DocumentCode
1167633
Title
Lumped-circuit models for nonlinear inductors exhibiting hysteresis loops
Author
Chua, Leon O. ; Stromsmoe, Keith A.
Volume
17
Issue
4
fYear
1970
fDate
11/1/1970 12:00:00 AM
Firstpage
564
Lastpage
574
Abstract
A new mathematical model of dynamic hysteresis loops is presented. The model is completely specified by two strictly monotonically increasing functions: a restoring function f(.) and a dissipation function g(.). Simple procedures are given for constructing these two functions so that the resulting model will simulate a given hysteresis loop exactly. The model is shown to exhibit many important hysteretic properties commonly observed in practice such as the presence of minor loops and an increase in area of the loop with frequency. In the case of an iron-core inductor, the mathematical model is shown to be equivalent to a lumped-circuit model, consisting of a nonlinear inductor in parallel with a nonlinear resistor. Extensive experimental investigations using different types of cores show remarkable agreement between results predicted by the model with those actually measured. The most serious limitation of this dynamic model is its inability to predict dc behaviors. For the class of switching circuits where dc solutions are important, a special dc lumped-circuit model is also presented.
Keywords
Hysteresis loops; Inductors; Mathematical models; Network models; Nonlinear network analysis & design; Circuit analysis computing; Dielectric materials; Ferrimagnetic materials; Frequency locked loops; Hysteresis; Inductors; Mathematical model; Partial differential equations; Predictive models; Testing;
fLanguage
English
Journal_Title
Circuit Theory, IEEE Transactions on
Publisher
ieee
ISSN
0018-9324
Type
jour
DOI
10.1109/TCT.1970.1083192
Filename
1083192
Link To Document