Large-scale phase retrieval

Xuyang Chang,Liheng Bian,Jun Zhang

doi:10.1186/s43593-021-00004-w

Xuyang Chang, Liheng Bian + Show 1 more

Open Access

https://doi.org/10.1186/s43593-021-00004-w

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Journal: eLight	Publication Date: Sep 3, 2021
Citations: 59	License type: open-access

Affiliation: Beijing Institute of Technology

Abstract

High-throughput computational imaging requires efficient processing algorithms to retrieve multi-dimensional and multi-scale information. In computational phase imaging, phase retrieval (PR) is required to reconstruct both amplitude and phase in complex space from intensity-only measurements. The existing PR algorithms suffer from the tradeoff among low computational complexity, robustness to measurement noise and strong generalization on different modalities. In this work, we report an efficient large-scale phase retrieval technique termed as LPR. It extends the plug-and-play generalized-alternating-projection framework from real space to nonlinear complex space. The alternating projection solver and enhancing neural network are respectively derived to tackle the measurement formation and statistical prior regularization. This framework compensates the shortcomings of each operator, so as to realize high-fidelity phase retrieval with low computational complexity and strong generalization. We applied the technique for a series of computational phase imaging modalities including coherent diffraction imaging, coded diffraction pattern imaging, and Fourier ptychographic microscopy. Extensive simulations and experiments validate that the technique outperforms the existing PR algorithms with as much as 17dB enhancement on signal-to-noise ratio, and more than one order-of-magnitude increased running efficiency. Besides, we for the first time demonstrate ultra-large-scale phase retrieval at the 8K level (7680times 4320 pixels) in minute-level time.

Highlights

Wide field of view and high resolution are both desirable for various imaging applications, such as medical imaging [1,2,3,4] and remote sensing [5], providing multidimensional and multi-scale target information
As PNP-GAP decomposes reconstruction into separate sub-problems including measurement formation and statistical prior regularization [9, 32], we further introduce an alternating projection solver and an enhancing neural network respectively to solve the two sub-problems
The convergence is determined when the intensity difference of reconstructed image between two successive iterations is smaller than a preset threshold

Summary

Introduction

Wide field of view and high resolution are both desirable for various imaging applications, such as medical imaging [1,2,3,4] and remote sensing [5], providing multidimensional and multi-scale target information. As the recent development of computational imaging, largescale detection has been widely employed in a variety of computational imaging modalities [3, 4, 6, 7]. The SBP of the real-time, ultra-large-scale, high-resolution (RUSH) platform [4] and the Fourier ptychographic microscopy (FPM) [3] have reached to as high as 108–109. Such a large amount of data poses a great challenge for post software processing.

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