一种星载ATI-GMTI系统最优基线设计方法被引量：2

An Optimization Method of Baseline for Spaceborne ATI-GMTI System

下载PDF

导出

摘要为提高星载ATI-GMTI系统灵敏度和防止卫星碰撞,卫星间距一般较远,盲速问题比较突出,严重影响系统动目标检测性能.设计沿航向基线以获得优化的速度响应是星载系统需要研究的重要问题.本文以获得最优速度响应为目的,在对单颗星接收天线进行子阵分割的基础上,首先推导了理想杂波假设下系统输出信杂噪比的表达式,进而提出了最优基线设计方法,最后计算机仿真验证了该方法的有效性. The Spacebome ATI-GMTI system is made up of several satellites equipped with Synthetic Aperture Radar. The space between satellites must be big enough to acquire high sensitivity and avoid collision. However, the long baseline brings on blind velocity and worsens the GMTI performance. It is an important problem to determinate the length of the along track baseline for an ATI-GMTI system. Basing on splitting the whole aperture into multiple sub-apertures, this paper investigates the design method of optimum velocity response. Firstly, the output signal-to-clutter-plus-noise ratio expression of the system is derived, and then the way of designing optimum velocity response is presented.Finally,computer simulation results validate its effectiveness.

作者杨垒王彤保铮

机构地区西安电子科技大学雷达信号处理国家重点实验室

出处《电子学报》 EI CAS CSCD 北大核心 2009年第6期1175-1179,共5页 Acta Electronica Sinica

基金国家自然科学基金资助课题(No.60872140)

关键词沿航迹干涉地面运动目标检测输出信杂噪比 along track intefferometric ground moving target indication output SCNR

分类号 TN957 [电子电信—信号与信息处理]

引文网络
相关文献

参考文献9

1Cerutti-Maori D, Ender J. Performance analysis of multistatic configuratiom for spacebome GMTI based on the auxiliary beam approach[J]. IEE Proceedings Radar Sonar and Navigation,2006,153(2) :96 - 103.
2Delphine J, Cerutfi-Maori D,Ender J.An approach to multistatic spacebome SAR/MTI processing and performance analysis [ A]. Proceedings IGARSS [ C ]. Toulouse: IGARSS, 2003.4446- 4449.
3Hovanession S A, Jocic L B. Spacebome radar design equations and concepts [ A ]. IEEE Aerospace Conference [ C ]. USA: IEEE, 1997. 125 - 136.
4Martin M,Klupar P, Kilberg S, Winter J. Techsat 21 and revolutionizing space missions using microsatellites[ A]. 15th American Institute of Aeronautics Astronautics Conferencep [ C ]. USA;AIAAC,2001.1 - 10.
5Massonnet D. Capabilities and limitations of the interferometric cartwheel[ J]. IEEE Trans Geosci Remote Sens, 2001,39(3 ): 506 - 520.
6Aguttes J P.The SAR train concept:required antenna area distributed over N smaller satellites, increase of performance by N [A]. Proceedings IGARSS [ C ]. Toulouse: IGARSS, 2003. 542-544.
7Wang H. Mainlobe clutter cancellation by DPCA for space- based radars[ A]. IEEE Aerosp Applications Conference Digest [ C]. Crested Butte, CO, USA, 1991.1 - 28.
8Yang L, Wang T, Xing M, et al. A new channel equalization method for airborne multi-channel SAR-GMTI system[ A]. 1st Asian and Pacific Conference on Synthetic Aperture Radar [ C], Huangshan: APCSAR,2007.271 - 274.
9Brennan L, Reed I S. Theory of adaptive radar[ J]. IEEE Trans on Aeros and Electro Syst, 1973,9(2) :237 - 253.

同被引文献19

1Gierull CH,Livingstone C. SAR- GMTI concept for RA- DARSAT-2[M]. The Applications of Space-Time Adap- tive Processing. Klemm R, Ed. London, UK.. IEE Pub- lishers, 2004 : 177 - 206.
2Ender JHG, Gierull CH, Cerutti-Maori D. Improved space- based moving target indication via alternate transmission and receiver switching[J]. IEEE Trans. on Geoscience and Remote Sensing, 2008,46(12) :3960 - 3974.
3Lombardo P, Colone F, Pastina D. Monitoring and surveillance potentialities obtained by splitting the antenna of the COSMO-SkyMed SAR into multiple sub-apertures[J]. IEE Proe. Radar, Sonar and Navigation, 2006,53 (2) : 104 - 116.
4Stimson GW. Introduction to airborne radar [M]. 2nd ed. Rayleigh, NC: SeiTeeh Publishing, 1998.
5Rtiegg M, Meier E, Niiesch D. Capabilities of dual-frequency millimeter wave SAR with monopulse processing for ground moving target indication [J]. IEEE Trans. on Geoseience and Remote Sensing, 2007,45 (3): 539 - 553.
6Ender JHG. Space-time adaptive processing for synthetic aperture radar[R]. London: Space-time adaptive process- ing, 1998.
7Soumekh M, Himed B. Multi-channel signal subspaee proeessing methods for SAR-MTI [C]// Proe. IEEE Radar Conferenee. Huntsville, AL: 2003:126-132.
8Fienup JR. Detecting moving targets in SAR imagery by focusing[J]. IEEE Trans. on Aerospace and Electronic Systems, 2001,37(3) :794 - 809.
9Horn RA, Johnson CR. Topics in matrix analysis[M]. Cambridge University Press, 1991.
10Ward J. Space-time adaptive processing for airborne radar [R]. US: Teehnical Report of Lincoln Lab, 1994.

引证文献2

1叶巍,张驿.星载雷达应用多频率多通道技术研究[J].航天电子对抗,2013,29(3):11-14.
2胡瑞贤,张昭,骆成.一种分布式卫星系统基线优化设计方法[J].系统工程与电子技术,2023,45(8):2423-2437. 被引量：1

二级引证文献1

1胡瑞贤,贾秀权,曹晨.基于频控阵波束锐化的主瓣干扰抑制技术[J].中国电子科学研究院学报,2023,18(8):770-778.

1朱燕,赵国庆,张煜.假目标在动目标检测中的效果分析[J].电子信息对抗技术,2009,24(6):60-63. 被引量：1
2李穗平.相控阵雷达应用进展[J].电子工程信息,2006(4):13-16. 被引量：1
3霍家道.一种基于免疫算法的雷达信号目标检测方法[J].弹箭与制导学报,2004,24(S4):370-372.
4赵志钦,刘醒凡.机载雷达地面杂波抑制技术[J].电子科技大学学报,1993,22(5):455-458. 被引量：4
5朱燕,赵国庆,崔艳鹏.移频干扰在动目标检测中的效果分析[J].航天电子对抗,2009,25(2):55-57. 被引量：4
6黄波,付平,梁山红.分布式卫星AT-INSAR测速仿真实现[J].四川理工学院学报（自然科学版）,2006,19(2):23-25.
7胡庆东,毛士艺,洪文.干涉合成孔径雷达系统的最优基线[J].电子学报,1999,27(5):93-95. 被引量：7
8姜岩,陈筠力,王贇,王文峰.星载SAR的GMTI技术[J].上海航天,2009,26(6):60-64. 被引量：2
9蔚婧,廖桂生.一种新的双通道运动目标测速定位方法[J].系统工程与电子技术,2009,31(7):1620-1622.
10张红波,孙进平,高飞,毛士艺.基于信号子空间处理的ATI误差校正方法[J].系统工程与电子技术,2009,31(1):62-65.

电子学报

2009年第6期

浏览历史

内容加载中请稍等...

一种星载ATI-GMTI系统最优基线设计方法被引量：2

参考文献9

同被引文献19

引证文献2

二级引证文献1

相关作者

相关机构

相关主题

浏览历史

一种星载ATI-GMTI系统最优基线设计方法 被引量：2

参考文献9

同被引文献19

引证文献2

二级引证文献1

相关作者

相关机构

相关主题

浏览历史

一种星载ATI-GMTI系统最优基线设计方法被引量：2