Title :
Inductance computation by incremental finite element analysis
Author :
Gyimesi, Miklos ; Ostergaard, Dale
Author_Institution :
ANSYS Inc. Southpointe, Canonsburg, PA, USA
fDate :
5/1/1999 12:00:00 AM
Abstract :
The paper introduces the enhanced incremental energy method (EIEM) for the accurate and efficient computation of nonlinear differential inductance coefficients. The EIEM has the following advantages: (i) only one incremental analysis is required for any coefficient, self or mutual; (ii) first derivative evaluation; (iii) the current increment may be large; (iv) there is no need to evaluate the nonlinear magnetic energy, instead, an "incremental energy" is calculated according to a simple expression; (v) only load vectors should be computed, the stiffness matrix can be saved; (vi) if a direct solver is applied, additional matrix factorization is avoided. These advantages provide improved accuracy and computational efficiency. The paper outlines the new EIEM and illustrates it the example of a transformer
Keywords :
finite element analysis; inductance; magnetic fields; magnetic flux; transformers; coil; current increment; direct solver; enhanced incremental energy method; incremental finite element analysis; inductance computation; load vectors; magnetic analysis; magnetic flux; nonlinear differential inductance coefficients; transformer; Circuits; Coils; Couplings; Finite element methods; Geometry; Inductance; Integral equations; Interpolation; Magnetic analysis; Magnetic flux;
Journal_Title :
Magnetics, IEEE Transactions on
