Constrained Locally Corrected Nyström Method

Author

Hendijani, Nastaran ; Jin Cheng ; Adams, Robert J. ; Young, John C.

Author_Institution

Dept. of Electr. & Comput. Eng., Univ. of Kentucky, Lexington, KY, USA

Volume

63

Issue

7

fYear

2015

fDate

Jul-15

Firstpage

3111

Lastpage

3121

Abstract

A generalization of the locally corrected Nyström (LCN) discretization method is outlined wherein sparse transformations of the LCN system matrix are obtained via singular- value decompositions of local constraint matrices. The local constraint matrices are used to impose normal continuity of the currents across boundaries shared by mesh elements. Due to the method´s simplicity and flexibility, it is straightforward to develop high-order constrained LCN (CLCN) systems for different formulations and mesh element types. Numerical examples demonstrate the memory savings provided by the CLCN method and its improved accuracy when applied to geometries with sharp edges. It is also shown that the CLCN method maintains the high-order convergence of the LCN method, and it eliminates the need to include line charges in Nyström-based discretizations of formulations that involve the continuity equation.

Keywords

geometry; singular value decomposition; sparse matrices; CLCN system; LCN discretization method; constrained locally corrected Nyström method; geometry; high-order constrained LCN system; local constraint matrix; mesh element type; singular value decomposition; sparse transformation; Geometry; Impedance; Integral equations; Method of moments; Null space; Polynomials; Sparse matrices; Locally corrected Nystr??m (LCN) method; locally corrected Nyström method; moment method; numerical methods;

fLanguage

English

Journal_Title

Antennas and Propagation, IEEE Transactions on

Publisher

ieee

ISSN

0018-926X

Type

jour

DOI

10.1109/TAP.2015.2429732

Filename

7101841