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Main Authors: Li, Tingyou, Xu, Zixin, Chu, Yong S., Huang, Xiaojing, Li, Jizhou
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2311.14925
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author Li, Tingyou
Xu, Zixin
Chu, Yong S.
Huang, Xiaojing
Li, Jizhou
author_facet Li, Tingyou
Xu, Zixin
Chu, Yong S.
Huang, Xiaojing
Li, Jizhou
contents Fourier phase retrieval is essential for high-definition imaging of nanoscale structures across diverse fields, notably coherent diffraction imaging. This study presents the Single impliCit neurAl Network (SCAN), a tool built upon coordinate neural networks meticulously designed for enhanced phase retrieval performance. Remedying the drawbacks of conventional iterative methods which are easiliy trapped into local minimum solutions and sensitive to noise, SCAN adeptly connects object coordinates to their amplitude and phase within a unified network in an unsupervised manner. While many existing methods primarily use Fourier magnitude in their loss function, our approach incorporates both the predicted magnitude and phase, enhancing retrieval accuracy. Comprehensive tests validate SCAN's superiority over traditional and other deep learning models regarding accuracy and noise robustness. We also demonstrate that SCAN excels in the ptychography setting.
format Preprint
id arxiv_https___arxiv_org_abs_2311_14925
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Coordinate-based Neural Network for Fourier Phase Retrieval
Li, Tingyou
Xu, Zixin
Chu, Yong S.
Huang, Xiaojing
Li, Jizhou
Computer Vision and Pattern Recognition
Image and Video Processing
Fourier phase retrieval is essential for high-definition imaging of nanoscale structures across diverse fields, notably coherent diffraction imaging. This study presents the Single impliCit neurAl Network (SCAN), a tool built upon coordinate neural networks meticulously designed for enhanced phase retrieval performance. Remedying the drawbacks of conventional iterative methods which are easiliy trapped into local minimum solutions and sensitive to noise, SCAN adeptly connects object coordinates to their amplitude and phase within a unified network in an unsupervised manner. While many existing methods primarily use Fourier magnitude in their loss function, our approach incorporates both the predicted magnitude and phase, enhancing retrieval accuracy. Comprehensive tests validate SCAN's superiority over traditional and other deep learning models regarding accuracy and noise robustness. We also demonstrate that SCAN excels in the ptychography setting.
title Coordinate-based Neural Network for Fourier Phase Retrieval
topic Computer Vision and Pattern Recognition
Image and Video Processing
url https://arxiv.org/abs/2311.14925