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Analysis of HTS circular patch antennas including radome effects

Published online by Cambridge University Press:  10 April 2018

Sami Bedra*
Affiliation:
Department of Industrial Engineering, University of Khenchela, Khenchela 40004, Algeria
Randa Bedra
Affiliation:
Department of Electronics, University of Batna 2, Batna 05000, Algeria
Siham Benkouda
Affiliation:
Department of Electronics, University of Frères Mentouri-Constantine 1, Constantine 25000, Algeria
Tarek Fortaki
Affiliation:
Department of Industrial Engineering, University of Khenchela, Khenchela 40004, Algeria
*
Author for correspondence: Sami Bedra, E-mail: [email protected]

Abstract

In this paper, the resonant frequencies, quality factors and bandwidths of high Tc superconducting circular microstrip patches in the presence of a dielectric superstrate loading have been studied using Galerkin testing procedure in the Hankel transform domain. The exact Green's function of the grounded dielectric slab is used to derive an electric field integral equation for the unknown current distribution on the circular disc. Thus, surface waves, as well as space wave radiation, are included in the formulation. London's equations and the two-fluid model of Gorter and Casimir are used in the calculation of the complex surface impedance of the superconducting circular disc. Galerkin testing is used in the resolution of the electric field integral equation. Two solutions using two different basis sets to expand the unknown disk currents are developed. The first set of basis functions used is the complete set of transverse magnetic and transverse electric modes of a cylindrical cavity with magnetic side walls. The second set of basis functions used employ Chebyshev polynomials and enforce the current edge condition. The computed values for a wide range of variations of superstrate thickness and dielectric constant are compared with different theoretical and experimental values available in the open literature, showing close agreement. Results are showing that the superstrate parameters should always be kept into account in the design stage of the superconducting microstrip resonators.

Type
Research Papers
Copyright
Copyright © Cambridge University Press and the European Microwave Association 2018 

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References

1.Ansari, J, Singh, P and Yadav, NP (2009) Analysis of wideband multilayer patch antenna with two parasitic elements. Microwave and Optical Technology Letters 51, 13971401.Google Scholar
2.Mbinack, C, Tonye, E and Bajon, D (2015) Microstrip-line theory and experimental study for the characterization of the inset-fed rectangular microstrip-patch antenna impedance. Microwave and Optical Technology Letters 57, 514518.Google Scholar
3.Guney, K and Kurt, E (2016) Effective side length formula for resonant frequency of equilateral triangular microstrip antenna. International Journal of Electronics 103, 261268.Google Scholar
4.Razi, ZM, Rezaei, P and Valizade, A (2015) A novel design of Fabry–Perot antenna using metamaterial superstrate for gain and bandwidth enhancement. AEU-International Journal of Electronics and Communications 69, 15251532.Google Scholar
5.Biswas, M and Mandal, A (2015) Experimental and theoretical investigation of resonance and radiation characteristics of superstrate loaded rectangular patch antenna. Microwave and Optical Technology Letters 57, 791799.Google Scholar
6.Attia, H, Yousefi, L and Ramahi, OM (2011) Analytical model for calculating the radiation field of microstrip antennas with artificial magnetic superstrates: theory and experiment. IEEE Transactions on Antennas and Propagation 59, 14381445.Google Scholar
7.Bedra, S and Fortaki, T (2015) Hankel transform domain analysis of covered circular microstrip patch printed on an anisotropic dielectric layer. Journal of Computational Electronics 14, 747753.Google Scholar
8.Zebiri, C, Lashab, M and Benabdelaziz, F (2013) Asymmetrical effects of bi-anisotropic substrate-superstrate sandwich structure on patch resonator. Progress in Electromagnetics Research B 49, 319337.Google Scholar
9.Klein, N (2002) High-frequency applications of high-temperature superconductor thin films. Reports on Progress in Physics 65, 1387.Google Scholar
10.Benmeddour, F, Dumond, C, Benabdelaziz, F and Bouttout, F (2010) Improving the performances of a high TC superconducting circular microstrip antenna with multilayered configuration and anisotropic dielectrics. Progress in Electromagnetics Research 18, 169183.Google Scholar
11.Bouraiou, A, Benkouda, S and Fortaki, T (2016) A rigorous full-wave analysis of high TC superconducting circular disc microstrip antenna. 8th International Conference on Modelling, Identification and Control (ICMIC), Algiers, pp. 719724.Google Scholar
12.Bedra, S and Fortaki, T (2016) High-Tc superconducting rectangular microstrip patch covered with a dielectric layer. Physica C: Superconductivity and its Applications 524, 3136.Google Scholar
13.Fortaki, T, Khedrouche, D, Bouttout, F and Benghalia, F (2005) Vector Hankel transform analysis of a tunable circular microstrip patch. International Journal for Numerical Methods in Biomedical Engineering 21, 219231.Google Scholar
14.Kumar, R and Malathi, P (2011) Experimental investigation of resonant frequency of multilayered rectangular and circular microstrip antennas. Microwave and Optical Technology Letters 53, 352356.Google Scholar
15.Losada, V, Boix, RR and Horno, M (2000) Resonant modes of circular microstrip patches over ground planes with circular apertures in multilayered substrates containing anisotropic and ferrite materials. IEEE Transactions on Microwave Theory and Techniques 48, 17561762.Google Scholar
16.Richard, MA, Bhasin, KB and Claspy, PC (1993) Superconducting microstrip antennas: an experimental comparison of two feeding methods. IEEE Transactions on Antennas and Propagation 41, 967974.Google Scholar