Modeling Previous Trial Effect in Human Manipulation through Iterative Learning Control

Advanced Intelligent Systems Pub Date : 2020-07-01 DOI:10.1002/aisy.201900074

Lorenzo Cenceschi, C. D. Santina, Giuseppe Averta, M. Garabini, Qiushi Fu, M. Santello, M. Bianchi, A. Bicchi

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Abstract

In the execution of repetitive tasks, humans can capitalize on experience to improve their motor performance. Prominent examples of this ability can be recognized in our capacity of grasping and manipulating in uncertain conditions. With the aim of providing a mathematical description for such behavior, experiments are considered where participants are required to lift an object with an unexpected mass distribution. By repeating multiple times the same lifting action, participants can learn the correct motor command for task accomplishment. Three models are proposed that combine reactive terms and a learned anticipatory action to explain experimental data. The models feature intratrial and intertrial memory, and the effect of slowly and fast adaptive sensory receptors. The architectures’ effectiveness in explaining experimental data is compared with a general‐purpose state of the art model. The proposed algorithms conspicuously outperform the state of the art in all the considered validation routines. Global and within‐trial human behavior is predicted with 88% of accuracy in nominal conditions. When the object's center of mass is moved, the accuracy is maintained up to 83%. Finally, convergence properties of proposed algorithms are analytically discussed, and their stability and robustness against measurement noise are evaluated in simulation.

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基于迭代学习控制的人类操作前试效应建模

在执行重复性任务时，人类可以利用经验来提高他们的运动表现。这种能力的突出例子可以从我们在不确定条件下掌握和操纵的能力中得到认识。为了提供这种行为的数学描述，实验被考虑要求参与者举起一个具有意想不到的质量分布的物体。通过多次重复相同的举重动作，参与者可以学习完成任务的正确运动命令。提出了反应性术语和习得预期作用相结合的三个模型来解释实验数据。这些模型具有房内记忆和房间记忆，以及慢速和快速适应感觉受体的作用。该体系结构在解释实验数据方面的有效性与通用状态的艺术模型进行了比较。在所有考虑的验证例程中，所提出的算法明显优于当前的技术状态。在名义条件下，全球和试验内人类行为的预测准确率为88%。当物体的质心移动时，精度保持在83%以上。最后，对所提算法的收敛性进行了分析讨论，并在仿真中评估了算法的稳定性和对测量噪声的鲁棒性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Advanced Intelligent Systems

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