Determination of Resonant Frequencies of Shielded Circular Ring Resonators with Thick Strip Conductors

Faton TEFIKU; Eikichi YAMASHITA

Determination of Resonant Frequencies of Shielded Circular Ring Resonators with Thick Strip Conductors

Faton TEFIKU, Eikichi YAMASHITA

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In this paper, boundary integral equations are derived from the Green's identity of the second kind in circular cylindrical coordinates, and are applied to determine the resonant frequencies of shielded circular ring and disk resonators. The integral equations are numerically solved by discretizating the integration path representing the air-dielectric interface and the surface of thick strip conductor. Because of the choice of the eigen-functions as weighted functions instead of Green's functions, the overall integral path length is shortened and computational time is reduced. Computational results on thick circular disk and ring resonators are compared with other available numerical results and experimental data.

Publication: IEICE TRANSACTIONS on Electronics Vol.E76-C No.4 pp.649-656

Publication Date: 1993/04/25

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Type of Manuscript: PAPER

Category: Electromagnetic Theory

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Faton TEFIKU, Eikichi YAMASHITA, "Determination of Resonant Frequencies of Shielded Circular Ring Resonators with Thick Strip Conductors" in IEICE TRANSACTIONS on Electronics, vol. E76-C, no. 4, pp. 649-656, April 1993, doi: .
Abstract: In this paper, boundary integral equations are derived from the Green's identity of the second kind in circular cylindrical coordinates, and are applied to determine the resonant frequencies of shielded circular ring and disk resonators. The integral equations are numerically solved by discretizating the integration path representing the air-dielectric interface and the surface of thick strip conductor. Because of the choice of the eigen-functions as weighted functions instead of Green's functions, the overall integral path length is shortened and computational time is reduced. Computational results on thick circular disk and ring resonators are compared with other available numerical results and experimental data.
URL: https://global.ieice.org/en_transactions/electronics/10.1587/e76-c_4_649/_p

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@ARTICLE{e76-c_4_649,
author={Faton TEFIKU, Eikichi YAMASHITA, },
journal={IEICE TRANSACTIONS on Electronics},
title={Determination of Resonant Frequencies of Shielded Circular Ring Resonators with Thick Strip Conductors},
year={1993},
volume={E76-C},
number={4},
pages={649-656},
abstract={In this paper, boundary integral equations are derived from the Green's identity of the second kind in circular cylindrical coordinates, and are applied to determine the resonant frequencies of shielded circular ring and disk resonators. The integral equations are numerically solved by discretizating the integration path representing the air-dielectric interface and the surface of thick strip conductor. Because of the choice of the eigen-functions as weighted functions instead of Green's functions, the overall integral path length is shortened and computational time is reduced. Computational results on thick circular disk and ring resonators are compared with other available numerical results and experimental data.},
keywords={},
doi={},
ISSN={},
month={April},}

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TY - JOUR
TI - Determination of Resonant Frequencies of Shielded Circular Ring Resonators with Thick Strip Conductors
T2 - IEICE TRANSACTIONS on Electronics
SP - 649
EP - 656
AU - Faton TEFIKU
AU - Eikichi YAMASHITA
PY - 1993
DO -
JO - IEICE TRANSACTIONS on Electronics
SN -
VL - E76-C
IS - 4
JA - IEICE TRANSACTIONS on Electronics
Y1 - April 1993
AB - In this paper, boundary integral equations are derived from the Green's identity of the second kind in circular cylindrical coordinates, and are applied to determine the resonant frequencies of shielded circular ring and disk resonators. The integral equations are numerically solved by discretizating the integration path representing the air-dielectric interface and the surface of thick strip conductor. Because of the choice of the eigen-functions as weighted functions instead of Green's functions, the overall integral path length is shortened and computational time is reduced. Computational results on thick circular disk and ring resonators are compared with other available numerical results and experimental data.
ER -