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International Journal of Control Volume 91, 2018 - Issue 4
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Original Articles

Dynamic modelling and adaptive robust tracking control of a space robot with two-link flexible manipulators under unknown disturbances

Xinxin YangSchool of Automation Science and Electrical Engineering, Beihang University, Haidian District, Beijing, China
,
Shuzhi Sam GeDepartment of Electrical and Computer Engineering, National University of Singapore, SingaporeCorrespondence[email protected]
&
Wei HeSchool of Automation, University of Science and Technology Beijing, Beijing, ChinaORCID Iconhttp://orcid.org/0000-0002-8944-9861
ORCID Icon
Pages 969-988 | Received 02 Sep 2015, Accepted 25 Feb 2017, Published online: 27 Mar 2017

References

  • Book, W.J. (1993). Structural flexibility of motion systems in the space environment. IEEE Transactions on Robotics and Automation, 9(5), 524–530.
  • Carusone, J., Buchan, K.S., & D’Eleuterio, G.M.T. (1993). Experiments in end-effector tracking control for structurally flexible space manipulators. IEEE Transactions on Robotics and Automation, 9(5), 553–560.
  • Chen, Z.Y., & Chen, L. (2009). Robust adaptive composite control of space-based robot system with uncertain parameters and external disturbances. Proceedings of the 2009 International Conference on Intelligent Robots and Systems, 18, 2353–2358.
  • Chen, Y., & Meirovitch, L. (1995). Control of a flexible space robot executing a docking maneuver. Journal of Guidance, control, and Dynamics, 18(4), 756–766.
  • Chu, Z., & Ren, S. (2013). Semi-physical simulation on vibration control of small satellite with flexible manipulators. Journal of Astronautics, 34(6), 748–754.
  • Chu, Z., Cui, J., & Sun, F. (2014). Fuzzy adaptive disturbance-observer-based robust tracking control of electrically driven free-floating space manipulator. IEEE Systems Journal, 8(2), 343–352.
  • Chu, Z., Sun, F., & Cui, J. (2008). Disturbance observer-based robust control of free-floating space manipulators. Journal of Astronautics, 2(1), 114–119.
  • Damaren, C.J. (1995). Passivity analysis for flexible multilink space manipulators. Journal of Guidance, Control, and Dynamics, 18(2), 272–279.
  • Gawronski, W., Ih, C.-H. C., & Wang, S.J. (1990). On dynamics and control of multi-link flexible space manipulators. In AIAA Guidance, Navigation and Control Conference, AIAA-90-3396-CP (pp. 725–734).
  • Goldstein, H. (1951). Classical mechanics. Reading, MA: Addison-Wesley.
  • Green, A., & Sasiadek, J.Z. (2007). Intelligent tracking control of a free-flying flexible space robot manipulator. In AIAA Guidance, Navigation and Control Conference and Exhibit, AIAA-2007-6320 (pp. 1–25).
  • He, W., & Ge, S.S. (2012). Robust adaptive boundary control of a vibrating string under unknown time-varying disturbance. IEEE Transactions on Control Systems Technology, 20(1), 48–58.
  • He, W., & Ge, S.S. (2015). Vibration control of a flexible beam with output constraint. IEEE Transactions on Industrial Electronics, 62(8), 5023–5030.
  • He, W., Sun, C., & Ge, S.S. (2015). Top tension control of a flexible marine riser by using integral-barrier Lyapunov function. IEEE/ASME Transactions on Mechatronics, 20(2), 497–505.
  • He, W., Ge, S.S., How, B.V.E., Choo, Y.S., & Hong, K.S. (2011). Robust adaptive boundary control of a flexible marine riser with vessel dynamics. Automatica, 47(4), 722–732.
  • Hokamoto, S., Kuwahara, M., Modi, V., & Misra, A. (1998). Formulation and control of space-based flexible robots with slewing-deployable links. Acta Astronautica, 42(9), 519–531.
  • Hong, Z., Yun, C., & Chen, L. (2007). Modeling and trajectory tracking control of a free-floating space robot with flexible manipulators. Robot, 29(1), 92–96.
  • Hong, Z., & Chen, L. (2010). Active vibration control and fuzzy control of free-floating space flexible manipulator based on singular perturbation theory. Journal of Mechanical Engineering, 46(7), 35–41.
  • Hung, J.Y., Gao, W., & Hung, J.C. (1993). Variable structure control: a survey. IEEE Transactions on Industrial Electronics, 40(1), 2–22.
  • Jiang, Z. (1992). Kinematics and dynamics of flexible space robot arms. Proceedings of the 1992 IEEE/RSJ International Conference on Intelligent Robots and Systems, 3, 1681–1688.
  • Kane, T.R., Ryan, R., & Banerjee, A.K. (1987). Dynamics of a cantilever beam attached to a moving base. Journal of Guidance, Control, and Dynamics, 10(2), 139–151.
  • Kumar, A., Pathak, M.P., & Sukavanam, N. (2011). Reduced model based control of two link flexible space robot. Intelligent Control and Automation, 2(2), 112–120.
  • Kumar, A., Pathak, M.P., & Sukavanam, N. (2013). Trajectory control of a two DOF rigid-flexible space robot by a virtual space vehicle. Robotics and Autonomous Systems, 61(5), 473–482.
  • Liu, S., Wu, L., & Lu, Z. (2007). Impact dynamics and control of a flexible dual-arm space robot capturing an object. Applied Mathematics and Computation, 185(2), 1149–1159.
  • Masoudi, R., & Mahzoon, M. (2011). Maneuvering and vibrations control of a free-floating space robot with flexible arms. Journal of Dynamic Systems, Measurement, and Control, 133(5), 051001.
  • Meirovitch, L., & Lim, S. (1994). Maneuvering and control of flexible space robots. Journal of Guidance, Control, and Dynamics, 17(3), 520–528.
  • Murotsu, Y., Senda, K., Mitsuya, A., Yamane, K., & Nunohara, T. (1993). Theoretical and experimental studies for continuous path control of flexible manipulator mounted on a free-flying space robot. In Guidance, Navigation and Control Conference, AIAA-93-3863-CP (pp. 1458–1471).
  • Murotsu, Y., Tsujio, S., Senda, K., & Hayashi, M. (1990). Dynamics and positioning control of space robot with flexible manipulators , Guidance, Navigation and Control Conference , AIAA-90-2297-CP (pp. 735–742).
  • Murotsu, Y., Tsujio, S., Senda, K., & Hayashi, M. (1992). Trajectory control of flexible manipulators on a free-flying space robot. Control Systems, IEEE, 12(3), 51–57.
  • Ortega, R., Perez, J.A.L., Nicklasson, P. J., & Sira-Ramirez, H. (2013) . Passivity-based control of Euler-Lagrange systems: Mechanical, electrical and electromechanical applications, New York, Springer Science Business Media.
  • Rivals-Mazeres, G.de., Yim, W., Mora-Camino, F., & Singh, S.N. (1997). Dual mode inverse control and stabilization of flexible space robots. In Guidance, Navigation and Control Conference, AIAA-97-3559 (pp. 552–560).
  • Sabatini, M., Gasbarri, P., Monti, R., & Palmerini, G.B. (2012). Vibration control of a flexible space manipulator during on orbit operations. Acta Astronautica, 73, 109–121.
  • Schaefer, B. E., Loesch, M., & Rulka, W. (1997). Real-time simulation of flexible space manipulator dynamics. In AIAA Guidance, Navigation and Control Conference. AIAA-97-3560 (pp. 561–571).
  • Senda, K. & Murotsu, Y. (2000). Methodology for control of a space robot with flexible links. IEEE Proceedings-Control Theory and Applications, 147(6), 562–568.
  • Siciliano, B., & Book, W.J. (1988). A singular perturbation approach to control of lightweight flexible manipulators. The International Journal of Robotics Research, 7(4), 79–90.
  • Tan, D. (2003). Dynamics simulations of space manipulator with flexible links. In 54th International Astronautical Congress of the International Astronautical Federation, the International Academy of Astronautics, and the International Institute of Space Law, IAC-03-A.6.04 (pp. 1–11).
  • Toglia, C., Sabatini, M., Gasbarri, P., & Palmerini, G.B. (2011). Optimal target grasping of a flexible space manipulator for a class of objectives. Acta Astronautica, 68(7–8), 1031–1041.
  • Trivailo, P., & Gilbert, T. (2004). Dynamic modelling of flexible space robotic manipulators during payload capture. In 55th International Astronautical Congress, IAC-04-A.5.07 (pp. 1–12).
  • Wang, J. (2010). Passivity-based control theory and its applications. Beijing: Electronic Industry Press.
  • Wu, L., Sun, F., Sun, Z., & Su, W. (2002). Dynamic modeling, control and simulation of flexible dual-arm space robot. TENCON’02. Proceedings. 2002 IEEE Region 10 Conference on Computers, Communications, Control and Power Engineering, 3, 1282–1285.
  • Xie, L., & Chen, L. (2012). Robust control and vibration suppression of free-floating flexible space robot. Chinese Journal of Theoretical and Applied Mechanics, 44(6), 1057–1065.
  • Yang, X., & Ge, S.S. (2014a). Dynamics and tracking control for a free-flying space robot with rigid-flexible links. 2014 IEEE International Conference on Information and Automation (ICIA), (pp. 394–399).
  • Yang, X., , & Ge, S.S. (2014b). Backstepping control and active vibration control for a free-flying space robot with rigid-flexible links by singular perturbation approach. 2014 IEEE International Conference on Information and Automation (ICIA), (pp. 164–169).
  • Yu, X.Y., & Chen, L. (2015). Singular perturbation adaptive control and vibration suppression of free-flying flexible space manipulators. Proc IMechE Part C: J Mechanical Engineering Science, 229(11), 1989–1997.
  • Yu, X.Y., & Chen, L. (2015). Velocity observer based singular perturbation robust control and vibration suppression for a free-floating flexible space manipulator with unknown payload parameters and bounded disturbances. Journal of Vibration and Shock, 34(14), 85–92.
  • Yu, X.Y. & Chen, L. (2016). Globally robust terminal sliding mode control for a free-floating two-flexible-link space manipulator. Manned Spaceflight, 22(4), 370–377.
  • Yu, X.Y., & Chen, L. (2016). Observer based robust control and vibration control for a free-floating flexible space manipulator. Journal of Mechanical Engineering. [ Online].
  • Yu, X.Y., & Chen, L. (2016). Robust joint motion control and vibration control for a free-floating two-flexile-link space manipulator. Chinese Journal of Computational Mechanics, 33(2), 370–149.
  • Yu, X.Y., Chen, L., & Xie, L.M. (2013, September 23). Observer-based two time control of free-flying flexible space manipulator. 64th International Astronautical Congress, Beijing.
  • Zhai, Y., Hu, Q., Xu, L., & Huo, X. (2012). Trajectory-tracking control for free-floating flexible space robots with bounded inputs. Control Theory and Applications, 29(3), 395–400.

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