Title :
Fixed-Point Harmonic-Balanced Method for DC-Biasing Hysteresis Analysis Using the Neural Network and Consuming Function
Author :
Zhao, Xiaojun ; Lu, Junwei ; Li, Lin ; Li, Huiqi ; Cheng, Zhiguang ; Lu, Tiebing
Author_Institution :
State Key Lab. of Alternate Electr. Power Syst. with Renewable Energy Sources, NCEPU, Baoding, China
Abstract :
The magnetic flux includes dc component and ac component in the square laminated core (SLC) under dc-biased magnetization. Hysteresis loops are distorted by dc component of magnetic field intensity in ferromagnetic core and exhibit asymmetrical and special nonlinearities. A neural network (NN) is trained on the basis of the experimental data to model hysteresis effects in the limb-yoke of the SLC. Hysteresis effects in the mitered-joint region are modeled by the consuming function combined with the dc-biasing magnetization curve. The global fixed-point magnetic reluctivity is properly determined in harmonic-balanced finite-element method (HBFEM) to ensure globally convergent computation. The magnetic field in the SLC under dc-biased magnetization is computed by the proposed method taking account of the dc-biasing hysteresis effects.
Keywords :
ferromagnetism; finite element analysis; harmonic analysis; magnetic flux; magnetic hysteresis; neural nets; consuming function; dc-biased magnetization; dc-biasing hysteresis analysis; dc-biasing hysteresis effects; ferromagnetic core; fixed-point harmonic-balanced method; global fixed-point magnetic reluctivity; harmonic-balanced finite-element method; hysteresis loops; magnetic Ωux; neural network; square laminated core; Artificial neural networks; Computational modeling; Magnetic cores; Magnetic domains; Magnetic hysteresis; Magnetization; Numerical models; Consuming function; dc-biasing hysteresis loops; fixed-point magnetic reluctivity; neural network;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2012.2195720
