Efficient analysis of arbitrarily shaped inductive obstacles in rectangular waveguides using a surface integral equation formulation

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URI: http://hdl.handle.net/10317/661
ISSN: 0018-9480
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Author
Quesada Pereira, Fernando Daniel; Boria Esbert, Vicente E.; Pascual García, Juan; Álvarez Melcón , Alejandro; Gómez Tornero, José Luis; [et al.]
Research Group
Grupo de Electromagnetismo Aplicado a las Telecomunicaciones (GEAT)
Knowledge Area
Teoría de la Señal y las Comunicaciones
Sponsors
The authors would like to thank Alcatel Alenia Space (Madrid, Spain) for having provided data of the lossy dielectric loaded evanescent waveguide filter. They also wish to acknowledge the economic support of MEC, Spanish Government, through the coordinated Research Project TEC2004/04313-C02.
Publication date
2007-04-01
Publisher
IEEE Microwave Theory and Techniques Society
Bibliographic Citation
QUESADA PEREIRA, Fernando D., BORIA ESBERT, Vicente, PASCUAL GARCÍA, Juan, VIDAL PANTALEONI, Ana, ÁLVAREZ MELCÓN, Alejandro, GÓMEZ TORNERO, José Luis, GIMENO, Benito. Efficient analysis of arbitrarily shaped inductive obstacles in rectangular waveguides using a surface integral equation formulation. IEEE Transactions on Microwave Theory and Techniques, 55 (4): 715-721. ISSN 0018-9480
Keywords
Componentes de guía de ondas
Resonadores dieléctricos
Ecuaciones integrales
Funciones Green
Discontinuidades de ondas guía
Waveguide components
Dielectric resonators
Integral equation (IE)
Methods currently
Waveguide discontinuities
Moment methods
Green's functions
Métodos de momentos
Abstract
In this paper we propose to use the Surface Integral Equation technique for the analysis of arbitrarily shaped Hplane obstacles in rectangular waveguides, which can contain both metallic and/or dielectric objects. The Green functions are formulated using both spectral and spatial images series, whose convergence behavior has been improved through several acceleration techniques. Proceeding in this way, the convergence of the series is not attached to the employment of any particular basis or test function, thus consequently increasing the flexibility of the implemented technique. In order to test the accuracy and numerical efficiency of the proposed method, results for practical microwave circuits have been successfully compared with other numerical approaches.
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