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Auteurs principaux: Fan, Jun, Yan, Ailing, Xiu, Xianchao, Liu, Wanquan
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2505.23273
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author Fan, Jun
Yan, Ailing
Xiu, Xianchao
Liu, Wanquan
author_facet Fan, Jun
Yan, Ailing
Xiu, Xianchao
Liu, Wanquan
contents Phase retrieval (PR) is a popular research topic in signal processing and machine learning. However, its performance degrades significantly when the measurements are corrupted by noise or outliers. To address this limitation, we propose a novel robust sparse PR method that covers both real- and complex-valued cases. The core is to leverage the Huber function to measure the loss and adopt the $\ell_{1/2}$-norm regularization to realize feature selection, thereby improving the robustness of PR. In theory, we establish statistical guarantees for such robustness and derive necessary optimality conditions for global minimizers. Particularly, for the complex-valued case, we provide a fixed point inclusion property inspired by Wirtinger derivatives. Furthermore, we develop an efficient optimization algorithm by integrating the gradient descent method into a majorization-minimization (MM) framework. It is rigorously proved that the whole generated sequence is convergent and also has a linear convergence rate under mild conditions, which has not been investigated before. Numerical examples under different types of noise validate the robustness and effectiveness of our proposed method.
format Preprint
id arxiv_https___arxiv_org_abs_2505_23273
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Robust Sparse Phase Retrieval: Statistical Guarantee, Optimality Theory and Convergent Algorithm
Fan, Jun
Yan, Ailing
Xiu, Xianchao
Liu, Wanquan
Optimization and Control
Phase retrieval (PR) is a popular research topic in signal processing and machine learning. However, its performance degrades significantly when the measurements are corrupted by noise or outliers. To address this limitation, we propose a novel robust sparse PR method that covers both real- and complex-valued cases. The core is to leverage the Huber function to measure the loss and adopt the $\ell_{1/2}$-norm regularization to realize feature selection, thereby improving the robustness of PR. In theory, we establish statistical guarantees for such robustness and derive necessary optimality conditions for global minimizers. Particularly, for the complex-valued case, we provide a fixed point inclusion property inspired by Wirtinger derivatives. Furthermore, we develop an efficient optimization algorithm by integrating the gradient descent method into a majorization-minimization (MM) framework. It is rigorously proved that the whole generated sequence is convergent and also has a linear convergence rate under mild conditions, which has not been investigated before. Numerical examples under different types of noise validate the robustness and effectiveness of our proposed method.
title Robust Sparse Phase Retrieval: Statistical Guarantee, Optimality Theory and Convergent Algorithm
topic Optimization and Control
url https://arxiv.org/abs/2505.23273