HIGH IMPEDANCE ACTUATOR FUSION: A NEW CONCEPT FOR A HAPTIC SYSTEM

Niphon Lapanaphan and Erik L.J. Bohez

References

  1. [1] C.W. Chesney, Implementation of planar hybrid active/passive force-feedback user input device, Doctoral Dissertation, University of Florida, 2002.
  2. [2] P.A. Millman, Haptic perception of localized features, Doctoral Dissertation, Department of Mechanical Engineering, North-western University, 1995.
  3. [3] B. Davies, A review of robotics in surgery, Proceedings of the Institution of Mechanical Engineers, Part H: Journal of Engineering in Medicine, 214(1), 2000, 129–140.
  4. [4] I. Elhajj, et al., Haptic information in Internet-based teleoperation, IEEE/ASME Transactions on Mechatronics, 6(3), 2001, 295–304.
  5. [5] S. Mammar, J. Sainte-Marie, and S. Glaser, On the use of steer-by-wire systems in lateral driving assistance applications, Proc. 10th IEEE International Workshop on Robot and Human Interactive Communication, 2001, 487–492.
  6. [6] E.P. Scilingo, et al., A magnetorheological fluid as a haptic display to replicate perceived biological tissues compliance, 1st Annual International Conf. on Microtechnologies in Medicine and Biology, 2000, 229–233.
  7. [7] K.I. Koyanagi, T. Inoue, and J. Furusho, Rehabilitation application of force display system using ER fluid, International Conf. on Motion and Vibration Control, 6(3), 2002, 831–836.
  8. [8] T. Yoshikawa, Y. Yokokohji, T. Matsumoto, and X.-Z. Zheng, Display of feel for the manipulation of dynamic virtual objects, Trans. ASME, Journal of Dynamic Systems, Measurement, and Control, 117(4), 1995, 554–558.
  9. [9] V. Hayward, et al., Design and multi-objective optimization of a linkage for a haptic interface, Advances in Robot Kinematics, 1994, 352–359.
  10. [10] T.H. Massie and J.K. Salisbury, The phantom haptic interface: A device for probing virtual objects, Proc. of the ASME Winter Annual Meeting, Symposium on Haptic Interfaces for Virtual Environment and Teleoperator Systems, 55(1), November 1994, 295–300.
  11. [11] R.J. Adams and B. Hannaford, Stable haptic interaction with virtual environments, IEEE Transactions on Robotics and Automation, 15(3), 1999, 465–474.
  12. [12] Y. Yokokohji, R.L. Hollis, and T. Kanade, What you can see is what you can feel-development of a visual/haptic interface to virtual environment, Proc. of the IEEE Virtual Reality Annual International Symposium, 1996, 46–53.
  13. [13] E.L. Faulring, et al., Haptic display of constrained dynamic systems via admittance displays, IEEE Transactions on Robotics, 23(1), 2007, 101–111.
  14. [14] D.K. Swanson, Implementation of arbitrary path constraints using dissipative passive haptic displays, Doctoral Dissertation, Georgia Institute of Technology, 2003.
  15. [15] M. Bergamasco, et al., An arm exoskeleton system for teleoperation and virtual environments applications, Proc. IEEE International Conf. on Robotics and Automation, 1994, 1449–1454.
  16. [16] M.A. Peshkin, et al., Cobot architecture, IEEE Transactions on Robotics and Automation, 17(4), 2001, 377–390.
  17. [17] A.D. Poole and J.D. Booker, Design methodology and case studies in actuator selection, Mechanism and Machine Theory, 46(5), 2011, 647–661
  18. [18] Y. Hirata, T. Isoda, and K. Kosuge, Development of passive wearable walking helper controlled by servo brake, International Journal of Mechatronics and Manufacturing Systems, 3(3), 2010, 291–306.
  19. [19] A. Gosline, G. Campion, and V. Hayward, On the use of Eddy current brakes as tunable, fast turn-on viscous dampers for haptic rendering, Proc. of Euro-Haptics, 2006, 229–234.
  20. [20] E. Simeu and D. Georges, Modeling and control of an Eddy current brake, Control Engineering Practice, 4(1), 1996, 19–26.
  21. [21] J.H. Wouterse, Critical torque of Eddy current brake with widely separated soft iron poles, IEE Proc., 138(4), 1991.
  22. [22] Placid Industries Inc., http://www.placidindustries.com, 2008.
  23. [23] J.J. Gil, A. Avello, A. Rubio, and J. Fl´orez, Stability analysis of a 1 DOF haptic interface using the Routh–Hurwitz criterion, IEEE Transactions on Control Systems Technology, 12(4), 2004, 583–588.
  24. [24] N. Hogan, Controlling impedance at the man/machine, Proc. IEEE International Conf. on Robotics and Automation, 1989, 1626–1631.
  25. [25] J.J. Gil, et al., Stability boundary for haptic rendering: Influence of damping and delay, Journal of Computing and Information Science in Engineering, 9(1), 2009, 011005.
  26. [26] J.E. Colgate and G.G. Schenkel, Passivity of a class of sampled-data systems: Application to haptic interfaces, Journal of Robotic Systems, 14(1), 1997, 37–47.
  27. [27] N. Diolaiti, G. Niemeyer, F. Barbagli, and J.K.J. Salisbury, Stability of haptic rendering: Discretization, quantization, time delay, and Coulomb effects, IEEE Transactions on Robotics, 22(2), 2006, 256–268.
  28. [28] R.J. Adams and B. Hannaford, Stable haptic interaction with virtual environments, IEEE Transactions on Robotics and Automation, 15(3), 1999, 465–474.
  29. [29] K.C. Walker and D.W. Wang, Analytical modelling of deformable objects for haptics virtual environments, International Journal of Robotics and Automation, 27(1), 2012, 92.
  30. [30] C.H. Ho, C. Basdogan, and M.A. Srinivasan, Efficient point-based rendering techniques for haptic display of virtual objects, Presence: Teleoperators and Virtual Environments, 8(5), 1999, 477–491.
  31. [31] M. Bordegoni and U. Cugini, Haptic modeling in the conceptual phases of product design, Virtual Reality, 9(2–3), 2006, 192–202.
  32. [32] J. An and D.S. Kwon, Stability and performance of haptic interfaces with active/passive actuators – theory and experiments, The International Journal of Robotics Research, 25(11), 2006, 1121–1136.
  33. [33] T.B. Kwon and J.B. Song, Force display using a hybrid haptic device composed of motors and brakes, Mechatronics, 16, 2006, 249–257.
  34. [34] F. Conti and O. Khatib, A new actuation approach for haptic interface design, The International Journal of Robotics Research, 28, 2009, 834–848.
  35. [35] B. Chebbi, D. Lazaroff, and P.X. Liu, A collaborative virtual haptic environment for surgical training and tele-mentoring, International Journal of Robotics and Automation, 22(1), 2007, 69–78.
  36. [36] Z. Visram, A haptics approach to evidence based learning, World Conf. on E-Learning in Corporate, Government, Health-care, and Higher Education, 2005(1), 1776–1784.
  37. [37] L. Zhong, M.F. Rahman, W.Y. Hu, K.W. Lim, and M.A. Rahman, A direct torque controller for permanent magnet synchronous motor drives, IEEE Transactions on Energy Conversion, 14(3), 1999, 637–642.
  38. [38] M.R. Reed, Development of an improved dissipative passive haptic display, Doctoral Dissertation, Georgia Institute of Technology, GA, 2003.
  39. [39] K. Ogata, Modern control engineering (Englewood Cliffs, NJ: Prentice-Hall, 1970).
  40. [40] C.-T. Chen, Analysis and synthesis of linear control systems, 4th ed. (Stony Brook, NY: Pond Woods Press, 1978).
  41. [41] C. Richard and M.R. Cutkosky, Friction modeling and display in haptic applications involving user performance, Proc. IEEE International Conf. Robotics and Automation, Vol. 1, 2002, 605–611.

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