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Improved bounds for sparse recovery from subsampled random convolutions

Information Theory 2018-03-28 v2 math.IT Probability

Abstract

We study the recovery of sparse vectors from subsampled random convolutions via 1\ell_1-minimization. We consider the setup in which both the subsampling locations as well as the generating vector are chosen at random. For a subgaussian generator with independent entries, we improve previously known estimates: if the sparsity ss is small enough, i.e., sn/log(n)s \lesssim \sqrt{n/\log(n)}, we show that mslog(en/s)m \gtrsim s \log(en/s) measurements are sufficient to recover ss-sparse vectors in dimension nn with high probability, matching the well-known condition for recovery from standard Gaussian measurements. If ss is larger, then essentially mslog2(s)log(log(s))log(n)m \geq s \log^2(s) \log(\log(s)) \log(n) measurements are sufficient, again improving over previous estimates. Our results are shown via the so-called robust null space property which is weaker than the standard restricted isometry property. Our method of proof involves a novel combination of small ball estimates with chaining techniques {which should be of independent interest.

Keywords

Cite

@article{arxiv.1610.04983,
  title  = {Improved bounds for sparse recovery from subsampled random convolutions},
  author = {Shahar Mendelson and Holger Rauhut and Rachel Ward},
  journal= {arXiv preprint arXiv:1610.04983},
  year   = {2018}
}

Comments

34 pages

R2 v1 2026-06-22T16:22:32.386Z