[1] XIE Yong-chun, ZHANG Hao, HU Jun, et al. Automatic control system design of Shenzhou spacecraft for rendezvous and docking[J]. Scientia Sinica Technologica, 2014, 44(1): 12-19.
[4] ROBSON S, BERALDIN J A, BROWNHILL A, et al. Artefacts for optical surface measurement[C]. SPIE, 2011, V8085: 80850C.
[5] RIOUX M. Laser range finder based on synchronized scanners[J]. Applied Optics, 1984, 23(21): 3837-3844.
[6] BERALDIN J A, BLAIS F, RIOUX M, et al. Eye-safe digital 3-D sensing for space applications[J]. Optical Engineering, 2000, 39(1): 196-211.
[7] ZHU X, SMITH I C, BABIN F. A hybrid 3D sensor (NEPTEC TriDAR) for object tracking and inspection[A]. Gary W. K. Laser Radar Technology and Applications XI[C]. Proceedings of SPIE, 2006, 6214: 1-8.
[8] SAMSON C, ENGLISH C, DESLAURIERS A. et al. Imaging and tracking elements of the International Space Station using a 3D auto-synchronized scanner[C]. SPIE, 2002, 4714: 87-96.
[9] DU Xiao-ping, ZHAO Shi-yue, SONG Yi-shuo. Comparative studies on the relative-pose measurements in foreign space operations for targets[J]. Journal of Academy of Equipment, 2013, 24(5): 58-62.
[10] BERALDIN J A, JEAN-ANGELO, EL-HAKIM, et al. Practical range camera calibration[J]. SPIE, 1993, 2067: 21-31.
[11] WANG Xiao-jia, GAO Jun, WANG Lei, et al. Survey on the laser triangulation[J]. Chinese Journal of Scintific Instument, 2004, 25(4): 601-608.