A unified approach to the analysis of radial waveguides, dielectric resonators, and microstrip antennas on spherical multilayer structures

This paper presents a uniform procedure to analyze radial waveguides, dielectric resonators, dielectric resonator antennas, and microstrip antennas on spherical structures. It can be applied to any type of spherical multilayer closed and sector structures, which also include hemispherical structures...

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Bibliographic Details
Published in:IEEE transactions on microwave theory and techniques 2005-01, Vol.53 (1), p.404-409
Main Authors: Truong Vu Bang Giang, Thiel, M., Dreher, A.
Format: Article
Language:English
Subjects:
Applied sciences
Circuit properties
Dielectric resonator antennas
Dielectric substrates
Dielectrics
Dyadics
Electric, optical and optoelectronic circuits
Electronics
Equations
Equivalent circuits
Exact sciences and technology
Green's function methods
Green's functions
Kernel
Mathematical analysis
Metallization
Microstrip antennas
Microstrip resonators
Microwave circuits, microwave integrated circuits, microwave transmission lines, submillimeter wave circuits
Multilayers
Nonhomogeneous media
radial waveguides
Resonators
Spectra
spherical closed and sector structures
spherical resonators
Studies
Theoretical study. Circuits analysis and design
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Summary:This paper presents a uniform procedure to analyze radial waveguides, dielectric resonators, dielectric resonator antennas, and microstrip antennas on spherical structures. It can be applied to any type of spherical multilayer closed and sector structures, which also include hemispherical structures. The arbitrary layers may be airgaps or dielectric substrates with or without metallizations in the interfaces. The inner layer can be a metallic or dielectric core. The kernel of this approach is the derivation of the spectral- and space-domain dyadic Green's function of multilayer spherical structures by using an equivalent circuit and simple network analysis techniques. The relations between the spectral and space domains are derived using the vector-Legendre transformation. For the demonstration of the applicability of this approach, the dyadic Green's functions and the system equations of some commonly used spherical structures are presented, among which the system equation of a two-layer dielectric resonator is verified analytically with the literature. As an example, the resonant frequencies of a spherical resonator with two dielectric layers covering a metallic inner layer are calculated and verified with commercial software.
ISSN:0018-9480
1557-9670
DOI:10.1109/TMTT.2004.839945