Title :
High-order adaptive time-domain solution of nonlinear coupled electromagnetic-thermal problems
Author :
Badics, Zsolt ; Ionescu, Bogdan ; Cendes, Zoltan J.
Author_Institution :
Ansoft Corp., Pittsburgh, PA, USA
fDate :
3/1/2004 12:00:00 AM
Abstract :
An adaptive time-integration algorithm is described for the solution of nonlinear one-way coupled electromagnetic-thermal problems. The thermal excitations are time-varying thermal loads or/and EM (electromagnetic) loss distributions due to dc or ac excitation sequences. The equations are discretized in time by an implicit Runge-Kutta one-step method. No Newton iteration is required in a time step; only one linear equation with multiple right hand sides has to be solved. High-order integration is achieved by incorporating the Jacobian into the time-integration formula. The thermal analysis of an induction hardening problem and an insulated gate bipolar transistor test module is presented to illustrate the efficiency of the algorithm.
Keywords :
Runge-Kutta methods; computational electromagnetics; electromagnetic coupling; finite element analysis; induction heating; insulated gate bipolar transistors; nonlinear systems; semiconductor device models; semiconductor device testing; thermal analysis; time-domain analysis; Jacobian formula; Newton iteration; ac excitation sequences; adaptive time-integration algorithm; coupled electromagnetic-thermal problems; dc excitation sequences; electromagnetic coupling; electromagnetic loss distributions; finite element methods; high-order adaptive time-domain solution; high-order integration; implicit Runge-Kutta one-step method; induction hardening problem; insulated gate bipolar transistor test; linear equation; nonlinear electromagnetic-thermal problems; nonlinear systems; thermal analysis; thermal excitations; time-integration formula; time-varying thermal loads; transient analysis; Boundary value problems; Computational modeling; Electromagnetic coupling; Electromagnetic heating; Finite element methods; Heat transfer; Nonlinear equations; Temperature distribution; Thermal loading; Time domain analysis;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2004.824733
