Analysis of the parameters of a lossy coaxial cable for cable fault location

This paper presents an estimation of the per-unit-length parameters of a lossy cable. A RLGC lumped element model for the lossy transmission line parameters of a coaxial cable including frequency dependent filtering effect is used in this study to evaluate reflectometry responses of the cable system...

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Hauptverfasser:	Qinghai Shi, Troltzsch, U, Kanoun, O
Format:	Tagungsbericht
Sprache:	eng
Schlagworte:	branched cable networks cable fault location and detection Coaxial cables Impedance impedance spectroscopy lossy coaxial cable Mathematical model Power cables Time domain analysis time domain reflectometry Transmission line measurements transmission line modeling
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creator	Qinghai Shi Troltzsch, U Kanoun, O
description	This paper presents an estimation of the per-unit-length parameters of a lossy cable. A RLGC lumped element model for the lossy transmission line parameters of a coaxial cable including frequency dependent filtering effect is used in this study to evaluate reflectometry responses of the cable systems. The simulated results of this model are compared with the measured results of a coaxial cable using impedance spectroscopy to show the accuracy in frequency domain. This lossy transmission line model then is solved in the time domain to accurately locate the faults. The simulated results are compared with the measured results using time domain reflectometry. Finally this model is used to simulate branched cable networks.
doi_str_mv	10.1109/SSD.2011.5767393
format	Conference Proceeding
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A RLGC lumped element model for the lossy transmission line parameters of a coaxial cable including frequency dependent filtering effect is used in this study to evaluate reflectometry responses of the cable systems. The simulated results of this model are compared with the measured results of a coaxial cable using impedance spectroscopy to show the accuracy in frequency domain. This lossy transmission line model then is solved in the time domain to accurately locate the faults. The simulated results are compared with the measured results using time domain reflectometry. Finally this model is used to simulate branched cable networks.</abstract><pub>IEEE</pub><doi>10.1109/SSD.2011.5767393</doi><tpages>6</tpages></addata></record>
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subjects	branched cable networks cable fault location and detection Coaxial cables Impedance impedance spectroscopy lossy coaxial cable Mathematical model Power cables Time domain analysis time domain reflectometry Transmission line measurements transmission line modeling
title	Analysis of the parameters of a lossy coaxial cable for cable fault location
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