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Robust Decoding from Binary Measurements with Cardinality Constraint Least Squares

Information Theory 2020-06-05 v1 math.IT

Abstract

The main goal of 1-bit compressive sampling is to decode nn dimensional signals with sparsity level ss from mm binary measurements. This is a challenging task due to the presence of nonlinearity, noises and sign flips. In this paper, the cardinality constraint least square is proposed as a desired decoder. We prove that, up to a constant cc, with high probability, the proposed decoder achieves a minimax estimation error as long as mO(slogn)m \geq \mathcal{O}( s\log n). Computationally, we utilize a generalized Newton algorithm (GNA) to solve the cardinality constraint minimization problem with the cost of solving a least squares problem with small size at each iteration. We prove that, with high probability, the \ell_{\infty} norm of the estimation error between the output of GNA and the underlying target decays to O(lognm)\mathcal{O}(\sqrt{\frac{\log n }{m}}) after at most O(logs)\mathcal{O}(\log s) iterations. Moreover, the underlying support can be recovered with high probability in O(logs)\mathcal{O}(\log s) steps provided that the target signal is detectable. Extensive numerical simulations and comparisons with state-of-the-art methods are presented to illustrate the robustness of our proposed decoder and the efficiency of the GNA algorithm.

Keywords

Cite

@article{arxiv.2006.02890,
  title  = {Robust Decoding from Binary Measurements with Cardinality Constraint Least Squares},
  author = {Zhao Ding and Junjun Huang and Yuling Jiao and Xiliang Lu and Zhijian Yang},
  journal= {arXiv preprint arXiv:2006.02890},
  year   = {2020}
}

Comments

arXiv admin note: text overlap with arXiv:1711.01206

R2 v1 2026-06-23T16:03:30.968Z