Abstract
This paper presents bimanual haptic teleoperation system with implemented haptic tunnel for optimized task performance. The teleoperation system includes two industrial robots as slaves and two haptic robots as masters. The bimanual control is based on impedance control with included adaptive haptic tunnel. Task is performed in relative coordinates where base of the robot is set at end effector of one slave robot while the position of second slave robot is defined relatively to the new base. Haptic tunnel is defined with (a) reference trajectory obtained with initial task execution and described with Gaussian radial basis functions, (b) adaptive radius of the tunnel based on error between reference and traveled trajectory and percentage of the contact with the haptic tunnel. After each task execution the performance is evaluated following by proper adaptation of haptic tunnel. Developed algorithm was tested with a simple assembly task of inserting car bulb into its base.
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References
Sheridan, T.B.: Teleoperation, telerobotics and telepresence: a progress report. Control Eng. Pract. 3(2), 205–214 (1995)
Sheridan, T.B.: Space teleoperation through time delay: review and prognosis. IEEE Trans. Robot. Autom. 9(5), 592–606 (1993)
Vertut, J. (ed.): Teleoperation and Robotics: Applications and Technology. Springer, Netherlands (1985)
Iida, W., Ohnishi, K.: Reproducibility and operationality in bilateral teleoperation. In: The 8th IEEE International Workshop on Advanced Motion Control, 2004, AMC 2004, pp. 217–222 (2004)
Argall, B., Chernova, S., Veloso, M.M., Browning, B.: A survey of robot learning from demonstration. Robot. Auton. Syst. 57, 469–483 (2009)
Calinon, S., Guenter, F., Billard, A.: On Learning, representing, and generalizing a task in a humanoid robot. IEEE Trans. Syst. Man Cybern. Part B (Cybernetics) 37(2), 286–298 (2007)
Billard, A., Calinon, S., Dillmann, R., Schaal, S.: Robot programming by demonstration. In: Siciliano, B., Khatib, O., (eds.) Springer Handbook of Robotics, pp. 1371–1394. Springer Heidelberg (2008)
Buss, M., Schmidt, G.: Control problems in multi-modal telepresence systems. In: Advances in Control, London, pp. 65–101 (1999)
Mihelj, M., Šlajpah, S., Čepon, P., Munih, M.: yControl - open architecture controller for Yaskawa Motoman MH5 robot. In: 2012 IEEE International Conference on Control Applications, 2012, pp. 1051–1056 (2012)
Mihelj, M., et al.: Robot control. In: Robotics, pp. 133–152. Springer, Cham (2019)
Nemec, B., Ude, A.: Action sequencing using dynamic movement primitives. Robotica 30(5), 837–846 (2012)
Nemec, B., Žlajpah, L., Ude, A., Šlajpah, S., Piškur, J.: An efficient PbB framework for fast deployment of bi-manual assembly tasks. In: IEEE-RAS 18th International Conference on Humanoid Robots, Beijing, China, vol. 2018, pp. 166–173 (2018)
Acknowledgements
The work reported in this paper was supported by project No. J2-7360 supported by Slovenian Research Agency (research core funding No. P2-0228).
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Piškur, J., Šlajpah, S., Nemec, B., Mihelj, M., Munih, M. (2020). Use of Bimanual Haptic Teleoperation System for Optimized Task Performance with Adaptive Haptic Tunnel. In: Berns, K., Görges, D. (eds) Advances in Service and Industrial Robotics. RAAD 2019. Advances in Intelligent Systems and Computing, vol 980. Springer, Cham. https://doi.org/10.1007/978-3-030-19648-6_38
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DOI: https://doi.org/10.1007/978-3-030-19648-6_38
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