Murside Degirmenci, Yilmaz Kemal Yuce, Matjaž Perc, Yalcin Isler
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引用次数: 0
Abstract
Introduction: Motor Imagery (MI) Electroencephalography (EEG) signals are non-stationary and dynamic physiological signals which have low signal-to-noise ratio. Hence, it is difficult to achieve high classification accuracy. Although various machine learning methods have already proven useful to that effect, the use of many features and ineffective EEG channels often leads to a complex structure of classifier algorithms. State-of-the-art studies were interested in improving classification performance with complex feature extraction and classification methods by neglecting detailed EEG channel and feature investigation in predicting MI tasks from EEGs. Here, we investigate the effects of the statistically significant feature selection method on four different feature domains (time-domain, frequency-domain, time-frequency domain, and non-linear domain) and their two different combinations to reduce the number of features and classify MI-EEG features by comparing low-dimensional matrices with well-known machine learning algorithms.
Methods: Our main goal is not to find the best classifier performance but to perform feature and channel investigation in MI task classification. Therefore, the detailed investigation of the effect of EEG channels and features is implemented using a statistically significant feature distribution on 22 EEG channels for each feature set separately. We used the BCI Competition IV Dataset IIa and 288 samples per person. A total of 1,364 MI-EEG features were analyzed in this study. We tested nine distinct classifiers: Decision tree, Discriminant analysis, Logistic regression, Naive Bayes, Support vector machine, k-Nearest neighbor, Ensemble learning, Neural networks, and Kernel approximation.
Results: Among all feature sets considered, classifications performed with non-linear and combined feature sets resulted in a maximum accuracy of 63.04% and 47.36% for binary and multiple MI task predictions, respectively. The ensemble learning classifier achieved the maximum accuracy in almost all feature sets for binary and multiple MI task classifications.
Discussion: Our research thus shows that the statistically significant feature-based feature selection method significantly improves the classification performance with fewer features in almost all feature sets, enabling detailed and effective EEG channel and feature investigation.
运动意象(MI)脑电图(EEG)信号是非平稳的动态生理信号,具有较低的信噪比。因此,很难达到较高的分类精度。尽管各种机器学习方法已经被证明对这一效果有用,但使用许多特征和无效的EEG通道通常会导致分类器算法结构复杂。目前的研究关注的是通过复杂的特征提取和分类方法来提高分类性能,而忽略了详细的脑电信号通道和特征研究,从而从脑电信号中预测MI任务。在这里,我们研究了统计显著特征选择方法在四个不同的特征域(时域、频域、时频域和非线性域)及其两种不同组合上的效果,通过比较低维矩阵和著名的机器学习算法,减少特征数量并对MI-EEG特征进行分类。方法:我们的主要目标不是找到最好的分类器性能,而是在MI任务分类中进行特征和通道调查。因此,对脑电信号通道和特征的影响进行了详细的研究,对每个特征集分别使用22个脑电信号通道的统计显著特征分布。我们使用了BCI Competition IV Dataset IIa,每人288个样本。本研究共分析了1364个MI-EEG特征。我们测试了九种不同的分类器:决策树、判别分析、逻辑回归、朴素贝叶斯、支持向量机、k近邻、集成学习、神经网络和核近似。结果:在所考虑的所有特征集中,使用非线性和组合特征集进行分类,二元和多重MI任务预测的最高准确率分别为63.04%和47.36%。集成学习分类器在几乎所有的二元和多重MI任务分类特征集中都达到了最高的准确率。讨论:我们的研究表明,基于统计显著性特征的特征选择方法在几乎所有特征集中都能以更少的特征显著提高分类性能,实现详细有效的脑电通道和特征调查。
期刊介绍:
Frontiers in Human Neuroscience is a first-tier electronic journal devoted to understanding the brain mechanisms supporting cognitive and social behavior in humans, and how these mechanisms might be altered in disease states. The last 25 years have seen an explosive growth in both the methods and the theoretical constructs available to study the human brain. Advances in electrophysiological, neuroimaging, neuropsychological, psychophysical, neuropharmacological and computational approaches have provided key insights into the mechanisms of a broad range of human behaviors in both health and disease. Work in human neuroscience ranges from the cognitive domain, including areas such as memory, attention, language and perception to the social domain, with this last subject addressing topics, such as interpersonal interactions, social discourse and emotional regulation. How these processes unfold during development, mature in adulthood and often decline in aging, and how they are altered in a host of developmental, neurological and psychiatric disorders, has become increasingly amenable to human neuroscience research approaches. Work in human neuroscience has influenced many areas of inquiry ranging from social and cognitive psychology to economics, law and public policy. Accordingly, our journal will provide a forum for human research spanning all areas of human cognitive, social, developmental and translational neuroscience using any research approach.
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