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Home > All Issues > PIER > Vol. 139 > pp. 671-687

Vol. 139

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2013-05-19

On-Road Magnetic Emissions Prediction of Electric Cars in Terms of Driving Dynamics Using Neural Networks

By Ahmed Wefky, Felipe Espinosa, Frank Leferink, Alfredo Gardel, and Robert Vogt-Ardatjew
Progress In Electromagnetics Research, Vol. 139, 671-687, 2013
doi:10.2528/PIER13040405

Abstract

This paper presents a novel artificial neural network (ANN) model estimating vehicle-level radiated magnetic emissions of an electric car as a function of the corresponding driving pattern. Real world electromagnetic interference (EMI) experiments have been realized in a semi-anechoic chamber using Renault Twizy. Time-domain electromagnetic interference (TDEMI) measurement techniques have been employed to record the radiated disturbances in the 150 kHz-30 MHz range. Interesting emissions have been found in the range 150 kHz-3.8 MHz approximately. The instantaneous vehicle speed and acceleration have been chosen to represent the vehicle operational modes. A comparative study of the prediction performance between different static and dynamic neural networks has been done. Results showed that a Multilayer Perceptron (MLP) model trained with extreme learning machines (ELM) has achieved the best prediction results. The proposed model has been used to estimate the radiated magnetic field levels of an urban trip carried out with a Think City electric car.

Citation


Ahmed Wefky, Felipe Espinosa, Frank Leferink, Alfredo Gardel, and Robert Vogt-Ardatjew, "On-Road Magnetic Emissions Prediction of Electric Cars in Terms of Driving Dynamics Using Neural Networks," Progress In Electromagnetics Research, Vol. 139, 671-687, 2013.
doi:10.2528/PIER13040405
http://test.jpier.org/PIER/pier.php?paper=13040405

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