Design of a Fuzzy Fractional Order Adaptive Impedance Controller with Integer Order Approximation for Stable Robotic Contact Force Tracking in Uncertain Environment

Hongli Cao

doi:10.2478/ama-2022-0003

Abstract

Current research in robot compliance control is unable to take both transient contact force overshoots and steady-state force tracking problems into account. To address this problem, we propose a fuzzy fractional order (FO) adaptive impedance controller to avoid the force overshoots in the contact stage while keeping force error in the dynamic tracking stage, where traditional control algorithms are not competent. A percentage gain is adopted to map FO parameters to integer order (IO) parameters by their natural properties, and a fuzzy logical controller is introduced to improve the system stability. The simulation results indicate that the proposed controller can be made more stable than and superior to the general impedance controller, and the force tracking results also have been compared with the previous control methods.

References

1. Liang L, Chen Y, Liao L, Sun H, Liu YJR, Manufacturing C-I. A novel impedance control method of rubber unstacking robot dealing with unpredictable and time-variable adhesion force. 2021;67:102038.10.1016/j.rcim.2020.102038
Search in Google Scholar Back to article
2. Cao H, He Y, Chen X, Zhao XJIRtijorr, application. Smooth adaptive hybrid impedance control for robotic contact force tracking in dynamic environments. 2020.10.1108/IR-09-2019-0191
Search in Google Scholar Back to article
3. Mokhtari M, Taghizadeh M, Mazare MJR. Hybrid adaptive robust control based on CPG and ZMP for a lower limb exoskeleton. 2021;39(2):181-99.10.1017/S0263574720000260
Search in Google Scholar Back to article
4. Dong Y, Ren T, Wu D, Chen KJJoI, Systems R. Compliance control for robot manipulation in contact with a varied environment based on a new joint torque controller. 2020;99(1):79-90.10.1007/s10846-019-01109-8
Search in Google Scholar Back to article
5. Raibert MH, Craig JJ. Hybrid position/force control of manipulators. 1981.10.1115/1.3139652
Search in Google Scholar Back to article
6. Mason MTJIToS, Man,, Cybernetics. Compliance and force control for computer controlled manipulators. 1981;11(6):418-32.10.1109/TSMC.1981.4308708
Search in Google Scholar Back to article
7. Hogan N. Impedance control: An approach to manipulation: Part I—Theory. 1985.10.23919/ACC.1984.4788393
Search in Google Scholar Back to article
8. Komati B, Pac MR, Ranatunga I, Clévy C, Popa DO, Lutz P, editors. Explicit force control vs impedance control for micromanipulation. International Design Engineering Technical Conferences and Computers and Information in Engineering Conference; 2013: American Society of Mechanical Engineers.10.1115/DETC2013-13067
Search in Google Scholar Back to article
9. Wu J, Ni F, Zhang Y, Fan S, Zhang Q, Lu J, et al. Smooth transition adaptive hybrid impedance control for connector assembly. 2018.10.1108/IR-11-2017-0193
Search in Google Scholar Back to article
10. Akdoğan E, Aktan ME, Koru AT, Arslan MS, Atlıhan M, Kuran BJM. Hybrid impedance control of a robot manipulator for wrist and forearm rehabilitation: Performance analysis and clinical results. 2018;49:77-91.10.1016/j.mechatronics.2017.12.001
Search in Google Scholar Back to article
11. Jung S, Hsia TC, Bonitz RGJIToCST. Force tracking impedance control of robot manipulators under unknown environment. 2004;12(3):474-83.10.1109/TCST.2004.824320
Search in Google Scholar Back to article
12. Duan J, Gan Y, Chen M, Dai XJR, Systems A. Adaptive variable impedance control for dynamic contact force tracking in uncertain environment. 2018;102:54-65.10.1016/j.robot.2018.01.009
Search in Google Scholar Back to article
13. Solanes JE, Gracia L, Muñoz-Benavent P, Esparza A, Miro JV, Tornero JJR, et al. Adaptive robust control and admittance control for contact-driven robotic surface conditioning. 2018;54:115-32.10.1016/j.rcim.2018.05.003
Search in Google Scholar Back to article
14. Lu Z, Goldenberg AAJTIjorr. Robust impedance control and force regulation: Theory and experiments. 1995;14(3):225-54.10.1177/027836499501400303
Search in Google Scholar Back to article
15. Fateh MM, Khorashadizadeh SJND. Robust control of electrically driven robots by adaptive fuzzy estimation of uncertainty. 2012;69(3):1465-77.10.1007/s11071-012-0362-x
Search in Google Scholar Back to article
16. Li Y, Ge SS, Zhang Q, Lee THJICT, Applications. Neural networks impedance control of robots interacting with environments. 2013;7(11):1509-19.10.1049/iet-cta.2012.1032
Search in Google Scholar Back to article
17. Cao H, Chen X, He Y, Zhao XJIA. Dynamic adaptive hybrid impedance control for dynamic contact force tracking in uncertain environments. 2019;7:83162-74.10.1109/ACCESS.2019.2924696
Search in Google Scholar Back to article
18. Xu WJJoDS, Measurement,, Control. Robotic time-varying force tracking in position-based impedance control. 2016;138(9):091008.10.1115/1.4033409
Search in Google Scholar Back to article
19. Sheng X, Zhang XJM. Fuzzy adaptive hybrid impedance control for mirror milling system. 2018;53:20-7.10.1016/j.mechatronics.2018.05.008
Search in Google Scholar Back to article
20. Zhou Q, Li H, Shi PJIToFS. Decentralized adaptive fuzzy tracking control for robot finger dynamics. 2014;23(3):501-10.10.1109/TFUZZ.2014.2315661
Search in Google Scholar Back to article
21. Nikdel N, Badamchizadeh M, Azimirad V, Nazari MAJIToIE. Fractional-order adaptive backstepping control of robotic manipulators in the presence of model uncertainties and external disturbances. 2016;63(10):6249-56.10.1109/TIE.2016.2577624
Search in Google Scholar Back to article
22. Zhong J, Li LJItocst. Tuning Fractional-Order ${PI}^{\lambda}{D}^{\mu} $ Controllers for a Solid-Core Magnetic Bearing System. 2015;23(4):1648-56.10.1109/TCST.2014.2382642
Search in Google Scholar Back to article
23. Padula F, Visioli AJICT, Applications. Optimal tuning rules for proportional-integral-derivative and fractional-order proportional-integral-derivative controllers for integral and unstable processes. 2012;6(6):776-86.10.1049/iet-cta.2011.0419
Search in Google Scholar Back to article
24. Aguila-Camacho N, Duarte-Mermoud MAJIt. Fractional adaptive control for an automatic voltage regulator. 2013;52(6):807-15.10.1016/j.isatra.2013.06.005
Search in Google Scholar Back to article
25. Shahri ESA, Alfi A, Machado JTJASC. Fractional fixed-structure H∞ controller design using augmented lagrangian particle swarm optimization with fractional order velocity. 2019;77:688-95.10.1016/j.asoc.2019.01.037
Search in Google Scholar Back to article
26. Haji VH, Monje CAJAsc. Fractional order fuzzy-PID control of a combined cycle power plant using Particle Swarm Optimization algorithm with an improved dynamic parameters selection. 2017;58:256-64.10.1016/j.asoc.2017.04.033
Search in Google Scholar Back to article
27. Efe MÖJIToII. Fractional order systems in industrial automation—a survey. 2011;7(4):582-91.10.1109/TII.2011.2166775
Search in Google Scholar Back to article
28. Ahmed S, Wang H, Tian YJAJoC. Robust adaptive fractional-order terminal sliding mode control for lower-limb exoskeleton. 2019;21(1):473-82.10.1002/asjc.1964
Search in Google Scholar Back to article
29. Efe MÖJTotIoM, Control. Integral sliding mode control of a quadrotor with fractional order reaching dynamics. 2011;33(8):985-1003.10.1177/0142331210377227
Search in Google Scholar Back to article
30. Feliu-Talegon D, Feliu-Batlle V, Tejado I, Vinagre BM, HosseinNia SHJIt. Stable force control and contact transition of a single link flexible robot using a fractional-order controller. 2019;89:139-57.10.1016/j.isatra.2018.12.031
Search in Google Scholar Back to article
31. Muñoz-Vázquez AJ, Gaxiola F, Martínez-Reyes F, Manzo-Martínez AJAsc. A fuzzy fractional-order control of robotic manipulators with PID error manifolds. 2019;83:105646.10.1016/j.asoc.2019.105646
Search in Google Scholar Back to article
32. Oustaloup A, Levron F, Mathieu B, Nanot FMJIToC, Theory SIF, Applications. Frequency-band complex noninteger differentiator: characterization and synthesis. 2000;47(1):25-39.10.1109/81.817385
Search in Google Scholar Back to article
33. Wang Y, Luo G, Gu L, Li XJJoV, Control. Fractional-order nonsingular terminal sliding mode control of hydraulic manipulators using time delay estimation. 2016;22(19):3998-4011.10.1177/1077546315569518
Search in Google Scholar Back to article

Design of a Fuzzy Fractional Order Adaptive Impedance Controller with Integer Order Approximation for Stable Robotic Contact Force Tracking in Uncertain Environment

Abstract

Paradigm

My account