On the recovery of two function-valued coefficients in the Helmholtz equation for inverse scattering problems via neural networks

IF 2.1 3区数学 Q2 MATHEMATICS, APPLIED

Advances in Computational Mathematics Pub Date : 2025-02-11 DOI:10.1007/s10444-025-10225-z

Zehui Zhou

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引用次数: 0

Abstract

Recently, deep neural networks (DNNs) have become powerful tools for solving inverse scattering problems. However, the approximation and generalization rates of DNNs for solving these problems remain largely under-explored. In this work, we introduce two types of combined DNNs (uncompressed and compressed) to reconstruct two function-valued coefficients in the Helmholtz equation for inverse scattering problems from the scattering data at two different frequencies. An analysis of the approximation and generalization capabilities of the proposed neural networks for simulating the regularized pseudo-inverses of the linearized forward operators in direct scattering problems is provided. The results show that, with sufficient training data and parameters, the proposed neural networks can effectively approximate the inverse process with desirable generalization. Preliminary numerical results show the feasibility of the proposed neural networks for recovering two types of isotropic inhomogeneous media. Furthermore, the trained neural network is capable of reconstructing the isotropic representation of certain types of anisotropic media.

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反散射问题中Helmholtz方程中两个函数值系数的神经网络恢复

近年来，深度神经网络（dnn）已成为求解逆散射问题的有力工具。然而，dnn解决这些问题的近似和泛化率在很大程度上仍未得到充分探索。在这项工作中，我们引入了两种类型的组合dnn（非压缩和压缩），从两个不同频率的散射数据中重构逆散射问题的Helmholtz方程中的两个函数值系数。分析了所提出的神经网络在模拟直接散射问题中线性化正演算子的正则化伪逆时的逼近和泛化能力。结果表明，在训练数据和参数充足的情况下，所提出的神经网络可以有效地逼近逆过程，并具有良好的泛化效果。初步的数值结果表明，所提出的神经网络对两类各向同性非均匀介质的恢复是可行的。此外，训练后的神经网络能够重建某些类型的各向异性介质的各向同性表示。

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

Advances in Computational Mathematics 数学-应用数学

CiteScore

3.00

自引率

5.90%

发文量

审稿时长

3 months

期刊介绍： Advances in Computational Mathematics publishes high quality, accessible and original articles at the forefront of computational and applied mathematics, with a clear potential for impact across the sciences. The journal emphasizes three core areas: approximation theory and computational geometry; numerical analysis, modelling and simulation; imaging, signal processing and data analysis. This journal welcomes papers that are accessible to a broad audience in the mathematical sciences and that show either an advance in computational methodology or a novel scientific application area, or both. Methods papers should rely on rigorous analysis and/or convincing numerical studies.