Solving Full-Wave Nonlinear Inverse Scattering Problems by Deep Learning Schemes

2019 IEEE International Conference on Computational Electromagnetics (ICCEM) Pub Date : 2019-03-20 DOI:10.1109/COMPEM.2019.8779092

Zhun Wei, Xudong Chen

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引用次数: 2

Abstract

This paper aims to solve a full-wave inverse scattering problem, which is a quantitative imaging problem, i.e., to reconstruct the permittivities of dielectric scatterers from the knowledge of measured scattering data. Scatterers are represented in pixel basis, which is a versatile approach since the value of permittivity of each pixel is an independent parameter. This paper compares three different deep learning schemes in solving full-wave nonlinear ISPs. It is well known that in order to make machine learning more powerful when solving a particular problem, researchers must have a deep understanding of the corresponding forward problem. The same applies to inverse scattering problems. The concept of induced current plays an essential role in the proposed CNN technique, which enables us to design architecture of learning machine such that unnecessary computational effort spent in learning wave physics is minimized or avoided. Several representative tests are carried out, and it is demonstrated that the proposed CNN scheme outperforms a brute-force application of CNN.

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用深度学习方法求解全波非线性逆散射问题

本文旨在解决全波逆散射问题，这是一个定量成像问题，即根据实测散射数据重建介质散射体的介电常数。散射体以像素为单位表示，这是一种通用的方法，因为每个像素的介电常数值是一个独立的参数。本文比较了求解全波非线性isp的三种不同的深度学习方案。众所周知，为了使机器学习在解决特定问题时更加强大，研究人员必须对相应的前向问题有深刻的理解。这同样适用于逆散射问题。感应电流的概念在提出的CNN技术中起着至关重要的作用，它使我们能够设计学习机的架构，从而最小化或避免在学习波物理上花费的不必要的计算工作量。进行了几个有代表性的测试，结果表明所提出的CNN方案优于CNN的暴力破解应用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

2019 IEEE International Conference on Computational Electromagnetics (ICCEM)

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