[1] [1] GSCHWENDTNER A B, KEICHER W E. Development of coherent laser radar at lincoln laboratory［J］.Lincoln Laboratory Journal, 2000,12(2): 383-394.

[2] [2] KRAUSE B W, BUCK J, RYAN C, et al. Synthetic aperture ladar flight demonstration［C］. Optical Society of America/Conference on Lasers and Electro-optics (OSA/CLEO), 2011.

[3] [3] CONTRACTS［EB/OL］.［2018-01-04］http: //archive.defense.gov/Contracts/Contract.aspx ContractID=5140.

[4] [4] XING Meng-dao. Synthetic aperture ladar techniques research［R］. National High Technology Research and Development (863)Program Report, 2008.

[5] [5] LIU L R. Coherent and incoherent synthetic-aperture imaging ladars and laboratory-space experimental demonstrations［J］. Applied Optics, 2013, 52(4): 579-599.

[6] [6] LUAN Z, SUN J, ZHOU Y, et al. Down-looking synthetic aperture imaging ladar demonstrator and its experiments over 1.2 km outdoor［J］. Chinese Optics Letters, 2014, 12(11): 111101.

[7] [7] LI Dao-jing, DU Jian-bo, MA Meng, et al. The system analysis of spaceborne synthetic aperture ladar［J］. Infrared and Laser Engine, 2016, 45(11): 269-276.

[8] [8] GAO Yang-te, ZHAO Bing-ji. Distribution and moving characteristic analysis of space craps［C］. The second conference of national THz technology and application, 2016: 437-443.

[9] [9] LIAO Hui. Studies on the attitude determination and control system of an earth-oriented three-axis stabilized satellite［D］. Xi’an: Northwestern Polytechnical University, 2000: 51-112.

[12] [12] DU Jian-bo. Research on wideband signal generation and imaging processing technology for SAL［D］. Beijing: University of Chinese Academy of Scicences, 2017: 49-69.

[14] [14] HU Xuan, LI Dao-jing, TIAN He, et al. Impact and correction of phase error in ladar signal to synthetic aperture imaging［J］. Infrared and Laser Engine, 2018, 47(3): 0306001

[15] [15] HU Xuan, LI Dao-jing, ZHAO Xu-feng. One method to remain signal coherence in synthetic aperture ladar based on local oscillator digital delay［J］. Chinese Journal of Lasers, 2018,45(5): 0510003.

[16] [16] MA Meng, LI Dao-jing, DU Jian-bo. Imaging of airborne synthetic aperture ladar under platform vibration condition［J］. Journal of Radars, 2014, 3(5): 591-602.

[17] [17] DU Jian-bo, LI Dao-jing, MA Meng, et al. Vibration estimation and imaging of airborne synthetic aperture ladar based on interferometry processing［J］. Chinese Journal of Lasers, 2016, 43(9): 247-258.

[18] [18] MA Meng, LI Dao-jing. 3-D imaging for moving targets based on millimeter-wave InISAR with long orthogonal baselines［J］. Journal of Infrared and Millimeter Waves, 2016, 35(4): 488-495.

[19] [19] HU Xuan, LI Dao-jing. Vibration estimation of synthetic aperture lidar based on division of inner view field by two detectors along track［C］.IGARSS2016.

[20] [20] DAI Pin-juan, LIU Guo-guo, WU Jin. Numerical simulation on synthetic aperture ladar imaging through atmospheric turbulence with phase gradient algorithm compensation［J］. Acta Optica Sinica. 2010,30(3): 739-746.

[21] [21] JIANG Wen-hang. Adaptive optical technology［J］. Journal of Nature, 2006,28(1): 7-13.

[22] [22] CHEN Wen-chi, BAO Zheng, XING Meng-dao. Keystone transformation based ISAR imaging at the low SNR level［J］. Journal of XIDIAN University. 2003, 30(2): 155-159.