English

Coded Compressive Sensing: A Compute-and-Recover Approach

Information Theory 2016-01-27 v1 math.IT

Abstract

In this paper, we propose \textit{coded compressive sensing} that recovers an nn-dimensional integer sparse signal vector from a noisy and quantized measurement vector whose dimension mm is far-fewer than nn. The core idea of coded compressive sensing is to construct a linear sensing matrix whose columns consist of lattice codes. We present a two-stage decoding method named \textit{compute-and-recover} to detect the sparse signal from the noisy and quantized measurements. In the first stage, we transform such measurements into noiseless finite-field measurements using the linearity of lattice codewords. In the second stage, syndrome decoding is applied over the finite-field to reconstruct the sparse signal vector. A sufficient condition of a perfect recovery is derived. Our theoretical result demonstrates an interplay among the quantization level pp, the sparsity level kk, the signal dimension nn, and the number of measurements mm for the perfect recovery. Considering 1-bit compressive sensing as a special case, we show that the proposed algorithm empirically outperforms an existing greedy recovery algorithm.

Keywords

Cite

@article{arxiv.1601.06899,
  title  = {Coded Compressive Sensing: A Compute-and-Recover Approach},
  author = {Namyoon Lee and Song-Nam Hong},
  journal= {arXiv preprint arXiv:1601.06899},
  year   = {2016}
}

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Submitted to ISIT 2016

R2 v1 2026-06-22T12:36:39.574Z