采用并行层次神经网络模型进行力-轨迹控制时的虚拟轨迹和刚度椭圆

Fifth International Conference on Advanced Robotics 'Robots in Unstructured Environments Pub Date : 1991-06-19 DOI:10.1109/ICAR.1991.240394

M. Katayama, M. Kawato

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引用次数: 19

摘要

提出了一种基于反馈-错误学习的并行-分层神经网络模型。这个模型解释了同时控制轨迹和力的生物运动学习。此外，作者还提出了一种基于最小运动-命令变化轨迹准则的控制律。在计算运动指令时，直接考虑了肌肉的可变粘弹性。对两连杆四肌肉臂进行了学习轨迹和力控制。推导出在力和轨迹控制过程中隐式确定的虚拟轨迹和刚度椭圆。他们发现虚拟的轨迹比期望的轨迹要复杂得多。刚度椭圆与Mussa-Ivaldi实验结果相似。

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Virtual trajectory and stiffness ellipse during force-trajectory control using a parallel-hierarchical neural network model

Proposes a parallel-hierarchical neural network model using a feedback-error-learning scheme. This model explains the biological motor learning for simultaneous control of both trajectory and force. Moreover, the authors propose a control law based on a criterion related to the minimum motor-command-change trajectory. The motor commands are calculated while directly taking account of variable viscous-elastic properties of muscles. Learning trajectory and force control is performed for a two-link four-muscle arm. They derive the virtual trajectory and stiffness ellipse, which are implicitly determined during force and trajectory control. They found that the virtual trajectory was much more complex than the desired trajectory. The stiffness ellipses were similar to those obtained in Mussa-Ivaldi experiment.<>

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Fifth International Conference on Advanced Robotics 'Robots in Unstructured Environments

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