arXiv:0711.0366 Abstract | arXiv Analytics

arXiv:0711.0366 [cs.IT]Abstract References Reviews Resources

Shannon Theoretic Limits on Noisy Compressive Sampling

Published 2007-11-02Version 1

In this paper, we study the number of measurements required to recover a sparse signal in ${\mathbb C}^M$ with $L$ non-zero coefficients from compressed samples in the presence of noise. For a number of different recovery criteria, we prove that $O(L)$ (an asymptotically linear multiple of $L$) measurements are necessary and sufficient if $L$ grows linearly as a function of $M$. This improves on the existing literature that is mostly focused on variants of a specific recovery algorithm based on convex programming, for which $O(L\log(M-L))$ measurements are required. We also show that $O(L\log(M-L))$ measurements are required in the sublinear regime ($L = o(M)$).

Comments: 21 pages, submitted

Categories: cs.IT, math.IT

Subjects: 94A12, 62B10

Keywords: shannon theoretic limits, noisy compressive sampling, measurements, specific recovery algorithm, asymptotically linear multiple

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