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Full wave analysis of a superconducting stripline with large width-to-separation ratio

This paper presents a full-wave analysis on the wave propagating in a superconducting stripline with a large width-to-separation ratio. A set of transcendental equation is derived, by matching the ratio of the tangential electric and magnetic fields, respectively, with the surface impedance of the s...

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Main Authors: Yeap K.H., Tham C.Y., Yeong K.C., Woo H.J., Chong K.H.
Other Authors: 36024759100
Format: Conference paper
Published: 2023
Subjects:
Attenuation constant
Phase velocity
Superconducting stripline
Surface impedance
Magnetic fields
Strip telecommunication lines
Analytical equations
Attenuation constants
Complex conductivity
Electric and magnetic fields
Full wave analysis
Propagation constant
Separation ratio
Superconducting strips
Surface impedances
Transcendental equations
Transmission line models
Superconductivity
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id my.uniten.dspace-30762
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spelling my.uniten.dspace-307622023-12-29T15:52:47Z Full wave analysis of a superconducting stripline with large width-to-separation ratio Yeap K.H. Tham C.Y. Yeong K.C. Woo H.J. Chong K.H. 36024759100 7006081245 36024779300 52464951900 36994481200 Attenuation constant Phase velocity Superconducting stripline Surface impedance Magnetic fields Phase velocity Strip telecommunication lines Analytical equations Attenuation constants Complex conductivity Electric and magnetic fields Full wave analysis Propagation constant Separation ratio Superconducting stripline Superconducting strips Surface impedances Transcendental equations Transmission line models Superconductivity This paper presents a full-wave analysis on the wave propagating in a superconducting stripline with a large width-to-separation ratio. A set of transcendental equation is derived, by matching the ratio of the tangential electric and magnetic fields, respectively, with the surface impedance of the strip. The propagation constant can be obtained by substituting the complex conductivity of the superconducting strip into the equation and numerically solving for the root. We have computed the attenuation constant and phase velocity using our method and compared with the analytical equation formulated by Matick using the general transmission line model, which is applied by Kautz in a superconducting stripline. The results for both methods agree exceedingly well. �2009 IEEE. Final 2023-12-29T07:52:47Z 2023-12-29T07:52:47Z 2009 Conference paper 10.1109/SCORED.2009.5442946 2-s2.0-77952659805 https://www.scopus.com/inward/record.uri?eid=2-s2.0-77952659805&doi=10.1109%2fSCORED.2009.5442946&partnerID=40&md5=cc7571ab122ad314413525b54ba2af4f https://irepository.uniten.edu.my/handle/123456789/30762 5442946 520 522 Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic Attenuation constant
Phase velocity
Superconducting stripline
Surface impedance
Magnetic fields
Phase velocity
Strip telecommunication lines
Analytical equations
Attenuation constants
Complex conductivity
Electric and magnetic fields
Full wave analysis
Propagation constant
Separation ratio
Superconducting stripline
Superconducting strips
Surface impedances
Transcendental equations
Transmission line models
Superconductivity
spellingShingle Attenuation constant
Phase velocity
Superconducting stripline
Surface impedance
Magnetic fields
Phase velocity
Strip telecommunication lines
Analytical equations
Attenuation constants
Complex conductivity
Electric and magnetic fields
Full wave analysis
Propagation constant
Separation ratio
Superconducting stripline
Superconducting strips
Surface impedances
Transcendental equations
Transmission line models
Superconductivity
Yeap K.H.
Tham C.Y.
Yeong K.C.
Woo H.J.
Chong K.H.
Full wave analysis of a superconducting stripline with large width-to-separation ratio
description This paper presents a full-wave analysis on the wave propagating in a superconducting stripline with a large width-to-separation ratio. A set of transcendental equation is derived, by matching the ratio of the tangential electric and magnetic fields, respectively, with the surface impedance of the strip. The propagation constant can be obtained by substituting the complex conductivity of the superconducting strip into the equation and numerically solving for the root. We have computed the attenuation constant and phase velocity using our method and compared with the analytical equation formulated by Matick using the general transmission line model, which is applied by Kautz in a superconducting stripline. The results for both methods agree exceedingly well. �2009 IEEE.
author2 36024759100
author_facet 36024759100
Yeap K.H.
Tham C.Y.
Yeong K.C.
Woo H.J.
Chong K.H.
format Conference paper
author Yeap K.H.
Tham C.Y.
Yeong K.C.
Woo H.J.
Chong K.H.
author_sort Yeap K.H.
title Full wave analysis of a superconducting stripline with large width-to-separation ratio
title_short Full wave analysis of a superconducting stripline with large width-to-separation ratio
title_full Full wave analysis of a superconducting stripline with large width-to-separation ratio
title_fullStr Full wave analysis of a superconducting stripline with large width-to-separation ratio
title_full_unstemmed Full wave analysis of a superconducting stripline with large width-to-separation ratio
title_sort full wave analysis of a superconducting stripline with large width-to-separation ratio
publishDate 2023
_version_ 1806424306734858240
score 13.188404

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