Window length insensitive real-time EMG hand gesture classification using entropy calculated from globally parsed histograms

Ayber Eray Algüner, H. Ergezer
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Abstract

Electromyography (EMG) signal classification is vital to diagnose musculoskeletal abnormalities and control devices by motion intention detection. Machine learning assists both areas by classifying conditions or motion intentions. This paper proposes a novel window length insensitive EMG classification method utilizing the Entropy feature. The main goal of this study is to show that entropy can be used as the only feature for fast real-time classification of EMG signals of hand gestures. The main goal of this study is to show that entropy can be used as the only feature for fast real-time classification of EMG signals of hand gestures. Additionally, the entropy feature can classify feature vectors of different sliding window lengths without including them in the training data. Many kinds of entropy feature succeeded in electroencephalography (EEG) and electrocardiography (ECG) classification research. However, to the best of our knowledge, the Entropy Feature proposed by Shannon stays untested for EMG classification to this day. All the machine learning models are tested on datasets NinaPro DB5 and the newly collected SingleMyo. As an initial analysis to test the entropy feature, classic Machine Learning (ML) models are trained on the NinaPro DB5 dataset. This stage showed that except for the K Nearest Neighbor (kNN) with high inference time, Support Vector Machines (SVM) gave the best validation accuracy. Later, SVM models trained with feature vectors created by 1 s (200 samples) sliding windows are tested on feature vectors created by 250 ms (50 samples) to 1500 ms (300 samples) sliding windows. This experiment resulted in slight accuracy differences through changing window length, indicating that the Entropy feature is insensitive to this parameter. Lastly, Locally Parsed Histogram (LPH), typical in standard entropy functions, makes learning hard for ML methods. Globally Parsed Histogram (GPH) was proposed, and classification accuracy increased from 60.35% to 89.06% while window length insensitivity is preserved. This study shows that Shannon’s entropy is a compelling feature with low window length sensitivity for EMG hand gesture classification. The effect of the GPH approach against an easy-to-make mistake LPH is shown. A real-time classification algorithm for the entropy features is tested on the newly created SingleMyo dataset.
基于全局解析直方图计算熵的窗长不敏感实时肌电信号手势分类
肌电图(EMG)信号分类对于诊断肌肉骨骼异常和通过运动意图检测控制装置至关重要。机器学习通过分类条件或运动意图来帮助这两个领域。提出了一种基于熵特征的窗长不敏感肌电信号分类方法。本研究的主要目的是证明熵可以作为手势肌电信号快速实时分类的唯一特征。本研究的主要目的是证明熵可以作为手势肌电信号快速实时分类的唯一特征。此外,熵特征可以对不同滑动窗长度的特征向量进行分类,而无需将其包含在训练数据中。多种熵特征在脑电图和心电图分类研究中取得了成功。然而,据我们所知,香农提出的熵特征至今仍未被用于肌电分类。所有的机器学习模型都在NinaPro DB5和新收集的SingleMyo数据集上进行了测试。作为测试熵特征的初始分析,经典机器学习(ML)模型在NinaPro DB5数据集上进行训练。该阶段表明,除了K近邻(kNN)具有较高的推理时间外,支持向量机(SVM)具有最好的验证精度。然后,用1 s(200个样本)滑动窗口生成的特征向量训练SVM模型,在250 ms(50个样本)至1500 ms(300个样本)滑动窗口生成的特征向量上进行测试。本实验通过改变窗长导致的准确率差异较小,说明熵特征对该参数不敏感。最后,局部解析直方图(LPH),典型的标准熵函数,使机器学习方法学习困难。提出了全局解析直方图(global Parsed Histogram, GPH),分类准确率从60.35%提高到89.06%,同时保持了窗长不敏感性。研究表明,香农熵是一种具有较低窗长灵敏度的肌电信号手势分类方法。显示了GPH方法对容易犯错误的LPH的影响。在新创建的SingleMyo数据集上测试了熵特征的实时分类算法。
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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