DYNAMIC POSITIONING CONTROL OF UUV IN THE PRESENCE OF DISTURBANCES CAUSED BY WORKING MANIPULATORS

Gengshi Zhang, Jian Xu, Zheping Yan, Tao Chen, and Xue Du

References

  1. [1] Y.R. Xu and K. Xiao, Technology development of autonomous ocean vehicle, Acta Automatica Sinica, 33(5), 2007, 518–521.
  2. [2] G.A. Marani, S.K.A.B. Choi, and J.C. Yuh, Underwater autonomous manipulation for intervention missions AUVs, Ocean Engineering, 36(1), 2009, 15–23.
  3. [3] H. Yu, A. Shen, and Y. Su, Continuous motion planning in complex and dynamic underwater environments, International Journal of Robotics and Automation, 30(2), 2015, 192–204.
  4. [4] S.A.B. Mohan and J.B. Kim, Indirect adaptive control of an autonomous underwater vehicle-manipulator system for underwater manipulation tasks, Ocean Engineering, 54(1), 2012, 233–243.
  5. [5] C.H.F.A. Dos Santos and E.R.B. De Pieri, Functional machine with Takagi–Sugeno inference to coordinated movement in underwater vehicle-manipulator systems, IEEE Transactions on Fuzzy Systems, 21(6), 2013, 1105–1114.
  6. [6] H.A. Nejatbakhsh Esfahani, V.A. Azimirad, M.B. Danesh, A time delay controller included terminal sliding mode and fuzzy gain tuning for underwater vehicle-manipulator systems, Ocean Engineering, 107(1), 2015, 97–107.
  7. [7] S. Mohan and J. Kim, Coordinated motion control in task space of an autonomous underwater vehicle-manipulator system, Ocean Engineering, 104, 2015, 155–167.
  8. [8] D. Kim, H. Choi, J. Kim, et al., Trajectory generation and sliding-mode controller design of an underwater vehiclemanipulator system with redundancy, International Journal of Precision Engineering and Manufacturing, 16(7), 2015, 1561–1570.
  9. [9] J.A. Han and W.K.B. Chung, Active use of restoring moments for motion control of an underwater vehicle-manipulator system, IEEE Journal of Oceanic Engineering, 39(1), 2014, 100–109.
  10. [10] R.A. Bin Ambar, S.A. Sagara, and F.B. Takemura, Coordinated motion control of a 3-link dual-arm underwater vehiclemanipulator system using resolved acceleration control method, 25th Int. Ocean and Polar Engineering Conference, ISOPE 2015, Kona, Big Island, 2015, 598–605.
  11. [11] O.A. Korkmaz, S.B. Kemal Ider, and M.B. Kemal Ozgoren, Control of an underactuated underwater vehicle manipulator system in the presence of parametric uncertainty and disturbance, 2013 American Control Conference, ACC 2013, Washington, DC, 2013, 578–584.
  12. [12] F. Fahimi and C. Nolen, A configuration control approach for external disturbance compensation of simulated humanoid robots, International Journal of Robotics and Automation, 31(2), 2016, 93–99.
  13. [13] J.A. Gao, A.B. Proctor, and C.B. Bradley, Adaptive neural network visual servo control for dynamic positioning of underwater vehicles, Neurocomputing, 167(1), 2015, 604–613.
  14. [14] G. Xia, C. Pang, and J. Xue, Fuzzy neural network-based robust adaptive control for dynamic positioning of underwater vehicles with input dead-zone, Journal of Intelligent and Fuzzy Systems, 29(6), 2015, 2585–2595.
  15. [15] Y. Zhao, A bio-inspired neurodynamics based backstepping path-following control of an AUV with ocean current, International Journal of Robotics and Automation, 27(27), 2012, 298–307.
  16. [16] A.P. Aguiar and A.M. Pascoal, Dynamic positioning and waypoint tracking of underactuated AUVs in the presence of ocean currents, International Journal of Control, 80(7), 2007, 1092–1108. 603
  17. [17] K.W. Zhu, L.Y. Gu, X.J. Ma, et al., Studies on multivariable robust output feedback control for underwater vehicles, Journal of Zhejiang University (Engineering Science), 46(8), 2012, 1397–1406.
  18. [18] K. Kherraz, M. Hamerlain, and N. Achour, Robust neurofuzzy sliding mode controller for a flexible robot manipulator, International Journal of Robotics and Automation, 30(1), 2015, 40–49.
  19. [19] B. Sun, D. Zhu, and S.X. Yang, A bio-inspired cascaded approach for three-dimensional tracking control of unmanned underwater vehicles, International Journal of Robotics and Automation, 29(4), 2014, 349–358.
  20. [20] S. Islam, X.P. Liu, and A. El Saddik, Adaptive sliding mode control of unmanned fourrotor flying vehicle, International Journal of Robotics and Automation, 30(2), 2015, 140–148.
  21. [21] B.Z. Guo, H.C. Zhou, A.S. Al-Fhaid, et al., Stabilization of Euler–Bernoulli beam equation with boundary moment control and disturbance by active disturbance rejection control and sliding mode control approaches, Journal of Dynamical and Control Systems, 20(4), 2014, 539–558.
  22. [22] R. Cui, X. Zhang, and D. Cui, Adaptive sliding-mode attitude control for autonomous underwater vehicles with input nonlinearities, Ocean Engineering, 123, 2016; 45–54.
  23. [23] W.M.A. Bessa, M.S.B. Dutra, and E.C. Kreuzer, An adaptive fuzzy sliding mode controller for remotely operated underwater vehicles, Robotics and Autonomous Systems, 58(1), 2010, 16– 26.
  24. [24] L.G. Garcia-Valdovinos and T. Salgado-Jimenez, On the dynamic positioning control of underwater vehicles subject to ocean currents, 8th Int. Conf. Electrical Engineering, Computing Science and Automatic Control, CCE 2011, Merida, Yucatan, 2011, 1–6.
  25. [25] J.A. Wang, A.B.B. Rad, and P.T.B. Chan, Indirect adaptive fuzzy sliding mode control: Part I: Fuzzy switching, Fuzzy Sets and Systems, 122(1), 2001, 21–30.
  26. [26] T.I. Fossen, Handbook of Marine Craft Hydrodynamics and Motion Control (Chichester: John Wiley & Sons Ltd, 2011), 167–183.
  27. [27] H. Wei, Robot Dynamics and Control (Beijing: Higher Education Press, 2005), 16–31.
  28. [28] T.I. Fossen, Guidance and Control of Ocean Vehicles (Chichester: John Willey & Sons Ltd, 1994), 5–30.
  29. [29] K.N. Leabourne and S.M. Rock, Model development of an underwater manipulator for coordinated arm-vehicle control, Oceans Conference Record 1998 (IEEE), Nice, 1998, 941–946.
  30. [30] W. Lixin, A Course in Fuzzy Systems and Control (Beijing: Tsinghua University Press, 2003), 91–99.
  31. [31] K.A. Kherraz, M.B. Hamerlain, and N.A. Achour, Robust neuro-fuzzy sliding mode controller for a flexible robot manipulator, International Journal of Robotics and Automation, 30(1), 2015, 40–49.
  32. [32] G.A. Xia, A.A. Zhao, H.B. Wu, et al., Adaptive robust output feedback trajectory tracking control for ships with input nonlinearities, International Journal of Robotics and Automation. 31(4), 2016, 341–353.

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