DocumentCode
1245625
Title
ScanSAR processing using standard high precision SAR algorithms
Author
Bamler, Richard ; Eineder, Michael
Author_Institution
Remote Sensing Data Center, German Aerosp. Res. Establ., Oberpfaffenhofen, Germany
Volume
34
Issue
1
fYear
1996
fDate
1/1/1996 12:00:00 AM
Firstpage
212
Lastpage
218
Abstract
Processing ScanSAR or burst-mode SAR data by standard high precision algorithms (e.g., range/Doppler, wavenumber domain, or chirp scaling) is shown to be an interesting alternative to the normally used SPECAN (or deramp) algorithm. Long burst trains with zeroes inserted into the interburst intervals can be processed coherently. This kind of processing preserves the phase information of the data-an important aspect for ScanSAR interferometry. Due to the interference of the burst images the impulse response shows a periodic modulation that can be eliminated by a subsequent low-pass filtering of the detected image. This strategy allows an easy and safe adaptation of existing SAR processors to ScanSAR data if throughput is not an issue. The images are automatically consistent with regular SAR mode images both with respect to geometry and radiometry. The amount and diversity of the software for a multimode SAR processor are reduced. The impulse response and transfer functions of a burst-mode end-to-end system are derived. Special attention is drawn to the achievable image quality, the radiometric accuracy, and the effective number of looks. The scalloping effect known from burst-mode systems can be controlled by the spectral weighting of the processor transfer function. It is shown that the fact that the burst cycle period is in general not an integer multiple of the sampling grid distance does not complicate the algorithm. An image example using X-SAR data for simulation of a burst system is presented
Keywords
geophysical signal processing; geophysical techniques; radar imaging; remote sensing by radar; spaceborne radar; synthetic aperture radar; SAR; ScanSAR; ScanSAR interferometry; burst image; burst-mode SAR; geophysical measurement technique; high precision SAR algorithm; image processing; image quality; impulse response; land surface; multimode SAR processor; phase information; radar imaging; remote sensing; scalloping effect; spaceborne radar; synthetic aperture radar; terrain mapping; transfer function weighting; Chirp; Filtering; Geometry; Image quality; Interference elimination; Interferometry; Low pass filters; Radiometry; Throughput; Transfer functions;
fLanguage
English
Journal_Title
Geoscience and Remote Sensing, IEEE Transactions on
Publisher
ieee
ISSN
0196-2892
Type
jour
DOI
10.1109/36.481905
Filename
481905
Link To Document