A DYNAMIC VELOCITY REGULATION APPROACH TO PLANAR TRAJECTORY TRACKING CONTROL OF UNDERACTUATED AUVs

Junpeng Zhou, Jiajia Zhou, Simon X. Yang, and Wei Zhang

References

  1. [1] D.W. Kim, Tracking of REMUS autonomous underwater vehicles with actuator saturations, Automatica, 58(2015), 2015, 15–21.
  2. [2] G.C. Karras, C.P. Bechlioulis, S. Nagappa, and N. Palomeras, Modelling motion control for autonomous underwater vehicles: a robust model – free approach, Proc. 11th IEEE Int. Conf. on Robotics and Automation, Hong Kong, China, 2014, 6529–6534.
  3. [3] T.I. Fossen, Hydrodynamics and motion control, Handbook of Marine, vol. 2 (Chichester: Wiley, 2011), 15–44.
  4. [4] F. Repoulias and E. Papadopoulos, Planar trajectory planning and tracking control design for underactuated AUVs, Ocean Engineering, 34, 2007, 1650–1667.
  5. [5] K.D. Do and J. Pan, Control of ships and underwater vehicles: Design for underactuated and nonlinear marine systems (London: Springer Press, 2009).
  6. [6] Z.-P. Yan, H.-M. Yu, W.i Zhang, B.-Y. Li, et al., Globally finite-time stable tracking control of underactuated UUVs, Ocean Engineering, 107, 2015, 132–246.
  7. [7] J. Xu, M. Wang, and L. Qiao, Dynamical sliding mode control for the trajectory tracking of underactuated unmanned underwater vehicles, Ocean Engineering, 105, 2015, 54–63.
  8. [8] H.-M. Jia and L.-J. Zhang, Three-dimensional path following control for an underactuated UUV based on nonlinear iterative sliding mode, Acta Automatica Sinica, 38(2), 2012, 308–314.
  9. [9] J.-J. Zhou, Z.-D. Tang, H.-H. Zhang, and J.-F. Jiao, Spatial path following for AUVs using adaptive neural network controllers, Mathematical Problems in Engineering, 2013(9), 1–9.
  10. [10] L.-J. Zhang, H.-M. Jia, and X. Qi, NNFFC-adaptive output feedback trajectory tracking control for a surface ship at high speed, Ocean Engineering, 38, 2011, 1430–1438.
  11. [11] A. Aguiar, Trajectory-tracking and path-following of underactuated autonomous vehicles with parametric modeling uncertainty, IEEE Transactions on Automatic Control, 52(8), 2007, 1362–1379.
  12. [12] F.Y. Bi, Y.J. Wei, J.Z. Zhang, and W. Cao, Position-tracking control of underactuated autonomous underwater vehicles in the presence of unknown ocean currents, IET Control Theory and Applications, 4(11), 2010, 2369–2380.
  13. [13] K.D. Do and J. Pan, Global robust adaptive path following of underactuated ships, Automatica, 42(10), 2006, 1713–1722.
  14. [14] A. Aguiar and P. Joao, Dynamic positioning and way-point tracking of underactuated AUVs in the presence of ocean currents, Proc. 41th IEEE Conf. on Decision and Control, Las Vegas, CA, 2002, 2105–2110.
  15. [15] K.D. Do, J. Pan, and Z.P. Jiang, Robust and adaptive path following for underactuated autonomous underwater vehicles, Ocean Engineering, 31(16), 2004, 1967–1997.
  16. [16] D.-Q. Zhu, X. Hua, and B. Sun, A neurodynamics control strategy for real-time tracking control of autonomous underwater vehicles, Journal of Navigation, 67(2), 2014, 113–127.
  17. [17] B. Sun, D.-Q. 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.
  18. [18] A. Zhu and S.X. Yang, Tracking control of a mobile robot with stability analysis, International Journal of Robotics and Automation, 28(4), 2013, 340–348.
  19. [19] A. Zhu and S.X. Yang, Neurofuzzy-based approach to mobile robot navigation in unknown environments, IEEE Transactions on Systems, Man and Cybernetics. Part C: Applications and Reviews, 37(4), 2007, 610–621.
  20. [20] S.X. Yang, A. Zhu, G. Yuan, and M.Q.-H. Meng, A bioinspired neurodynamics-based approach to tracking control of mobile robots, IEEE Transactions on Industrial Electronics, 59(8), 2012, 3211–3220.
  21. [21] A. Zhu and S.X. Yang, An improved approach to dynamic task assignment of non-holonomic multi-robots, International Journal of Robotics and Automation, 26(4), 2011, 362–368.
  22. [22] T.I. Fossen, K.Y. Pettersen, and R. Galeazzi, Line-of-sight path following for Dubins paths with adaptive sideslip compensation of drift forces, IEEE Transactions on Control Systems Technology, 23 (2), 2015, 820–827.
  23. [23] T.I. Fossen and K.Y. Pettersen, On uniform semiglobal exponential stability (USGES) of proportional line-of-sight guidance laws, Automatica, 50(11), 2015, 2912–2917.
  24. [24] K.D. Do, Z.P. Jiang, and J. Pan, Underactuated ship global tracking under relaxed conditions, IEEE Transactions on Automatic Control, 47(9), 2002, 1529–1536.
  25. [25] K.D. Do, Z.P. Jiang, and J. Pan, A global output feedback controller for stabilization and tracking of underactuated ODIN: A spherical underwater vehicle, Automatica, 40(1), 2004, 117–124.
  26. [26] A.L. Hodgkin and A.F. Huxley, A quantitative description of membrane current and its application to conduction and excitation in nerve, Journal of Physiology, 117(4), 1952, 500–544.
  27. [27] S. Grossberg, Nonlinear neural networks: Principles, mechanisms, and architecture, Neural Networks, 1(1), 1988, 17–61.

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