Your search keyword '"Vollaire, Christian"' showing total 8 results

1. Power Efficiency and EMI Attenuation Optimization in Filter Design.

Author

Ferber, Moises, Mrad, Roberto, Morel, Florent, Pillonnet, Gael, Vollaire, Christian, and Nagari, Angelo

Subjects

ELECTROMAGNETIC interference, WIRELESS communications, ELECTRIC circuits, ELECTRICAL engineering, ELECTRIC potential, ELECTRONIC circuits, COINCIDENCE circuits

Abstract

This paper presents a discrete conducted electromagnetic (EM) interference filter optimization procedure, based on a genetic algorithms. A macromodeling technique taking into account the load impedance, the source emissions and the filter parasitic components, including the filter layout, is used to obtain an accurate solution for the optimization process. The latter searches among supplier passive component databases and provides, for a given filter topology, an optimal set of components available on the market. This approach has been applied to a differential Class-D audio amplifier for validation. By considering the electromagnetic interference (EMI), the additional power losses introduced by the filter and the audio gain, two different optimization formulations have been tested. The first corresponds to maximizing the power efficiency of the system while respecting a determined level of EM emissions. The second corresponds to minimizing the EMI without exceeding a determined level of power loss. The optimized filters are built and measurements are carried out. The results show a remarkable power efficiency improvement and a significant EM emission reduction when compared to a reference filter. [ABSTRACT FROM AUTHOR]

Published

2018

2. Uncertainty Analysis of the Conducted Interferences in a DC-DC Converter

Author

Ferber de Vieira Lessa, Moises, Vollaire, Christian, Krähenbühl, Laurent, Vasconcelos, Joao, Ampère (AMPERE), École Centrale de Lyon (ECL), Université de Lyon-Université de Lyon-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Institut National des Sciences Appliquées de Lyon (INSA Lyon), Université de Lyon-Institut National des Sciences Appliquées (INSA)-Institut National des Sciences Appliquées (INSA)-Centre National de la Recherche Scientifique (CNRS)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Departamento de Engenharia Elétrica [Minas Gerais] (DEE - UFMG), Universidade Federal de Minas Gerais, LIA franco brésilien James Clerk Maxwell (CNRS-CNPq) (LIA817), ANR-10-VPTT-0013,E-CEM,Compatibilité électromagnétique des systèmes de puissance(2010), Ampère, Publications, and Véhicules pour les Transports Terrestres - Compatibilité électromagnétique des systèmes de puissance - - E-CEM2010 - ANR-10-VPTT-0013 - VTT - VALID

Subjects

[SPI.NRJ]Engineering Sciences [physics]/Electric power, Electromagnetic Compatibility, Power Electronics, Monte Carlo, Parametric Uncertainty, [SPI.NRJ] Engineering Sciences [physics]/Electric power, Probability Density Functions

Abstract

International audience; A new methodology to analyze systems in the time and frequency domain, containing large number of uncertain parameters, is presented. As an example, the conducted interferences of a DC-DC Converter with uncertainties in its component values is analyzed. The model has a large number of parameters, which are described by Probability Density Functions (PDF). The output considered is a standard measurement of conducted interferences and its PDF is rapidly determined, when compared to the Monte Carlo (MC) approach.

Published

2012

3. Modeling and Analysis of Conducted and Radiated Emissions Due to Common Mode Current of a Buck Converter.

Author

Laour, Mohammed, Tahmi, Redouane, and Vollaire, Christian

Subjects

DC-to-DC converters, RADIATION & the environment, CABLES, ELECTROMAGNETIC interference, FINITE difference time domain method

Abstract

This paper presents the study of conducted and radiated emissions due to common-mode (CM) currents flowing through the power cables of a DC–DC converter system. In order to predict the conducted electromagnetic interferences (EMI) emissions, a model of power converter system is presented. The finite-difference time-domain method (FDTD) is used for predicting the magnetic near field radiated by the power supply cable of a buck converter and that due to CM current flowing through the cable. The CM current resulting from the model is compared with the experimental ones and implemented in the FDTD algorithm as current source of disturbance. The comparison with experimental results shows the validity of the FDTD model over a wide frequency range. The goal of this study is to predict the level of conducted and radiated EMI emissions. Therefore, proposing and investigating a simple and effective filtering solution that allows to reduce the emissions located in the switching noise zone, the results show that the conducted and radiated emission levels can be reduced by as much as 30 dB when using this technique. [ABSTRACT FROM AUTHOR]

Published

2017

4. Overview on the Evolution of Near Magnetic Field Coupling Prediction Using Equivalent Multipole Spherical Harmonic Sources.

Author

Breard, Arnaud, Chadebec, Olivier N., Krahenbuhl, Laurent F., Sartori, Carlos A. F., Vollaire, Christian, Fabregue, Olivier, Li, Zhao, Muylaert, Rafael P. B., Tavernier, Francois, and Voyer, Damien

Subjects

NEAR-fields, CASCADE converters, ELECTROMAGNETIC fields, MAGNETIC coupling, DEGREES of freedom

Abstract

In the electromagnetic compatibility behavior of power electronic converters, parasitic magnetic couplings between components are one of the main causes of dysfunctions or poor filtering. These couplings may be either conducted or near-field interferences. To handle interaction problems, full knowledge of these magnetic couplings is essential. This paper is an overview of the work on near magnetic field interference undertaken in the last 15 years by the International Maxwell Laboratory. This paper details a predictive method that accurately and efficiently calculates near magnetic field coupling between two sources. The method uses near-field multipolar expansion in spherical harmonics of electromagnetic sources to determine close magnetic coupling between two sources from their equivalent models. This paper also shows how theoretical developments of large loop antennas have evolved from the van Veen antenna, a model with only two degrees of freedom, to a more complex model in terms of degrees, order, and types of harmonics. In parallel, it describes developments in the measurement method that provides input to the theoretical model. To illustrate how the research has evolved, we discuss coupling between two complex sources to assess the accuracy of this predictive method. [ABSTRACT FROM PUBLISHER]

Published

2017

5. Metamodel of Power Electronic Converters Using Learning SVR Method Coupling With Wavelet Compression.

Author

Breard, Arnaud, Moulla, Redha, and Vollaire, Christian

Subjects

POWER electronics, CONVERTERS (Electronics), ELECTROMAGNETIC compatibility, MATHEMATICAL models, WAVELET transforms, INTEGRATED circuits

Abstract

This paper deals with a new method of metamodel construction for electromagnetic compatibility (EMC) simulation of power electronic converters. The proposed method uses a compressed wavelet coefficients vector of a time-domain signal and a learning method [support vector regression (SVR)]. This can be applied for a black box approach of modeling of complex systems such as power converters. This allows the study of EMC behavior, the impact of the uncertainties and their propagations inside the model or the design of EMC filters. [ABSTRACT FROM PUBLISHER]

Published

2016

6. Predicting the Impact of Magnetic Components Used for EMI Suppression on the Base-Band of a Power Amplifier.

Author

Mrad, Roberto, Pillonnet, Gaël, Morel, Florent, Vollaire, Christian, and Nagari, Angelo

Subjects

POWER amplifiers, ELECTROMAGNETISM, POWER electronics, ELECTROMAGNETIC compatibility, MAGNETIC materials, NONLINEAR analysis

Abstract

Class-D audio amplifiers are switching circuits that produce serious Electromagnetic (EM) emissions and disturb the surrounding electronics. In order to reduce these emissions, electromagnetic compatibility (EMC) filters with ferrite beads are used. However, ferrite beads contain magnetic materials that have a nonlinear behavior. Thus, they have an unfavorable impact on the system audio quality. The common ferrite bead models do not take into account nonlinear phenomena. Thus, to predict the impact on the signal quality, this paper models the ferrite bead using the Jiles-Atherton magnetic material theory. The presented model provides the designers with a tool to quantify the effect of EMC filters on the total harmonic distortion (THD) of audio amplifiers. The simulated and measured results show that the tested ferrite bead have a negative effect on the audio signal for a wide range of amplitudes and can increase the THD up to 37 dB. Finally, this paper highlights the impact of the magnetic material type on the audio distortion by simulating the same component with different types of materials. [ABSTRACT FROM AUTHOR]

Published

2015

7. Near Magnetic Field Coupling Prediction Using Equivalent Spherical Harmonic Sources.

Author

Van Hoang, Thi Quynh, Breard, Arnaud, and Vollaire, Christian

Subjects

MAGNETIC fields, MAGNETIC coupling, ELECTROMAGNETIC compatibility, POWER electronics, CASCADE converters, MAGNETIC sensors

Abstract

In the electromagnetic compatibility (EMC) behavior of power electronic converters, magnetic parasitic couplings between components are one of the main causes of dysfunctions or bad filtering (e.g., in EMC filter). These couplings could be as conducted or near-field interferences. In order to handle interaction problems, a complete knowledge of these magnetic couplings is then necessary. Our study is focused on near magnetic field's interferences. Indeed, the characterization of electromagnetic field in power electronics is still in active research. This paper details a predictive method that calculates accurately and efficiently the near magnetic field coupling between two sources. By using the near-field multipolar expansion in spherical harmonics of electromagnetic sources, the close magnetic coupling between two sources is determined from their equivalent model. It is shown that the increase in degree up to the fourth provides a more precise representation of the elements and thus a better accuracy of the near-field coupling prediction. Also, theoretical and experimental developments will be presented. The coupling between two complex sources will be considered to validate the predictive method. [ABSTRACT FROM AUTHOR]

Published

2014

8. Conducted EMI of DC–DC Converters With Parametric Uncertainties.

Author

Ferber, Moises, Vollaire, Christian, Krahenbuhl, Laurent, Coulomb, Jean-Louis, and Vasconcelos, Joao A.

Subjects

*ELECTROMAGNETIC interference, *ROTARY converters, *PARAMETRIC modeling, *DENSITY functionals, *CONFIDENCE intervals, *INTEGRATED circuits, *SENSITIVITY analysis

Abstract

This paper presents a new methodology to analyze the conducted interferences of power converters when its parameters are described by probability density functions rather than numerical values. The methodology is based on determining a set of surrogate models per frequency of the converter, which has less input and output variables, and shorter simulation time but similar precision for the evaluation of conducted emissions. This approach presents several advantages when compared to classical ones, such as Monte Carlo simulations and collocation methods. The results are presented as probability density functions and confidence intervals. [ABSTRACT FROM PUBLISHER]

Published

2013