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Abstract

This paper presents a new teleoperation approach using a virtual spring, and local contact force control on the slave robot. The operational space framework provides the control structure needed to achieve decoupled task dynamics. A virtual spring connects the master and slave systems and a closed-loop force controller compensates for the dynamics of the slave system, rendering transparent the effector of the slave robotic system. The active force control approach allows the desired motion and contact forces to be combined in a single force command. The required performance and robustness of force control are achieved by a full state reconstruction using a modified Kalman estimator, which addresses disturbances and modeling uncertainties. The performance of both telepresence and force control are further improved by on-line stiffness estimation of the object in contact with the effector. The redundancy of the mobile manipulation system is addressed through a decoupled decomposition of task and posture dynamics.

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References

Anderson, R. J. and Spong, M. W. 1989. Bilateral control of teleoperators with time delay . IEEE Transactions on Automatic Control 34: 494-501 .

Armstrong, B., Khatib, O., and Burdick, J. 1986. The explicit dynamic model and intertial parameters of the puma 560 arm . In Proc. of the Int. Conf. on Robotics and Automation, pp. 510-518 .

Cortesão, R. 2002. Kalman Techniques for Intelligent Control Systems: Theory and Robotic Experiments. PhD thesis, University of Coimbra.

Cortesão, R., Park, J., and Khatib, O. 2003. Real-time adaptive control for haptic manipulation with active observers . In Proc. of the Int. Conf. on Intelligent Robots and Systems (IROS), Las Vegas.

Daniel, R. and McAree, P. 1998. Fundamental limits of performance for force reflecting teleoperation . International Journal of Robotics Research 17(8): 811-830 .

Diolaiti, N., Niemeyer, G., Barbagli, F., Salisbury, K., and Melchiorri, C. 2005. The effect of quantization and coulomb friction on the stability of haptic rendering . In Proceedings of IEEE World Haptics Conference.

Erickson, D., Weber, M., and Sharf, I. 2003. Contact stiffness and damping estimaation for robotic systems . International Journal of Robotics Research 22(1): 41-57 .

Franklin, G. F., Powell, J. D., and Emami-Naeini, A. 2002. Feedback Control of Dynamic Systems, 4th edition. Prentice Hall .

Freund, E. 1975. The structure of decoupled nonlinear systems . Int. J. Contr. 21(3): 443-450 .

10.

Hannaford, B. 1989. A design framework for teleoperators with kinesthetic feedback . IEEE Transactions on Robotics and Automation 5: 426-434 .

11.

Hashtrudi-Zaad, K. and Salcudean, S. E. 2002. Transparency in time-delayed systems and the effect of local force feedback for transparent teleoperation . International Journal on Robotics and Automation 18(1): 108-114 .

12.

Holmberg, R. and Khatib, O. 2000. Development and control of a holonomic mobile robot for mobile manipulation tasks . International Journal of Robotics Research 19(11): 1066-1074 .

13.

Khatib, O. 1987. A unified approach for motion and force control of robot manipulators: The operational space formulation . Int. J. on Robotics and Automation 3(1): 43-53 .

14.

Khatib, O. and Burdick, J. 1986. Motion and force control of robot manipulators . In Proceedings of the International Conference on Robotics and Automation, pp. 1381-1386 .

15.

Khatib, O., Sentis, L., Park, J., and Warren, J. 2004. Whole-body dynamic behavior and control of human-like robots . Int. J. of Humanoid Robotics 1(1): 29-43 .

16.

Kim, W. S., Hannaford, B., and Bejczy, A. K. 1992. Force-reflecting and shared compliant control in operating tele-manipulators with time delay . International Journal on Robotics and Automation 8: 176-185 .

17.

Lawrence, D. 1993. Stability and transparancy in bilateral teleoperation . IEEE Trans. on Robotics and Automation 9(5): 624-637 .

18.

Love, L. and Book, W. 1995. Environment estimation for enhanced impedance control . In Proc. of the Int. Conf. on Robotics and Automation, pp. 1854-1859 .

19.

Niemeyer, G. and Slotine, J. 1991. Stable adaptive teleoperation . IEEE Journal of Oceanic Engineering 16(1): 152-162 .

20.

Niemeyer, G. and Slotine, J. 2004. Telemanipulation with time delays . The International Journal of Robotics Research 23: 873-890 .

21.

Ryu, J., Kwon, D., and Hannaford, B. 2004. Stable teleoperation with time-domain passivity control . IEEE Transactions on Robotics and Automation 20(2): 365-373 .

22.

Seraji, H. and Colbaugh, R. 1997. Force tracking in impedance control . International Journal of Robotics Research 16(1): 97-117 .

23.

Singh, S. and Popa, D. 1995. An analysis of some fundamental problems in adaptive control of fooorce and impedance behavior: Theory and experiments . IEEE Transactions on Robotics and Automation 11(6): 912-921 .

24.

Yokokohji, Y. and Yoshikawa, T. 1994. Bilateral control of master-slave manipulators for idela kinesthetic coupling . IEEE Transactions on Robotics and Automation 10: 605-620 .

25.

Zhu, W. and Salcudean, S. 2000. Stability guaranteed teleoperation: An adaptive motion/force control approach . IEEE Transactions on Automatic Control 45(11): 1951-1969 .

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A Haptic Teleoperation Approach Based on Contact Force Control

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