Solution of the Electric Field Integral Equation Using Higher-Order Method of Moments

Wang Shao-gang; Guan Xin-pu; Wang Dang-wei; Ma Xing-yi; Su Yi

doi:10.3724/SP.J.1146.2006.00628

Volume 29 Issue 9

Jan. 2011

Turn off MathJax

Article Contents

Article Navigation > Journal of Electronics & Information Technology > 2007 > 29(9): 2265-2268

Wang Shao-gang, Guan Xin-pu, Wang Dang-wei, Ma Xing-yi, Su Yi. Solution of the Electric Field Integral Equation Using Higher-Order Method of Moments[J]. Journal of Electronics & Information Technology, 2007, 29(9): 2265-2268. doi: 10.3724/SP.J.1146.2006.00628

Citation:

Wang Shao-gang, Guan Xin-pu, Wang Dang-wei, Ma Xing-yi, Su Yi. Solution of the Electric Field Integral Equation Using Higher-Order Method of Moments[J]. Journal of Electronics & Information Technology, 2007, 29(9): 2265-2268. doi: 10.3724/SP.J.1146.2006.00628

Citation:

PDF( 270 KB)

Solution of the Electric Field Integral Equation Using Higher-Order Method of Moments

doi: 10.3724/SP.J.1146.2006.00628

Received Date: 2006-05-11
Rev Recd Date: 2006-09-29
Publish Date: 2007-09-19

Abstract

Abstract

The Higher-Order Method of Moments (HO-MoM) is frequently used to calculate the electromagnetic scattering, because of its high efficient and accurate. Several issues are analyzed in this paper for using the HO-MoM. Firstly, multi-dimension numerical integrations calculated again and again, a novel method is presented in this paper to translate integrations to the product of matrices. When the matrix from MoM filled, it is only needed to calculated the Greens function at integral nodes. That will reduces CPU time and increase the efficiency of HO-MoM. Secondly, the different methods, used to treat with singular integral or quasi-singular integral, is summarized and estimated.

FullText(HTML)

References(1)

References

Jrgensen E, Volakis J L, and Meincke P, et al.. Higher order hierarchical legendre basis functions for electromagnetic modeling[J].IEEE Trans. on Antennas Propagat.2004, 52(11):2985-2995[2]Djordjevic M and Notaro B M. Double higher order method of moments for surface integral equation modeling of metallic and dielectric antennas and scatters[J].IEEE Trans. on Antennas Propagat.2004, 52(8):2118-2129[3]Graglia R D, Wilton D R, and Peterson A F. Higher order interpolatory vector bases for computational electromagnetics[J].IEEE Trans. on Antennas Propagat.1997, 45(3):329-342[4]Canino L S, Ottusch J J, Stalzer M A, Visher J L, and Wandzura S. Numerical solution of the Helmholtz equation in 2D and 3D using a high-order Nystrm discritization[J].J. Comput. Phys.1998, 146:627-663[5]Notaro B M and Popovic B D. Optimized entire-domain moment-method analysis of 3D dielectric scatterers[J].Int. J. Numerical Modelling: Electronic Networks, Devices and Fields.1997, 10(5-6):177-1923.0.CO;2-B' target='_blank'>[6]Duffy M G. Quadrature over a pyramid or cube of integrands with a singularity at a vertex[J].SIAM Journal of Numerical Analysis.1982, 19:1260-1262[7]Seppo J, Matti T, and Pasi Y O. Singularity subtraction technique for high-order polynomial vector basis functions on planar triangles, IEEE Trans[J].on Antennas Propagat.2006, 54(6):42-49[8]Song J M and Chew W C. Moment method solution using parametric geometry[J].J. of Electromagnetic Wave and Appl.1995, 9(1/2):71-83[9]Kolundzija B M. On the inclusion of edge effects into surface vector basis functions. Proceedings of the 1998 AP-S Symposium, 1998: 282-285.

Relative Articles

Supplements(0)

Cited By

Proportional views