Analysis of Bi-Isotropic Media using Hybrid Boundary Element Method

作者

  • Mirjana T. Peric Department of Theoretical Electrical Engineering University of Niš, Faculty of Electronic Engineering, 18000 Niš, Serbia
  • Saša S. Ilić Department of Theoretical Electrical Engineering University of Niš, Faculty of Electronic Engineering, 18000 Niš, Serbia
  • Ana N. Vučković Department of Theoretical Electrical Engineering University of Niš, Faculty of Electronic Engineering, 18000 Niš, Serbia
  • Nebojša B. Raičević Department of Theoretical Electrical Engineering University of Niš, Faculty of Electronic Engineering, 18000 Niš, Serbia

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https://doi.org/10.13052/2021.ACES.J.361001

关键词:

Bi-isotropic media, Characteristic impedance, effective relative permittivity, finite element methods, hybrid boundary element method, microstrip line.

摘要

This paper proposes the application of the hybrid boundary element method (HBEM) for analysis of bi-isotropic media of Tellegen type. In previous applications of this method it was possible to analyze only the electromagnetic problems in isotropic media. The main contribution of this paper is the modification of the method itself, in order to solve a large scale of quasi-static TEM problems in bi-isotropic media. Detailed theoretical analysis and HBEM procedure are described and applied. Characteristic parameters of a microstrip line with bi-isotropic substrate are analyzed. Obtained results have been compared with available numerical and software simulation results. A close results match can be noticed.

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Mirjana Perić received the Dipl.–Ing., M.Sc. and Ph.D. degrees from the Faculty of Electronic Engineering (FEE) of Niš, Serbia. In 2001, she joined the Department of Theoretical Electrical Engineering at the FEE. She is currently an assistant professor at the same faculty.

Her researching interests are: electromagnetic field theory, analytical and numerical methods for electromagnetic field calculations, electromagnetic compatibility, and transmission line analysis.

She is a member of the ACES, IEEE MTT and IEEE EMC societies.

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Saša S. Ilić received Dipl.-Ing. degree in electronics and telecommunications in 1995 from the Faculty of Electronic Engineering (FEE) of Niš, Serbia. At the same faculty he received M.Sc. and Ph.D. degrees in theoretical electrical engineering in 2001 and 2014, respectively.

From January 1998 up to now, he has engaged to the Department of Theoretical Electrical Engineering, at the FEE.

His researching areas are: lightning protection systems, low-frequency electromagnetic fields penetrated into human body and microstrip transmission lines analysis with isotropic, anisotropic, and bianisotropic media.

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Ana Vučković received the Dipl.-Ing., M.Sc., and Ph.D. degrees from the Faculty of Electronic Engineering of Niš, Serbia. In 2003, she joined the Department of Theoretical Electrical Engineering at the FEE. She works as an assistant professor at the same faculty.

Her main research area is computational electromagnetics (electromagnetic field theory, analytical and numerical methods for electromagnetic field calculations, electromagnetic compatibility and permanent magnet analysis). Also, she took part in numerous international projects and projects supported by the Serbian Ministry of Education and Science. She is a member of the ACES society.

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Nebojša Raičević received his Dipl.-Ing., M. Sc., and Ph.D. degrees at the Faculty of Electronic Engineering (FEE) of Niš, Serbia, in 1989, 1998, and 2010, respectively. He received the Dr.-Ing. degree with a PhD-thesis dealing with the numerical electromagnetic field calculations.

He is currently an associate professor at the FEE. His research interests include: cable terminations and joints, numerical methods for EM problems solving, microstrip transmission lines with isotropic, anisotropic, and bianisotropic media, metamaterial structures, EMC, nonlinear electrostatic problems, magnetic field calculation of coils and permanent magnets. He is a member of the IEEE AP Society, IEEE EMC Society, IEEE Dielectrics and Electrical Insulation Society, and IEEE Magnetics Society.

参考

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已出版

2021-11-21

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General Submission