Airship SAR System for Precision Microwave Measurement of Ground Targets

Wang Yan-fei; Xu Xiang-hui; Liu Chang; Zhou Chang-yi

doi:10.3724/SP.J.1146.2009.00500

Volume 32 Issue 1

Aug. 2010

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Article Navigation > Journal of Electronics & Information Technology > 2010 > 32(1): 28-31

Wang Yan-fei, Xu Xiang-hui, Liu Chang, Zhou Chang-yi. Airship SAR System for Precision Microwave Measurement of Ground Targets[J]. Journal of Electronics & Information Technology, 2010, 32(1): 28-31. doi: 10.3724/SP.J.1146.2009.00500

Citation:

Wang Yan-fei, Xu Xiang-hui, Liu Chang, Zhou Chang-yi. Airship SAR System for Precision Microwave Measurement of Ground Targets[J]. Journal of Electronics & Information Technology, 2010, 32(1): 28-31. doi: 10.3724/SP.J.1146.2009.00500

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Airship SAR System for Precision Microwave Measurement of Ground Targets

doi: 10.3724/SP.J.1146.2009.00500

Received Date: 2009-04-08
Rev Recd Date: 2009-11-11
Publish Date: 2010-01-19

Abstract

Abstract

This paper describes an airship borne SAR developed at the Institute of Electronics, Chinese Academy of Sciences. The airship borne SAR system features high resolution imaging capability of ground targets in the limited area. The function and architecture of the SAR are described in detail. An effective motion compensation method integrated IMU, DGPS and autofocus algorithm is proposed for the low speed airship platform. High quality images formed in the flight tests demonstrate the precision microwave imaging and measurement capacity provided by the airship borne SAR.

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References

[1] Ulaby F T, Moore R K, and Fung A K. Microwave RemoteSensing: Active and Passive, Vol. I, Artech House, Norwood,1981. [2] Poulter M and Tee H S. Remote minefield detection system(REMIDS): A UK programme for airborne minefielddetection. 2001. IGARSS apos;01. IEEE 2001 InternationalGeoscience and Remote Sensing Symposium, Sydney,Australia, 2001: Vol.1: 243-245. [3] Gasson J, Hughes D, Poulter M, and Crisp G. Developmentof an ultra wide-band SAR for minefield detection. 1999.IGARSS apos;99 Proceedings. IEEE 1999 InternationalGeoscience and Remote Sensing Symposium, Hamburg,Germany, 1999, Vol.5: 2474-2476. [4] Buckreuss S. Motion compensation for airborne SAR basedon inertial data, RDM and GPS[J].1994. Geoscience andRemote Sensing Symposium. IGARSS '94. Pasadena,California, United States.1994, Vol.4:1971-1973 [5] Prats P, Macedo K A, Reigber A, Scheiber R, and MallorquiJ J. Comparison of topography and aperture-dependentmotion compensation algorithms for airborne SAR[J].IEEEGeoscience and Remote Sensing Letters.2007, 4(3):349-353 [6] Wahl D E, Eichel P H, Ghiglia D C, and Jakowatz Jr V C.Phase gradient autofocusA robust tool for high resolutionSAR phase correction[J].IEEE Transactions on Aerospace andElectronics Systems.1994, 30(3):827-835 [7] De Macedo K A C, Scheiber R, and Moreira A. An autofocusapproach for residual motion errors with application toairborne repeat-pass SAR interferometry. IEEE InternationalGeoscience and Remote Sensing Symposium, IGARSS 2007,Barcelona, Spain, July 2007: 4886-4889. [8] Andres C, Keil T, Herrmann R, and Scheiber R. Amultiprocessing framework for SAR image processing.2007,IGARSS IEEE International Geoscience and RemoteSensing Symposium, Barcelona, Spain, 2007: 524-527. [9] Moreira A and Huang Yong-hong. Airborne SAR processingof highly squinted data using a chirp scaling approach withIntegrated motion Compensation[J].IEEE Transactions onGeoscience and Remote Sensing.1994, 32(5):1029-1040

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