Your search keyword '"Chen, Po-Hsiang"' showing total 3 results

1. Electromagnetic Imaging of Uniaxial Objects by Two-Step Neural Network.

Author

Chien, Wei, Chiu, Chien-Ching, Chen, Po-Hsiang, Wu, Hung-Yu, and Lim, Eng Hock

Subjects

CONVOLUTIONAL neural networks, INTERNET of things

Abstract

The integration of electromagnetic imaging technology with the Internet of Things plays an important role in fields as diverse as healthcare, geophysics, and industrial diagnostics. This paper presents a novel two-step neural network architecture to solve the electromagnetic imaging for uniaxial objects which can be used in the Internet of Things. We incident TM and TE waves to unknown objects and receive the scattered fields. In order to reduce the training difficulty, we first input the gathered scattered field information into a deep convolutional neural network (DCNN) to obtain the preliminary guess. In the second step, we feed the guessed image into the convolutional neural network (CNN) to reconstruct high-resolution images. Our numerical results demonstrate the real-time imaging capability of our proposed two-step method in reconstructing high-contrast scatterers. [ABSTRACT FROM AUTHOR]

Published

2024

2. Electromagnetic Imaging for Buried Conductors Using Deep Convolutional Neural Networks.

Author

Chiu, Chien-Ching, Chien, Wei, Yu, Kai-Xu, Chen, Po-Hsiang, and Lim, Eng Hock

Subjects

CONVOLUTIONAL neural networks, STANDARD deviations, GREEN'S functions, PARTICLE swarm optimization, MICROWAVE imaging, ELECTRICAL conductors

Abstract

Featured Application: Electromagnetic imaging. Featured applications include military measurements, medical imaging, industrial applications, underground gas pipe and electrical high-voltage cable detection, etc. In the past, many conventional algorithms, such as self-adaptive dynamic differential evolution and asynchronous particle swarm optimization, were used to reconstruct buried objects in the frequency domain; these were unfortunately time-consuming during the iterative, repeated computing process of the scattered field. Consequently, we propose an innovative deep convolutional neural network approach to solve the electromagnetic inverse scattering problem for buried conductors in this paper. Different shapes of conductors are buried in one half-space and the electromagnetic wave from the other half-space is incident. The shape of the conductor can be reconstructed promptly by inputting the received scattered fields measured from the upper half-space into the deep convolutional neural network module, which avoids the computational complexity of Green's function for training. Numerical results show that the root mean square error for differently shaped—circular, elliptical, arrow, peanut, four-petal, and three-petal—reconstructed images are, respectively, 2.95%, 3.11%, 17.81%, 15.10%, 14.14%, and 15.24%. Briefly speaking, not only can circular and elliptical buried conductors be reconstructed; some irregular shapes can be reconstructed well. On the contrary, the reconstruction result by U-Net for buried objects is worse since it is not able to obtain a good preliminary image by processing only the upper scattered field—that is, rather than the full space. In other words, our proposed deep convolutional neural network can efficiently solve the electromagnetic inverse scattering problem of buried conductors and provide a novel method for the microwave imaging of the buried conductors. This is the first successful attempt at using deep convolutional neural networks for buried conductors in the frequency domain, which may be useful for practical applications in various fields such as the medical, military, or industrial fields, including magnetic resonance imaging, mine detection and clearance, non-destructive testing, gas or wire pipeline detection, etc. [ABSTRACT FROM AUTHOR]

Published

2023

3. Microwave Imaging for Half-Space Conductors Using the Whale Optimization Algorithm and the Spotted Hyena Optimizer.

Author

Chiu, Chien-Ching, Chen, Po-Hsiang, Chien, Wei, Lim, Eng Hock, and Chen, Guo-Zheng

Subjects

METAHEURISTIC algorithms, MICROWAVE imaging, INVERSE scattering transform

Abstract

This research implements the whale optimization algorithm (WOA) and spotted hyena optimizer (SHO) in inverse scattering to regenerate the conductor shape concealed in the half-space. TM waves are irradiated from the other half-space to a perfect conductor with an unknown shape buried in one half-space. The scattered field measured outside the conductor surface with the boundary condition is used to reconstruct the object using the WOA and SHO algorithms. Several scenarios of reconstruction accuracy were compared for the WOA and SHO. The numerical simulations prove that the WOA has a better reconstruction capability. [ABSTRACT FROM AUTHOR]

Published

2023