|Table of Contents|

Sliding mode control for ship dynamic positioning based on linear matrix inequality(PDF)

《交通运输工程学报》[ISSN:1671-1637/CN:61-1369/U]

Issue:
2018年05期
Page:
119-129
Research Field:
载运工具运用工程
Publishing date:

Info

Title:
Sliding mode control for ship dynamic positioning based on linear matrix inequality
Author(s):
XUE Han SHAO Zhe-ping PAN Jia-cai FANG Qiong-lin
(School of Navigation, Jimei University, Xiamen 361021, Fujian, China)
Keywords:
ship engineering dynamic positioning sliding mode control linear matrix inequality motion control robustness
PACS:
U661.33
DOI:
-
Abstract:
In order to solve the control problem of ship dynamic positioning systems with nonlinear and environmental disturbances, a sliding mode control algorithm based on the linear matrix inequality(LMI)was proposed. The tracking error was designed as a sliding mode function, and a linear matrix inequality was designed to solve the state feedback gain. Based on the quadratic Lyapunov function, the stability of the closed-loop system was proved. The switching function was designed to make the system robust to uncertainties and external disturbances and to avoid chattering. The sliding mode controller based on the LMI was simulated, and the forward speed, sway speed, heading angular speed, forward acceleration, sway acceleration, heading angular acceleration, forward control force, sway control force, and heading control moment of a dynamic-positioning ship were calculated under two different conditions, namely, uniform motion without disturbance and variable-speed motion with external environment disturbance. The effects of parameters such as the linear matrix of state feedback gain, boundary layer, and switching gain on control performance were analyzed and compared. Analysis result indicates that it takes 29 s for the forward speed to reach the expected value by using the basic sliding mode control, whereas the new algorithm saves 48.28% at 15 s. It takes 24 s for the sway speed to reach the expected value by using the basic sliding mode control, whereas the new algorithm saves 41.67% at 14 s. It takes 13 s for the heading angular speed to reach the expected value by using the basic sliding mode control, whereas the new algorithm saves 23.08% at 10 s. Thus, the designed controller has strong robustness for the ship dynamic positioning system with nonlinear and environmental disturbances, and has the characteristics of continuous control input, no control chattering, and no high gain. 1 tab, 23 figs, 30 refs.

References:


[1] SØRENSEN A J. A survey of dynamic positioning control systems[J]. Annual Reviews in Control, 2011, 35(1): 123-136.
[2] NGUYEN T D, SØRENSEN A J, QUEK S T. Design of hybrid controller for dynamic positioning from calm to extreme sea conditions[J]. Automatica, 2007, 43(5): 768-785.
[3] FANG M C, LEE Z Y. Application of neuro-fuzzy algorithm to portable dynamic positioning control system for ships[J]. International Journal of Naval Architecture and Ocean Engineering, 2016, 8(1): 38-52.
[4] PARK K P, JO A R, CHOI J W. A study on the key performance indicator of the dynamic positioning system[J]. International Journal of Naval Architecture and Ocean Engineering, 2016, 8(5): 511-518.
[5] DU Jia-lu, HU Xin, KRSTIC' M, et al. Robust dynamic positioning of ships with disturbances under input saturation[J]. Automatica, 2016, 73(11): 207-214.
[6] 陈士安,王骏骋,姚 明.车辆半主动悬架全息最优滑模控制器设计方法[J].交通运输工程学报,2016,16(3):72-83,99. CHEN Shi-an, WANG Jun-cheng, YAO Ming. Design method of holographic optimal sliding mode controller for semi-active suspension of vehicle[J]. Journal of Traffic and Transportation Engineering, 2016, 16(3): 72-83, 99.(in Chinese)
[7] ASHRAFIUON H, MUSKE K R, MCNINCH L C, et a1. Sliding-mode tracking control of surface vessels[J]. IEEE Transactions on Industrial Electronics, 2008, 55(11): 4004-4012.
[8] ROY S, KAR I N. Adaptive sliding mode control of a class of nonlinear systems with artificial delay[J]. Journal of the Franklin Institute, 2017, 354(18): 8156-8179.
[9] 刘金琨,孙富春.滑模变结构控制理论及其算法研究与进展[J].控制理论与应用,2007,24(3):407-418. LIU Jin-kun, SUN Fu-chun. Research and development on theory and algorithms of sliding mode control[J]. Control Theory and Applications, 2007, 24(3): 407-418.(in Chinese)
[10] LIU Jin-kun, SUN Fu-chun. Nominal model-based sliding mode control with backstepping for 3-axis flight table[J]. Chinese Journal of Aeronautics, 2006, 19(1): 65-71.
[11] DAI Yan-yan, KIM Y G, WEE S G, et al. Symmetric caging formation for convex polygonal object transportation by multiple mobile robots based on fuzzy sliding mode control[J]. ISA Transactions, 2016, 60: 321-332.
[12] 邵井丰.基于滑模变结构的船舶动力定位控制研究[D].大连:大连海事大学,2015. SHAO Jing-feng. Research on ship dynamic positioning control based on sliding mode variable structure[D]. Dalian: Dalian Maritime University, 2015.(in Chinese)
[13] 代昌盛.欠驱动船舶运动的自适应迭代滑模控制研究[D].大连:大连海事大学,2017. DAI Chang-sheng. Research on adaptive iterative sliding mode control for underactuated ship motion[D]. Dalian: Dalian Maritime University, 2017.(in Chinese)
[14] 秦朝宇.基于终端滑模自抗扰的船舶航迹跟踪控制[D].大连:大连海事大学,2017. QIN Chao-yu. Active disturbance rejection control for ship path following based terminal sliding mode[D]. Dalian: Dalian Maritime University, 2017.(in Chinese)
[15] 王昱棋.基于终端滑模的欠驱动水面船舶航迹跟踪及编队控制[D].大连:大连海事大学,2017. WANG Yu-qi. Terminal sliding mode control for tracking and formation of underactuated surface vessels[D]. Dalian: Dalian Maritime University, 2017.(in Chinese)
[16] HAN Yao-zhen, PAN Wei-gang. Gain-scheduled continuous higher-order sliding mode control for uncertain nonlinear system[J]. Optik, 2016, 127(10): 4345-4354.
[17] SUN Zhi-jian, ZHANG Guo-qing, YI Bo-wen, et al. Practical proportional integral sliding mode control for underactuated surface ships in the fields of marine practice[J]. Ocean Engineering, 2017, 142: 217-223.
[18] LIAO Yu-lei, WAN Lei, ZHUANG Jia-yuan. Backstepping dynamical sliding mode control method for the path following of the underactuated surface vessel[J]. Procedia Engineering, 2011, 15: 256-263.
[19] SUN Zhi-jian, ZHANG Guo-qing, LU Yu, et al. Leader- follower formation control of underactuated surface vehicles based on sliding mode control andparameter estimation[J]. ISA Transactions, 2018, 72: 15-24.
[20] ESFAHANI H N, AZIMIRAD V, DANESH M. A time delay controller included terminal sliding mode and fuzzy gaintuning for underwater vehicle-manipulator systems[J]. Ocean Engineering, 2015, 107: 97-107.
[21] ZHANG Ming-jun, LIU Xing, YIN Bao-ji, et al. Adaptive terminal sliding mode based thruster fault tolerant control for underwater vehicle in time-varying ocean currents[J]. Journal of the Franklin Institute, 2015, 352(11): 4935-4961.
[22] 邹 剑.船舶航向动态滑模变结构控制研究[D].重庆:重庆大学,2012. ZOU Jian. The research of ship heading dynamic sliding variable structure control system[D]. Chongqing: Chongqing University, 2012.(in Chinese)
[23] WANG Hui-min, YANG Guang-hong. Piecewise controller design for affine fuzzy systems via dilated linear matrix inequality characterizations[J]. ISA Transactions, 2012, 51(6): 771-777.
[24] WANG Qing, XU Peng-cheng, LAM E Y, et al. Iterative solution to linear matrix inequality arising from time delay descriptor systems[J]. Applied Mathematics and Computation, 2013, 219(9): 4176-4184.
[25] GARONE E, NTOGRAMATZIDIS L. Linear matrix inequalities for globally monotonic tracking control[J]. Automatica, 2015, 61(11): 173-177.
[26] DE CAMPOSV A F, DA CRUZ J J, ZANETTA JR L C. Robust and optimal adjustment of power system stabilizers through linear matrix inequalities [J]. International Journal of Electrical Power and Energy Systems, 2012, 42(1): 478-486.
[27] BACULI J, AYOUBI M A.Fuzzy attitude control of solar sail via linear matrix inequalities[J]. Acta Astronautica, 2017, 138(9): 233-241.
[28] YANG Y U, DUBLJEVIC S. Linear matrix inequalities(LMIs)observer and controller design synthesis for parabolic PDE[J]. European Journal of Control, 2014, 20(5): 227-236.
[29] AMMAR M E, DUMONT G A. Automatic tuning of paper machines cross-direction controllers via linear matrix inequalities[J]. Journal of Electrical Systems and Information Technology, 2015, 2(3): 283-295.
[30] SUN Jia, WANG Shi-heng, WANG Ke. Zhang neural networks for a set of linear matrix inequalities withtime-varying coefficient matrix[J]. Information Processing Letters, 2016, 116(10): 603-610.

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Last Update: 2018-05-30