Ambiguity Function of Formation Flying Satellites SAR System

Li Li; Wang Yan-fei; Zhang Bing-chen

Volume 28 Issue 3

Sep. 2010

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Article Navigation > Journal of Electronics & Information Technology > 2006 > 28(3): 512-516

Li Li, Wang Yan-fei, Zhang Bing-chen. Ambiguity Function of Formation Flying Satellites SAR System[J]. Journal of Electronics & Information Technology, 2006, 28(3): 512-516.

Citation:

Li Li, Wang Yan-fei, Zhang Bing-chen. Ambiguity Function of Formation Flying Satellites SAR System[J]. Journal of Electronics & Information Technology, 2006, 28(3): 512-516.

Li Li, Wang Yan-fei, Zhang Bing-chen. Ambiguity Function of Formation Flying Satellites SAR System[J]. Journal of Electronics & Information Technology, 2006, 28(3): 512-516.

Citation:

Li Li, Wang Yan-fei, Zhang Bing-chen. Ambiguity Function of Formation Flying Satellites SAR System[J]. Journal of Electronics & Information Technology, 2006, 28(3): 512-516.

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Ambiguity Function of Formation Flying Satellites SAR System

Received Date: 2004-08-27
Rev Recd Date: 2004-12-28
Publish Date: 2006-03-19

Abstract

Abstract

In this paper, the ambiguity function is defined and derived from the character of formation flying satellites SAR. The results of the computer simulations demonstrate the efficacy of the proposed function. Further, by analyzing the ambiguity function, it is clear to demonstrate the influence of satellites configuration on the system resolution, which provides principle for the selection of satellites configuration.

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References

Martin M, Kilberg S. Techsat 21 and revolutionizing space missions using microsatellites, American Institute of Aeronautics and Astronautics 2001: SSC01-13. .[2]Kitts C, Twiggs R, Pranajaya F, et al.. Emerald: a low-cost spacecraft mission for validating formation flying technologies, Proc. 1999 IEEE Aerospace Conf., Aspen, CO, 1999: 217.226.[3]Massonnet D, Thouvenot E, Ramongassie S, et al.. A wheel of passive radar microsats for upgrading existing SAR projects. Proc. IEEE 2000 Int. Geoscience Remote Sensing Symposium., Honolulu, HI, 2000: 10001003. .[4]国家高技术航天领域专家委员会微小卫星技术组, 微小卫星编队飞行及应用论文集, 北京: 2000, 7.[5]Lush D C. Airborne radar analysis using the ambiguity function. Proc. 1990 IEEE International Radar Conference. New York, 1990: 600.605.[6]刘国岁, 顾红. 随机雷达信号的平均模糊函数. 电子学报, 1991, 19(5): 3540. .[7]Tsao T, Weiner D, Varshney P, et al.. Ambiguity function for a bistatic radar, IEEE Trans. on Aerospace and Electronic Systems, 1997, 33(3): 10411051. .[8]Goodman N A. Radar satellite constellations: SAR charac-terization and analysis, Proc. 2003 Advanced SARWorkshop, Montreal, Canada, June 2003: 1.10.[9]张澄波. 综合孔径雷达. 北京: 科学出版社, 1989: 24.30.[10]Cheney M. A mathematical tutorial on synthetic aperture radar. SIAM Review, 2001, 43: 301312. .[11]Massonnet D. The interferometric cartwheel: a constellation of passive satellite to produce radar images to be coherently combined[J].International Journal of Remote Sensing.2001, 22(12):2413-

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