EMI Prediction of Multiple Radiators

Javad Meiguni; Wei Zhang; Morten Soerensen; Kaustav Ghosh; Ahmad Hosseinbeig; Abhishek Patnaik; David Johannes Pommerenke; Jacques Rollin; Jing Li; Qian Liu; Philippe Sochoux

doi:10.1109/TEMC.2019.2914240

EMI Prediction of Multiple Radiators

Javad Meiguni, Wei Zhang, Morten Soerensen, Kaustav Ghosh, Ahmad Hosseinbeig, Abhishek Patnaik, David Johannes Pommerenke, Jacques Rollin, Jing Li, Qian Liu, Philippe Sochoux

Research output: Contribution to journal › Article › peer-review

Abstract

A new method is developed to predict the scaling of the electromagnetic interference from a large system if similar subsystems are added. The method gives the predicted emission from multiple radiators as well as the level of certainty of the estimation. The proposed statistical approach is based on the phased array antenna theory and Monte Carlo simulation for a router with several line cards ( N ) and optical modules inserted. To validate the method, a large router with 498 optical modules with an unwanted radiation at 10.31 GHz was investigated in two different cases: the same frequency and different frequency per radiating subsystem. Several statistical experiments were performed for the proposed problem. The effect of phase and amplitude variations over the radiators is reported in this paper. The method is useful when it is not practical to assemble extraordinary amounts of identical hardware in a product installation. The results indicate the existence of a 10 log N (dB) tendency for the maximum electric field emission in a system radiating at the same frequency with random phase distribution over the radiators. For different frequency subsystems, the slope of the maximum electric field emission is lower than the 10 log N (dB) formula.

Original language	English
Article number	8716552
Pages (from-to)	415 - 424
Number of pages	10
Journal	IEEE Transactions on Electromagnetic Compatibility
Volume	62
Issue number	2
DOIs	https://doi.org/10.1109/TEMC.2019.2914240
Publication status	Published - Apr 2020
Externally published	Yes

Keywords

Electromagnetic emission
maximum electric-field prediction
Monte Carlo simulation (MCS)
optical router
statistical design of experiments (DOEs)
total radiated power (TRP)

ASJC Scopus subject areas

Condensed Matter Physics
Atomic and Molecular Physics, and Optics
Electrical and Electronic Engineering

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10.1109/TEMC.2019.2914240

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@article{16e44abcc9174d2f89ac5fe260683639,

title = "EMI Prediction of Multiple Radiators",

abstract = "A new method is developed to predict the scaling of the electromagnetic interference from a large system if similar subsystems are added. The method gives the predicted emission from multiple radiators as well as the level of certainty of the estimation. The proposed statistical approach is based on the phased array antenna theory and Monte Carlo simulation for a router with several line cards ( N ) and optical modules inserted. To validate the method, a large router with 498 optical modules with an unwanted radiation at 10.31 GHz was investigated in two different cases: the same frequency and different frequency per radiating subsystem. Several statistical experiments were performed for the proposed problem. The effect of phase and amplitude variations over the radiators is reported in this paper. The method is useful when it is not practical to assemble extraordinary amounts of identical hardware in a product installation. The results indicate the existence of a 10 log N (dB) tendency for the maximum electric field emission in a system radiating at the same frequency with random phase distribution over the radiators. For different frequency subsystems, the slope of the maximum electric field emission is lower than the 10 log N (dB) formula.",

keywords = "Electromagnetic emission, maximum electric-field prediction, Monte Carlo simulation (MCS), optical router, statistical design of experiments (DOEs), total radiated power (TRP)",

author = "Javad Meiguni and Wei Zhang and Morten Soerensen and Kaustav Ghosh and Ahmad Hosseinbeig and Abhishek Patnaik and Pommerenke, {David Johannes} and Jacques Rollin and Jing Li and Qian Liu and Philippe Sochoux",

year = "2020",

month = apr,

doi = "10.1109/TEMC.2019.2914240",

language = "English",

volume = "62",

pages = "415 -- 424",

journal = "IEEE Transactions on Electromagnetic Compatibility",

issn = "0018-9375",

publisher = "Institute of Electrical and Electronics Engineers",

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AU - Meiguni, Javad

AU - Zhang, Wei

AU - Soerensen, Morten

AU - Ghosh, Kaustav

AU - Hosseinbeig, Ahmad

AU - Patnaik, Abhishek

AU - Pommerenke, David Johannes

AU - Rollin, Jacques

AU - Li, Jing

AU - Liu, Qian

AU - Sochoux, Philippe

PY - 2020/4

Y1 - 2020/4

N2 - A new method is developed to predict the scaling of the electromagnetic interference from a large system if similar subsystems are added. The method gives the predicted emission from multiple radiators as well as the level of certainty of the estimation. The proposed statistical approach is based on the phased array antenna theory and Monte Carlo simulation for a router with several line cards ( N ) and optical modules inserted. To validate the method, a large router with 498 optical modules with an unwanted radiation at 10.31 GHz was investigated in two different cases: the same frequency and different frequency per radiating subsystem. Several statistical experiments were performed for the proposed problem. The effect of phase and amplitude variations over the radiators is reported in this paper. The method is useful when it is not practical to assemble extraordinary amounts of identical hardware in a product installation. The results indicate the existence of a 10 log N (dB) tendency for the maximum electric field emission in a system radiating at the same frequency with random phase distribution over the radiators. For different frequency subsystems, the slope of the maximum electric field emission is lower than the 10 log N (dB) formula.

AB - A new method is developed to predict the scaling of the electromagnetic interference from a large system if similar subsystems are added. The method gives the predicted emission from multiple radiators as well as the level of certainty of the estimation. The proposed statistical approach is based on the phased array antenna theory and Monte Carlo simulation for a router with several line cards ( N ) and optical modules inserted. To validate the method, a large router with 498 optical modules with an unwanted radiation at 10.31 GHz was investigated in two different cases: the same frequency and different frequency per radiating subsystem. Several statistical experiments were performed for the proposed problem. The effect of phase and amplitude variations over the radiators is reported in this paper. The method is useful when it is not practical to assemble extraordinary amounts of identical hardware in a product installation. The results indicate the existence of a 10 log N (dB) tendency for the maximum electric field emission in a system radiating at the same frequency with random phase distribution over the radiators. For different frequency subsystems, the slope of the maximum electric field emission is lower than the 10 log N (dB) formula.

KW - Electromagnetic emission

KW - maximum electric-field prediction

KW - Monte Carlo simulation (MCS)

KW - optical router

KW - statistical design of experiments (DOEs)

KW - total radiated power (TRP)

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EMI Prediction of Multiple Radiators

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Keywords

ASJC Scopus subject areas

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