DocumentCode
1553169
Title
Interferometric Circular SAR Method for Three-Dimensional Imaging
Author
Lin, Yun ; Hong, Wen ; Tan, Weixian ; Wang, Yanping ; Wu, YiRong
Author_Institution
Nat. Key Lab. of Microwave Imaging Technol., Chinese Acad. of Sci., Beijing, China
Volume
8
Issue
6
fYear
2011
Firstpage
1026
Lastpage
1030
Abstract
The aperture of 360° gives circular synthetic aperture radar (SAR) (CSAR) the capability to detect hidden target when its orientation is unknown. Subwavelength resolution can also be achieved when the target in the spotted area is observed under a complete circular aperture. Furthermore, the aspect angle diversity inherent to the circular trajectory makes possible a 3-D target reconstruction. However, the latter two potentials require certain target reflectivity homogeneity. For a highly directive scatterer, it has no resolving ability in the direction normal to the data collection plane. In this letter, a new interferometric CSAR method is presented to enhance the tomographic imaging capability for highly directive scatterers without sacrificing other scatterers´ resolutions. This method takes advantage of the coherence and the phase difference between a pair of 3-D SAR images formed from data collected at two separate circular apertures to eliminate targets that focused at a wrong elevation. In addition, it uses two different transmit frequencies to solve the problem of phase cycle ambiguities. Finally, simulation results validate this new approach.
Keywords
coherence; radar imaging; remote sensing by radar; synthetic aperture radar; circular apertures; coherence; interferometric CSAR method; phase cycle ambiguities; phase difference; three dimensional imaging; tomographic imaging capability; Apertures; Image reconstruction; Image resolution; Radar imaging; Tomography; 3-D imaging; Circular synthetic aperture radar (SAR) (CSAR); interferometric phase difference (IPD); interferometry;
fLanguage
English
Journal_Title
Geoscience and Remote Sensing Letters, IEEE
Publisher
ieee
ISSN
1545-598X
Type
jour
DOI
10.1109/LGRS.2011.2150732
Filename
5875868
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