English

Sparse Phase Retrieval via Truncated Amplitude Flow

Information Theory 2017-10-31 v2 math.IT Optimization and Control

Abstract

This paper develops a novel algorithm, termed \emph{SPARse Truncated Amplitude flow} (SPARTA), to reconstruct a sparse signal from a small number of magnitude-only measurements. It deals with what is also known as sparse phase retrieval (PR), which is \emph{NP-hard} in general and emerges in many science and engineering applications. Upon formulating sparse PR as an amplitude-based nonconvex optimization task, SPARTA works iteratively in two stages: In stage one, the support of the underlying sparse signal is recovered using an analytically well-justified rule, and subsequently, a sparse orthogonality-promoting initialization is obtained via power iterations restricted on the support; and, in the second stage, the initialization is successively refined by means of hard thresholding based gradient-type iterations. SPARTA is a simple yet effective, scalable, and fast sparse PR solver. On the theoretical side, for any nn-dimensional kk-sparse (knk\ll n) signal x\bm{x} with minimum (in modulus) nonzero entries on the order of (1/k)x2(1/\sqrt{k})\|\bm{x}\|_2, SPARTA recovers the signal exactly (up to a global unimodular constant) from about k2lognk^2\log n random Gaussian measurements with high probability. Furthermore, SPARTA incurs computational complexity on the order of k2nlognk^2n\log n with total runtime proportional to the time required to read the data, which improves upon the state-of-the-art by at least a factor of kk. Finally, SPARTA is robust against additive noise of bounded support. Extensive numerical tests corroborate markedly improved recovery performance and speedups of SPARTA relative to existing alternatives.

Keywords

Cite

@article{arxiv.1611.07641,
  title  = {Sparse Phase Retrieval via Truncated Amplitude Flow},
  author = {Gang Wang and Liang Zhang and Georgios B. Giannakis and Mehmet Akcakaya and Jie Chen},
  journal= {arXiv preprint arXiv:1611.07641},
  year   = {2017}
}

Comments

23 pages; 5 figures

R2 v1 2026-06-22T17:01:49.026Z