研究肢体位置对基于模式识别的肌电控制的不良影响。

Examining the adverse effects of limb position on pattern recognition based myoelectric control.

作者信息

Scheme E, Fougner A, Stavdahl Ø, Chan A C, Englehart K

机构信息

Institute of Biomedical Engineering at the University of New Brunswick, Fredericton, Canada.

出版信息

Annu Int Conf IEEE Eng Med Biol Soc. 2010;2010:6337-40. doi: 10.1109/IEMBS.2010.5627638.

DOI:10.1109/IEMBS.2010.5627638

PMID:21097173

Abstract

Pattern recognition of myoelectric signals for the control of prosthetic devices has been widely reported and debated. A large portion of the literature focuses on offline classification accuracy of pre-recorded signals. Historically, however, there has been a semantic gap between research findings and a clinically viable implementation. Recently, renewed focus on prosthetics research has pushed the field to provide more clinically relevant outcomes. One way to work towards this goal is to examine the differences between research and clinical results. The constrained nature in which offline training and test data is often collected compared to the dynamic nature of prosthetic use is just one example. In this work, we demonstrate that variations in limb position after training can have a substantial impact on the robustness of myoelectric pattern recognition.

摘要

用于控制假肢装置的肌电信号模式识别已被广泛报道和讨论。大部分文献集中于预先记录信号的离线分类准确率。然而，从历史上看，研究结果与临床可行的实施方案之间存在语义鸿沟。最近，对假肢研究的重新关注推动该领域提供更具临床相关性的成果。朝着这个目标努力的一种方法是研究研究结果与临床结果之间的差异。与假肢使用的动态性质相比，离线训练和测试数据通常收集的受限性质只是一个例子。在这项工作中，我们证明训练后肢体位置的变化会对肌电模式识别的稳健性产生重大影响。

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研究肢体位置对基于模式识别的肌电控制的不良影响。

Examining the adverse effects of limb position on pattern recognition based myoelectric control.

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