Hostname: page-component-586b7cd67f-l7hp2 Total loading time: 0 Render date: 2024-11-28T16:15:48.334Z Has data issue: false hasContentIssue false

Adaptive Sliding Mode Control for Depth Trajectory Tracking of Remotely Operated Vehicle with Thruster Nonlinearity

Published online by Cambridge University Press:  28 July 2016

Zhenzhong Chu*
Affiliation:
(Laboratory of Underwater Vehicles and Intelligent Systems, Shanghai Maritime University, Shanghai, 201306, China)
Daqi Zhu
Affiliation:
(Laboratory of Underwater Vehicles and Intelligent Systems, Shanghai Maritime University, Shanghai, 201306, China)
Simon X. Yang
Affiliation:
(The Advanced Robotics and Intelligent Systems Laboratory, School of Engineering, University of Guelph, Guelph, ON. N1G2W1, Canada)
Gene Eu Jan
Affiliation:
(Department of Computer Science and Information Engineering, National Taipei University, Taipei County, 237, Taiwan, ROC)
*

Abstract

This paper focuses on depth trajectory tracking control for a Remotely Operated Vehicle (ROV) with dead-zone nonlinearity and saturation nonlinearity of thruster; an adaptive sliding mode control method based on neural network is proposed. Through the analysis of dead-zone nonlinearity and saturation nonlinearity of thruster, the depth trajectory tracking control system model of a ROV which uses thruster control signals as system input has been established. According to the principle of sliding mode control, an adaptive sliding mode depth trajectory tracking controller is built by using three-layer feed-forward neural network for online identification of unknown items. The selection method and update laws of the control parameters are also given. The uniform ultimate boundedness of trajectory tracking error is analysed by Lyapunov theorem. Finally, the effectiveness of the proposed method is illustrated by simulations.

Type
Research Article
Copyright
Copyright © The Royal Institute of Navigation 2016 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Alessandri, A., Caccia, M. and Veruggio, G. (1999). Fault detection of actuator faults in unmanned underwater vehicles. Control Engineering Practice, 7, 357368.Google Scholar
Avila, J.P.J, Adamowski, J.C., Maruyama, N. and Takase, F.K. (2012). Modeling and identification of an open-frame underwater vehicle: the yaw motion dynamics. Journal of Intelligent & Robot Systems, 66, 3756.CrossRefGoogle Scholar
Avila, J.P.J., Donha, D.C. and Adamowski, J.C. (2013). Experimental model identification of open-frame underwater vehicles. Ocean Engineering, 60, 8194.CrossRefGoogle Scholar
Bessa, W.M., Dutra, M.S. and Kreuzer, E. (2008). Depth control of remotely operated underwater vehicles using an adaptive fuzzy sliding mode controller. Robotics and Autonomous Systems, 56, 670677.Google Scholar
Bessa, W.M., Dutra, M.S. and Kreuzer, E. (2010). An adaptive fuzzy sliding mode controller for remotely operated underwater vehicles. Robotics and Autonomous Systems, 58, 1626.Google Scholar
Cao, X. and Zhu, D. (2015). Multi-AUV underwater cooperative search algorithm based on biological inspired neurodynamics model and velocity synthesis. The Journal of Navigation, 68, 10751087.Google Scholar
Chen, M., Ge, S.S. and Ren, B. (2011). Adaptive tracking control of uncertain MIMO nonlinear systems with input constraints. Automatica, 47, 452465.Google Scholar
Chu, Z., Zhu, D. and Yang, S.X. (2016a). Observer-based adaptive neural network trajectory tracking control for remotely operated vehicle. IEEE Transaction on Neural Networks and Learning Systems, DOI: 10.1109/TNNLS.2016.2544786.Google Scholar
Chu, Z., Zhu, D. and Yang, S.X. (2016b). Adaptive terminal sliding mode based sensorless speed control for underwater thruster. International Journal of Robotics and Automation, DOI: 10.2316/Journal.206.2016.3.206–4428.Google Scholar
Feng, Z. and Allen, R. (2004). Reduced order H∞ control of an autonomous underwater vehicle. Control Engineering Practice, 12, 15111520.Google Scholar
Gan, Y., Wang, L.R., Liu, J.C. and Xu, Y.R. (2004). The embedded basic motion control system of autonomous underwater vehicle. Robot, 26, 246250.Google Scholar
Gao, D.X., Wang, S.X. and Zhang, H.J. (2014). A singularly perturbed system approach to adaptive neural back-stepping control design of hypersonic vehicles. Journal of Intelligent & Robotic Systems, 73, 249259.Google Scholar
Gao., J., Proctor, A. and Bradley, C. (2015a). Adaptive neural network visual servo control for dynamic positioning of underwater vehicles. Neurocomputing, 167, 604613.Google Scholar
Gao, J., Proctor, A., Shi, Y. and Bradley, C. (2015b). Hierarchical model predictive image-based visual servoing of underwater vehicles with adaptive neural network dynamic control. IEEE Transactions on Cybernetics, DOI: 10.1109/TCYB.2015.2475376.Google Scholar
Gao, W., Yang, J., Liu, J., Shi, H.Y. and Xu, B. (2015c). Moving horizon estimation for cooperative localization with communication delay. Journal of Navigation, 68, 493510.CrossRefGoogle Scholar
Hoang, N.Q. and Kreuzer, E. (2007). Adaptive PD-controller for positioning of a remotely operated vehicle close to an underwater structure: Theory and experiments. Control Engineering Practice, 15, 411419.Google Scholar
Hussain, M.A., Ho, P.Y. (2004). Adaptive sliding mode control with neural network based hybrid models. Journal of Process Control, 14, 157176.Google Scholar
Kim, J. and Chung, W.K. (2006). Accurate and practical thruster modelling for underwater vehicles, Ocean Engineering, 33, 566586.Google Scholar
Liu, Y.J. and Zhou, N. (2010). Observer-based adaptive fuzzy-neural control for a class of uncertain nonlinear systems with unknown dead-zone input. ISA Transactions, 49, 462469.CrossRefGoogle ScholarPubMed
Ma, C. and Zeng, Q. (2015). Distributed formation control of 6-DOF autonomous underwater vehicles networked by sampled-data information under directed topology. Neurocomputing, 154, 3340.Google Scholar
Pan, H. and Xin, M. (2012). Depth control of autonomous underwater vehicle using indirect robust control method. International Journal of Control, 85, 98113.Google Scholar
Peng, J. and Duba, R. (2012). Nonlinear inversion-based control with adaptive neural network compensation for uncertain MIMO systems, Expert Systems with Applications, 39, 81628171.CrossRefGoogle Scholar
Podder, T.P. and Sarkar, N. (2001). Fault-tolerant control of an autonomous underwater vehicle under thruster redundancy. Robotics and Autonomous Systems, 34, 3952.Google Scholar
Sun, B., Zhu, D. and Yang, X. (2014). A bioinspired filtered backstepping tracking control of 7000-m manned submarine vehicle. IEEE Transactions on Industrial Electronics, 61, 36823693.Google Scholar
Tong, S., Sui, S. and Li, Y. (2013). Adaptive fuzzy decentralized control for stochastic large-scale nonlinear systems with unknown dead-zone and unmodeled dynamics. Neurocomputing, 135, 367377.Google Scholar
Wang, Z.H., Ge, T. and Zhu, J.M. (2006). Timing sequence and logicality design of ROV's dynamic positioning system. Ocean Engineering, 24, 6166.Google Scholar
Wu, W., Gao, L., Mei, D. and Zhou, S. (2012). L1 adaptive controller for aircraft attitude with input constraints. Journal of Nanjing University of Aeronautics & Astronautics, 44, 809817.Google Scholar
Yang, Y.S. and Wang, X.F. (2007). Adaptive H∞ tracking control for a class of uncertain nonlinear systems using radial-basis-function neural networks. Neurocomputing, 70, 932941.CrossRefGoogle Scholar
Zhang, L.J., Qi, X. and Pang, Y.J. (2009). Adaptive output feedback control based on DRFNN for AUV. Ocean Engineering, 36, 716722.Google Scholar
Zhang, M.J. and Chu, Z.Z. (2012). Adaptive sliding mode control based on local recurrent neural networks for underwater robot. Ocean Engineering, 45, 5662.Google Scholar
Zhang, M., Liu, X., Yin, B. and Liu, W. (2015). Adaptive terminal sliding mode based thruster fault tolerant control for underwater vehicle in time-varying ocean currents. Journal of the Franklin Institute, 352, 49354961.Google Scholar
Zhu, D.Q., Hua, X. and Sun, B. (2014). A neurodynamics control strategy for real-time tracking control of autonomous underwater vehicle. Journal of Navigation, 67, 113127.Google Scholar