基于卷积神经网络的肌电信号分类

Kaan Bakircioğlu, Nalan Özkurt
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引用次数: 3

摘要

肌肉收缩时产生电信号;这种电信号包含有关肌肉的信息,这些信号的记录称为肌电图(EMG)。这些信息经常用于假肢、肌肉损伤检测和运动检测等研究中。分类器如人工神经网络、支持向量机等通常用于肌电信号的分类。尽管这些方法取得了成功的结果,但要给分类器的特征的提取和特征的选择影响分类的成功。在这项研究中,它旨在提高使用卷积神经网络(CNN)对日常使用的手部动作进行分类的成功率。像CNN这样的深度学习技术的优势在于,大数据中的关系是由网络学习的。首先,对接收到的前臂肌电信号进行窗口化处理,增加数据量,聚焦于收缩点;然后,为了比较成功率,将原始信号、信号的傅里叶变换、均方根和经验模态分解(EMD)应用于信号,得到固有模态函数。这些信号被传递给四个不同的CNN。之后,为了找到最有效的参数,将数据集分成三个部分,分别是70%的训练集、15%的验证集和15%的测试集,得到结果。已应用5个交叉验证来评估系统的性能。以EMD应用信号为输入的CNN得到了最好的效果。交叉验证的结果为95.90%,另一种分离方法的结果为93.70%。当对结果进行检查时,可以看出即使将原始信号应用到分类器中,CNN仍然是一个很有前途的分类器。同时,也观察到EMD方法具有更好的分类精度。这是一篇基于CC BY-SA 4.0许可的开放获取文章。(https://creativecommons.org/licenses/by-sa/4.0/)
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Classification of Emg Signals Using Convolution Neural Network
An electrical signal is produced by the contraction of the muscles; this electrical signal contains information about the muscles, the recording of these signals called electromyography (EMG). This information is often used in studies such as prosthetic arm, muscle damage detection, and motion detection. Classifiers such as artificial neural networks, support vector machines are generally used for the classification of EMG signals. Despite successful results with such methods the extraction of the features to be given to the classifiers and the selection of the features affect the classification success. In this study, it is aimed to increase the success of the classification of the daily used hand movements using the Convolutional neural networks (CNN). The advantage of the deep learning techniques like CNN is that the relationships in big data are learned by the network. Firstly, the received EMG signals for forearms are windowed to increase the number of data and focus on the contraction points. Then, to compare the success rate, raw signals, Fourier transform of the signal, the root means square, and the Empirical mode decomposition (EMD) is applied to the signal and intrinsic mode functions are obtained. These signals are given to four different CNN. Afterward, to find the most efficient parameters, the results were obtained by splitting data set into three as 70% training set, 15% validation set, and 15% test set. 5 cross-validations have been applied to assess the system’s performance. The best results are obtained from the CNN, which receive the EMD applied signal as input. The result obtained with the cross-validation is 95.90% and the result obtained with the other separation method is 93.70%. When the results were examined, it was seen that CNN is a promising classifier even the raw signal is applied to the classifier. Also, it has been observed that EMD method creates better accuracy of classification. This is an open access article under the CC BY-SA 4.0 license. (https://creativecommons.org/licenses/by-sa/4.0/)
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