Deep Learning Electromagnetic Inversion Solver Based on a Two-Step Framework for High-Contrast and Heterogeneous Scatterers

He Ming Yao; Michael Ng; Lijun Jiang

doi:10.1109/TAP.2024.3372772

Deep Learning Electromagnetic Inversion Solver Based on a Two-Step Framework for High-Contrast and Heterogeneous Scatterers

He Ming Yao, Michael Ng^*, Lijun Jiang

^*Corresponding author for this work

Department of Mathematics

Research output: Contribution to journal › Journal article › peer-review

4 Citations (Scopus)

Abstract

This communication proposes a novel electromagnetic (EM) inversion solver based on a two-step deep learning (DL) framework. The framework consists of the deep convolutional asymmetric encoder–decoder structure (DCAEDS) followed by the deep residual convolutional neural network (DRCNN). In the first step, DCAEDS utilizes EM scattered field data from a single-frequency one-time measurement to coarsely retrieve the initial contrasts (permittivities) of target scatterers. In the second step, DRCNN employs a mixed input scheme, comprising the initially reconstructed permittivities from the first step and the original EM scattered field data, to significantly improve the retrieved contrasts (permittivities) and refine the reconstruction of targets. Consequently, the proposed EM inversion solver achieves excellent accuracy and efficiency, even for high-contrast targets. The proposed solver is flexible as it is required only for a single-frequency one-time measurement on the EM scattered field. Moreover, the proposed two-step DL-based solver overcomes the limitations of conventional methods, such as high computational costs and ill-posedness. Numerical benchmarks based on various dielectric objects demonstrate the feasibility of the proposed EM inversion solver, highlighting its potential as a candidate for real-time quantitative EM inversion for high-contrast targets.

Original language	English
Article number	10464185
Pages (from-to)	5337-5342
Number of pages	6
Journal	IEEE Transactions on Antennas and Propagation
Volume	72
Issue number	6
Early online date	12 Mar 2024
DOIs	https://doi.org/10.1109/TAP.2024.3372772
Publication status	Published - Jun 2024

Scopus Subject Areas

Electrical and Electronic Engineering

User-Defined Keywords

Biomedical measurement
Computational modeling
Convolutional neural network
Electromagnetic interference
Frequency measurement
Iterative methods
Mathematical models
Training
electromagnetic (EM) inverse scattering
high contrast
residual learning
two-step process

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10.1109/TAP.2024.3372772

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@article{e1d972fe18c84969a2c090548d875f8b,

title = "Deep Learning Electromagnetic Inversion Solver Based on a Two-Step Framework for High-Contrast and Heterogeneous Scatterers",

abstract = "This communication proposes a novel electromagnetic (EM) inversion solver based on a two-step deep learning (DL) framework. The framework consists of the deep convolutional asymmetric encoder–decoder structure (DCAEDS) followed by the deep residual convolutional neural network (DRCNN). In the first step, DCAEDS utilizes EM scattered field data from a single-frequency one-time measurement to coarsely retrieve the initial contrasts (permittivities) of target scatterers. In the second step, DRCNN employs a mixed input scheme, comprising the initially reconstructed permittivities from the first step and the original EM scattered field data, to significantly improve the retrieved contrasts (permittivities) and refine the reconstruction of targets. Consequently, the proposed EM inversion solver achieves excellent accuracy and efficiency, even for high-contrast targets. The proposed solver is flexible as it is required only for a single-frequency one-time measurement on the EM scattered field. Moreover, the proposed two-step DL-based solver overcomes the limitations of conventional methods, such as high computational costs and ill-posedness. Numerical benchmarks based on various dielectric objects demonstrate the feasibility of the proposed EM inversion solver, highlighting its potential as a candidate for real-time quantitative EM inversion for high-contrast targets.",

keywords = "Biomedical measurement, Computational modeling, Convolutional neural network, Electromagnetic interference, Frequency measurement, Iterative methods, Mathematical models, Training, electromagnetic (EM) inverse scattering, high contrast, residual learning, two-step process",

author = "Yao, {He Ming} and Michael Ng and Lijun Jiang",

note = "Funding Information: This work was supported in part by Hong Kong Research Grant Council General Research Fund (GRF) under Grant 12300218, Grant 12300519, Grant 17201020, Grant 17300021, Grant C1013-21GF, and Grant C7004-21GF; in part by the Joint Natural Science Foundation of China— Research Grants Council (NSFC-RGC) under Grant N-HKU76921; and in part by the Research Grants Council of Hong Kong Special Administrative Region, China, under Grant HKU PDFS2122-7S05. Publisher copyright: {\textcopyright} 2024 IEEE. ",

year = "2024",

month = jun,

doi = "10.1109/TAP.2024.3372772",

language = "English",

volume = "72",

pages = "5337--5342",

journal = "IEEE Transactions on Antennas and Propagation",

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TY - JOUR

T1 - Deep Learning Electromagnetic Inversion Solver Based on a Two-Step Framework for High-Contrast and Heterogeneous Scatterers

AU - Yao, He Ming

AU - Ng, Michael

AU - Jiang, Lijun

N1 - Funding Information: This work was supported in part by Hong Kong Research Grant Council General Research Fund (GRF) under Grant 12300218, Grant 12300519, Grant 17201020, Grant 17300021, Grant C1013-21GF, and Grant C7004-21GF; in part by the Joint Natural Science Foundation of China— Research Grants Council (NSFC-RGC) under Grant N-HKU76921; and in part by the Research Grants Council of Hong Kong Special Administrative Region, China, under Grant HKU PDFS2122-7S05. Publisher copyright: © 2024 IEEE.

PY - 2024/6

Y1 - 2024/6

N2 - This communication proposes a novel electromagnetic (EM) inversion solver based on a two-step deep learning (DL) framework. The framework consists of the deep convolutional asymmetric encoder–decoder structure (DCAEDS) followed by the deep residual convolutional neural network (DRCNN). In the first step, DCAEDS utilizes EM scattered field data from a single-frequency one-time measurement to coarsely retrieve the initial contrasts (permittivities) of target scatterers. In the second step, DRCNN employs a mixed input scheme, comprising the initially reconstructed permittivities from the first step and the original EM scattered field data, to significantly improve the retrieved contrasts (permittivities) and refine the reconstruction of targets. Consequently, the proposed EM inversion solver achieves excellent accuracy and efficiency, even for high-contrast targets. The proposed solver is flexible as it is required only for a single-frequency one-time measurement on the EM scattered field. Moreover, the proposed two-step DL-based solver overcomes the limitations of conventional methods, such as high computational costs and ill-posedness. Numerical benchmarks based on various dielectric objects demonstrate the feasibility of the proposed EM inversion solver, highlighting its potential as a candidate for real-time quantitative EM inversion for high-contrast targets.

AB - This communication proposes a novel electromagnetic (EM) inversion solver based on a two-step deep learning (DL) framework. The framework consists of the deep convolutional asymmetric encoder–decoder structure (DCAEDS) followed by the deep residual convolutional neural network (DRCNN). In the first step, DCAEDS utilizes EM scattered field data from a single-frequency one-time measurement to coarsely retrieve the initial contrasts (permittivities) of target scatterers. In the second step, DRCNN employs a mixed input scheme, comprising the initially reconstructed permittivities from the first step and the original EM scattered field data, to significantly improve the retrieved contrasts (permittivities) and refine the reconstruction of targets. Consequently, the proposed EM inversion solver achieves excellent accuracy and efficiency, even for high-contrast targets. The proposed solver is flexible as it is required only for a single-frequency one-time measurement on the EM scattered field. Moreover, the proposed two-step DL-based solver overcomes the limitations of conventional methods, such as high computational costs and ill-posedness. Numerical benchmarks based on various dielectric objects demonstrate the feasibility of the proposed EM inversion solver, highlighting its potential as a candidate for real-time quantitative EM inversion for high-contrast targets.

KW - Biomedical measurement

KW - Computational modeling

KW - Convolutional neural network

KW - Electromagnetic interference

KW - Frequency measurement

KW - Iterative methods

KW - Mathematical models

KW - Training

KW - electromagnetic (EM) inverse scattering

KW - high contrast

KW - residual learning

KW - two-step process

UR - http://www.scopus.com/inward/record.url?scp=85187975758&partnerID=8YFLogxK

U2 - 10.1109/TAP.2024.3372772

DO - 10.1109/TAP.2024.3372772

M3 - Journal article

SN - 0018-926X

VL - 72

SP - 5337

EP - 5342

JO - IEEE Transactions on Antennas and Propagation

JF - IEEE Transactions on Antennas and Propagation

IS - 6

M1 - 10464185

ER -

Deep Learning Electromagnetic Inversion Solver Based on a Two-Step Framework for High-Contrast and Heterogeneous Scatterers

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