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Journal of Microwave Power
and Electromagnetic Energy (JMPEE) |
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TITLE |
An Analysis of the
Finite-Difference Time-Domain Method for Modeling
the Microwave Heating of Dielectric Materials Within a Three-Dimensional
Cavity System [PDF] |
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AUTHORS |
H. Zhao
and 1996 31 4 199-215 |
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Abstract In this paper, an investigation
of the microwave heating of a lossy material
located inside a cavity by the Finite-Difference Time-Domain (FD-TD) method
is undertaken. The emphasis of this work focuses on the performance of the
FD-TD method when certain traditional assumptions are used within the
framework of the model. The limitations of these assumptions will be
deliberated and more accurate counterparts will be proposed and tested. In
particular, it will be shown that when only a single mode is assumed to exist
around the aperture between the waveguide and the cavity, spurious numerical
results arise. Further, the numerical
simulation indicates that the treatment of the interfacial boundary condition
located between free-space and the material becomes very important when
predicting the dissipated power distribution for a glossy dielectric
material. A new approximation of this interfacial boundary condition is
developed and a comparison between existing and new methodologies is made.
The treatment of singular field behavior near sharp
edges of the cavity is also examined and a study of the effect of using
different techniques to model regions where this condition arises is
presented. In order to validate the numerical simulation results, comparisons
against experimental data sets previously reported in the literature will be
made. In summary, the new techniques proposed in this research yield a
solution of high accuracy and demonstrate an increased flexibility for
simulating microwave systems. It will be shown that the FD-TD method
satisfies the important Maxwell equation field divergence condition
everywhere within the applicator. Key Words: Finite-difference
time-domain method, multimode cavity, input waveguide,
interface; boundary condition, edge behavior,
power density distribution. |
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