English

Energy-efficient Decoders for Compressive Sensing: Fundamental Limits and Implementations

Information Theory 2015-02-17 v4 math.IT

Abstract

The fundamental problem considered in this paper is "What is the \textit{energy} consumed for the implementation of a \emph{compressive sensing} decoding algorithm on a circuit?". Using the "information-friction" framework, we examine the smallest amount of \textit{bit-meters} as a measure for the energy consumed by a circuit. We derive a fundamental lower bound for the implementation of compressive sensing decoding algorithms on a circuit. In the setting where the number of measurements scales linearly with the sparsity and the sparsity is sub-linear with the length of the signal, we show that the \textit{bit-meters} consumption for these algorithms is order-tight, i.e., it matches the lower bound asymptotically up to a constant factor. Our implementations yield interesting insights into design of energy-efficient circuits that are not captured by the notion of computational efficiency alone.

Keywords

Cite

@article{arxiv.1411.4253,
  title  = {Energy-efficient Decoders for Compressive Sensing: Fundamental Limits and Implementations},
  author = {Tongxin Li and Mayank Bakshi and Pulkit Grover},
  journal= {arXiv preprint arXiv:1411.4253},
  year   = {2015}
}

Comments

Submitted to ISIT2015; 23 pages, 12 figures

R2 v1 2026-06-22T07:00:26.758Z