[1. T. Pastore and V. Djapic, “Improving autonomy and control of autonomous surface vehicles in port protection and mine countermeasure scenarios,” Journal of Field Robotics, 2010, 27(6):903–914.]Search in Google Scholar
[2. Z. Liu, Y. Zhang, X. Yu and Yuan C, “Unmanned surface vehicles: An overview of developments and challenges,” Annual Reviews in Control, 2016, 41:71–93.10.1016/j.arcontrol.2016.04.018]Search in Google Scholar
[3. L. Qiao and W. Zhang, “Adaptive non-singular integral terminal sliding mode tracking control for autonomous underwater vehicles,” IET Control Theory & Applications, 2017, 11(8):1293–1306.]Search in Google Scholar
[4. W. Dong and Y. Guo, “Global time-varying stabilization of underactuated surface vessel,” IEEE Transactions on Automatic Control, 2005, 50(6):859–864.]Search in Google Scholar
[5. K. Y. Wichlund, O. J. Sordalen and O. Egeland, “Control properties of underactuated vehicles,” IEEE International Conference on Robotics and Automation, 21–27 May 1995, Nagoya, Japan.]Search in Google Scholar
[6. E. Lefeber, K. Y. Pettersen and H. Nijmeijer, “Tracking control of an underactuated ship,” IEEE Transactions on Control Systems Technology, 2003, 11(1), 52–61.10.1109/TCST.2002.806465]Search in Google Scholar
[7. S. Wang, M. Fu and Y. Wang, “Robust adaptive steering control for unmanned surface vehicle with unknown control direction and input saturation,” International Journal of Adaptive Control and Signal Processing, 2019, 33(2):1214–1224.]Search in Google Scholar
[8. K. D. Do, Z. P. Jiang and J. Pan, “Robust global stabilization of underactuated ships on a linear course: State and output feedback,” International Journal of Control, 2003, 76(1):1–17.]Search in Google Scholar
[9. H. N. Esfahani and R. Szlapczynski, “Model predictive super-twisting sliding mode control for an autonomous surface vehicle,” Polish Maritime Research, 2019, 26(3):163–171.]Search in Google Scholar
[10. P. Liu, H. Yu and S. Cang, “Adaptive neural network tracking control for underactuated systems with matched and mismatched disturbances,” Nonlinear Dynamics, 2019, 98:1447–1464.10.1007/s11071-019-05170-8]Search in Google Scholar
[11. G. Zhang, W. Yan, J. Gao and C. Liu, “High-gain observer-based model predictive control for cross tracking of underactuated autonomous underwater vehicles,” IEEE International Conference on Underwater System Technology: Theory & Applications, 13–14 Dec. 2017, Penang, Malaysia.]Search in Google Scholar
[12. J. Li, P. M. Lee, B. Jun and Y. K. Lim, “Point-to-point navigation of underactuated ships,” Automatica, 2008, 44(12):3201–3205.]Search in Google Scholar
[13. C. P. Bechlioulis and G. A. Rovithakis, “Robust adaptive control of feedback linearizable MIMO nonlinear systems with prescribed performance,” IEEE Transactions on Automatic Control, 2008, 53(9):2090–2099.]Search in Google Scholar
[14. X. Wang, X. Yin and F. Shen, “Disturbance observer based adaptive neural prescribed performance control for a class of uncertain nonlinear systems with unknown backlash-like hysteresis,” Neurocomputing, 2018, 299(19):10–19.]Search in Google Scholar
[15. C. P. Bechlioulis, Z. Doulgeri and G. A. Rovithakis, “Neuro-adaptive force/position control with prescribed performance and guaranteed contact maintenance,” IEEE Transactions on Neural Networks, 2010, 21(12):1857–1868.]Search in Google Scholar
[16. O. Elhaki and K. Shojaei, “Neural network-based target tracking control of underactuated autonomous underwater vehicles with a prescribed performance,” Ocean Engineering, 2018, 167(1):239–256.]Search in Google Scholar
[17. S. He, M. Wang, S. Dai and F. Luo, “Leader-follower formation control of USVs with prescribed performance and collision avoidance,” IEEE Transactions on Industrial Informatics, 2018, 15(1):572–581.]Search in Google Scholar
[18. T. Gao, J. Huang, Y. Zhou and Y. Song, “Robust adaptive tracking control of an underactuated ship with guaranteed transient performance,” International Journal of Systems Science, 2016, 48(2): 272–279.]Search in Google Scholar
[19. B. S. Park and S. J. Yoo, “Robust fault-tolerant tracking with predefined performance for underactuated surface vessels,” Ocean Engineering, 2016, 115:159–167.10.1016/j.oceaneng.2016.02.006]Search in Google Scholar
[20. S. J. Yoo and B. S. Park, “Guaranteed performance design for distributed bounded containment control of networked uncertain underactuated surface vessels,” Journal of the Franklin Institute, 2017, 354(3):1584–1602.]Search in Google Scholar
[21. C. P. Bechlioulis, G. C. Karras, S. Heshmati-Alamdari and K. J. Kyriakopoulos, “Trajectory tracking with prescribed performance for underactuated underwater vehicles under model uncertainties and external disturbances,” IEEE Transactions on Control Systems Technology, 2017, 25(2):429–440.]Search in Google Scholar
[22. R. Skjetne, Y. I. Fossen and P. V. Kokotovic, “Adaptive maneuvering, with experiments, for a model ship in a marine control laboratory,” Automatica, 2005, 41(2):289–298.]Search in Google Scholar
[23. Q. Yang and M. Chen, “Adaptive neural prescribed performance tracking control for near space vehicles with input nonlinearity,” Neurocomputing, 2016, 174:780–789.10.1016/j.neucom.2015.09.099]Search in Google Scholar
[24. S. Wang, M. Fu, Y. Wang and H. Wei, “Area-keeping robust sliding mode control for underactuated surface vehicle,” Journal of Harbin Engineering University, 2020, 41(5):684–690.]Search in Google Scholar