ABSTRACT
Fine manipulation by multifingered robot hand is a new avenue in the area of robotic research. The ability to manipulate a part in a dexterous hand depends generally on the contact conditions between the fingers and object. It can be easily observed in fine manipulation where small motions and low velocities lead to dexterous grasp. In this paper we study a strategy for dexterous manipulation, which we call finger gaiting. We show how the finger gaiting may be used to control the fingers of a robot hand to generate the rotational motion of grasped object. A simulation for multifingered robotic hand has been developed for finger gaiting. Paper also investigates the problem of dexterous manipulation, how can robots affects the world around them by means of their end-effector? Dexterous manipulation is fundamental to robot operating independently, but progress in this area has been low.
- Li., Z., and Sastry, S.S. 1998. Grasping and coordinated manipulation by a multifingered robot hand. Int. J. Robot Res. 8,4 (April 1989), 33--50.Google Scholar
- B. Mishra and N. Silver. 1989. Some discussion of Static gripping and its stability. IEEE Transactions on systems, Man and Cybernetics.19,4 (April 1989), 783--796.Google ScholarCross Ref
- Baker, S.S., Fortune, S., and Grosse, E., 1985 Stable prehension with a multifingered hand, Proc. IEEE Int. Conf. Robotics and Automation. 1985, 570--575.Google Scholar
- Mason, M. T., and Salisbury, J. K. 1985. Robot hand and mechanics of manipulation. Cambridge, MA: MIT Press. Google ScholarDigital Library
- Bastuscheck, C.M. Philadelphia. 1988 On the stability of grasping: Three fingers and a planner polygon. Proc. Conf. Robot Automation. 1988, 100--102.Google ScholarCross Ref
- R. M. Murray and S.S. Sastry. 1990. Grasping and manipulation using multifingered robot hands. Proc, Symp. Applied Mathematics, 41, 1 (Jan. 1990), 91--127.Google Scholar
- Hanafusa, H., and Asada, H. 1977. Stable prehension by a robot hand with elastic fingers. Proc. 7th ISIR, Tokyo. (April 1977), 361--368.Google Scholar
- Okada, T. 1979. Object-Handling system for manual Industry IEEE Transactions on System, Man, and Cybernetics, 9,2 (Feb. 1979), 342--349.Google Scholar
- Salisbury, J. K., Mason, M. T., and Criag, J.J. 1982 Articulated Hands: Force control and kinematic issues. Int. J. Robot. Res. 1,1 (Jan. 1982), 4--17.Google ScholarCross Ref
- Jacobsen, S.C, et al. 1982. Development of the Utah Artificial Arm. IEEE Transactions on biomedical Engineering. 29,4 (April 1982), 667--673.Google Scholar
- Fu, K. S., Lee, C. S. G., and Gonzalez, R., C. 1987. Robotics, Control, Sensing, Vision, and Intelligence. McGraw-Hill International Edition. Google ScholarDigital Library
- M. Buss, H. Hashimoto, and J.B. Moore. 1996. Dexterous hand grasping force optimization. IEEE Trans Robot. Automat. 12,4 (Dec. 1996) 406--418.Google ScholarCross Ref
- Kumar, V. and Waldron, K.J. 1988. Force Distribution in closed Kinematic Chains. IEEE Transaction of Robotics and Automation, 4,6, (December 1988), 544--542.Google Scholar
- Holzmann, W., and Mc Carthy, J. M. 1985. Computing the friction forces associated with three-fingered grasps. IEEE Trans., Robot, Automation, 1,4 (Jan.1985), 206--210.Google Scholar
- Suhaib, M. 2010. Multifingered robotic hand dexterity for rotation of spherical object. International journal of Mechanical Engineering. l2,4 (Dec 2010) 88--92.Google Scholar
- Jameson, J. and Leifer, L. 1986 Quasi-Static Analyses: A method for predicting grasp stability. Proceedings of IEEE International Conference on Robotics and Automation. 6,2 (Feb 1986) 876--883.Google Scholar
Index Terms
- Finger Gaiting For Rotation of Sphere by Multifingered Robot Hand
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