Synthetic-aperture assessment of a dispersive surface

Author

Cheney, Margaret

Author_Institution

Dept. of Math. Sci., Rensselaer Polytech. Inst., Troy, NY, USA

fYear

2004

fDate

26-29 April 2004

Firstpage

181

Lastpage

195

Abstract

This paper considers synthetic aperture radar and other synthetic aperture imaging systems in which a backscattered wave is measured from a variety of locations. We focus on the case in which the ground-reflectivity function depends on frequency as well as on position. The paper begins with a (linearized) mathematical model, based on a scalar approximation to Maxwell´s equations, that includes the effects of the source waveform and the antenna beam pattern. The model can also accommodate other effects such as antenna steering and motion. For this mathematical model, we use the tools of microlocal analysis to develop and analyze a three-dimensional inversion algorithm that uses measurements made on a surface and determines the frequency-dependent ground reflectivity.

Keywords

Maxwell equations; antenna radiation patterns; backscatter; beam steering; dispersion (wave); electromagnetic wave reflection; electromagnetic wave scattering; radar antennas; radar imaging; synthetic aperture radar; Maxwell equations; antenna beam pattern; antenna motion; antenna steering; backscattered wave; dispersive surface; frequency-dependent ground reflectivity; ground-reflectivity function; linearized mathematical model; microlocal analysis; scalar approximation; source waveform effects; synthetic aperture imaging; synthetic aperture radar; three-dimensional inversion algorithm; Algorithm design and analysis; Dispersion; Frequency; Image analysis; Image reconstruction; Mathematical model; Radar antennas; Radar scattering; Reflectivity; Synthetic aperture radar;

fLanguage

English

Publisher

ieee

Conference_Titel

Radar Conference, 2004. Proceedings of the IEEE

Print_ISBN

0-7803-8234-X

Type

conf

DOI

10.1109/NRC.2004.1316419

Filename

1316419