English

Precisely Verifying the Null Space Conditions in Compressed Sensing: A Sandwiching Algorithm

Information Theory 2013-08-13 v3 Machine Learning Systems and Control math.IT Optimization and Control Machine Learning

Abstract

In this paper, we propose new efficient algorithms to verify the null space condition in compressed sensing (CS). Given an (nm)×n(n-m) \times n (m>0m>0) CS matrix AA and a positive kk, we are interested in computing αk=max{z:Az=0,z0}max{K:Kk}\displaystyle \alpha_k = \max_{\{z: Az=0,z\neq 0\}}\max_{\{K: |K|\leq k\}} zK1z1{\|z_K \|_{1}}{\|z\|_{1}}, where KK represents subsets of {1,2,...,n}\{1,2,...,n\}, and K|K| is the cardinality of KK. In particular, we are interested in finding the maximum kk such that αk<12\alpha_k < {1}{2}. However, computing αk\alpha_k is known to be extremely challenging. In this paper, we first propose a series of new polynomial-time algorithms to compute upper bounds on αk\alpha_k. Based on these new polynomial-time algorithms, we further design a new sandwiching algorithm, to compute the \emph{exact} αk\alpha_k with greatly reduced complexity. When needed, this new sandwiching algorithm also achieves a smooth tradeoff between computational complexity and result accuracy. Empirical results show the performance improvements of our algorithm over existing known methods; and our algorithm outputs precise values of αk\alpha_k, with much lower complexity than exhaustive search.

Keywords

Cite

@article{arxiv.1306.2665,
  title  = {Precisely Verifying the Null Space Conditions in Compressed Sensing: A Sandwiching Algorithm},
  author = {Myung Cho and Weiyu Xu},
  journal= {arXiv preprint arXiv:1306.2665},
  year   = {2013}
}

Comments

30 pages

R2 v1 2026-06-22T00:32:20.654Z