Study on High Resolution Overlapped Subaperture Imaging Algorithm 

for High Squint Airborne SAR Processing

Li Yong; Zhu Dai-yin; Zhu Zhao-da

Volume 28 Issue 9

Sep. 2010

Turn off MathJax

Article Contents

Article Navigation > Journal of Electronics & Information Technology > 2006 > 28(9): 1577-1581

Li Yong, Zhu Dai-yin, Zhu Zhao-da. Study on High Resolution Overlapped Subaperture Imaging Algorithm for High Squint Airborne SAR Processing[J]. Journal of Electronics & Information Technology, 2006, 28(9): 1577-1581.

Citation:

Li Yong, Zhu Dai-yin, Zhu Zhao-da. Study on High Resolution Overlapped Subaperture Imaging Algorithm for High Squint Airborne SAR Processing[J]. Journal of Electronics & Information Technology, 2006, 28(9): 1577-1581.

Citation:

PDF( 365 KB)

Study on High Resolution Overlapped Subaperture Imaging Algorithm for High Squint Airborne SAR Processing

Received Date: 2004-12-27
Rev Recd Date: 2005-09-30
Publish Date: 2006-09-19

Abstract

Abstract

A high-resolution subaperture imaging algorithm incorporated with the correction of 2-D image geometric distortion and the compensation of spatially-variant phase error for high squint airborne synthetic aperture radar is presented. Each subaperture processing is based on linear range-Doppler algorithm. According to the basic theory of rotating-object imaging, a methodology is developed to realize the range and Doppler alignment of the corresponding scatterers in successive subimages by the geographical coordinate transforming and positioning, while the step transform technique based on SPECAN is employed to obtain the high-resolution image. The point-target simulations and live data processing results show the validity of the proposed approach.

FullText(HTML)

References(1)

References

Ausherman D A, Kozma A, Walker J L，et al.. Developments inRadar Imaging[J].IEEE Trans. on Aerospace rend ElectronicSystems.1984, 20(4):363-400[2]Munson D C, O'Brien J D, Jenkins W K. A tomographicformulation of spotlight-mode synthetic aperture radar. Proc.IEEE, 1983, 72(8): 917-925.[3]Raney R K, Runge H, Bamler R, et al.. Precision SAR processing using chirp scaling. IEEE Trans. on Geoscience rend RemoteSensing, 1994, 32(4): 786-799.[4]Cafforio C, Prati C, Rocca F. SAR data focusing using seismicmigration techniques[J].IEEE Trans. on Aerospace and Electronicsystems.1991, 27(2):194-207[5]Mittermayer J, Moreira A, Loffeld O. Spotlight SAR dataprocessing using the frequency scaling algorithm[J].IEEE Trans. onGeoscience and Remote Sensing.1999, 37(5):2198-2213[6]Sack M, Ito M R, Gumming I. Application of efficient linear FMmatched filtering algorithms to synthetic aperture radarprocessing.lEEPro.-F, 1985, 132(1):45-57.[7]Wu K H, Vant M R. Extensions to the step transform SARprocessing technique[J].IEEE Trans. on Aerospace and Electronicsysterm.1985, 21(3):338-344[8]Burns B L, Cordaro J T. A SAR image-formation algorithm thatcompensates for the spatially-variant effects of antenna motion.SPIE Conference Proceedings, Orlando, April 1994, 2230: 14-24.[9]Tsunoda S I, Pace F, Stence J, et al. Lynx a high-resolutionsynthetic aperture radar. IEEE Aerospace ConferenceProceedings, 2000, 5: 1-8.[10]Walker B, Sander C, Thompson M, et al.. A high-resolution,four-band SAR testbed with real-time image formation. IEEECeoscience and Remote Sensing Symposium, 1996, 3: 27-31.[11]Walk J L. Range-Doppler imaging of rotating objects[J].IEEE Transon Aerospace and Electronic Systems.1980, 16(1):23-52[12]朱岱寅，朱兆达，叶少华，等.机载SAR斜视区域成像研究，电子学报，2002. 30(9): 1387-1389.[13]Li Yong, Zhu Daiyin, Zhu Zhaoda. Geometric distortioncorrection in the subaperture processing for high squint airborneSAR imaging. IEEE Ceoscience and Remote SensingSymposium, 2004, 6: 3919-3922.[14]李勇，朱岱寅，朱兆达.机载合成孔径需达的高分辨率子孔径成像算法研究，电r与信息学报，2004. 26(SuppI): 91-96.

Relative Articles

Supplements(0)

Cited By

Proportional views