A Feasible and Applicable Motion Control Method for AUV

Lei Zhang; Zhuo Wang; Jin Xin Zhao; Ying Liu

doi:10.4028/www.scientific.net/AMR.694-697.1771

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 694-697A Feasible and Applicable Motion Control Method...

A Feasible and Applicable Motion Control Method for AUV

Abstract:

Both the high speed and the changing excess buoyancy can make it difficult in motion control of AUV, in order to solve the problems, an improved control method based on S-surface control is proposed. Taking static forces and coupling effects between longitude velocity and other dimensions into account, the compensation related to the speed is brought into the method to handle the effects caused by high speed. In accordance with the thoughts of S-surface control, an anti-windup intelligent integral method is presented to handle the changing excess buoyancy and propulsion loss via an adaptive weight determined by estimating the motion states of AUV. Finally, experiments of velocity control, yaw control and depth control are conducted, and the results prove the feasibility and advantages in application to AUV motion control.

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Periodical:

Advanced Materials Research (Volumes 694-697)

Pages:

1771-1778

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.694-697.1771

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Online since:

May 2013

Authors:

Lei Zhang*, Zhuo Wang, Jin Xin Zhao, Ying Liu

Keywords:

Anti-Windup Integral, Autonomous Underwater Vehicle (AUV), High-Speed, Motion Control

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References

[1] LI Ye, LIU Jian-cheng, SHEN Ming-xue. Journal of Harbin Institute of Technology. 12(4). (2005). pp.456-459. (in Chinese)

Google Scholar

[2] LIU Xue-min, XU Yu-ru. Ocean Engineering. 19(3). (2001), pp.81-84. (in Chinese)

Google Scholar

[3] LIU Jian-cheng, YU Hua-nan, XU Yuru., 23(1). (2002), pp.33-36. (in Chinese)

Google Scholar

[4] LI Ye, PANG Yong-jie, WAN Lei, et al. Journal of Harbin Engineering University. 27(suppl.). (2006), pp.325-330. (in Chinese)

Google Scholar

[5] TIAN Hong-qi. Sliding mode control theory and its application. Wuhan: Press of Wuhan, 1995.

Google Scholar

[6] LIU Jin-kun, SUN Fu-chun. Control Theory & Applications. 24(3). (2007), pp.407-418. (in Chinese)

Google Scholar

[7] LIAO Xiao-xin. Stability Theory and Application of Dynamic System. Beijing: Press of National Defense Industry, 2000.

Google Scholar

[8] YANG Hong, ZHAO Jun, ZHANG Lei. Control Theory & Applications. 24(5). (2007), pp.861-865. (in Chinese)

Google Scholar

[9] CHANG Wen-jun, LIU Jian-cheng, YU Hua-nan, et al. Ship Engineering. 2002(3), pp.58-60. (in Chinese)

Google Scholar