volume | PIER Journals

2013-06-04

Simple, Taylor-Based Worst-Case Model for Field-to-Line Coupling

Sjoerd T. Op 't Land,

Mr. Sjoerd T. Op 't Land

Groupe ESEO, EMC Research Group

France

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Mohamed Ramdani,

Dr. Mohamed Ramdani

Ecole Super Elect Ouest & Telecommun Rennes

France

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Richard Perdriau,

Dr. Richard Perdriau

Ecole Super Elect Ouest & Telecommun Rennes

France

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Marco Leone,

Prof. Marco Leone

Otto von Guericke University of Magdeburg

Germany

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Mhamed Drissi

Prof. Mhamed Drissi

INSA, CNRS

France

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Progress In Electromagnetics Research, Vol. 140, 297-311, 2013

doi:10.2528/PIER13041207

Abstract

To obtain Electromagnetic Compatibility (EMC), we would like to study the worst-case electromagnetic eld-induced voltages at the ends of Printed Circuit Board (PCB) traces. With increasing frequencies, modelling these traces as electrically short no longer suffices. Accurate long line models exist, but are too complicated to easily induce the worst case. Therefore, we need a simple analytical model. In this article, we predict the terminal voltages of an electrically long, two-wire transmission line with characteristic loads in vacuum, excited by a linearly polarised plane wave. The model consists of a short line model (one Taylor cell) with an intuitive correction factor for long line effects: the modified Taylor cell. We then adapt the model to the case of a PCB trace above a ground plane, illuminated by a grazing, vertically polarised wave. For this case, we prove that end-fire illumination constitutes the worst case. We derive the worst-case envelope and try to falsify it by measurement in a Gigahertz Transverse Electromagnetic (GTEM) cell.

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Sjoerd T. Op 't Land, Mohamed Ramdani, Richard Perdriau, Marco Leone, and Mhamed Drissi, "Simple, Taylor-Based Worst-Case Model for Field-to-Line Coupling," Progress In Electromagnetics Research, Vol. 140, 297-311, 2013.
doi:10.2528/PIER13041207

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