实时连续预测肩关节角度

Y. Aung, K. Anam, Adel Al-Jumaily
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引用次数: 2

摘要

肌表电(sEMG)信号连续预测关节动态角度是脑卒中幸存者康复领域最重要的应用之一,因为它可以直接反映使用者的运动意图。本研究提出了一种基于生物信号肌电信号的肩关节角度实时预测方法。首先,建立表面肌电信号到肌肉激活模型,从收缩的肌肉中提取用户意图,然后输入极限学习机(ELM)实时连续估计角度;然后将估计的关节角与摄像头捕获的关节角进行比较,以分析所提方法的有效性。结果表明,实际角度与预估角度在离线模式下的相关系数高达0.96,在线模式下的相关系数高达0.93。此外,在这两种情况下,估计的处理时间都小于32ms,符合人类自然运动的外观。因此,该方法能够很好、自然地预测用户的运动意图,适合于实时应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Continuous prediction of shoulder joint angle in real-time
Continuous prediction of dynamic joint angle from surface electromyography (sEMG) signal is one of the most important applications in rehabilitation area for stroke survivors as these can directly reflect the user motor intention. In this study, new shoulder joint angle prediction method in real-time based on the biosignal: sEMG is proposed. Firstly, sEMG to muscle activation model is built up to extract the user intention from contracted muscles and then feed into the extreme learning machine (ELM) to estimate the angle in real-time continuously. The estimated joint angle is then compare with the webcam captured joint angle to analyze the effectiveness of the proposed method. The result reveals that correlation coefficient between actual angle and estimated angle is as high as 0.96 in offline and 0.93 in online mode. In addition, the processing time for the estimation is less than 32ms in both cases which is within the semblance of human natural movements. Therefore, the proposed method is able to predict the user intended movement very well and naturally and hence, it is suitable for real-time applications.
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