International audienceThe modeling of eddy currents in conductors is split into a sequence of progressive finite element subproblems. The source fields generated by the inductors alone are calculated at first via either the Biot- Savart law or finite elements. The associated reaction fields for each added conductive region, and in return for the source regions themselves when massive, are then calculated with finite element models, possibly with initial perfect conductor and/or impedance boundary conditions to be further corrected. The resulting subproblem method allows efficient solving of parameterized analyses thanks to a proper mesh for each subproblem and the reuse of previous solutions to be locally corrected
Progressive refinements of inductors are done with a subproblem method, from their wire or filament ...
Purpose – This paper seeks to develop a sub-domain perturbation technique to efficiently calculate s...
International audienceProgressive refinements of inductors are done with a subproblem method, from t...
peer reviewedThe modeling of inductors is split into a sequence of progressive finite element subpro...
peer reviewedMagnetodynamic models are split into a sequence of progressive finite element subproble...
International audienceModel refinements of transformers are performed via a subproblem finite elemen...
Progressive refinements of the current sources in magnetic vector potential finite-element (FE) form...
International audienceProgressive refinements of the current sources in magnetic vector potential fi...
A finite element subproblem method is developed to correct the inaccuracies proper to perfect conduc...
Skin and proximity effects are calculated in both active and passive conductors via a subproblem fin...
Analyses of magnetic circuits with position changes of both massive and stranded conductors are perf...
International audiencePurposeThis paper aims to develop a methodology for progressive finite element...
Purpose - This paper seeks to develop a sub-domain perturbation technique to efficiently calculate s...
Nos remerciements à IEEE pour l'autorisation de mise à disposition du papier complet. © IEEE Copyrig...
Progressive refinements of inductors are done with a subproblem method, from their wire or filament ...
Purpose – This paper seeks to develop a sub-domain perturbation technique to efficiently calculate s...
International audienceProgressive refinements of inductors are done with a subproblem method, from t...
peer reviewedThe modeling of inductors is split into a sequence of progressive finite element subpro...
peer reviewedMagnetodynamic models are split into a sequence of progressive finite element subproble...
International audienceModel refinements of transformers are performed via a subproblem finite elemen...
Progressive refinements of the current sources in magnetic vector potential finite-element (FE) form...
International audienceProgressive refinements of the current sources in magnetic vector potential fi...
A finite element subproblem method is developed to correct the inaccuracies proper to perfect conduc...
Skin and proximity effects are calculated in both active and passive conductors via a subproblem fin...
Analyses of magnetic circuits with position changes of both massive and stranded conductors are perf...
International audiencePurposeThis paper aims to develop a methodology for progressive finite element...
Purpose - This paper seeks to develop a sub-domain perturbation technique to efficiently calculate s...
Nos remerciements à IEEE pour l'autorisation de mise à disposition du papier complet. © IEEE Copyrig...
Progressive refinements of inductors are done with a subproblem method, from their wire or filament ...
Purpose – This paper seeks to develop a sub-domain perturbation technique to efficiently calculate s...
International audienceProgressive refinements of inductors are done with a subproblem method, from t...