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Influence of Dielectric Permittivity on Radiated Immunity in Real and Emulated Far-Fields

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Abstract:

This paper presents the impact of dielectric permittivity on radiated immunity of integrated circuits (ICs) in far-field, extending in detail a technique recently propose...Show More

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Abstract:

This paper presents the impact of dielectric permittivity on radiated immunity of integrated circuits (ICs) in far-field, extending in detail a technique recently proposed by the authors. To this end, the IEC 10 cm 10 cm square PCB with an equivalent patch as a rough approximation of an IC was considered in two different far-field conditions: (1) on a TEM cell aperture, and (2) in a far-field zone of a radiating antenna. In (2), the PCB was considered in horizontal and vertical orientations. The patch was then loaded by small solid piece of demetalized low-loss substrate of two different relative permittivities to examine the load presence influence on the radiated immunity. The wave impedance was used as the criterion. Results show that, in both cases, the load presence lowers the wave impedance, disregarding the PCB orientation with respect to the antenna in scenario (2). Moreover, no improvements due to the variation of the load permittivity value were observed in the E / H ratio distribution in a TEM cell similar to those obtained with the PCB oriented perpendicularly to the antenna in a real far-field zone. In the case where the PCB is parallel to the antenna, further improvement in the wave impedance was observed for a loaded PCB with a higher permittivity value.

Published in: 2019 International Symposium on Electromagnetic Compatibility - EMC EUROPE

Date of Conference: 02-06 September 2019

Date Added to IEEE Xplore: 17 October 2019

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ISSN Information:

DOI: 10.1109/EMCEurope.2019.8871964

Conference Location: Barcelona, Spain

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Contents

I. Introduction

Electromagnetic immunity (EMI) and electromagnetic compatibility (EMC) concepts, guidelines, and testing are an essential part of electronic systems design particularly with the fast increasing functionality and complexity of integrated circuits (ICs) [1]–[4]. EMC/EMI testing of electronic devices are performed according to standardized methodologies and regulations in precisely defined manner and environment (e.g. by international electrotechnical commission IEC [5]). This provides EMC test engineers an insight to lower the measurement uncertainty.

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References is not available for this document.

Influence of Dielectric Permittivity on Radiated Immunity in Real and Emulated Far-Fields

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Influence of Dielectric Permittivity on Radiated Immunity in Real and Emulated Far-Fields

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