Chang-Zhong Pan, Xu-Zhi Lai, Simon X. Yang, and Min Wu
[1] D. Zhu, J. Liu, and S.X. Yang, Particle swarm optimization approach to thruster fault-tolerant control of unmanned underwater vehicles, International Journal of Robotics and Automation, 26 (3), 2011, 282–287. [2] C.-Z. Pan, X.-Z. Lai, S.X. Yang, and M. Wu, An efficient neural network approach to tracking control of an autonomous surface vehicle with unknown dynamics, Expert Systems with Applications, 40 (5), 2013, 1629–1635. [3] R. Fierro and F.V. Lewis, Control of a nonholonomic mobile robot: backstepping kinematics into dynamics, Journal of Robotic Systems, 14 (6), 1997, 149–163. [4] K.Y. Pettersen and H. Nijmeijer, Global practical stabilization and tracking for an underactuated ship – a combined averaging and back-stepping approach, Modeling, Identification and Control, 20 (4), 1999, 189–199. [5] T.I. Fossen, Guidance and control of ocean vehicles (England: John Wiley and Sons, 1994). [6] H. Sira-Ramlrez, Dynamic second-order sliding mode control of the hovercraft vessel, IEEE Transactions on Control Systems Technology, 10 (6), 2002, 860–865. [7] H. Ashrafiuon, K.R. Muske, L.C. McNinch, and R.A. Soltan, Sliding mode tracking control of surface vessels, IEEE Transactions on Industrial Electronics, 55 (11), 2008, 4004–4012. [8] 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 Theoryand Applications, 4 (11), 2010, 2369–2380. [9] B.-L. Ma, Global κ-exponential asymptotic stabilization of underactuated surface vessels, Systems and Control Letters, 58, 2009, 194–201. [10] J.S. Shamma and J.R. Cloutier, Gain-scheduled missile autopilot design using linear parameter varying transformations, Journal of Guidance, Control and Dynamics, 16 (2), 1993, 256–263. [11] I. Kaminer, A. Pascoal, E. Hallberg, and C. Silvestre, Trajectory tracking controllers for autonomous vehicles: an integrated approach to guidance and control, Journal of Guidance, Control and Dynamics, 21 (1), 1998, 29–38. [12] K. Pettersen and H. Nijmeijer, Underactuated ship tracking control: theory and experiments, International Journal of Control, 74 (14), 2001, 1435–1446. [13] E. Lefeber, K. Pettersen, and H. Nijmeijer, Tracking control of an underactuated ship, IEEE Transactions on Control Systems Technology, 11(1), 2003, 52–61. [14] Z.-P. Jiang, Global tracking control of underactuated ships by Lyapunovs direct method, Automatica, 38, 2002, 301–309. [15] J. Ghommam, F. Mnif, and N. Derbel, Global stabilisation and tracking control of underactuated surface vessels, IET Control Theory and Applications, 4 (1), 2010, 71–88. [16] A.P. Aguiar and J.P. Hespanha, Trajectory-tracking and path-following of underactuated autonomous vehicles with parametric modeling uncertainty, IEEE Transactions on Automatic Control, 52 (8), 2007, 1362–1379. [17] 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, 1952, 500–554. [18] S. Grossberg, Nonlinear neural networks: principles, mechanisms, and architecture, Neural Networks, 1, 1988, 17–61. [19] ¨gmen and S. Gagn´e, Neural network architectures for motion perception and elementary motion detection in the fly visual system, Neural Networks, 3, 1990, 487–505. [20] S.X. Yang and M.Q.-H. Meng, Neural network approaches to dynamic collision-free trajectory generation, IEEE Transactions on Systems, Man, and Cybernetics, Part B, 31 (3), 2001, 302–318. [21] 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.
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