A Discontinuous Galerkin Surface Integral Equation Method for Scattering from Multiscale Homogeneous Objects

Bei Bei Kong; Xin Qing Sheng

doi:10.1109/TAP.2018.2803133

A Discontinuous Galerkin Surface Integral Equation Method for Scattering from Multiscale Homogeneous Objects

Bei Bei Kong, Xin Qing Sheng^*

^*Corresponding author for this work

School of Integrated Circuits and Electronics

Beijing Institute of Technology

Research output: Contribution to journal › Article › peer-review

58 Citations (Scopus)

Abstract

A discontinuous Galerkin (DG) surface integral equation approach is proposed for scattering from homogeneous dielectric objects. The formulation of DG for homogeneous bodies is derived from the combined tangential field integral equation. The differences of DG for penetrable and nonpenetrable objects are presented by numerical experiments to demonstrate the numerical mechanism of DG. Numerical experiments demonstrate the great advantages of our presented formulation of DG for homogeneous objects in efficiency, flexibility, and scalability. A series numerical results are presented to show the capability of the presented DG solution for homogeneous bodies, especially for multiscale homogeneous bodies.

Original language	English
Pages (from-to)	1937-1946
Number of pages	10
Journal	IEEE Transactions on Antennas and Propagation
Volume	66
Issue number	4
DOIs	https://doi.org/10.1109/TAP.2018.2803133
Publication status	Published - Apr 2018

Keywords

Discontinuous galerkin (DG) method
domain decomposition method (DDM)
homogeneous objects
multiscale
the combined tangential field (CTF) formulation

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10.1109/TAP.2018.2803133

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abstract = "A discontinuous Galerkin (DG) surface integral equation approach is proposed for scattering from homogeneous dielectric objects. The formulation of DG for homogeneous bodies is derived from the combined tangential field integral equation. The differences of DG for penetrable and nonpenetrable objects are presented by numerical experiments to demonstrate the numerical mechanism of DG. Numerical experiments demonstrate the great advantages of our presented formulation of DG for homogeneous objects in efficiency, flexibility, and scalability. A series numerical results are presented to show the capability of the presented DG solution for homogeneous bodies, especially for multiscale homogeneous bodies.",

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AB - A discontinuous Galerkin (DG) surface integral equation approach is proposed for scattering from homogeneous dielectric objects. The formulation of DG for homogeneous bodies is derived from the combined tangential field integral equation. The differences of DG for penetrable and nonpenetrable objects are presented by numerical experiments to demonstrate the numerical mechanism of DG. Numerical experiments demonstrate the great advantages of our presented formulation of DG for homogeneous objects in efficiency, flexibility, and scalability. A series numerical results are presented to show the capability of the presented DG solution for homogeneous bodies, especially for multiscale homogeneous bodies.

KW - Discontinuous galerkin (DG) method

KW - domain decomposition method (DDM)

KW - homogeneous objects

KW - multiscale

KW - the combined tangential field (CTF) formulation

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A Discontinuous Galerkin Surface Integral Equation Method for Scattering from Multiscale Homogeneous Objects

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Keywords

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