基于原始技能的监督机器人控制体系结构

ICAR '05. Proceedings., 12th International Conference on Advanced Robotics, 2005. Pub Date : 2005-07-18 DOI:10.1109/ICAR.2005.1507404

G. Milighetti, H. Kuntze, C. Frey, B. Diestel-Feddersen, J. Balzer

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引用次数: 19

摘要

人形机器人在复杂的公共、私人或工业环境中的智能交互需要引入基于原始技能的离散-连续监督控制概念。提出的分层机器人监督控制体系结构的功能既捕获了表示复杂技能所需的层次结构，也捕获了在执行过程中检测故障的机制。首先，通过几个互补的(如内部、光学、触觉或声学)传感器和基于神经模糊的相关传感器特征融合，连续诊断实际运动阶段或故障事件。根据所识别的运动阶段或随机故障事件，选择最适合的离散-连续控制策略并执行。本文首先报道了实验结果和仿真结果

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On a primitive skill-based supervisory robot control architecture

Smart interaction of humanoid robots in a complex public, private or industrial environment requires the introduction of primitive skill-based discrete-continuous supervisory control concepts. The functionality of the proposed hierarchical robot supervisory control architecture captures both the hierarchy that is required for representing complex skills as well as the mechanisms for detecting failures during their execution. At first by means of several complementary (e.g. internal, optical, tactile or acoustic) sensors and by neuro-fuzzy based fusion of relevant sensor features, the actual motion phase or fault event is continuously diagnosed. Depending on the identified motion phase or random fault event, the most appropriate discrete-continuous control strategy coping optimally with the corresponding situation will be selected and executed. First experimental and simulation results are reported in this paper

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ICAR '05. Proceedings., 12th International Conference on Advanced Robotics, 2005.

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