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Journals & Magazines >IEEE Transactions on Microwav... >Volume: 53 Issue: 3

Evaluation of the input impedance of a top-loaded monopole in a parallel-plate waveguide by the MoM/Green's function method

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A. Valero-Nogueira; J.I. Herranz-Herruzo; E. Antonino-Daviu; M. Cabedo-Fabres
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Abstract:

An accurate modeling of a top-hat monopole transition in a parallel-plate waveguide is performed using the method of moments/Green's function method. The selection of the...Show More

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Abstract:

An accurate modeling of a top-hat monopole transition in a parallel-plate waveguide is performed using the method of moments/Green's function method. The selection of the appropriate source-field relationship to override divergence series is discussed in detail. Numerical results are given for the input impedance of a top-loaded coaxial transition. A mode-matching solution is used as a reference to validate the results.
Published in: IEEE Transactions on Microwave Theory and Techniques ( Volume: 53, Issue: 3, March 2005)
Page(s): 868 - 873
Date of Publication: 14 March 2005

ISSN Information:

DOI: 10.1109/TMTT.2004.842501
References is not available for this document.
Contents

I. Introduction

Coaxial probes are often used as transitions to rectangular or parallel-plate waveguides. Such transitions have been studied in great detail by numerous authors [1]–[7]. When the geometry is separable, there are basically two ways of facing the problem. The first way requires dividing the problem in a number of canonical regions, expanding the fields in terms of the solutions of the Helmholtz equation in these regions, and enforcing the tangential-field continuity at the boundaries between them. This technique is commonly known as mode matching and some good examples of application to the problem of our concern are discussed in [1]–[4]. The second approach entails the use of the specialized Green's functions of the sources present within the guide [7]. Conventionally, mode-matching solutions are adopted over specialized Green's functions. A number of reasons can be alleged for this preference. Firstly because, for separable geometries, field solutions may be more straightforward to formulate. Secondly, this type of methods can cope with a fairly large variety of geometries of practical interest, such as coaxial sleeves [4], top-hat loading [1], multilayer insulation [5], etc., and thirdly, due to the recognized accuracy and computational efficiency of these methods.

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