全向自主移动机器人路径规划与控制的分层任务分解方法

Proceedings of the 1999 IEEE International Symposium on Intelligent Control Intelligent Systems and Semiotics (Cat. No.99CH37014) Pub Date : 1900-01-01 DOI:10.1109/ISIC.1999.796672

K. Moore, N. Flann

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引用次数: 24

摘要

描述了一种新型六轮全向自主机器人的多分辨率行为生成策略。该策略的特点是分层任务分解方法。在监督层面，使用基于知识的规划器和a *优化算法将车辆的路径指定为一系列基本动作。在飞行器水平上，这些基本动作被转换为时域轨迹。然后使用基于模型的反馈线性化控制器在惯性参考系中跟踪这些轨迹，该控制器计算每个车轮的低级驱动电机和转向角电机控制器的设定点。该策略的有效性在一个真实机器人的实际测试中得到了验证，并在分布式处理环境中实现了路径规划和控制算法。

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Hierarchical task decomposition approach to path planning and control for an omni-directional autonomous mobile robot

Describes a multi-resolution behavior generation strategy for a novel six-wheel omni-directional autonomous robot. The strategy is characterized by a hierarchical task decomposition approach. At the supervisory level a knowledge-based planner and an A*-optimization algorithm are used to specify the vehicle's path as a sequence of basic maneuvers. At the vehicle level these basic maneuvers are converted to time-domain trajectories. These trajectories are then tracked in an inertial reference frame using a model-based feedback linearization controller that computes set points for each wheel's low-level drive motor and steering angle motor controllers. The effectiveness of the strategy is demonstrated in actual tests with a real robot in which the path planning and control algorithms are implemented in a distributed processing environment.

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来源期刊

Proceedings of the 1999 IEEE International Symposium on Intelligent Control Intelligent Systems and Semiotics (Cat. No.99CH37014)

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