Combining the moment method with geometrical modelling by NURBS surfaces and Bezier patches

Author

Valle, L. ; Rivas, F. ; Catedra, M.F.

Author_Institution

Dept. de Electron., Cantabria Univ., Santander, Spain

Volume

42

Issue

3

fYear

1994

fDate

3/1/1994 12:00:00 AM

Firstpage

373

Lastpage

381

Abstract

Induced current distributions on conducting bodies of arbitrary shape modelled by NURBS (non uniform rational B-splines) surfaces are obtained by using a moment method approach to solve an electric field integral equation (EFIE). The NURBS surfaces are expanded in terms of Bezier patches by applying the Cox-de Boor transformation algorithm. This transformation is justified because Bezier patches are numerically more stable than NURBS surfaces. New basis functions have been developed which extend over pairs of Bezier patches. These basis functions can be considered as a generalization of “rooftop” functions. The method is applied to obtain RCS values of several objects modelled with NURBS surfaces. Good agreement with results from other methods is observed. The method is efficient and versatile because it uses geometrical modelling tools that are quite powerful

Keywords

computational geometry; current distribution; electric fields; electrical engineering computing; electromagnetic wave scattering; integral equations; numerical analysis; radar cross-sections; splines (mathematics); transforms; Bezier patches; Cox-de Boor transformation algorithm; EFIE; NURBS surfaces; basis functions; conducting bodies; electric field integral equation; geometrical modelling; induced current distributions; moment method; nonuniform rational B-splines; rooftop functions; Conductors; Current distribution; Integral equations; Moment methods; Polynomials; Shape; Solid modeling; Spline; Surface reconstruction; Surface topography;

fLanguage

English

Journal_Title

Antennas and Propagation, IEEE Transactions on

Publisher

ieee

ISSN

0018-926X

Type

jour

DOI

10.1109/8.280724

Filename

280724