A Sigmoid-plane adaptive control algorithm for unmanned surface vessel considering marine environment interference

Abstract

This article presents an application of a Sigmoid-plane (S-plane) adaptive control algorithm to an automatic steering system in the presence of uncertain parametric of the unmanned surface vessel (USV) and the unknown disturbance of the marine environment. Due to technical difficulties such as sensor noise, the marine environment disturbance is assumed to be unmeasured. To overcome this problem, an S-plane control is designed to resist marine environment disturbances by the improved adaptive term. Based on the gradient method, the USV heading model reference adaptive controller of the USV is designed, so that the USV has a certain ability to resist model parameter changes. Considering the uncertainty of marine environment interference, a model-reference-based S-plane adaptive controller for the USV is designed. After the reference of the USV course model, the S-plane adaptive control approach is employed to reduce the effect of the marine environment. It is proved that the USV course control system is stable, despite the adverse bad sea conditions. Finally, the course control simulation experiment for the USV with the unknown marine environmental interference is carried out. To demonstrate the benefits of the S-plane adaptive controller, the results are presented in comparison with a Lyapunov method controller. The results show that the S-plane adaptive controller is robust to the changed model parameter and external disturbances.

Keywords

Adaptive control environmental interference Sigmoid-plane control unmanned surface vessel automatic steering

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References

Cervantes-Rojas

Muñoz

Chairez

, et al. (2020) Adaptive tracking control of an unmanned aerial system based on a dynamic neural-fuzzy disturbance estimator. ISA Transactions 101: 309–326.

Chen

Delefortrie

Lataire

(2020) Experimental investigation of practical autopilots for maritime autonomous surface ships in shallow water. Ocean Engineering 218: 108246.

Chen

Zhou

Liu

, et al. (2018) Adaptive sliding-mode trajectory tracking control of underactuated unmanned surface vessels. Journal of National University of Defense Technology 40(3): 127–134.

Chu

Mao

Dong

, et al. (2020) Parameter identification of high-speed USV maneuvering response model based on maximum likelihood algorithm. Acta Armamentarii 41(1): 127–134.

Filip

Vasar

Szeidert

, et al. (2019) Self-tuning strategy for a minimum variance control system of a highly disturbed process. European Journal of Control 46: 49–62.

Iovino

Savvaris

Tsourdos

(2018) Experimental testing of a path manager for unmanned surface vehicles in survey missions. IFAC PapersOnLine 51(29): 226–231.

Jia

Qiao

Zhang

(2020) Adaptive tracking control of unmanned underwater vehicles with compensation for external perturbations and uncertainties using Port-Hamiltonian theory. Ocean Engineering 209: 1–13.

Jiang

(2019) Design and implement of a kind of automatic steering system integrated simulation operation platform. Ship Electronic Engineering 39(1): 54–59.

Khaled

Nabil

(2013) A self-tuning guidance and control system for marine surface vessels. Nonlinear Dynamics 73(1–2): 897–906.

10.

Zhao

Mao

(2017) Analysis of six-degree-of-freedom motion in submarines under sea disturbance. Journal of Harbin Engineering University 38(1): 94–100.

11.

Jiang

, et al. (2018) Dynamic positioning test for removable of ocean observation platform. Ocean Engineering 153: 112–121.

12.

Pang

Wan

(2012) Adaptive S plane control for autonomous underwater vehicle. Journal of Shanghai Jiaotong University 46(2): 195–200.

13.

Liao

Wan

Zhuang

(2011) Backstepping dynamical sliding mode control method for the path following of the underactuated surface vessel. Procedia Engineering 15: 256–263.

14.

Liu

Chen

(2020) A sufficient descent nonlinear conjugate gradient method for solving M-tensor equations. Journal of Computational and Applied Mathematics 371: 112709.

15.

Liu

Wang

Peng

(2019a) State recovery and disturbance estimation of unmanned surface vehicles based on nonlinear extended state observers. Ocean Engineering 171: 625–632.

16.

Liu

Yang

Guo

(2019b) Application of unmanned surface vehicle in electronic warfare. Science & Technology Review 37(4): 20–25.

17.

Liu

Bucknall

(2018) Efficient multi-task allocation and path planning for unmanned surface vehicle in support of ocean operations. Neurocomputing 275: 1550–1566.

18.

Liu

Yuan

Zhang

(2015) Linear parameter varying adaptive control of an unmanned surface vehicle. IFAC PapersOnLine 48(16): 140–145.

19.

Mareels

IMY

Anderson

BDO

Bitmead

, et al. (1987) Revisiting the MIT rule for adaptive control. IFAC Proceedings 20(2): 161–166.

20.

Moradi

Katebi

(2001) Predictive PID control for ship autopilot design. IFAC Proceedings Volumes 34(7): 375–380.

21.

Wang

Fan

, et al. (2018) Adaptive course control based on trajectory linearization control for unmanned surface vehicle with unmodeled dynamics and input saturation. Neurocomputing 330: 101–105.

22.

Sharma

Naeem

Sutton

(2012) An autopilot based on a local control network design for an unmanned surface vehicle. Journal of Navigation 65(2): 281–301.

23.

Sun

Ran

Cao

, et al. (2020) Deep submergence rescue vehicle docking based on parameter adaptive control with acoustic and visual guidance. International Journal of Advanced Robotic Systems 17(2): 1–14.

24.

Tao

Zhu

Wen

, et al. (2019) Preparation of papers for IFAC Conferences & Symposia: Designing a characteristic model-based adaptive path following controller for unmanned surface vehicles. IFAC PapersOnLine52(21): 347–352.

25.

Atilla

Tahsin

, et al. (2021) Long-voyage route planning method based on multi-scale visibility graph for autonomous ships. Ocean Engineering 219: 108242.

26.

Yan

Dai

(2017) Research on automatic control algorithm of ship automatic rudder based on neural network. Ship Science and Technology 39(12): 55–57.

27.

Yang

Gao

(2020) Robust model reference adaptive control for transient performance enhancement. International Journal of Robust and Nonlinear Control 30(15): 6207–6228.

28.

Yüksel

(2019) An intelligent visual servo control system for quadrotors. Transactions of the Institute of Measurement and Control 41(1): 3–13.

29.

Zhang

Yan

, et al. (2020) Fixed-time output feedback sliding mode tracking control of marine surface vessels under actuator faults with disturbance cancellation. Applied Ocean Research 104: 1–10.

30.

Zhang

(2019) Control method of ship autopilot based on BP neural network and PID. Ship Science and Technology 41(16): 124–126.

31.

Zhao

Pan

, et al. (2008) Direct adaptive control based on gradient estimation. Chinese Journal of Chemical Engineering 16(5): 752–761.