Sway and disturbance rejection control for varying rope tower cranes suffering from friction and unknown payload mass

Zheng Tian; Lili Yu; Huimin Ouyang; Guangming Zhang

doi:10.1007/s11071-021-06793-6

Sway and disturbance rejection control for varying rope tower cranes suffering from friction and unknown payload mass

Zheng Tian, Lili Yu, Huimin Ouyang, Guangming Zhang

COLLEGE OF ELECTRICAL ENGINEERING AND CONTROL SCIENCE

Nanjing Tech University

Research output: Contribution to journal › Article › peer-review

25 Scopus citations

Abstract

Tower cranes are well-known underactuated systems, where the design of controllers for them with time-varying rope length was weak in the past because of their complex dynamic characteristic. The payload oscillation will become worse when the jib slew angle, the trolley position and the rope length are changed simultaneously. The proposed method is designed based on robust adaptive sliding mode control via tracking nonzero initial reference trajectories, in which frictions and lumped disturbances in the crane system are eliminated, and unknown payload mass is effectively estimated online. Lyapunov technique is combined with LaSalle’s invariance theorem to design controller and analyze stability. Various and strict simulations are applied, which validate the effectiveness and extreme robustness of the proposed method.

Original language	English
Pages (from-to)	3149-3165
Number of pages	17
Journal	Nonlinear Dynamics
Volume	105
Issue number	4
DOIs	https://doi.org/10.1007/s11071-021-06793-6
State	Published - Sep 2021

Keywords

Robust adaptive sliding mode control
Sway rejection
Time-varying rope length
Tower crane
Underactuated system

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10.1007/s11071-021-06793-6

Cite this

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title = "Sway and disturbance rejection control for varying rope tower cranes suffering from friction and unknown payload mass",

abstract = "Tower cranes are well-known underactuated systems, where the design of controllers for them with time-varying rope length was weak in the past because of their complex dynamic characteristic. The payload oscillation will become worse when the jib slew angle, the trolley position and the rope length are changed simultaneously. The proposed method is designed based on robust adaptive sliding mode control via tracking nonzero initial reference trajectories, in which frictions and lumped disturbances in the crane system are eliminated, and unknown payload mass is effectively estimated online. Lyapunov technique is combined with LaSalle{\textquoteright}s invariance theorem to design controller and analyze stability. Various and strict simulations are applied, which validate the effectiveness and extreme robustness of the proposed method.",

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T1 - Sway and disturbance rejection control for varying rope tower cranes suffering from friction and unknown payload mass

AU - Tian, Zheng

AU - Yu, Lili

AU - Ouyang, Huimin

AU - Zhang, Guangming

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Y1 - 2021/9

N2 - Tower cranes are well-known underactuated systems, where the design of controllers for them with time-varying rope length was weak in the past because of their complex dynamic characteristic. The payload oscillation will become worse when the jib slew angle, the trolley position and the rope length are changed simultaneously. The proposed method is designed based on robust adaptive sliding mode control via tracking nonzero initial reference trajectories, in which frictions and lumped disturbances in the crane system are eliminated, and unknown payload mass is effectively estimated online. Lyapunov technique is combined with LaSalle’s invariance theorem to design controller and analyze stability. Various and strict simulations are applied, which validate the effectiveness and extreme robustness of the proposed method.

AB - Tower cranes are well-known underactuated systems, where the design of controllers for them with time-varying rope length was weak in the past because of their complex dynamic characteristic. The payload oscillation will become worse when the jib slew angle, the trolley position and the rope length are changed simultaneously. The proposed method is designed based on robust adaptive sliding mode control via tracking nonzero initial reference trajectories, in which frictions and lumped disturbances in the crane system are eliminated, and unknown payload mass is effectively estimated online. Lyapunov technique is combined with LaSalle’s invariance theorem to design controller and analyze stability. Various and strict simulations are applied, which validate the effectiveness and extreme robustness of the proposed method.

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Sway and disturbance rejection control for varying rope tower cranes suffering from friction and unknown payload mass

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Keywords

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