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The Track: Technion Robot And Controller Kit

Published online by Cambridge University Press:  09 March 2009

David Bar-On
Affiliation:
Department of Electrical Engineering and Department of Mechanical Engineering,
Shaul Gutman
Affiliation:
Department of Mechanical Engineering
Amos Israeli
Affiliation:
Department of Electrical Engineering, Technion Israel Institute of Technology, Haifa 32000, (Israel)

Summary

A modular hierarchical model for controlling robots is presented. This model is targeted mainly for research and development; it enables researchers to concentrate on a certain specific task of robotics, while using existing building blocks for the rest of their applications. The presentation begins by discussing the problems with which researchers and engineers of robotics are faced whenever trying to use existing commercial robots. Based on this discussion we propose a new general model for robot control to be referred as TERM (TEchnion Robotic Model). The viability of the new model is demonstrated by implementing a general purpose robot controller.

Type
Research Article
Copyright
Copyright © Cambridge University Press 1993

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References

Nagy, P.V., The PUMA 560 industrial Robot, Inside-out ROBOTS 12 Conference Proceedings Detroit(June, 1988) pp. 4.67-4.78.Google Scholar
Anderson, R.L., A PING-PONG Robot Player AT&T Bell Laboratories (MIT Press, Cambridge Mass, 1988)Google Scholar
Borenstein, J., Development of a Triaxial-Force Sensor for the PUMA-600 Industrial robot M.Sc. Thesis (Technion I.I.T, Haifa, Israel., 1983).Google Scholar
Bihn, D. & Hsia, T.C. Steve, Universal Six Joint Robot Controller, IEEE Control System Magazine 3136 (Feb. 1988).CrossRefGoogle Scholar
Bihn, D., Universal Six Joint Robot Controller M.Sc. Thesis (University of California Davis, June 1986).Google Scholar
Nagy, P.V., A New Approach to Operating a PUMA Manipulator Without Using VAL ROBOTS 12 Conference Proceedings-Detroit(June, 1988) pp. 4.81-4.93.Google Scholar
Graham, J.H., Special Computer Architectures for Robotics, IEEE Transactions on Robotics 543554 (October, 1989).CrossRefGoogle Scholar
Leung, S.S. & Shanblatt, M.A., Computer Architecture Design For Robotics IEEE Int. Conference on Robotics and Automation(1988) pp. 453456.Google Scholar
Albus, J.S., McCain, H.G. & Lumia, R. NASA/NBS Standard Reference model for Telerobot Control System Architecture NBS Technical Note 1235 (1987)Google Scholar
Bar-On, D., Gutman, S. & Israeli, A., Modular Control of Robots presented at the first Israel Conference on Control, Tel-Aviv (May 1990) pp. A5–A10.Google Scholar
Bar-On, D., A Parallel Multi-processor Controller for Robots M.Sc. Thesis (Technion I.I.T., Haifa, Israel, 03, 1990).Google Scholar
Unimation Inc., PUMA Robot Technical Manual (1978).Google Scholar
Bar-On, D., Gutman, S. & Israeli, A., The TRACK IEEE International Conference on Robotics and Automation(1991) pp. 332337.Google Scholar