References

1. Charles W. Steele, Numerical computation of electric and magnetic fields.Van Nostrand Reinhold, New York, 1987
2. J. Jin, The finite element method in electromagnetics.New York: Wiley, 1993
3. D. Meeker, Finite Element Method Magnetics, URL: http://members.aol.com/dcm3c
4. B.M. Jaworski, A.A. Detlaf, Physik griffbereit.Braunschweig: Vieweg, 1972
5. B. Streibl, "Dynamische mikromagnetische Simulation von mumag Standardproblemen", Diplomarbeit, TU Wien, 1998
6. WebElements, URL: http://www.webelements.com
7. T. Morisue, M. Fukumi, "3-D eddy current calculation using the magnetic vector potential." IEEE Trans. Magn., vol. 24, no. 1, pp.106-109, 1988

• International Compumag Society, URL: http://ics.ec-lyon.fr/
• Testing Electromagnetic Analysis Methods (T.E.A.M.),
  URL: http://ics.ec-lyon.fr/team.html
• R. Albanese, G. Rubinacci, "Solution of three dimensional eddy current problems by integral and differential methods." IEEE Trans. Magn., Vol. 24, No. 1, January 1988, pp. 98-101.
• O. Biro, "Use of a two-component vector potential for 3-D eddy current calculations." IEEE Trans. Magn., Vol. 24, No. 1, January 1988, pp. 102-105.
• W. Renhart, H. Stögner, K. Preis, "Calculation of 3D eddy current problems by finite element method using either an electric or a magnetic vector potential." IEEE Trans. Magn., Vol. 24, No. 1, January 1988, pp. 122-125.
• T. Misaki and H. Tsuboi, "Techniques for boundary element analysis of three-dimensional eddy current distribution." IEEE Trans. Magn., Vol. 24, No. 1, January 1988, pp. 146-149.
• , "." IEEE Trans. Magn., Vol. 24, No. 1, January 1988, pp. 431-434.
• T.P.Theodoulidis, C.S.Antonopoulos, E.E.Kriezis, "Analytical Solution for the eddy current problem inside a conducting cylinder using the secont order magnetic vector potential." International Journal for Comput. and Math. in Electrical and Electronic Engineering, Vol. 14, No. 4, 1995, pp. 45-48.
• T. Nakata, N. Takahashi; K. Fujiwara, "Summary of results for benchmark problem 10 (steel plates around a coil)." The International Journal for Computation and Mathematics in Electrical and Electronic Engineering.vol.14, no.2-3; Sept. 1995; p.103-12.
  Abstract: Benchmark problem 10 of the TEAM workshop consists of steel plates around a coil (nonlinear transient eddy current problem). Eight computer codes are applied, and nine solutions are compared with each other and with the experimental results.
• T. Nakata, N. Takahashi; K. Fujiwara, "Summary of results for TEAM Workshop problem 13 (3-D nonlinear magnetostatic model). " The International Journal for Computation and Mathematics in Electrical and Electronic Engineering.vol.14, no.2-3; Sept. 1995; p.91-101.
  Abstract: Seven computer codes developed by five groups are applied to the benchmark problem 13 of the TEAM workshop which consists of steel plates around a coil (a nonlinear magnetostatic problem). The solutions are compared with each other and with experimental results.
• H. T. Yu, K. R. Shao, K. D. Zhou, J. D. Lavers, "H method for solving 3D eddy current problems." IEEE Trans. Magn., vol.31, no.6, pt.2; Nov. 1995; p.3518-20.
  Abstract: A novel finite element model, which uses magnetic field intensity H as a state variable in the whole solution region of 3D eddy current problems, is presented. A surface integral on the interface, which leads to asymmetric equations in discretization, is considered in this formulation. The formulation uses consistently linear edge elements and flux continuity is ensured by imposing Del .B=0 with the penalty method. Numerical results of the problem No. 3 of the Team Workshop are provided, showing the validity of the algorithm.
• D. Lavers, I. P. Boglaev, V. V. Sirotkin, "Domain decomposition technique for 2-D eddy current problem." IEEE CEFC '96. The Seventh Biennial IEEE Conference on Electromagnetic Field Computation. IEEE, New York, NY, USA; 1996; 498 pp. p.475.
  Abstract: Numerical solution of 2-D eddy current problem for an infinitely long conductive cylinder in a transverse oscillating field is considered. A domain decomposition algorithm suitable for parallelization is described. Numerical experiments are presented.
• Filtz, A. Nethe, "Some remarks on solving the problem of three-dimensional eddy currents in circular cylinders of finite length." Archiv für Elektrotechnik, vol.76, no.3; 1993; p.195-200.
  Abstract: The authors describe an analytical method to calculate three-dimensional eddy currents in a circular cylinder with finite dimensions. An examination of papers on this topic shows that some of them contain grave mistakes which are discussed in detail. The authors show that the disappearance of the normal component of the current density on the cylinder end faces is a necessary boundary condition but is, however, by no means sufficient. Moreover, in contrast to an infinitely long cylinder an additional TEM-field has to be taken into account. Finally, the solution method is practically applied to the example of a turbogenerator model and the results are compared with the values found in other references.

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