POSITION/FORCE CONTROL OF A DUAL COOPERATIVE MANIPULATOR SYSTEM BASED ON A SINGULARLY PERTURBED DYNAMIC MODEL

Hossein Bolandi and Amir F. Ehyaei

References

1. [1] Y. Cao, A.S. Fukunaga, and A.B. Kahng, Cooperative mobile robotics: Antecedents and directions, Autonomous Robots, 4 (1), 1997, 7–27.
2. [2] A. Farinelli, L. Iocchi, and D. Nardi, Multi-robot systems: A classification focused on coordination, IEEE Transactions on Systems, Manufacturing and Cybernetics, 34 (5), 2004, 2015–2028.
3. [3] N. Michael, J. Fink, and V. Kumar, Cooperative manipulation and transportation with aerial robots, Autonomous Robots, 30, 2011, 73–86.
4. [4] M.D. Zivanovic and M.K. Vukobratovic, Multi-arm cooperating robots: Dynamic and control (Dordrecht, The Netherlands: Springer, 2006).
5. [5] A. Tavasoli, M. Eghtesad, and H. Jafarian, Two-time scale control and observer design for trajectory tracking of two cooperating robot manipulators moving a flexible beam, Robotics and Autonomous Systems, 57 (2), 2009, 212–221.
6. [6] J. Kerr and B. Roth, Analysis of multifingered hands, The International Journal of Robotics Research, 4 (4), 1986, 3–17.
7. [7] J.K. Salisbury and J.J. Craig, Articulated hands: Force control and kinematic issues, The International Journal of Robotics Research, 1 (1), 1982, 4–17.
8. [8] S.M. Song and K.J. Waldron, Machines that walk (Cambridge, MA: MIT Press, 1989).
9. [9] J.A. Adams, R. Bajcsy, J. Kosecka, V. Kumar, R. Mandelbaum, M. Mintz, R. Paul, C.C. Wang, Y. Yamamoto, and X. Yun, Cooperative material handling by human and robotic agents: Module development and system synthesis, Proc. IEEE/RSJ Int. Conf. on Intelligent Robots and Systems, Pittsburgh, PA, USA, 1995, 200–205.
10. [10] G.F. Liu, Analysis and control of redundant parallel manipulators, Proc. IEEE Int. Conf. on Robotics and Automation, Seoul, South Korea, 2001, 3748–3754.
11. [11] S.H. Lee, Control of impact disturbance by redundantly actuated mechanism, Proc. IEEE Int. Conf. on Robotics and Automation, Seoul, South Korea, 2001, 3734–3741.
12. [12] L.S. Guo and Q. Zhang, Adaptive trajectory control of a two DOF closed-chain robot, Proc. of the American Control Conf., Arlington, VA, 2001, 658–663.
13. [13] W. Ailing, W. Zhonghua, and Z. Zhiqun, Adaptive control of closed kinematic chains based on singularly perturbed formulation, Proc. 26th Chinese Control Conf., Hunan, China, 2007, 128–132.
14. [14] S. Arimoto, F. Miyazaki, and S. Kawamura. Cooperativemotion control of multiple robot arms or fingers. Proc. IEEEInt. Conf. on Robotics and Automation, Raleigh, NC, USA,1987, 1407–1412.
15. [15] A. Ibeas and M. Sen, Robustly stable adaptive control of a tandem of master–slave robotic manipulators with forcereflection by using a multiestimation scheme, IEEE Transaction on Systems, Man, and Cybernetics – Part B : Cybernetics, 36 (5), 2006, 1162–1179.
16. [16] C.D. Kopf and T. Yabuta, Experimental comparison of master/slave and hybrid two-arm systems, Proc. IEEE Int. Conf. on Robotics and Automation, Philadelphia, PA, USA, 1988, 1633–1637.
17. [17] F. Caccavale, P. Chiacchio, A. Marino, and L. Villani, Six-DOF impedance control of dual-arm cooperative manipulators, IEEE/ASME Transactions on Mechatronics, 13 (5), 2008, 576–586.
18. [18] N.M.F. Ferreira, J.A.T. Machado, and J.K. Tar, Two cooperating manipulators with fractional controllers, International Journal of Advanced Robotic Systems, 6 (4), 2009, 343–347.
19. [19] A.A.G. Siqueira and M.H. Terra, Neural network-based H ∞ control for fully actuated and underactuated cooperative manipulators, Control Engineering Practice, 17 (3), 2009, 418–425.
20. [20] T.J. Tarn, A.K. Bejczy, and X. Yun, Coordinated control of two robot arms, Proc. IEEE Int. Conf. on Robotics and Automation, 1986, 1193–1202.
21. [21] A.J. Koivo and M.A. Unseren, Reduced order model and decoupled control architecture for two manipulators holding a rigid object, ASME Journal of Dynamic Systems, Measurement & Control, 113 (4), 1991, 646–654.
22. [22] T. Yoshikawa and X. Zheng, Coordinated dynamic hybridposition/force control for multiple robot manipulators handling one constrained object, Proc. IEEE Int. Conf. on Robotics and Automation, 1990, 1178–1183.
23. [23] Y.H. Liu, S. Arimoto, and T. Ogasawara, Decentralized cooperation control: Non-communication object handling, Proc. IEEE Int. Conf. on Robotics and Automation, 1996, 2414–2419.
24. [24] M.H. Raibert and J.J. Craig, Hybrid position/force control of manipulators, ASME Journal of Dynamic Systems, Measurement & Control, 103 (2), 1981, 126–133.
25. [25] S. Chiaverini and L. Sciavicco, The parallel approach to force/position control of robotic manipulators, IEEE Transaction on Robotics and Automation, 9 (4), 1993, 361–373.
26. [26] V. Perdereau and M. Drouin, Hybrid external control for two-robot coordinated motion, Robotica, 14, 1996, 141–153.
27. [27] O. Khatib, K. Yokoi, K. Chang, D. Ruspini, R. Holmberg, and A. Casal, Vehicle/arm coordination and multiple mobile manipulator decentralized cooperation, Proc. IEEE/RSJ Int. Conf. on Intelligent Robots and Systems, Osaka, Japan, 1996, 546–553.
28. [28] Y.H. Liu, Y. Xu, and M. Bergerman, Cooperation control of multiple manipulators with passive joints, IEEE Transactions on Robotics and Automation, 15 (2), 1999, 258–267.
29. [29] D. Sun and J.K. Mills, Manipulating rigid payloads with multiple robots using compliant grippers, IEEE/ASME Transactions on Mechatronics, 7 (1), 2002, 23–34.
30. [30] R. Tinos, M.H. Terra, and J.Y. Ishihara, Motion and force control of cooperative robotic manipulators with passive joints, IEEE Transactions on Control Systems Technology, 14 (4), 2006, 725–734.
31. [31] S.A. Moosavian and E. Papadopoulos, Cooperative objectmanipulation with contact impact using multiple impedancecontrol, International Journal of Control, Automation andSystems, 8 (2), 2010, 314–327.
32. [32] N. Yagiz, Y. Hacioglu, and Y.Z. Arslan, Load transportation by dual arm robot using sliding mode control, Journal of Mechanical Science and Technology, 24 (5), 2010, 1177–1184.
33. [33] J.D. Schutter, T.D. Laet, J. Rutgeerts, W. Decre, R. Smits, E. Aertbelien, K. Claes, and H. Bruyninckx, Constraint-based task specification and estimation for sensor-based robot systems in the presence of geometric uncertainty, International Journal of Robotics Research, 26 (5), 2007, 433–455.
34. [34] Z. Li, W. Chen, and J. Luo, Adaptive compliant force–motion control of coordinated non-holonomic mobile manipulators interacting with unknown non-rigid environments, Neurocomputing, 71 (7–9), 2008, 1330–1344.
35. [35] H. Krishnan and N.H. McClamroch, Tracking in nonlineardifferential–algebraic control systems with applications to constrained robot systems, Automatica, 30 (12), 1994, 1885–1897.
36. [36] A. Kumar and P. Daoutidis, Control of nonlinear differential algebraic equation systems (London, UK: Chapman & Hall/CRC, 1999).
37. [37] J. Dabney, F. Ghorbel, and Z. Wang, Modeling closed kinematic chains via singular perturbations, Proc. American Control Conf., Anchorage, AK, 2002, 4104–4110.
38. [38] Z. Wang and F. Ghorbel, Control of closed kinematic chains using a singularly perturbed dynamic model, Proc. 43rd IEEE Conf. on Decision and Control, Nassau, Bahamas, 2004, 317–322.
39. [39] M.E. Pittelkau, Adaptive load-sharing force control for two-arm manipulators, Proc. IEEE Int. Conf. on Robotics and Automation, Philadelphia, PA, USA, 1988, 498–503.
40. [40] F. Ghorbel, O. Chetelat, R. Gunawardana, and R. Longchamp, Modeling and setpoint control of closed-chain mechanisms: Theory and experiment, IEEE Transaction on Control System Technology, 8 (5), 2000, 801–815.

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• DOI: 10.2316/Journal.206.2012.1.206-3516
• From Journal (206) International Journal of Robotics and Automation - 2012

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