Computer codes using the A-φ, A-φ-Ω, A*-0Ω-E, T-Ω, and E-Ω methods were developed. The effects of the volume ratio of the conductor region to the whole region, the shape of the conductor, and the ratio of the hole region to the conductor region on the computer storage, the CPU time, and the accuracy of the methods are investigated systematically using a few simple models. The effect of the conductivity of the conductor is also examined. The computer storage, the CPU time, and the error are found to increase with increase of the volume ratio of the conductor region to the whole region. The computer storage and the CPU time are affected by the shape of the conductor in some methods of analysis. The error of the A...
The effects of the leakage flux, eddy current path, and end coil of electric machines on the flux an...
This paper describes an experimental verification of a 3D eddy current analysis code based on T-meth...
In this paper, the problem of defining the optimal mesh density for accurate computation of 3-D eddy...
Computer codes using the A-φ, A-φ-Ω, A*-0Ω-E, T-Ω, and E-Ω methods wer...
Computer codes developed for the A-φ, A-φ-Ω, A-Ω, T-Ω, and E-Ω methods...
An improved T-Ω method that can analyze magnetic fields produced not only by eddy currents but ...
In order to evaluate the best type of element for the finite-element analysis of 3-D eddy currents, ...
The general characteristics of the most suitable model for 3-D nonlinear eddy-current analysis are e...
There are many approaches to 3D eddy current analysis. Typical methods for the eddy current analysis...
In order to evaluate the best type of element for the finite element analysis of 3-D eddy currents, ...
The success of two-dimensional eddy current models for modeling a variety of important nondestructiv...
In order to evaluate the most suitable method of analysis (A- phi or T- Omega method) and finite ele...
The computation of three-dimensional electromagnetic field distributions in the eddy-current testing...
In this paper, we present numerical models and experimental benchmarks for eddy current testing (ECT...
The boundary element method for computing 3-dimensional eddy current distributions is presented. Thi...
The effects of the leakage flux, eddy current path, and end coil of electric machines on the flux an...
This paper describes an experimental verification of a 3D eddy current analysis code based on T-meth...
In this paper, the problem of defining the optimal mesh density for accurate computation of 3-D eddy...
Computer codes using the A-φ, A-φ-Ω, A*-0Ω-E, T-Ω, and E-Ω methods wer...
Computer codes developed for the A-φ, A-φ-Ω, A-Ω, T-Ω, and E-Ω methods...
An improved T-Ω method that can analyze magnetic fields produced not only by eddy currents but ...
In order to evaluate the best type of element for the finite-element analysis of 3-D eddy currents, ...
The general characteristics of the most suitable model for 3-D nonlinear eddy-current analysis are e...
There are many approaches to 3D eddy current analysis. Typical methods for the eddy current analysis...
In order to evaluate the best type of element for the finite element analysis of 3-D eddy currents, ...
The success of two-dimensional eddy current models for modeling a variety of important nondestructiv...
In order to evaluate the most suitable method of analysis (A- phi or T- Omega method) and finite ele...
The computation of three-dimensional electromagnetic field distributions in the eddy-current testing...
In this paper, we present numerical models and experimental benchmarks for eddy current testing (ECT...
The boundary element method for computing 3-dimensional eddy current distributions is presented. Thi...
The effects of the leakage flux, eddy current path, and end coil of electric machines on the flux an...
This paper describes an experimental verification of a 3D eddy current analysis code based on T-meth...
In this paper, the problem of defining the optimal mesh density for accurate computation of 3-D eddy...