高度冗余缆索驱动并联机器人无风险控制的实时方法

A Real-Time Approach to Risk-Free Control of Highly Redundant Cable-Driven Parallel Robots

IEEE Transactions on Systems, Man, and Cybernetics: Systems · 2024
被引 9
ABS 3

中文导读

提出一种基于控制的实时方法,用于保证缆索驱动并联机器人的缆索张力在正范围内,相比传统优化方法计算更快、对运动学不确定性不敏感,并能在轨迹超出工作空间时保持机器人于边界。

Abstract

In cable-driven parallel robots (CDPRs), the cable tension must be in an admissible positive range. The positive tension distribution (PTD) in CDPR is generally guaranteed using optimization-based methods, limiting their real-time applications due to the unpredictable worst-case computation time of such methods. In this study, we consider the PTD to be an integral part of the control system and introduce a computationally efficient control-based approach for generating positive tensions. This innovative approach offers several benefits for controlling redundant CDPRs. It significantly improves computation time compared to existing iterative methods, eliminates high sensitivity to kinematic uncertainties, and enhances trajectory tracking performance. Additionally, the proposed method keeps the robot on the boundary of the workspace when the trajectory exits the wrench-feasible workspace. To this end, we introduce a novel representation of CDPR dynamics as a nonaffine form, considering the tension of the cables as state variables. A robust unilateral constrained control structure is proposed using a third-order model, ensuring control efforts remain within a prescribed positive range. The computational efficiency of the method is investigated in a hyper-redundant CDPR and is compared with the conventional methods. It is also shown that for the desired trajectory out of the workspace, the proposed method keeps the robot at the boundary of the workspace while maintaining positive tensions.

机器人控制缆索驱动并联机器人实时控制张力分布