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Main Authors: Du, Yutong, Liu, Zicheng, Cao, Miao, Liang, Zupeng, Zong, Yali, Li, Changyou
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2504.20504
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author Du, Yutong
Liu, Zicheng
Cao, Miao
Liang, Zupeng
Zong, Yali
Li, Changyou
author_facet Du, Yutong
Liu, Zicheng
Cao, Miao
Liang, Zupeng
Zong, Yali
Li, Changyou
contents Deep neural networks have been applied to address electromagnetic inverse scattering problems (ISPs) and shown superior imaging performances, which can be affected by the training dataset, the network architecture and the applied loss function. Here, the quality of data samples is cared and valued by the defined quality factor. Based on the quality factor, the composition of the training dataset is optimized. The network architecture is integrated with the residual connections and channel attention mechanism to improve feature extraction. A loss function that incorporates data-fitting error, physical-information constraints and the desired feature of the solution is designed and analyzed to suppress the background artifacts and improve the reconstruction accuracy. Various numerical analysis are performed to demonstrate the superiority of the proposed quality-factor inspired deep neural network (QuaDNN) solver and the imaging performance is finally verified by experimental imaging test.
format Preprint
id arxiv_https___arxiv_org_abs_2504_20504
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Quality-factor inspired deep neural network solver for solving inverse scattering problems
Du, Yutong
Liu, Zicheng
Cao, Miao
Liang, Zupeng
Zong, Yali
Li, Changyou
Image and Video Processing
Machine Learning
Computational Physics
Deep neural networks have been applied to address electromagnetic inverse scattering problems (ISPs) and shown superior imaging performances, which can be affected by the training dataset, the network architecture and the applied loss function. Here, the quality of data samples is cared and valued by the defined quality factor. Based on the quality factor, the composition of the training dataset is optimized. The network architecture is integrated with the residual connections and channel attention mechanism to improve feature extraction. A loss function that incorporates data-fitting error, physical-information constraints and the desired feature of the solution is designed and analyzed to suppress the background artifacts and improve the reconstruction accuracy. Various numerical analysis are performed to demonstrate the superiority of the proposed quality-factor inspired deep neural network (QuaDNN) solver and the imaging performance is finally verified by experimental imaging test.
title Quality-factor inspired deep neural network solver for solving inverse scattering problems
topic Image and Video Processing
Machine Learning
Computational Physics
url https://arxiv.org/abs/2504.20504