A comparison of high-frequency scattering determined from PO fields enhanced with alternative ILDCs

Author

Shore, Robert A. ; Yaghjian, Arthur D.

Author_Institution

Antenna Technol. Branch (SNHA), Air Force Res. Lab., Hanscom AFB, MA, USA

Volume

52

Issue

1

fYear

2004

Firstpage

336

Lastpage

341

Abstract

In order to compare the accuracy of "source-based" and "diffraction-cone" incremental length diffraction coefficients (ILDCs), the high-frequency scattered far fields of a perfectly conducting circular disk are computed using physical optics (PO) enhanced with source-based and diffraction-cone ILDCs. For angles of incidence and scattering that are near grazing to the disk, the diffraction-cone ILDCs predict bistatic scattered far fields that are generally much greater than the exact far fields and that are much less accurate than the scattered far fields predicted by the source-based ILDCs. These results lead us to conclude that the source-based ILDCs are preferable for improving upon the accuracy of PO fields computed with general purpose computer codes.

Keywords

conducting bodies; electromagnetic wave scattering; physical optics; physical theory of diffraction; PO field; PTD; bistatic scattered far field; computer code; diffraction-cone incremental length diffraction coefficient; high-frequency scattered far field; incidence angle; perfectly conducting circular disk; physical optics; physical theory of diffraction; source-based incremental length diffraction coefficient; Electromagnetic scattering; Frequency; Optical computing; Optical diffraction; Optical scattering; Physical optics; Physical theory of diffraction; Physics computing; Radar scattering; Two dimensional displays;

fLanguage

English

Journal_Title

Antennas and Propagation, IEEE Transactions on

Publisher

ieee

ISSN

0018-926X

Type

jour

DOI

10.1109/TAP.2003.822452

Filename

1268334