Mixed potential Green's functions for a circular waveguide filled with uniaxially anisotropic layered media

Mingchih Chen; Chung I.G. Hsu; K. A. Michalski; Min-Hua Ho

Mixed potential Green's functions for a circular waveguide filled with uniaxially anisotropic layered media

Mingchih Chen, Chung I.G. Hsu, K. A. Michalski, Min-Hua Ho

Graduate Institute of Communication Engineering

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

Abstract

In this paper, the mixed potential dyadic Green's functions for a uniform cross-section circular waveguides filled with multilayered uniaxially anisotropic dielectrics are constructed. These Green's functions are developed from the procedure proposed by Felsen and Marcuvitz who built their theory on a complete eigenfunction expansions method in conjunction with multilayer media analog transmission line model. The Shank's series is used to accelerate the computations of these derived Green's functions. Sample numerical results are presented.

Original language	English
Pages (from-to)	61-66
Number of pages	6
Journal	International Journal of Electrical Engineering
Volume	16
Issue number	1
Publication status	Published - 2009 Feb 1

All Science Journal Classification (ASJC) codes

Electrical and Electronic Engineering

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abstract = "In this paper, the mixed potential dyadic Green's functions for a uniform cross-section circular waveguides filled with multilayered uniaxially anisotropic dielectrics are constructed. These Green's functions are developed from the procedure proposed by Felsen and Marcuvitz who built their theory on a complete eigenfunction expansions method in conjunction with multilayer media analog transmission line model. The Shank's series is used to accelerate the computations of these derived Green's functions. Sample numerical results are presented.",

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N2 - In this paper, the mixed potential dyadic Green's functions for a uniform cross-section circular waveguides filled with multilayered uniaxially anisotropic dielectrics are constructed. These Green's functions are developed from the procedure proposed by Felsen and Marcuvitz who built their theory on a complete eigenfunction expansions method in conjunction with multilayer media analog transmission line model. The Shank's series is used to accelerate the computations of these derived Green's functions. Sample numerical results are presented.

AB - In this paper, the mixed potential dyadic Green's functions for a uniform cross-section circular waveguides filled with multilayered uniaxially anisotropic dielectrics are constructed. These Green's functions are developed from the procedure proposed by Felsen and Marcuvitz who built their theory on a complete eigenfunction expansions method in conjunction with multilayer media analog transmission line model. The Shank's series is used to accelerate the computations of these derived Green's functions. Sample numerical results are presented.

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