Abstract
Conventional virtual coupling is designed mainly for stabilizing the virtual environment (VE) and it thus may have poor performances. This paper proposes a novel adaptive virtual coupling design approach for haptic display in passive or time-delayed non-passive virtual environment. According to the performance errors, the virtual coupling can be adaptively tuned through some fuzzy logic based law. The designed haptic controller can improve the “operating feel” in virtual environments, while the system’s stability condition can still be satisfied. Experimental results demonstrate the effectiveness of this novel virtual coupling design approach.
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Mandayam, A.S., Basdogan, C.: Haptics in VE: Taxonomy, Research Status, and Challenges. Computers and Graphics 21, 393–404 (1997)
Hannaford, B.: A Design Framework for Teleoperators with Kinesthetic Feedback. IEEE J. Robot. Automat. 5, 426–434 (1989)
Li, Y.F., Bi, D.: A Method for Dynamics Identification for Haptic Display of the Operating Feel in Virtual Environments. IEEE Transaction on Mechatronics 8, 1–7 (2003)
Minsky, M., Ouh, Y.M., Steele, O., Brooks, F.P., Behensky, M.: Feeling and Seeing Issues in Force Display. Computer Graphics 24, 235–243 (1990)
Colgate, J.E., Grafing, P.E., Stanely, M.C., Schenkel, G.: Implementation of Stiff Virtual Walls in Force Reflecting Interface. In: Proceeding of IEEE Virtual Reality Annual International Symptom, Seattle, WA, pp. 202–208 (1993)
Colgate, J.E., Brown, J.M.: Factors Affecting the Z-Width of a Haptic Display. In: Proceeding of IEEE International Conference on Robot and Automation, Los Alamitos, CA, pp. 3205–3210 (1994)
Zilles, C.B., Salisbury, J.K.: A Constraint-Based God-Object Method for Haptic Display. In: Proceeding of IEEE International Conference on Intelligent Robot system, Pittsburgh, PA, pp. 146–151 (1995)
Adams, R.J., Hannaford, B.: Control Law Design for Haptic Interfaces to Virtual Reality. IEEE Transaction on Control System Technology 10, 3–13 (2002)
Miller, B.E., Colgate, J.E., Freeman, R.A.: Guaranteed Stability of Haptic Systems with Nonlinear Virtual Environments. IEEE Transaction on Robotics and Automation 16, 712–719 (2000)
Hannaford, B., Ryu, J.H.: Time-Domain Passivity Control of Haptic Interfaces. IEEE Transaction on Robotics and Automation 18, 1–10 (2002)
Visioli, A.: Fuzzy Logic Based Set-Point Weighting for PID Controllers. IEEE Transactions on System, Man, Cybernatics, Part a 29, 587–592 (1999)
Visioli, A.: Tuning of PID Controllers with Fuzzy Logic. IEE Proceedings-Control Theory Application 148, 1–8 (1998)
Misir, D., Maliki, H.A., Chen, G.: Design and Analysis of a Fuzzy PID Controller. International Journal of Fuzzy Set System 79, 73–93 (1998)
Anderson, R.J., Spong, M.W.: Asymptotic Stability for Force Reflecting Teleoperators with Time Delay. Int. J. Robot. Res. 11, 135–149 (1992)
Schaft, A.V.D.: L2-Gain and Passivity Techniques in Nonlinear Control. Springer, London (2000)
Cavusoglu, M.C., Tendick, F.: Multirate Simulation for High Fidelity Haptic Interaction with Deformable Objects in Virtual Environments. In: Proceedings of the IEEE International Conference on Robotics and Automation (ICRA 2000), San Francisco, CA, pp. 2458–2465 (2000)
Margaret, L.M., Hespanha, J.P., Sukhatme, G.S.: Touch in Virtual Environments: Haptics and the Design of Interactive Systems. Prentice-Hall, Englewood Cliffs (2002)
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© 2005 Springer-Verlag Berlin Heidelberg
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Bi, D., Zhang, J., Wang, G.L. (2005). Fuzzy Virtual Coupling Design for High Performance Haptic Display. In: Wang, L., Jin, Y. (eds) Fuzzy Systems and Knowledge Discovery. FSKD 2005. Lecture Notes in Computer Science(), vol 3613. Springer, Berlin, Heidelberg. https://doi.org/10.1007/11539506_117
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DOI: https://doi.org/10.1007/11539506_117
Publisher Name: Springer, Berlin, Heidelberg
Print ISBN: 978-3-540-28312-6
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