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    Summary
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    This study introduces a novel motion control method for underactuated robots, enabling path following and constraint satisfaction for both actuated and unactuated states. The approach optimizes trajectories in time, ensuring robots navigate complex environments safely and efficiently.

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    Area of Science:

    • Robotics
    • Control Systems
    • Optimization

    Background:

    • Underactuated robots in complex environments require advanced control beyond point-to-point methods.
    • Existing path planning methods often fail for underactuated systems or rely on simplified models.
    • Controlling unactuated states, like crane payload swing, presents significant challenges.

    Purpose of the Study:

    • To develop a novel motion control method for general underactuated robots.
    • To achieve path following and satisfy motion constraints for both actuated and unactuated states.
    • To enable time-optimal trajectory planning for underactuated systems lacking direct control inputs.

    Main Methods:

    • A new time-optimal trajectory planning-based motion control method is proposed.
    • Auxiliary signals in Cartesian space are used to represent joint-space variables.
    • Position/velocity constraints are transformed into optimization inequalities for a path parameter.

    Main Results:

    • The method successfully converts full-state constraints into solvable optimization problems.
    • Time-optimal trajectories are derived for actuated states, ensuring path following.
    • The approach achieves a balance between path constraints, time optimization, and state limitations.

    Conclusions:

    • This work presents the first method to ensure path following and full-state constraints for underactuated systems.
    • The proposed framework is validated through analysis and hardware experiments on a rotary crane.
    • The method offers a robust solution for controlling underactuated robots in complex scenarios.