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Generalized Graph Representation of Tendon Driven Robot Mechanism

텐던 구동 로봇 메커니즘의 일반화된 그래프 표현

  • Cho, Youngsu (Control & Instrumentation Engineering, Korea University) ;
  • Cheong, Joono (Control & Instrumentation Engineering, Korea University) ;
  • Kim, Doohyung (Korea Institute of Machinery and Materials)
  • Received : 2014.05.08
  • Accepted : 2014.07.04
  • Published : 2014.08.28

Abstract

Tendon driven robot mechanisms have many advantages such as allowing miniaturization and light-weight designs and/or enhancing flexibility in the design of structures. When designing or analyzing tendon driven mechanisms, it is important to determine how the tendons should be connected and whether the designed mechanism is easily controllable. Graph representation is useful to view and analyze such tendon driven mechanisms that are complicatedly interconnected between mechanical elements. In this paper, we propose a method of generalized graph representation that provides us with an intuitive analysis tool not only for tendon driven manipulators, but also various other kinds of mechanical systems which are combined with tendons. This method leads us to easily obtain structure matrix - which is the one of the most important steps in analyzing tendon driven mechanisms.

Keywords

References

  1. J.J. Lee, "Tendon-Driven Manipulators: Analysis, Synthesis, and Control", Ph.D. Thesis, University of Maryland, 1991.
  2. M. Gredenstein and P. van der Smagt, "Antagonism for a Highly Anthropomorphic Hand-Arm System", Advanced Robotics, 22, pp.39-55, 2008. https://doi.org/10.1163/156855308X291836
  3. P. Tuffield and H. Elias, "The Shadow robot mimics human actions", Industrial robot: an international journal, 2003
  4. A.M. Tahmasebi, B. Taati, F. Mobasser and K. Hashtrudi-Zaad, "Dynamic parameter identification and analysis of a PHANToM haptic device", Proc. IEEE Conf. on Control Applications, 1251-1256, 2005.
  5. B.-H. Kang, S.M. Yoon, M. C. Lee and C.-Y. Kim, "Development of low-inertia master device for haptic system configuration of surgical robot," Journal of Korea Robotics Society, 7, pp. 267-275, 2012. https://doi.org/10.7746/jkros.2012.7.4.267
  6. S.J. Ball, "Novel robotic mechanisms for upper-limb rehabilitation and assessment", Ph.D. Thesis, Queen's University, 2008.
  7. J.R. Steger, C.R. Gerbi, G.M. Prisco, and W. Rogers, "Curbed cannula instrument", US Patent 12/618, 608.
  8. V. Potkonjak, B. Svetozarevic, K. Jovanovic and O. Holland, "The Puller-Follower Control of Compliant and Noncompliant Antagonistic Tendon Drives in Robotic Systems", International Journal of Advanced Robotics Systems, 2011.
  9. H.-S. Yoon, J.Y. Choi, S.M. Oh, B.-J. Yi, H.S. Yoon, Y.-J Cho, "Implementation of a spring backboned soft arm emulating human gestures," Journal of Korea Robotics Society, 7, pp.65-75, 2012. https://doi.org/10.7746/jkros.2012.7.2.065
  10. M. Uyguroglu and H. Demirel, "Kinematic analysis of tendon-driven robotic mechanisms using oriented graphs", Acta Mechanica, 182, pp.265-277, 2006. https://doi.org/10.1007/s00707-005-0298-z
  11. B.G. Seo, Y. Choe, H. C. Roh and M. J. Chung, "Graph-based segmentation for scene understanding of an autonomous vehicle in urban environment," Journal of Korea Robotics Society, 9, pp.1-10, 2014. https://doi.org/10.7746/jkros.2014.9.1.001
  12. G. Golumn and W. Kahan, "Calculating the singular values and pseudo-inverse of a matrix", SIAM Numer. Anal., B2, pp.205-224, 1965.
  13. J. Lee, J. Kim, J. Lee, D.-H. Kim, H.-K. Lim, and S.-H. Ryu, "Inverse kinematics solution and optimal motion planning for industrial robots with redundancy," Journal of Korea Robotics Society, 7, pp.35-44, 2012. https://doi.org/10.7746/jkros.2012.7.1.035
  14. http://www.barrett.com/robot/DS_WAM.pdf

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