Electromagnetic Imaging for Buried Conductors Using Deep Convolutional Neural Networks

Chiu, Chien‐Ching; Chien, Tsair‐Wei; Yu, Kwangmin; Chen, Po-Hsiang; Lim, Eng-Hock

doi:10.3390/app13116794

Cited by 2 publications

(1 citation statement)

References 17 publications

(17 reference statements)

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“…(1) We have successfully utilized neural networks and deep learning technology to reconstruct anisotropic objects in the microwave imaging research field. Compared to [74], our method does not need to designate the incident angle. It is worth mentioning that under the same noise level and training parameter settings, our proposed method can still reconstruct accurate anisotropic microwave images.…”

Section: Introductionmentioning

confidence: 99%

Microwave Imaging of Anisotropic Objects by Artificial Intelligence Technology

Liao,

Chiu,

Chen

et al. 2023

Sensors

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In this paper, we present the microwave imaging of anisotropic objects by artificial intelligence technology. Since the biaxial anisotropic scatterers have different dielectric constant components in different transverse directions, the problems faced by transverse electronic (TE) polarization waves are more complex than those of transverse magnetic (TM) polarization waves. In other words, measured scattered field information can scarcely reconstruct microwave images due to the high nonlinearity characteristic of TE polarization. Therefore, we first use the dominant current scheme (DCS) and the back-propagation scheme (BPS) to compute the initial guess image. We then apply a trained convolution neural network (CNN) to regenerate the microwave image. Numerical results show that the CNN possesses a good generalization ability under limited training data, which could be favorable to deploy in image processing. Finally, we compare DCS and BPS reconstruction images for anisotropic objects by the CNN and prove that DCS is better than BPS. In brief, successfully reconstructing biaxial anisotropic objects with a CNN is the contribution of this proposal.

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Section: Introductionmentioning

confidence: 99%

Microwave Imaging of Anisotropic Objects by Artificial Intelligence Technology

Liao,

Chiu,

Chen

et al. 2023

Sensors

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Electromagnetic Subsurface Imaging in the Presence of Metallic Structures: A Review of Numerical Strategies

Castillo-Reyes,

Queralt,

Piñas-Varas

et al. 2024

Surv Geophys

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Electromagnetic (EM) imaging aims to produce large-scale, high-resolution soil conductivity maps that provide essential information for Earth subsurface exploration. To rigorously generate EM subsurface models, one must address both the forward problem and the inverse problem. From these subsurface resistivity maps, also referred to as volumes of resistivity distribution, it is possible to extract useful information (lithology, temperature, porosity, permeability, among others) to improve our knowledge about geo-resources on which modern society depends (e.g., energy, groundwater, and raw materials, among others). However, this ability to detect electrical resistivity contrasts also makes EM imaging techniques sensitive to metallic structures whose EM footprint often exceeds their diminutive stature compared to surrounding materials. Depending on target applications, this behavior can be advantageous or disadvantageous. In this work, we review EM modeling and inverse solutions in the presence of metallic structures, emphasizing how these structures affect EM data acquisition and interpretation. By addressing the challenges posed by metallic structures, our aim is to enhance the accuracy and reliability of subsurface EM characterization, ultimately leading to improved management of geo-resources and environmental monitoring. Here, we consider the latter through the lens of a triple helix approach: physics behind metallic structures in EM modeling and imaging, development of computational tools (conventional strategies and artificial intelligence schemes), and configurations and applications. The literature review shows that, despite recent scientific advancements, EM imaging techniques are still being developed, as are software-based data processing and interpretation tools. Such progress must address geological complexities and metallic casing measurements integrity in increasing detail setups. We hope this review will provide inspiration for researchers to study the fascinating EM problem, as well as establishing a robust technological ecosystem to those interested in studying EM fields affected by metallic artifacts.

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Electromagnetic Imaging for Buried Conductors Using Deep Convolutional Neural Networks

Cited by 2 publications

References 17 publications

Microwave Imaging of Anisotropic Objects by Artificial Intelligence Technology

Microwave Imaging of Anisotropic Objects by Artificial Intelligence Technology

Electromagnetic Subsurface Imaging in the Presence of Metallic Structures: A Review of Numerical Strategies

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