The majority of structures of electromagnetic interest contain regions of non-metallic materials. The applicability of a numerical analysis tool is greatly reduced by an incapability or limitation in treating dielectric regions. The treatment of propagation medium properties is inherent in the formulation of field-based analysis tools. In the method of moments (MoM), dielectric regions require extended formulations and additional resources to model. A number of techniques for the optimum representation of these regions has been implemented in FEKO, a commercial MoM-based analysis tool. Each of the available techniques within the MoM have certain applications to which they are better suited. The optimum technique to use is often immediately evident to the inexperienced user. This paper briefly introduces each of the available techniques, and then demonstrate, by way of an example, how the choice of technique can influence the efficiency and accuracy of simulation.
[1]
Constantine A. Balanis,et al.
The finite-element method for modeling circuits and interconnects for electronic packaging
,
1997
.
[2]
D. M. Kokotoff,et al.
Rigorous analysis of probe-fed printed annular ring antennas
,
1999
.
[3]
U. Jakobus,et al.
Fast multipole solution of metallic and dielectric scattering problems in FEKO
,
2005,
IEEE/ACES International Conference on Wireless Communications and Applied Computational Electromagnetics, 2005..
[4]
Ulrich Jakobus,et al.
Human exposure assessment in the near field of GSM base-station antennas using a hybrid finite element/method of moments technique
,
2003,
IEEE Transactions on Biomedical Engineering.
[5]
J. Dyson.
The unidirectional equiangular spiral antenna
,
1959
.
[6]
Branko D. Popovic.
CAD of Wire Antennas and Related Radiating Structures
,
1991
.