Driver Fatigue Detection Through Chaotic Entropy Analysis of Cortical Sources Obtained From Scalp EEG Signals

Epilepsy is one of most common neurological disorders that affects people of all ages and can cause unpredictable seizures which may even cause death. The prediction of epileptic activities thus can have a great impact in avoiding fatal injuries through early preparation with medicines and also in improving the efficacy of medicines. A technique for early prediction of epileptic seizure from EEG signal is proposed in this paper. The pre-ictal period of epileptic seizure clearly depicts a start of seizure and comparing the changes in entropy of EEG signals in different brain regions during the pre-seizure period, the proposed technique could successfully predict the seizure using entropy analysis. Moreover, the region of the epileptic activities was also localized by dividing the total brain into four topographic regions and by calculating the entropy from this four zones separately. Thus, this proposed technique has the potential to help the clinical neurologists to investigate seizure detection and treat the patient in a better way with less supervision and better accuracy. Bangladesh Journal of Medical Physics Vol.11 No.1 2018 P 16-25

Download Full-text

A dynamic center and multi threshold point based stable feature extraction network for driver fatigue detection utilizing EEG signals

Cognitive Neurodynamics ◽

10.1007/s11571-020-09601-w ◽

2020 ◽

Cited By ~ 2

Author(s):

Turker Tuncer ◽

Sengul Dogan ◽

Fatih Ertam ◽

Abdulhamit Subasi

Keyword(s):

Feature Extraction ◽

Eeg Signals ◽

Driver Fatigue ◽

Fatigue Detection ◽

Threshold Point ◽

Stable Feature

Download Full-text

A Multivariate Weighted Ordinal Pattern Transition Network for Characterizing Driver Fatigue Behavior from EEG Signals

International Journal of Bifurcation and Chaos ◽

10.1142/s0218127420501187 ◽

2020 ◽

Vol 30 (08) ◽

pp. 2050118

Author(s):

Yu-Xuan Yang ◽

Zhong-Ke Gao

Keyword(s):

Traffic Accidents ◽

Fatigue Behavior ◽

Multivariate Time Series ◽

Detection Task ◽

Eeg Signals ◽

Driver Fatigue ◽

Driving Fatigue ◽

Fatigue Detection ◽

Ordinal Pattern ◽

Fatigue Mechanism

Driver fatigue has caused numerous vehicle crashes and traffic injuries. Exploring the fatigue mechanism and detecting fatigue state are of great significance for preventing traffic accidents, and further lessening economic and societal loss. Due to the objectivity of EEG signals and the availability of EEG acquisition equipment, EEG-based fatigue detection task has raised great attention in recent years. Although there exist various methods for this task, the study of fatigue mechanism and detection of fatigue state still remain much to be explored. To investigate these problems, a multivariate weighted ordinal pattern transition (MWOPT) network is proposed in this paper. To be specific, a simulated driving experiment was first conducted to obtain the EEG signals of subjects in alert state and fatigue state respectively. Then the MWOPT network is constructed based on a novel Shannon entropy. To probe into the mechanism underlying fatigue behavior, the small-worldness index is extracted from the generated MWOPT network. Furthermore, the nodal degree index is input into a classifier to distinguish the fatigue state from alert state. The obtained high accuracy indicates the effectiveness of the proposed network for EEG-based fatigue detection. Besides, four nodes are found to play an important role in identifying fatigue state. These results suggest that the proposed method enables to analyze nonlinear multivariate time series and investigate the driving fatigue behavior.

Download Full-text

Multiplex Limited Penetrable Horizontal Visibility Graph from EEG Signals for Driver Fatigue Detection

International Journal of Neural Systems ◽

10.1142/s0129065718500570 ◽

2019 ◽

Vol 29 (05) ◽

pp. 1850057 ◽

Cited By ~ 13

Author(s):

Qing Cai ◽

Zhong-Ke Gao ◽

Yu-Xuan Yang ◽

Wei-Dong Dang ◽

Celso Grebogi

Keyword(s):

Mental Fatigue ◽

Visibility Graph ◽

Clustering Coefficient ◽

Eeg Signals ◽

Driver Fatigue ◽

Horizontal Visibility ◽

Fatigue Driving ◽

Fatigue Detection ◽

The Brain ◽

Horizontal Visibility Graph

Driver fatigue is an important contributor to road accidents, and driver fatigue detection has attracted a great deal of attention on account of its significant importance. Numerous methods have been proposed to fulfill this challenging task, though, the characterization of the fatigue mechanism still, to a large extent, remains to be investigated. To address this problem, we, in this work, develop a novel Multiplex Limited Penetrable Horizontal Visibility Graph (Multiplex LPHVG) method, which allows in not only detecting fatigue driving but also probing into the brain fatigue behavior. Importantly, we use the method to construct brain networks from EEG signals recorded from different subjects performing simulated driving tasks under alert and fatigue driving states. We then employ clustering coefficient, global efficiency and characteristic path length to characterize the topological structure of the networks generated from different brain states. In addition, we combine average edge overlap with the network measures to distinguish alert and mental fatigue states. The high-accurate classification results clearly demonstrate and validate the efficacy of our multiplex LPHVG method for the fatigue detection from EEG signals. Furthermore, our findings show a significant increase of the clustering coefficient as the brain evolves from alert state to mental fatigue state, which yields novel insights into the brain behavior associated with fatigue driving.

Download Full-text