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Abstract

One of the prevalent methods in linear bilateral teleoperation systems with communication channel time delays is using position and velocity signals in the control scheme. Utilization of force signals in such controllers improves the performance significantly and reduces the tracking error. Measuring force signals in such cases is one of the major problems. In this paper, a control scheme in the presence of human and environment force signals for the linear bilateral teleoperation is proposed. Due to elimination of measuring forces in the control scheme, a force estimation approach based on disturbance observers has been utilized. The proposed approach guarantees asymptotic estimation of constant forces. The estimation error would only be bounded for time varying external forces. To cope with the variation of the human and environment force, a sliding-mode-controller is used. The stability and transparency condition in the teleoperation system with the designed control scheme is derived from absolute stability concept. The designed control scheme guarantees the stability of the teleoperation system in the presence of time varying human and environment forces. Experimental results show that the proposed control scheme improves position tracking in the free motion and in contact with the environment. In addition, the force estimation approach appropriately estimates human and environment forces.

Keywords

Estimation mechatronics robotics sliding-mode control teleoperation

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References

Ahn

(2010) Synchronization of teleoperation systems using state and force observer. International Conference on Control, Automation and Systems, Gyeonggi-do.

Chen

Ballance

Gawthrop

. (2000) A nonlinear disturbance observer for robotic manipulator. IEEE Transactions on Industrial Electronics 47: 932–938.

Cho

Park

(2005) Stable bilateral teleoperation under a time delay using a robust impedance control. Mechatronics 15: 611–625.

Cho

Park

Kim

. (2001) Sliding-model-based impedance controller for bilateral teleoperation under varying time-delay. Proceedings of the IEEE International Conference on Robotics and Automation, Seoul.

Colgate

Brown

(1994) Factors affecting the Z-width of a haptic display. Proceedings of the IEEE International Conference on Robotics and Automation, San Diego, CA.

Daly

Wang

DWL

(2009) Bilateral teleoperation using unknown input observers for force estimation. Proceeding of the American Control Conference, St. Louis, MO.

Daly

Wang

DWL

(2010) Time-delayed bilateral teleoperation with force estimation for n-DOF nonlinear robot manipulator. The IEEE/RSJ International Conference on Intelligent Control and Systems, Taipei.

Hashtrudi-Zaad

Salcudean

(2001) Analysis of control architectures for teleoperation systems with impedance/ admittance master and slave manipulators. The International Journal of Robotics Research 20: 419–445.

Haykin

(1970) Active Network Theory. Reading, MA: Addison-Wesley.

10.

Hua

Yang

(2011) Transparency performance improvement for bilateral teleoperation with direct force-feedback control. IEEE International Symposium on Haptic Audio-Visual Environments and Games, Qinhuangdao, Hebei.

11.

Imaida

Yokokohji

Doi

. (2004) Groundspace bilateral teleoperation of ETS-VII robot arm by direct bilateral coupling. IEEE Transaction on Robotics and Automation 20: 499–511.

12.

Ishii

Katsura

(2012) Bilateral control with local force feedback for delay-free teleoperation. 12th IEEE International Workshop on Advanced Motion Control, Sarajevo.

13.

Jafari

Rezaei

Shiry Ghidary

. (2012) A stable perturbation estimator in force-reflecting passivity-based teleoperation. Transactions of the Institute of Measurement and Control 34: 1–10.

14.

Khalil

(2002) Nonlinear Systems, 3rd ed. Englewood Cliffs, NJ: Prentice Hall.

15.

Lawrence

(1993) Stability and transparency in bilateral teleoperation. IEEE Transaction on Robotics and Automation 9: 624–637.

16.

Lee

Spong

(2006) Passive bilateral teleoperation with constant time delay. IEEE Transactions on Robotics 22: 269–281.

17.

Lichiardopol

van

Wouw

Kosti’c

. (2010) Trajectory tracking control for a tele-operation setup with disturbance estimation and compensation. 49th IEEE Conference on Decision and Control, Atlanta, GA.

18.

Goldenberg

(1995) A. Robust impedance control and force regulation: theory and experiments. The International Journal of Robotics Reasearch 14: 225–253.

19.

Mohammadi

Marquez

Tavakoli

(2011a) Disturbance observer-based trajectory following control of nonlinear robotic manipulators. Proceedings of the 23rd Canadian Congress of Applied Mechanics, Vancouver, BC.

20.

Mohammadi

Tavakoli

Marquez

(2011b) Disturbance observer-based control of nonlinear haptic teleoperation systems. IET Control Theory and Applications 5: 2063–2074.

21.

Nuno

Ortega

Barabanov

. (2008) A globally stable PD controller for bilateral teleoperators. IEEE Transactions on Robotics 24: 753–758.

22.

Preusche

Ortmaier

Hirzinger

(2002) Teleoperation concepts in minimal invasive surgery. Control Engineering Practice 10: 1245–1250.

23.

Zareinejad

Rezaei

Abdullah

. (2009) Development of a piezo-actuated micro-teleoperation system for cell manipulation. International Journal of Medical Robotics and Computer Assisted Surgery 5: 66–76.

Enhanced time delayed linear bilateral teleoperation system by external force estimation

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