Adaptive Sliding Mode Trajectory Tracking Control of Unmanned Surface Vessels Based on Time-Domain Wave Inversion

Mou, Tianyu; Shen, Zhipeng; Zheng, Zixuan

doi:10.3390/jmse12081278

JMSE

2024

DOI: 10.3390/jmse12081278

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Adaptive Sliding Mode Trajectory Tracking Control of Unmanned Surface Vessels Based on Time-Domain Wave Inversion

Tianyu Mou,

Zhipeng Shen,

Zixuan Zheng

Abstract: In this work, we develop a trajectory tracking control method for unmanned surface vessels (USVs) based on real-time compensation for actual wave disturbances. Firstly, wave information from the actual sea surface is extracted through stereoscopic visual observations, and data preprocessing is performed using a task-driven point cloud downsampling network. We reconstruct the phase-resolved wave field in real time. Subsequently, the wave disturbances are modeled mechanically, and real-time wave disturbances are… Show more

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2024

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Practical Fixed-Time Robust Containment Control of Multi-ASVs with Collision Avoidance

Wu,

Liu,

Shi

2024

JMSE

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A practical fixed-time robust containment control method for multiple autonomous surface vehicles (multi-ASVs) is proposed in this study. This method addresses the containment control problem of multi-ASVs, considering both collision risks and external disturbances. This control scheme improves the cooperative performance of the formation and guarantees safe collision avoidance behavior. First, to enable the online estimation of unknown time-varying disturbances from the external environment, a fixed-time disturbance observer (FNDO) is designed based on fixed-time control theory. Second, the distributed kinematic controller is modified to include the partial derivatives of the artificial potential energy function (APEF), thereby preventing collisions among multi-ASVs. Third, by applying fixed-time theory, graph theory, and fixed-time dynamic surface control techniques, a practical fixed-time robust containment controller for multi-ASVs is proposed. Additionally, the entire closed-loop control system is guaranteed to be practical and fixed-time stable through stability analysis. Finally, the proposed control strategy has been validated by simulation results.

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Practical Fixed-Time Robust Containment Control of Multi-ASVs with Collision Avoidance

Wu,

Liu,

Shi

2024

JMSE

View full text Add to dashboard Cite

show abstract

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Adaptive Sliding Mode Trajectory Tracking Control of Unmanned Surface Vessels Based on Time-Domain Wave Inversion

Cited by 1 publication

References 43 publications

Practical Fixed-Time Robust Containment Control of Multi-ASVs with Collision Avoidance

Practical Fixed-Time Robust Containment Control of Multi-ASVs with Collision Avoidance

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