EEG-based driver states discrimination by noise fraction analysis and novel clustering algorithm.

IF 1.3 4区 医学 Q4 ENGINEERING, BIOMEDICAL
Rongrong Fu, Zheyu Li, Shiwei Wang, Dong Xu, Xiaodong Huang, Haifeng Liang
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引用次数: 0

Abstract

Driver states are reported as one of the principal factors in driving safety. Distinguishing the driving driver state based on the artifact-free electroencephalogram (EEG) signal is an effective means, but redundant information and noise will inevitably reduce the signal-to-noise ratio of the EEG signal. This study proposes a method to automatically remove electrooculography (EOG) artifacts by noise fraction analysis. Specifically, multi-channel EEG recordings are collected after the driver experiences a long time driving and after a certain period of rest respectively. Noise fraction analysis is then applied to remove EOG artifacts by separating the multichannel EEG into components by optimizing the signal-to-noise quotient. The representation of data characteristics of the EEG after denoising is found in the Fisher ratio space. Additionally, a novel clustering algorithm is designed to identify denoising EEG by combining cluster ensemble and probability mixture model (CEPM). The EEG mapping plot is used to illustrate the effectiveness and efficiency of noise fraction analysis on the denoising of EEG signals. Adjusted rand index (ARI) and accuracy (ACC) are used to demonstrate clustering performance and precision. The results showed that the noise artifacts in the EEG were removed and the clustering accuracy of all participants was above 90%, resulting in a high driver fatigue recognition rate.

基于噪声分数分析和新型聚类算法的脑电图驾驶状态识别。
据报道,驾驶员状态是影响驾驶安全的主要因素之一。基于无伪影的脑电图信号识别驾驶人状态是一种有效手段,但冗余信息和噪声不可避免地会降低脑电图信号的信噪比。提出了一种基于噪声分数分析的眼电图伪影自动去除方法。具体而言,在驾驶员长时间驾驶和休息一段时间后分别采集多路EEG记录。然后,通过优化信噪比,将多通道EEG分离成多个分量,应用噪声分数分析去除EEG伪影。在Fisher比率空间中找到了去噪后的EEG数据特征的表示。此外,将聚类集成与概率混合模型(CEPM)相结合,设计了一种新的聚类算法来识别去噪的脑电信号。用脑电信号映射图说明了噪声分数分析对脑电信号去噪的有效性和有效性。调整后的rand指数(ARI)和精度(ACC)用来衡量聚类性能和精度。结果表明,该方法去除了脑电中的噪声伪影,所有参与者的聚类准确率均在90%以上,提高了驾驶员疲劳识别率。
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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来源期刊
CiteScore
3.50
自引率
5.90%
发文量
58
审稿时长
2-3 weeks
期刊介绍: Biomedical Engineering / Biomedizinische Technik (BMT) is a high-quality forum for the exchange of knowledge in the fields of biomedical engineering, medical information technology and biotechnology/bioengineering. As an established journal with a tradition of more than 60 years, BMT addresses engineers, natural scientists, and clinicians working in research, industry, or clinical practice.
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