用于假肢控制设计的肌电信号采样率动态变化分析

2022 6th International Conference on Electronics, Communication and Aerospace Technology Pub Date : 2022-12-01 DOI:10.1109/ICECA55336.2022.10009107

S. L. Kumar, M. Swathy, T. Arunkumar, M. Maniventhan, S. Vigneshwaran

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引用次数: 1

摘要

基于肌电图(EMG)的假肢装置使用分类器来识别从截肢者的肢体获得的肌电信号。然后分类器的输出控制假肢装置的运动。肌电图信号的频谱随着肌肉长度的变化而动态变化。这些变化反映在分类器的输出中，因此它们是构建一个强大的分类系统来确定用户意图的重要组成部分。本文提出了一种基于输入肌电信号频谱动态改变肌电图采样频率的方法。采样频率的变化允许校正肌肉长度变化和由此产生的信号分类弹性。该方法在模拟肌电图上得到了成功的验证和实现。结果表明，由肌肉长度变化引起的分类器输出的变化可以通过光谱的变化来补偿。

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Analysis of dynamic change in sampling rate of EMG signal for designing prosthesis control

Electromyograph (EMG)-based prosthetic devices use a classifier to identify the myoelectric signals obtained from the amputee's limb. The classifier's output then controls the movement of the prosthetic device. The spectrum of the EMG signal is known to dynamic change with muscle length. These changes are reflected in the classifier's output, and so they are an important component in constructing a strong classification system to determine the user's intent. This work presents a method for dynamically changing the sample frequency of the EMG based on the spectrum of the input myoelectric signal. The shift in sampling frequency allows for correction of muscle length variations and the resulting resilience in signal classification. The approach was successfully validated and implemented on simulated EMG. The results indicate that variations in classifier output caused by changes in muscle length may be compensated for by changes in the spectrum.

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2022 6th International Conference on Electronics, Communication and Aerospace Technology

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