[1]WILLIAMS R L. Kinematic modeling of a double octahedral variable geometry truss (VGT) as an extensible gimbal[R]. Hampton: NASA Technical Memorandum 109127,1994.
[2]WILLIAMS R L, Mayhew J B. Control of trussbased manipulators using virtual serial models[C]//ASME Design Technical Conferences.CA:Irvine,1996.
[3]HALL J J, WILLIAMS R L. Case study: inertial measurement unit calibration platform[J]. Journal of Robotic Systems, 2000, 17(17):623632.
[4]陈务军, 付功义, 何艳丽,等. 八面体桁架单元及其派生系所构成的空间伸展臂[J].上海交通大学学报,2001,35(4):509513.
CHEN W J, FU G Y, HE Y L, et al. Space masts constructed from octahedral truss units and their derivatives[J]. Journal of Shanghai Jiao Tong University, 2001,35(4):509513.
[5]姜柏森, 杨永胜, 胡士强. 八面体变几何桁架机器人的运动学分析及仿真研究[J]. 制造业自动化, 2015(6):2022.
JIANG B S, YANG Y S, HU S Q. The solution and simulation for the kinematic problem of octahedral VGT manipulator[J]. Manufacturing Automation, 2015(6):2022.
[6]YANG Y, JIANG B, HU S. Fast trajectory planning for VGT manipulator via convex optimization[J]. Advanced Robotic Systems, 2015, 12(9):136.
[7]齐乃明, 张文辉, 高九州, 等. 空间微重力环境地面模拟试验方法综述[J].航天控制,2011,29(3):95100.
QI N M, ZHANG W H, GAO J Z, et al. The primary discussion for the ground simulation system of spatial microgravity[J]. Aerospace Control, 2011, 29(3):95100.
[8]SATO Y, EJIRI A, IIDA Y, et al. MicroG emulation system using constanttension suspension for a space manipulator[C]//IEEE International Conference on Robotics and Automation. New York: IEEE, 1991.
[9]BROWN H B, DOLAN J M. A novel gravity compensation system for space robots[C]//ASCE Speciality conference on Robotics for Challenging Environments. Albuquerque: ASCE, 1994:250258.
[10]WHITE G, XU Y. An active verticaldirection gravity compensation system[J]. Instrumentation & Measurement IEEE Transactions on, 1994, 43(6):786792.
[11]JIANG Z, LIU S, LI H, et al. Mechanism design and system control for humanoid space robot movement using a simple gravitycompensation system[J]. International Journal of Advanced Robotic Systems, 2013, 10(389):502512.
[12]高吾益. 吊丝主动重力补偿系统设计与研究[D]. 哈尔滨:哈尔滨工程大学, 2010.
GAO W Y. Design and research on active gravity compensation system of hanging silk[D]. Harbin:Harbin Engineering University, 2010.
[13]邱亮. 基于阶跃辨识的PID自整定算法研究及其应用[D]. 上海: 上海交通大学, 2013.
QIU L. Research and application on PID autotuning control method based on step identification [D]. Shanghai: Shanghai Jiao Tong University, 2013.
[14]COHEN G H, COON G A. Theoretical considerations of retarded control[J]. Transactions of the ASME, 1953, 75:827834. |