Fast Compressive Phase Retrieval Under Bounded Noise
Abstract
We study the problem of recovering a t-sparse real vector from m quadratic equations yi=(ai*x)^2 with noisy measurements yi's. This is known as the problem of compressive phase retrieval, and has been widely applied to X-ray diffraction imaging, microscopy, quantum mechanics, etc. The challenge is to design a a) fast and b) noise-tolerant algorithms with c) near-optimal sample complexity. Prior work in this direction typically achieved one or two of these goals, but none of them enjoyed the three performance guarantees simultaneously. In this work, with a particular set of sensing vectors ai's, we give a provable algorithm that is robust to any bounded yet unstructured deterministic noise. Our algorithm requires roughly O(t) measurements and runs in O(tn*log (1/epsilon)) time, where epsilon is the error. This result advances the state-of-the-art work, and guarantees the applicability of our method to large datasets. Experiments on synthetic and real data verify our theory.
Cite
Text
Zhang et al. "Fast Compressive Phase Retrieval Under Bounded Noise." AAAI Conference on Artificial Intelligence, 2017. doi:10.1609/AAAI.V31I1.10876Markdown
[Zhang et al. "Fast Compressive Phase Retrieval Under Bounded Noise." AAAI Conference on Artificial Intelligence, 2017.](https://mlanthology.org/aaai/2017/zhang2017aaai-fast/) doi:10.1609/AAAI.V31I1.10876BibTeX
@inproceedings{zhang2017aaai-fast,
title = {{Fast Compressive Phase Retrieval Under Bounded Noise}},
author = {Zhang, Hongyang and You, Shan and Lin, Zhouchen and Xu, Chao},
booktitle = {AAAI Conference on Artificial Intelligence},
year = {2017},
pages = {2884-2890},
doi = {10.1609/AAAI.V31I1.10876},
url = {https://mlanthology.org/aaai/2017/zhang2017aaai-fast/}
}