Phase Retrieval: From Computational Imaging to Machine Learning
Abstract
Phase retrieval consists in the recovery of a complex-valued signal from intensity-only measurements. As it pervades a broad variety of applications, many researchers have striven to develop phase-retrieval algorithms. Classical approaches involve techniques as varied as generic gradient-descent routines or specialized spectral methods, to name a few. Yet, the phase-recovery problem remains a challenge to this day. Recently, however, advances in machine learning have revitalized the study of phase retrieval in two ways: significant theoretical advances have emerged from the analogy between phase retrieval and single-layer neural networks; practical breakthroughs have been obtained thanks to deep-learning regularization. In this tutorial, we review phase retrieval under a unifying framework that encompasses classical and machine-learning methods. We focus on three key elements: applications, overview of recent reconstruction algorithms, and the latest theoretical results.
Cite
@article{arxiv.2204.03554,
title = {Phase Retrieval: From Computational Imaging to Machine Learning},
author = {Jonathan Dong and Lorenzo Valzania and Antoine Maillard and Thanh-an Pham and Sylvain Gigan and Michael Unser},
journal= {arXiv preprint arXiv:2204.03554},
year = {2023}
}