Obstacle avoidance tracking control with antiswing and tracking errors constraint for underactuated automated lifting robots with load hoisting/lowering |
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Authors: | Zhiwen Tan Ke Zhang Huaitao Shi Lu Chen Guowei Li |
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Affiliation: | 1. School of Mechanical Engineering, Shenyang Jianzhu University, Shenyang, China;2. China Construction Seventh, Engineering Division. Corp., Ltd., Zhengzhou, China;3. Shenyang Sanyo Heavy Industry Group, Shenyang Sanyo Building Machinery Co., Ltd., Shenyang, China |
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Abstract: | The existing automated lifting robot technology focuses merely on motion control and ignores the surrounding environment. In practice, obstacles inevitably exist in the movement path of the automated lifting robot, which affects construction safety. Furthermore, due to the underactuated characteristics of the automated lifting robot, the load can be difficult to control when it swings violently, which undoubtedly poses huge challenges to obstacle avoidance trajectory planning and controller design. In this paper, an obstacle avoidance trajectory and its tracking controller with antiswing and tracking errors constraint are proposed. To ensure accurate load positioning and effective obstacle avoidance, the proposed control method introduces a four-segment polynomial trajectory interpolation curve to construct an obstacle avoidance trajectory based on analyzing the geometric relationship between variables. To improve the transient coupling control performance of the system, combined with the passive analysis of the automated lifting robot system, this method constructs a potential function that limits the tracking error and a coupling signal that enhances the coupling relationship between the system variables. Barbalat's lemma and Lyapunov techniques are used to analyze the stability of the system. Simulation and experimental results show that the proposed control method can significantly suppress or even eliminate load oscillation, accurately locate the load, avoid obstacles, improve the safety and efficiency of the working automated lifting robot, and have strong robustness to changes in system parameters and the addition of external disturbances. |
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Keywords: | antiswing control bounded tracking control load hoisting and lowering Lyapunov techniques obstacle avoidance trajectory planning underactuated automated lifting robots |
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