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Support Recovery in Universal One-bit Compressed Sensing

Information Theory 2021-09-15 v3 Discrete Mathematics Machine Learning math.IT Machine Learning

Abstract

One-bit compressed sensing (1bCS) is an extreme-quantized signal acquisition method that has been intermittently studied in the past decade. In 1bCS, linear samples of a high dimensional signal are quantized to only one bit per sample (sign of the measurement). The extreme quantization makes it an interesting case study of the more general single-index or generalized linear models. At the same time it can also be thought of as a `design' version of learning a binary linear classifier or halfspace-learning. Assuming the original signal vector to be sparse, existing results in 1bCS either aim to find the support of the vector, or approximate the signal within an ϵ\epsilon-ball. The focus of this paper is support recovery, which often also computationally facilitate approximate signal recovery. A \emph{universal} measurement matrix for 1bCS refers to one set of measurements that work \emph{for all} sparse signals. With universality, it is known that Θ~(k2)\tilde{\Theta}(k^2) 1bCS measurements are necessary and sufficient for support recovery (where kk denotes the sparsity). In this work, we show that it is possible to universally recover the support with a small number of false positives with O~(k3/2)\tilde{O}(k^{3/2}) measurements. If the dynamic range of the signal vector is known, then with a different technique, this result can be improved to only O~(k)\tilde{O}(k) measurements. Other results on universal but approximate support recovery are also provided in this paper. All of our main recovery algorithms are simple and polynomial-time.

Keywords

Cite

@article{arxiv.2107.09091,
  title  = {Support Recovery in Universal One-bit Compressed Sensing},
  author = {Arya Mazumdar and Soumyabrata Pal},
  journal= {arXiv preprint arXiv:2107.09091},
  year   = {2021}
}

Comments

20 pages

R2 v1 2026-06-24T04:20:17.210Z