Progressive refinements of the current sources in magnetic vector potential finite-element (FE) formulations are done with a subproblem method. The sources are first considered through magnetomotive force or Biot–Savart models up to their volume FE models, from statics to dynamics. A novel way to define the source fields is proposed to lighten the computational efforts, through the conversion of the common volume sources to surface sources, without the need for any preresolution. Accuracy improvements can then be obtained for local currents and fields, and global quantities, i.e., inductances, resistances, Joule losses, and forces.CNPq PVE project 400452/2014-
Purpose – The purpose of this paper is to develop a sub-domain perturbation technique for refining m...
peer reviewedA sub-problem finite element method is developed for refining the inductor models in ma...
International audienceProgressive refinements of inductors are done with a subproblem method, from t...
International audienceProgressive refinements of the current sources in magnetic vector potential fi...
peer reviewedWide range progressive refinements of the inductors in magnetic vector potential finite...
peer reviewedProgressive refinements of the current sources for the magnetic vector potential finite...
peer reviewedMagnetodynamic models are split into a sequence of progressive finite element subproble...
peer reviewedThe modeling of inductors is split into a sequence of progressive finite element subpro...
International audienceThe modeling of eddy currents in conductors is split into a sequence of progre...
Progressive refinements of inductors are done with a subproblem method, from their wire or filament ...
A three-dimensional finite element (FE) MVP (magnetic vector potential) formulation for electromagne...
Abstract: Accurate magnetic flux distributions are calculated in magnetic circuits via a subproblem ...
International audiencePurposeThis paper aims to develop a methodology for progressive finite element...
Purpose: The purpose of this paper is to develop a sub-domain perturbation technique for refining ma...
The voltage measurements on the scalp and magnetic held measurements near the scalp can be used to c...
Purpose – The purpose of this paper is to develop a sub-domain perturbation technique for refining m...
peer reviewedA sub-problem finite element method is developed for refining the inductor models in ma...
International audienceProgressive refinements of inductors are done with a subproblem method, from t...
International audienceProgressive refinements of the current sources in magnetic vector potential fi...
peer reviewedWide range progressive refinements of the inductors in magnetic vector potential finite...
peer reviewedProgressive refinements of the current sources for the magnetic vector potential finite...
peer reviewedMagnetodynamic models are split into a sequence of progressive finite element subproble...
peer reviewedThe modeling of inductors is split into a sequence of progressive finite element subpro...
International audienceThe modeling of eddy currents in conductors is split into a sequence of progre...
Progressive refinements of inductors are done with a subproblem method, from their wire or filament ...
A three-dimensional finite element (FE) MVP (magnetic vector potential) formulation for electromagne...
Abstract: Accurate magnetic flux distributions are calculated in magnetic circuits via a subproblem ...
International audiencePurposeThis paper aims to develop a methodology for progressive finite element...
Purpose: The purpose of this paper is to develop a sub-domain perturbation technique for refining ma...
The voltage measurements on the scalp and magnetic held measurements near the scalp can be used to c...
Purpose – The purpose of this paper is to develop a sub-domain perturbation technique for refining m...
peer reviewedA sub-problem finite element method is developed for refining the inductor models in ma...
International audienceProgressive refinements of inductors are done with a subproblem method, from t...