Gaussian width. We show that with high probability a simple algorithm is guaranteed to produce an accurate approximation to the normalized signal of interest under the -metric. On top of that, we establish an ensemble of new results that address norm estimation, support recovery, and model misspecification. On the computational side, it is shown that the non-convex program can be solved via one-step hard thresholding which is dramatically efficient in terms of time complexity and memory footprint. On the statistical side, it is shown that our estimator enjoys a near-optimal error rate under standard conditions. The theoretical results are substantiated by numerical experiments.
Cite
@article{arxiv.2007.03641,
title = {One-Bit Compressed Sensing via One-Shot Hard Thresholding},
author = {Jie Shen},
journal= {arXiv preprint arXiv:2007.03641},
year = {2020}
}
Comments
Accepted to The Conference on Uncertainty in Artificial Intelligence (UAI) 2020