[1. Tao Liu, Zaopeng Dong, Hongwagn Du., et al. (2017).Path following control of the underactuated USV based on the improved line-of-sight guidance algorithm. IEEE Polish Maritime Research. 1 (93),Vol. 24; pp. 3-11.10.1515/pomr-2017-0001]Search in Google Scholar
[2. Dong Z.P., Wan L., Liu T., et al. (2016).Horizontal-plane trajectory-tracking control of an unmanned maritime vehicle in the presence of ocean currents. International Journal of Advanced Robotic Systems, 13: 83, 1-14.10.5772/63634]Search in Google Scholar
[3. Larrazabal J.M., Penas M.S.(2016). Intelligent rudder control of an unmanned surface vessel. Expert Systems with Applications, 55: 106-117.10.1016/j.eswa.2016.01.057]Search in Google Scholar
[4. H. Ashrafiuon, K.R. Muske, L.C. Mcninch, (2010).Review of nonlinear tracking and set-point control approaches for autonomous under-actuated marine vehicles, in: American Control Conference, Baltimore, USA, IEEE, pp. 5203–5211.10.1109/ACC.2010.5530450]Search in Google Scholar
[5. W. Xie, B. Ma, (2015).Robust global uniform asymptotic stabilization of underactuated surface vessels with unknown model parameters, Int. J. Robust Nonlinear Control, 25:1037–1050.10.1002/rnc.3129]Search in Google Scholar
[6. K.Y. Pettersen, T.I. Fossen, (2000).Underactuated dynamic positioning of a ship—experimental results, IEEE Trans. Control Syst. Technol, 8 (5) 863–89110.1109/87.865859]Search in Google Scholar
[7. K.D. Do,(2010). Practical control of underactuated ships, Ocean Eng, 37 (13) 1111–111910.1016/j.oceaneng.2010.04.007]Search in Google Scholar
[8. J. Ghommam, M. Saad, (2014).Backstepping-based cooperative and adaptive tracking control design for a group of underactuated AUVs in horizontal plan, Int. J. Control, 87 (5) 1076–1093.10.1080/00207179.2013.868605]Search in Google Scholar
[9. R. Yu, Q. Zhu, G. Xia, Z. Liu, (2012).Sliding mode tracking control of an underactuated surface vessel, IET Control Theory Appl. 6 (3):461–46610.1049/iet-cta.2011.0176]Search in Google Scholar
[10. A.M. Lekkas, T.I. Fossen, (2014).Trajectory tracking and ocean current estimation for marine underactuated vehicles, IEEE Conference on Control Applications, IEEE, Juan Les Antibes, France, pp. 905–910.10.1109/CCA.2014.6981451]Search in Google Scholar
[11. M.E. Serrano, G.J.E. Scaglia, S.A. Godoy, et al., (2014).Trajectory tracking of underactuated surface vessels: A linear algebra approach, IEEE Trans. Control Syst. Technol, 22 (3) 1103–1111.10.1109/TCST.2013.2271505]Search in Google Scholar
[12. E. Lefeber, K.Y. Pettersen, H. Nijmeijer, (2003).Tracking control of an underactuated ship, IEEE Trans. Control Syst. Technol. 11 (1) 52–61.10.1109/TCST.2002.806465]Search in Google Scholar
[13. E. Peymani, T.I. Fossen, (2015).Path following of underwater robots using Lagrange multipliers, Robotics Auton. Syst, 67:44–5210.1016/j.robot.2014.10.011]Search in Google Scholar
[14. J. Pan, K.D. Do, (2006).Global robust adaptive path following of underactuated ships, Automatica 42 :1713–1722.10.1016/j.automatica.2006.04.026]Search in Google Scholar
[15. Mahmut Reyhanoglu, Arjan van der Schaft, N. Harris Mcclamroch, Kolmanovsky. (1999). Dynamics and Control of a class of underactuated Mechanical Systems. IEEE Transactions on Automatic Control. Vol(44), No.9:1663, 167l.10.1109/9.788533]Search in Google Scholar
[16. Chwa, D.(2011), Global tracking control of underactuated ships with input and velocity constraints using dynamic surface control method. IEEE Transactions on Control Systems Technology, 19,1357-137010.1109/TCST.2010.2090526]Search in Google Scholar
[17. Huang, J., Wen, C., Wang, W., et. al. (2015), Global stable tracking control of underactuated ships with input saturation. Systems & Control Letters, 85, 1-7.10.1016/j.sysconle.2015.07.002]Search in Google Scholar
[18. Li, J.-H.(2016), Path tracking of und ships with general form of dynamics International Journal of Control, 89, 506-517.10.1080/00207179.2015.1083123]Search in Google Scholar
[19. Shojaei, K.(2015), Neural adaptive robust control of underactuated marine surface vehicles with input saturation. Applied Ocean Research, 53,267-278.10.1016/j.apor.2015.09.010]Search in Google Scholar
[20. GUO Chen, WANG Yang, SUN Fu-chun, et. al. (2009). Survey for motion control of underactuated surface vessels. Control and Decision, 24(03):321-329.]Search in Google Scholar
[21. Bu Ren-xiang, LIU Zheng-jiang, HU Jiang-qiang.(2007). Straight-path Tracking control of underactuated ships using dynamic nonlinear sliding. J Tsing Univ (Sci&Tech), 47(02):1880-1883.]Search in Google Scholar
[22. P. Encarnacao, A. Pacoal, and M. Arcak. (2000).Path following for autonomous marine craft. Proc. of the 5th IFAC Conf. on MCMC, Aalborg, Denmark, pp.117-122.10.1016/S1474-6670(17)37061-1]Search in Google Scholar
[23. T. Temel, H. Ashrafiuon. (2015).Sliding-mode speed controller for tracking of underactuated surface vessels with extended Kalman filter. ELECTRONICS LETTERS 19th,51(06) :467–469.10.1049/el.2014.4516]Search in Google Scholar
[24. Zhang R, Chen Y B, Z Q Sun, et. al. (1998). Path control of a surface ship in restricted waters using sliding model. Proc. of the 37th IEEE CDC, FL, pp. 3195-3200.]Search in Google Scholar
[25. Sahu, B.K., Subudhi, B. (2014). Adaptive tracking control of an autonomous underwater vehicle. Int. J. Autom. Comput. 11(3), 299–30710.1007/s11633-014-0792-7]Search in Google Scholar
[26. Encarnacao, P.; Pascoal, A. (2001). Combined trajectory tracking and path following: an application to the coordinated control of autonomous marine craft Decision and Control. Proceedings of the 40th IEEE Conference. Vol.1:964–969.]Search in Google Scholar
[27. Do KD (2015). Global inverse optimal tracking control of underactuated omni-directional intelligent navigators (ODINs).Journal of Marine Science and Application, 14(1), 1-13.10.1007/s11804-015-1288-8]Search in Google Scholar
[28. LI Tie-shan. (2005).Nonlinear Design on Straight-Trajectory-Keeping Control for ships. Da Lian Maritime University, Da Lian, China.]Search in Google Scholar
[29. Chen M, Ge SS, How VE, et. al. (2013). Robust adaptive position mooring control for marine vessels. IEEE Transaction on Control Systems Technology; 21(2):395–409.10.1109/TCST.2012.2183676]Search in Google Scholar
[30. Mou Chen, Bing Jiang, Rongxin Cui. (2016).Actuator fault-tolerant control of ocean surface vessels with input saturation[J]. INTERNATIONAL JOURNAL OF ROBUST AND NONLINEAR CONTROL; 26:542–564.10.1002/rnc.3324]Search in Google Scholar
[31. Cheng Liu, Zao-jian Zou, Tie-shan Li. (2015). Path following of underactuated surface vessels with fin roll reduction based on neural network and hierarchical sliding mode technique[J]. Neural Comput & Applic 26:1525–1535.10.1007/s00521-015-1821-3]Search in Google Scholar
[32. S. Bououden, M. Chadli, H. R. Karimi.(2013).Fuzzy sliding mode controller design using Takagi-Sugeno modelled nonlinear systems. Mathematical Problems in Engineering. Vol. 2013 :1-7.10.1155/2013/734094]Search in Google Scholar
[33. LI Ronghui, LI Tieshan, BU Renxiang. (2013).Disturbance Decoupling Control Based Trajectory Tracking for Underactuated Ships. Proceedings of the 32nd Chinese Control Conference. July 26-28, Xi’an, China:8108-8113.]Search in Google Scholar
[34. T. Li, R. Li, J. Li.(2012) Decentralized adaptive neural control of nonlinear systems with unknown time delays, Nonlinear Dynamics, 67(3): 2017-2026.10.1007/s11071-011-0126-z]Search in Google Scholar
[35. Qian D, Tong S, Yi J (2013) Adaptive control based on incremental hierarchical sliding mode for overhead crane systems. Appl Math Inf Sci 7(4):1359–1364.10.12785/amis/070413]Search in Google Scholar
[36. Q. Yang, Z. Yang, Y. Sun. (2012). Universal neural network control of MIMO uncertain nonlinear systems. IEEE Transactions on Neural Networks. Vol. 23:1162–1169,10.1109/TNNLS.2012.2197219]Search in Google Scholar
[37. Cheng Liu, Zaojian Zou, Jianchuan Yin. (2015).Trajectory tracking of underactuated surface vessels based on neural network and hierarchical sliding mode. J Mar Sci Technol, Vol 20:322–330.10.1007/s00773-014-0285-y]Search in Google Scholar
[38. Bu, Ren-Xiang; Liu, Zheng-Jiang; Li, Tie-Shan.(2007). Iterative sliding mode based increment feedback control and its application to ship autopilot. Journal of Harbin Engineering University, 28:268-272.]Search in Google Scholar