IMPEDANCE CONTROL OF A TELEOPERATED PNEUMATIC ACTUATOR: IMPLEMENTATION AND STABILITY ANALYSIS

Naghmeh Garmsiri,∗ Yuming Sun,∗ and Nariman Sepehri∗

References

1. [1] M. Tufail and C. De Silva, Haptic teleoperation usingimpedance control with application in homecare robotics,Control and Intelligent Systems, 41(3), 2013. DOI: 10.2316/Journal.201.2013.3.201-2509.
2. [2] M. Kontz, J. Beckwith, and W. Book, Evaluation of a tele-operated haptic forklift, IEEE/ASME Int. Conf. AdvancedIntelligent Mechatronics, Monterey, CA, 2005, 295–300.
3. [3] M. Maddahi, R.F.W. Rahman, and N. Sepehri, Effect ofnetwork quality on performance of bilateral teleoperated hy-draulic: A comparatice study, Control and Intelligent Systems,41(1), 2013, 11–25.
4. [4] Y. Zhu and E. Barth, Impedance control of a pneumaticactuator for contact tasks, IEEE Int. Conf. Robotics andAutomation, Barcelona, Spain, 2005, 987–992.
5. [5] P. Lawrence, S. Salcudean, N. Sepehri, D. Chan, S. Bachmann,N. Parker, M. Zhu, and R. Frenette, Coordinated and forcefeedback control of hydraulic excavators, Proc. Int. Symp. ofExperimental Robotics, Stanford, CA, 1995, 181–994.
6. [6] M. Le, M. Pham, M. Tavakoli, and R. Moreau, Sliding modecontrol of a pneumatic haptic teleoperation system with on/offsolenoid valves, IEEE Int. Conf. Robotics and Automation,Shanghai, China, 2011, 874–879.
7. [7] B. Hannaford, A design framework for teleoperators withkinesthetic feedback, IEEE Transactions on Robotics andAutomation, 5(4), 1989, 426–434.
8. [8] A. Leleve, M. Pham, M. Tavakoli, and R. Moreau, Towardsdelayed teleoperation with pneumatic master and slave forMRI, Proc. ASME Biennial Conf. Engineering Systems Designand Analysis, Nantes, France, 2012, 837–846.
9. [9] V. Durbha and P. Li, Passive bilateral teleoperation and humanpower amplification with pneumatic actuators, Proc. ASMEDynamic Systems and Control Conference, Hollywood, CA,2009, 1775–1782.
10. [10] V. Durbha and P. Li, Passive tele-operation of pneumatic pow-ered robotic rescue crawler, Proc. 6th FPNI-PhD Symposium,West Lafayette, 2010, 451–466.
11. [11] R. Richardson, Control and actuation for robotic physiotherapy,PhD, Dissertation, University of Leeds, UK, 2001.
12. [12] N. Yu, C. Hollnagel, A. Blickenstor, S. Kollias, and R. Riener,Comparison of MRI-compatible mechatronic systems with hy-drodynamic and pneumatic actuation, IEEE/ASME Transac-tions on Mecahtronics, 13(3), 2008, 268–277.
13. [13] H.G. Daepp and W.J. Book, Compliant position control of apneumatic system for human interaction applications, FluidPower Innovation & Research Conference, Chicago, 2015.
14. [14] D. Ben-Dov and S. Salcudean, A force-controlled pneumaticactuator, IEEE Transactions on Robotics and Automation,11(6), 1995, 906–911.
15. [15] H. Kazerooni, Design and analysis of pneumatic force genera-tors for mobile robotic systems, IEEE/ASME Transaction onMechatronics, 10(4), 2005, 411–418.
16. [16] J. Bobrow and F. Jabbari, Adaptive pneumatic force actuationand position control, Journal of Dynamic System, Measurementand Control, 113, 1991, 367–2723.
17. [17] E. Richer and Y. Hurmuzlu, A high performance pneumaticforce actuator system: Part II—nonlinear controller design,Journal of Dynamic Systems, Measurement and Control,122(3), 2000, 426–434.
18. [18] H. Aschemann and D. Schindele, Sliding-mode control of ahigh-speed linear axis driven by pneumatic muscle actuators,IEEE Transaction on Industrial Electronics, 55(11), 2008,3855–3864.
19. [19] X. Shen and M. Goldfarb, Independent stiffness and forcecontrol of pneumatic actuators for contact stability duringrobot manipulation, Proc. 2005 IEEE Int. Conf. Robotics andAutomation, Barcelona, Spain, 2005, 2697–2702.
20. [20] R.J. Anderson, Bilateral control of teleoperators with timedelay, IEEE Transactions on Automatic Control, 34, 1989,494–501.
21. [21] F. Gao and Y. Wu, Global finite-time stabilization for a classof high-order time-varying non-linear systems with unknowncontrol coefficients, Control and Intelligent Systems, 43(3),2015. DOI: 10.2316/Journal.201.2015.3.201-2687
22. [22] J. Zhao, H. Pu, Y. Sun, S. Ma, Y. Shen, J. Luo, andZ. Gong, Stability analysis and gait planning of a quadrupedrobot based on the eccentric paddle mechanism, Control and in-telligent Systems, 42(4), 2014. DOI: 10.2316/Journal.201.2015.3.201-2687, 2014.
23. [23] M. Lyapunov, The general problem of the stability of motion(In Russian) University of Kharkov, Ph.D. Dissertation, 1892.
24. [24] C. Yang and C. Wu, On stabilization of bipedal robots duringdisturbed standing using the concept of Lyapunov exponents,Robotica, 24, (5), 2006, 621–624.
25. [25] P. Sekhavat, N. Sepehri, and C. Wu, Overall stability analysis ofhydraulic actuator’s switching contact control using the conceptof Lyapunov exponents, Int. Conf. Robotics and Automation,Barcelona, Spain, 2005, 550–556.
26. [26] N. Hogan, Impedance control: An approach to manipula-tion, Jounal of Dynamic Systems, Measurement, and Control,107(1), 1985, 1–24.
27. [27] S. Sadri and C. Wu, Stability analysis of a nonlinear vehi-cle model in plane motion using the concept of Lyapunovexponents, International Journal of Vehicle Mechanics andMobility, 51(6), 2013, 906–924.
28. [28] A. Wolf, J. Swift, H. Swinney, and J. Vastano, DeterminingLyapunov exponents from a time series, Journal of Physica,16(4), 1985, 285–317.
29. [29] V. Oseledec, A multiplicative ergodic theorem: Lyapunovcharacteristic numbers for dynamical system, TransactionofMoscow Math Society, 19, 1968, 197–231.
30. [30] D. Canudas, H. Olsson, K. Astrom, and P. Lischinsky, A newmodel for control of systems with friction, IEEE Transactionof Automation and Control, 40(3), 1995, 419–425.
31. [31] S. Liu and J. Bobrow, An analysis of a pneumatic servosystem, Transaction of ASME Journals on Dynamic SystemsMeasurment and Control, 110, 1988, 228–235.
32. [32] F. Sanville, A new method of specifying the flow capacity ofpneumatic fluid power valves, BHRA 2nd Int. Fluid PowerSymposium, Guildford, England, 1971, 37–47.
33. [33] M. Karpenko and N. Sepehri, Development and experimentalevaluation of a fixed-gain nonlinear control for a low-costpneumatic actuator, IEE Proc. Control Theory Applications,2006, 629–640.
34. [34] L. He, Dynamical adaptive backstepping-sliding mode controlof pneumatic actuator, University of Manitoba, M.Sc. Thesis,2010.
35. [35] R.A. Rahman, L. He, and N. Sepehri, Design and experimentalstudy of a dynamical adaptive backstepping-sliding mode con-trol scheme for position tracking and regulating of a low-costpneumatic cylinder, International Journal of Robust and Non-linear Control, 26(4), 2015, 853–875, Wiley Online Library,doi: 10.1002/rnc.3341, 2015.
36. [36] A. Filippov, Differential equations with discontinuous right-hand sides, Math Sbornnik, vol. 51, 1960, 99–128.
37. [37] A. Filippov, Differential equations with discontinuous right-hand sides (Dordrecht: Kluwer Academic Publishers, 1988).

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• DOI: 10.2316/Journal.201.2017.1.201-2766
• From Journal (201) Mechatronic Systems and Control - 2017

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