ADAPTIVE SLIDING MODE ADRC FOR ATTITUDE TRACKING WITH ACTUATOR SATURATION AND UNCERTAINTIES

Chunhua Cheng,∗ Lin Li,∗ Qiang Han,∗ Haiyang Ma,∗ Chaoyong Wang,∗ and Simin Bi∗

References

  1. [1] C.C. Kung, Nonlinear H8robust control applied to F-16 aircraft with mass uncertainty using control surface inverse algorithm, Journal of the Franklin Institute, 345(8), 2008, 851–876.
  2. [2] W. Cai, X. Liao, and D.Y. Song, Indirect robust adaptive fault -tolerant control for attitude tracking of spacecraft, Journal of Guidance, Control, and Dynamics, 31(5), 2008, 1456–1463.
  3. [3] Z. Zhu, Y. Xia, and M. Fu, Adaptive sliding mode control for attitude stabilization with actuator saturation, IEEE Transactions on Industrial Electronics, 58(10), 2011, 4898–4907.
  4. [4] B. Guo and Y. Chen, Adaptive fast sliding mode fault tolerant control integrated with disturbance observer for spacecraft attitude stabilization system, Isa Transactions, 94, 2019, 1–9.
  5. [5] C. Pukdeboon, A.S.I. Zinober, and M.W.L. Thein, Quasicontinuous higher order sliding-mode controllers for spacecraftattitude-tracking maneuvers, IEEE Transactions on Industrial Electronics, 57(4), 2010, 1436–1444.
  6. [6] P.M. Tiwari, S. Janardhanan, and M. un-Nabi, Spacecraft antiunwinding attitude control using second-order sliding mode, Asian Journal of Control, 20(1), 2017, 455–468.
  7. [7] Z. Wang and Y. Li, Rigid spacecraft robust optimal attitude stabilization under actuator misalignment, Aerospace Science and Technology, 105, 2020, 105990.
  8. [8] C. Pukdeboon, Inverse optimal attitude stabilization of flexible spacecraft with actuator saturation, International Journal of Aerospace Engineering, 2016, 2016, 1–14.
  9. [9] C. Pukdeboon, Inverse optimal sliding mode control of spacecraft with coupled translation and attitude dynamics, International Journal of Systems Science, 46(13), 2015, 2421–2438.
  10. [10] C. Cheng, Y. Di, J. Xu, and T. Yuan, Advanced backstepping control based on ADR for non-affine non-strict feedback nonlinear systems, Automatika, 59(2), 2018, 220–230.
  11. [11] C.H. Cheng, Y. Hu, and J. Wu, Auto disturbance controller of non-affine nonlinear pure feedback systems, Acta Automatica Sinica, 40(7), 2014, 1528–1536.
  12. [12] C.H. Cheng, Y. Hu, and J. Wu, Auto disturbance rejection controller for non-affine nonlinear systems with adaptive observers, Control Theory & Applications, 31(2), 2014, 148–158.
  13. [13] C. Cheng, Y. Hu, J. Wu, and Z. Xiao, Track control of system with uncertainty and non-affine input, Systems Engnineering and Electronics, 36(2), 2014, 354–360. 342
  14. [14] X. Zhicai and C. Chunhua, Control of nonlinear systems with unmeasured dynamic uncertainties, Systems Engnineering and Electronics, 38(4), 2016, 909–914.
  15. [15] C. Huang, C. Luo, Y. Li, and T. Zhang, Differential flatness active disturbance rejection control approach for a class of nonlinear uncertain systems, International Journal of Robotics & Automation, 34(2), 2019, 146–155.
  16. [16] J.D. Boskovic, S.-M. Li, and R.K. Mehra, Robust adaptive variable structure control of spacecraft under control input saturation, Journal of Guidance, Control, and Dynamics, 24(1), 2001, 14–22.
  17. [17] J.D. Boskovic, S.-M. Li, and R.K. Mehra, Robust tracking control design for spacecraft under control input saturation, Journal of Guidance, Control, and Dynamics, 27(4), 2004, 627–633.
  18. [18] Y. Wang, Y. Yang, and F. Sun, Robust control design of singularly perturbation systems with actuator saturation via delta operator approach, International Journal of Robotics & Automation, 2018, 33(4), 355–366.
  19. [19] C. Cheng, J. Wu, Y. Hu, and J. Li, Adaptive control of nonaffine nonlinear system with saturation constraint, Control Theory & Applications, 31(8), 2014, 1000–1008.
  20. [20] X. Shao, et al., Fault-tolerant prescribed performance attitude tracking control for spacecraft under input saturation, IEEE Transactions on Control Systems and Technology, 28(2), 2020, 574–582.
  21. [21] Shen, Q., et al., Active fault-tolerant control system design for spacecraft attitude maneuvers with actuator saturation and faults, IEEE Transactions on Industrial Electronics, 66(5), 2019, 3763–3772.
  22. [22] Q. Hu, B. Xiao, and M.I. Friswell, Robust fault-tolerant control for spacecraft attitude stabilisation subject to input saturation, IET Control Theory & Applications, 5(2), 2011, 271–282.
  23. [23] Q. Hu, et al., Adaptive fault-tolerant attitude tracking control for spacecraft with time-varying inertia uncertainties, Chinese Journal of Aeronautics, 32(3), 2019, 674–687.
  24. [24] K. Yan, et al., Backstepping-based adaptive fault-tolerant control design for satellite attitude system, 2020 International Conference on Unmanned Aircraft Systems (ICUAS), Athens, Greece, 2020, 176–181.
  25. [25] W. Gong, et al., Fixed-time integral-type sliding mode control for the quadrotor UAV attitude stabilization under actuator failures, Aerospace Science and Technology, 95, 2019, 105444.
  26. [26] B. Xiao, Q. Hu, and Y. Zhang, Adaptive sliding mode fault tolerant attitude tracking control for flexible spacecraft under actuator saturation, IEEE Transactions on Control Systems Technology, 20(6), 2012, 1605–1612.
  27. [27] C. Cheng, H. Yang, Q. Wang, L. Li, Q. Han, H. Ouyang, H. Ma, and X. Lv, Attitude tracking of rigid spacecraft with actuator saturation and fault based on a compound control, Mathematical Problems in Engineering, 2020, 2020, 1C14. doi:10.1155/2020/6692547.

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