基于Chirp-Z变换的分布式SAR地面运动目标检测方法
doi: 10.3724/SP.J.1146.2006.01651
A New GMTI Method Based on Chirp-Z Transform for Distributed Satellites Interferometric SAR
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摘要: 该文基于主辅星编队模式下的分布式卫星SAR系统,对Range-Doppler域地面运动目标检测方法进行了改进,提出回波信号经方位向相位补偿后,应用Chirp-Z变换能够将地面同一方位单元回波的频谱在不同通道内精确配准,而后通过干涉处理和频谱相位补偿来提取运动目标信息,并给出了频谱相位补偿对系统参数的约束条件以及频谱配准对目标速度的约束条件。最后仿真表明该方法在约束条件下是有效的。Abstract: Distributed satellites interferometric SAR is capable of detecting ground moving targets via along-track baseline. In this paper, the signal model and phase compensation for this INSAR system is analyzed firstly. A new method based on Chirp-Z transform for GMTI in range-Doppler domain is proposed. The received data of different channels can be co-registered precisely along azimuth direction after being transformed into Doppler domain via CZT, and moving target can be detected through interferometry procedure combined with spectrum phase compensation. In the end, the constraints of multistatic SAR configuration by spectrum phase compensation and target motion by spectrum co-registration are discussed. The final simulation demonstrates that this algorithm can detect moving target efficiently.
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Pascazio V, Schirinzi V, and Farina A. Moving targetdetection by along-track interferometry. Int. Geoscience andRemote Sensing Symposium (IGARSS), Sydney(AUS), 2001:3024-3026.[2]Gill E and Runge H. Tight formation flying for an alongtrackSAR interferometer[J].Acta Astronautica.2004, 55(3/9):473-485[3]Krieger G, Fiedler H, Mittermayer J, Papathanassiou K, andMoreira A. Analysis of multistatic configurations forspaceborne SAR intereometry[J].IEE Proc.Radar Sonar Navig.2003, 150(3):87-96[4]Cantalloube H, Dubois-Fernandez P, Giroux V, and KriegerG. Bistatic moving target indication, using across-track andalong-track interferometry. EURSAR, Dresden, Germany,2006. ID/155.[5]李景文,李春升,周荫清. 三孔径INSAR 动目标检测和成像.电子学报,1999, 27(6): 40-43.Li Jing-wen, Li Chun-sheng, and Zhou Yin-qing. ThreeapertureINSAR moving targets detection and imaging. ActaElectronica Sinica, 1999, 27(6): 40-43.[6]郑明洁. 合成孔径雷达动目标检测和成像研究. [博士论文].北京: 中国科学院电子学研究所, 2003.Zheng Ming-jie. The study of moving target detection andimaging for SAR.[Doctoral dissertation], Beijing: Institute ofElectronics, Chinese Academy of Sciences, 2003.[7]Didier Massonnet, Jean-Claude Souyris, and Jean-MarcGaudin. Radar processing and geometric specificity ofbistatic data. International Geoscience And Remote SensingSymposium (IGARSS), Toulouse, France, 2003, 3: 1459-1461.[8]高鑫. InSAR 误差分析与图像配准、相位解缠关键技术研究.博士后研究工作报告,中国科学院遥感应用研究所,2003.Gao Xin. Error analysis of InSAR and its key techniquesresearch: image registration and phase unwrapping[Post-Doctor Research Report]. Beijing: Institute of RemoteSensing Applications, Chinese Academy of Sciences, 2003.[9]Shen Chiu. A constant false alarm rate (CFAR) detector forRADARSAT-2 along-track interferometry. Can.J.RemoteSensing, 2005, 31(1): 73-84. 期刊类型引用(12)
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