Hybrid Design of Passive Mobile Robot Teleoperation System
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Abstract
This paper presents a preliminary design of remotely teleoperated vehicle such as mobile robot using haptic device. The perception principle of the slave side is constructed based on the classical Potential Field approach and especially used for detecting the presence of obstacles. A feedback linerization scheme is employed to render the mobile robot to be a passive system. As the interaction with the obstacle based on the potential ¯eld method is passive by nature, with additional assumption that the user is skilled, the connection between the haptic device and
the mobile robot is guaranteed to be stable. In this work, in order to simplify the controller development, no communication channel delay is assumed.
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References
[2] K. Kim, H. Lee, J. Park and M. Yang, "Robotic contamination cleaning system," In: IEEE Conference on Intelligent Robots ans Systems. Lausanne, Switzerland, 2002.
[3] Lin, Q. and C. Kuo, "Virtual tele-operation of underwater robots," In: Proceedings of IEEE International Conference on Robotics and Automation. Albuquerque, NM, USA, 1997.
[4] Smith, F.M., D.K. Backman and S.C. Jacobsen, "Telerobotic manipulator for hazardous environments," In: Journ. of Rob. Syst., Vol. 9, NO. 2. pp. 251-260, 1992.
[5] Roth, H., K. Schilling and O.J. Rosch, "Haptic interfaces for remote control of mobile robots," In: Proceedings of 15th IFAC World Congress. Barcelona, Spain, 2002.
[6] O. Khatib, "Real-time obstacle avoidance for manipulators and mobile robots," International Journal of Robotics Rearch vol.5(1),pp.90-98, 1986.
[7] R. Volpe and P. Khosla, "Manipulator control with superquadric artificial potential functions: Theory and experiments," IEEE Transactions on Systems, Man and Cybernetics, 1990.
[8] B.H. Krogh, "A generalized potential field approach to obstacle avoidance control," In: Proc of SME Conf on Robotics Research, 1984.
[9] H. Lau, "Behavioural Approach for Multi Robot Exploration," In: Proc of Australasian Conf on Robotics and Automation: Proc of IEEE Int Conf on Intelligent Robots and System, 2003.
[10] D.E. Koditschek and E. Rimon, "Robot navigation functions on manifolds with boundary," Advances in Applied Mathematics vol.11,pp.412-442, 1990.
[11] E.J. Colgate , "Power and Impedance Scaling in Bilateral Teleoperation," In: Proc of International Conf on Robotics and Automation, pp.2292-2298, 1991.
[12] J. Borenstein and Y. Koren, "Real-time obstacle avoidance for fast mobile robots," IEEE Transactions on Systems, Man and Cybernetics, vol.19,pp.1179-1187, 1989.
[13] Y.C. Chang and Y. Yamamoto, "Dynamic Decision Making of Mobile Robot under Obstructed Environment," In: Proc of IEEE/RSJ Int Conf on Intelligent Robots and Systems, 2006.
[14] Hough, PVC Method and means for recognizing complex patterns. US Patent 3069654, 1962.
[15] Y. Yamamoto and X. Yun, "A modular approach to dynamic modeling of a class of mobile manipulators," International Journal of Robotics and Automation, vol.12(2),pp.41-48, 1997.