逆散射问题
人工神经网络
积分方程
反问题
计算电磁学
理论(学习稳定性)
散射
正规化(语言学)
电磁场
计算机科学
算法
残余物
非线性系统
数学
无监督学习
介电常数
拉普拉斯算子
数值稳定性
电磁学
微波成像
反向
噪音(视频)
应用数学
约束(计算机辅助设计)
一般化
数学分析
反演(地质)
电磁学
稳健性(进化)
操作员(生物学)
反变换采样
趋同(经济学)
拉普拉斯变换
电磁兼容性
人工智能
作者
Tao Wei,Xiao-Hua Wang,Hongyu Ren,Hui Zhou,Jiao-Long Niu,Bing-Zhong Wang
标识
DOI:10.1109/tmtt.2025.3649884
摘要
An unsupervised deep learning framework is proposed for solving 2-D electromagnetic inverse scattering problems (ISPs) with either full- or phaseless-data (PD), featuring good accuracy, stability, and generalization. The proposed method first establishes a mapping based on the scattering-field integral equation (SFIE), where the scattering field data is the input of the neural network (NN), and the total electric field and the permittivity distribution are the outputs. Then, two residual terms derived from the SFIE and total-field integral equation (TFIE) are embedded into the loss function as physics-inspired constraints for nonlinear electromagnetic problems. Furthermore, Laplacian regularization and a ReLU-based soft constraint are incorporated to enhance the training stability of the network and improve the performance of inversion. Numerical and experimental results demonstrate that the proposed method achieves higher accuracy, stronger noise robustness, and better artifact suppression compared with traditional inversion techniques. Owing to the unsupervised nature, the proposed method exhibits excellent generalization ability without labeled data. These advantages indicate that the proposed approach provides a stable, accurate, and label-free solution to electromagnetic inverse scattering.
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