DocumentCode
1410791
Title
VSAR: a high resolution radar system for ocean imaging
Author
Friedlander, Benjamin ; Porat, Boaz
Author_Institution
Dept. of Electr. & Comput. Eng., California Univ., Davis, CA, USA
Volume
34
Issue
3
fYear
1998
fDate
7/1/1998 12:00:00 AM
Firstpage
755
Lastpage
776
Abstract
The velocity synthetic aperture radar (VSAR) is a conceptual synthetic aperture radar (SAR)-based sensor system for high resolution ocean imaging. The VSAR utilizes data collected by a multielement SAR system, to extract information not only about the radar reflectivity of the observed area, but also about the radial velocity of the scatterers in each pixel. This is accomplished by making use of the phase information contained in multiple SAR images, and not just the magnitude information as in conventional SAR. Using this velocity information, the VSAR attempts to compensate for the velocity distortion inherent in conventional SAR and to reconstruct the ocean reflectivity. We present the basic theory of the VSAR system and its performance. We also provide an analysis of the VSAR imaging mechanism for a statistical model of the radar returns, designed to capture the effects of speckle and of resolution degradation due to the decorrelation of the radar returns
Keywords
airborne radar; oceanographic techniques; radar imaging; radar theory; remote sensing by radar; speckle; synthetic aperture radar; decorrelation; high resolution radar system; imaging mechanism; multielement SAR system; multiple SAR images; ocean imaging; phase information; post-DFT phase correction; radar reflectivity; radar returns; radial velocity; resolution degradation; scatterers; speckle effects; statistical model; stochastic analysis; velocity SAR; Data mining; High-resolution imaging; Image reconstruction; Image resolution; Oceans; Radar imaging; Radar scattering; Reflectivity; Sensor systems; Synthetic aperture radar;
fLanguage
English
Journal_Title
Aerospace and Electronic Systems, IEEE Transactions on
Publisher
ieee
ISSN
0018-9251
Type
jour
DOI
10.1109/7.705884
Filename
705884
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