TY - GEN
T1 - Antenna modeling with the hybrid finite element - Boundary integral - Multilevel fast multipole - Uniform geometrical theory of diffraction method
AU - Tzoulis, A.
AU - Eibert, T. F.
PY - 2007
Y1 - 2007
N2 - In many antenna applications, the environment of the radiating system has a significant effect on the overall radiation of the antenna and should be taken into account in the simulations. The involved objects are often electrically very large, so that numerical techniques combining ray optical asymptotic methods are preferred to handle such configurations. In this contribution, simulation results of electromagnetic radiation problems including environment effects are presented, using the recently developed hybrid method, which combines the Uniform Geometrical Theory of Diffraction (UTD) with the Finite Element Boundary Integral (FEBI) technique and with the Multilevel Fast Multipole Method (MLFMM). Electrically large and simple flat objects in the neighborhood of antennas are treated with UTD, providing full electromagnetic coupling with composite metallic/dielectric arbitrarily shaped FEBI objects. Thereby, double diffracted high-frequency fields on pairs of straight metallic non-coplanar and skewed edges are taken into account using the hard and soft scalar diffraction coefficients of UTD. Also, near-field computations in the postprocessing stage are efficiently accelerated by MLFMM, where ray optical contributions due to the presence of electrically large objects are taken into account according to the hybridization of MLFMM with UTD.
AB - In many antenna applications, the environment of the radiating system has a significant effect on the overall radiation of the antenna and should be taken into account in the simulations. The involved objects are often electrically very large, so that numerical techniques combining ray optical asymptotic methods are preferred to handle such configurations. In this contribution, simulation results of electromagnetic radiation problems including environment effects are presented, using the recently developed hybrid method, which combines the Uniform Geometrical Theory of Diffraction (UTD) with the Finite Element Boundary Integral (FEBI) technique and with the Multilevel Fast Multipole Method (MLFMM). Electrically large and simple flat objects in the neighborhood of antennas are treated with UTD, providing full electromagnetic coupling with composite metallic/dielectric arbitrarily shaped FEBI objects. Thereby, double diffracted high-frequency fields on pairs of straight metallic non-coplanar and skewed edges are taken into account using the hard and soft scalar diffraction coefficients of UTD. Also, near-field computations in the postprocessing stage are efficiently accelerated by MLFMM, where ray optical contributions due to the presence of electrically large objects are taken into account according to the hybridization of MLFMM with UTD.
UR - http://www.scopus.com/inward/record.url?scp=47749106396&partnerID=8YFLogxK
U2 - 10.1109/INICA.2007.4353939
DO - 10.1109/INICA.2007.4353939
M3 - Conference contribution
AN - SCOPUS:47749106396
SN - 9783000216435
T3 - INICA 2007 International Conference on Antennas - Proceedings
SP - 91
EP - 95
BT - INICA 2007 International Conference on Antennas - Proceedings
T2 - 2nd International ITG Conference on Antennas, INICA 2007
Y2 - 28 March 2007 through 30 March 2007
ER -