Volume 40, Issue 2
On a Hybrid Method for Inverse Transmission Eigenvalue Problems

Weishi Yin, Zhaobin Xu, Pinchao Meng & Hongyu Liu

Ann. Appl. Math., 40 (2024), pp. 139-160.

Published online: 2024-05

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  • Abstract

In this paper, we are concerned with the inverse transmission eigenvalue problem to recover the shape as well as the constant refractive index of a penetrable medium scatterer. The linear sampling method is employed to determine the transmission eigenvalues within a certain wavenumber interval based on far-field measurements. Based on a prior information given by the linear sampling method, the neural network approach is proposed for the reconstruction of the unknown scatterer. We divide the wavenumber intervals into several subintervals, ensuring that each transmission eigenvalue is located in its corresponding subinterval. In each such subinterval, the wavenumber that yields the maximum value of the indicator functional will be included in the input set during the generation of the training data. This technique for data generation effectively ensures the consistent dimensions of model input. The refractive index and shape are taken as the output of the network. Due to the fact that transmission eigenvalues considered in our method are relatively small, certain super-resolution effects can also be generated. Numerical experiments are presented to verify the effectiveness and promising features of the proposed method in two and three dimensions.

  • AMS Subject Headings

35P25, 35R30, 35P15

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COPYRIGHT: © Global Science Press

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@Article{AAM-40-139, author = {Yin , WeishiXu , ZhaobinMeng , Pinchao and Liu , Hongyu}, title = {On a Hybrid Method for Inverse Transmission Eigenvalue Problems}, journal = {Annals of Applied Mathematics}, year = {2024}, volume = {40}, number = {2}, pages = {139--160}, abstract = {

In this paper, we are concerned with the inverse transmission eigenvalue problem to recover the shape as well as the constant refractive index of a penetrable medium scatterer. The linear sampling method is employed to determine the transmission eigenvalues within a certain wavenumber interval based on far-field measurements. Based on a prior information given by the linear sampling method, the neural network approach is proposed for the reconstruction of the unknown scatterer. We divide the wavenumber intervals into several subintervals, ensuring that each transmission eigenvalue is located in its corresponding subinterval. In each such subinterval, the wavenumber that yields the maximum value of the indicator functional will be included in the input set during the generation of the training data. This technique for data generation effectively ensures the consistent dimensions of model input. The refractive index and shape are taken as the output of the network. Due to the fact that transmission eigenvalues considered in our method are relatively small, certain super-resolution effects can also be generated. Numerical experiments are presented to verify the effectiveness and promising features of the proposed method in two and three dimensions.

}, issn = {}, doi = {https://doi.org/10.4208/aam.OA-2024-0003}, url = {http://global-sci.org/intro/article_detail/aam/23098.html} }
TY - JOUR T1 - On a Hybrid Method for Inverse Transmission Eigenvalue Problems AU - Yin , Weishi AU - Xu , Zhaobin AU - Meng , Pinchao AU - Liu , Hongyu JO - Annals of Applied Mathematics VL - 2 SP - 139 EP - 160 PY - 2024 DA - 2024/05 SN - 40 DO - http://doi.org/10.4208/aam.OA-2024-0003 UR - https://global-sci.org/intro/article_detail/aam/23098.html KW - Inverse transmission eigenvalue problem, linear sampling method, neural network, super-resolution. AB -

In this paper, we are concerned with the inverse transmission eigenvalue problem to recover the shape as well as the constant refractive index of a penetrable medium scatterer. The linear sampling method is employed to determine the transmission eigenvalues within a certain wavenumber interval based on far-field measurements. Based on a prior information given by the linear sampling method, the neural network approach is proposed for the reconstruction of the unknown scatterer. We divide the wavenumber intervals into several subintervals, ensuring that each transmission eigenvalue is located in its corresponding subinterval. In each such subinterval, the wavenumber that yields the maximum value of the indicator functional will be included in the input set during the generation of the training data. This technique for data generation effectively ensures the consistent dimensions of model input. The refractive index and shape are taken as the output of the network. Due to the fact that transmission eigenvalues considered in our method are relatively small, certain super-resolution effects can also be generated. Numerical experiments are presented to verify the effectiveness and promising features of the proposed method in two and three dimensions.

Yin , WeishiXu , ZhaobinMeng , Pinchao and Liu , Hongyu. (2024). On a Hybrid Method for Inverse Transmission Eigenvalue Problems. Annals of Applied Mathematics. 40 (2). 139-160. doi:10.4208/aam.OA-2024-0003
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