DocumentCode
1229668
Title
Focusing Spaceborne/Airborne Hybrid Bistatic SAR Data Using Wavenumber-Domain Algorithm
Author
Wang, Robert ; Loffeld, Otmar ; Nies, Holger ; Ender, Joachim H G
Author_Institution
Center for Sensorsystems, Univ. of Siegen, Siegen
Volume
47
Issue
7
fYear
2009
fDate
7/1/2009 12:00:00 AM
Firstpage
2275
Lastpage
2283
Abstract
This paper focuses on the bistatic synthetic aperture radar (SAR) data processing in a spaceborne/airborne hybrid bistatic configuration. Due to the extreme differences in platform velocities and slant ranges, the airborne system operates in the inverse sliding-spotlight mode, while the spaceborne system works in the sliding-spotlight mode to achieve a tradeoff between azimuth scene size and azimuth resolution. In this extreme bistatic configuration, our original bistatic formula shows a limitation of accurately describing the bistatic point-target reference spectrum, owing to the assumption of equal contributions of transmitter and receiver to the total Doppler spectrum. We extend our previous formula using the weighting operation where the weighting factor is the ratio of the azimuth time-bandwidth product (TBP) of the platform to the total azimuth TBP. In this paper, the bistatic-deformation and azimuth-dependent range-cell-migration terms were removed with phase multiplications performed blockwise in range-azimuth subsections. The remaining quasi-monostatic term shows the characteristic of the conventional monostatic SAR besides an additional azimuth-scaling term. For the monostatic characteristic, any precision monostatic SAR processing algorithms can handle. In this paper, we prefer the wavenumber-domain algorithm (also known as Omega-K), since it can accurately correct the range dependence of the range-azimuth coupling, as well as the azimuth-frequency dependence. For the azimuth-scaling term, an inverse scaled Fourier transformation is performed to correct it. Finally, a hybrid spaceborne/airborne simulation experiment is conducted to validate the proposed processing procedure.
Keywords
Fourier transforms; airborne radar; spaceborne radar; synthetic aperture radar; SAR data processing; azimuth time-bandwidth product; azimuth-dependent range-cell-migration terms; azimuth-frequency dependence; bistatic formula; bistatic point-target reference spectrum; bistatic synthetic aperture radar; bistatic-deformation; hybrid spaceborne/airborne simulation experiment; inverse scaled Fourier transformation; inverse sliding-spotlight mode; sliding-spotlight mode; spaceborne/airborne hybrid bistatic configuration; total Doppler spectrum; wavenumber-domain algorithm; weighting factor; Bistatic point-target reference spectrum (BPTRS); bistatic synthetic aperture radar (BiSAR); range cell migration (RCM); time-bandwidth product (TBP);
fLanguage
English
Journal_Title
Geoscience and Remote Sensing, IEEE Transactions on
Publisher
ieee
ISSN
0196-2892
Type
jour
DOI
10.1109/TGRS.2008.2010852
Filename
4812110
Link To Document