共线机械轮式机器人速度约束轨迹生成

M. Watson, D. Gladwin, T. Prescott, Sebastian O. Conran
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引用次数: 3

摘要

对于欠驱动不稳定飞行器(如四旋翼飞行器)的光滑轨迹的生成,已经进行了大量的研究,但对地面全向动平衡机器人的相同技术的应用却很少关注。与飞行器相比,这些系统对直线加速度有更多的控制权,这意味着轨迹平滑性不是一个关键的设计参数。然而,当在室内环境中运行时,这些系统通常必须遵守相对较低的速度限制,从而导致使用现有轨迹优化方法时轨迹非常保守。本文有两个贡献;通过对这些现有方法的扩展,建立了一个快速的速度约束轨迹规划器,该规划器的轨迹时序特征来源于简化的加速度和速度约束模型的最优最小时间解。其次,推导了利用共线机械驱动的全向平衡机器人的差分平面模型,并利用该模型使该构型的实验原型能够顺利地遵循这些速度约束轨迹。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Velocity Constrained Trajectory Generation for a Collinear Mecanum Wheeled Robot
While much research has been conducted into the generation of smooth trajectories for underactuated unstable aerial vehicles such as quadrotors, less attention has been paid to the application of the same techniques to ground based omnidirectional dynamically balancing robots. These systems have more control authority over their linear accelerations than aerial vehicles, meaning trajectory smoothness is less of a critical design parameter. However, when operating in indoor environments these systems must often adhere to relatively low velocity constraints, resulting in very conservative trajectories when enforced using existing trajectory optimisation methods. This paper makes two contributions; this gap is bridged by the extension of these existing methods to create a fast velocity constrained trajectory planner, with trajectory timing characteristics derived from the optimal minimum-time solution of a simplified acceleration and velocity constrained model. Next, a differentially flat model of an omnidirectional balancing robot utilizing a collinear Mecanum drive is derived, which is used to allow an experimental prototype of this configuration to smoothly follow these velocity constrained trajectories.
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