A hybrid approach to detect driver drowsiness utilizing physiological signals to improve system performance and Wearability

Awais, M. and Badruddin, N. and Drieberg, M. (2017) A hybrid approach to detect driver drowsiness utilizing physiological signals to improve system performance and Wearability. Sensors (Switzerland), 17 (9). ISSN 14248220

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Abstract

Driver drowsiness is a major cause of fatal accidents, injury, and property damage, and has become an area of substantial research attention in recent years. The present study proposes a method to detect drowsiness in drivers which integrates features of electrocardiography (ECG) and electroencephalography (EEG) to improve detection performance. The study measures differences between the alert and drowsy states from physiological data collected from 22 healthy subjects in a driving simulator-based study. A monotonous driving environment is used to induce drowsiness in the participants. Various time and frequency domain feature were extracted from EEG including time domain statistical descriptors, complexity measures and power spectral measures. Features extracted from the ECG signal included heart rate (HR) and heart rate variability (HRV), including low frequency (LF), high frequency (HF) and LF/HF ratio. Furthermore, subjective sleepiness scale is also assessed to study its relationship with drowsiness. We used paired t-tests to select only statistically significant features (p < 0.05), that can differentiate between the alert and drowsy states effectively. Significant features of both modalities (EEG and ECG) are then combined to investigate the improvement in performance using support vector machine (SVM) classifier. The other main contribution of this paper is the study on channel reduction and its impact to the performance of detection. The proposed method demonstrated that combining EEG and ECG has improved the system�s performance in discriminating between alert and drowsy states, instead of using them alone. Our channel reduction analysis revealed that an acceptable level of accuracy (80) could be achieved by combining just two electrodes (one EEG and one ECG), indicating the feasibility of a system with improved wearability compared with existing systems involving many electrodes. Overall, our results demonstrate that the proposed method can be a viable solution for a practical driver drowsiness system that is both accurate and comfortable to wear. © 2017 by the authors. Licensee MDPI, Basel, Switzerland.

Item Type: Article
Additional Information: cited By 178
Uncontrolled Keywords: Automobile drivers; Electrocardiography; Electrodes; Electroencephalography; Electrophysiology; Frequency domain analysis; Heart; Physiology; Support vector machines; Time domain analysis, Channel reduction; Detection performance; Driver drowsiness; Driving environment; Heart rate variability; Physiological signals; Statistical descriptors; Time and frequency domains, Feature extraction, car driving; electrocardiography; electroencephalography; human; sleep stage; support vector machine, Automobile Driving; Electrocardiography; Electroencephalography; Humans; Sleep Stages; Support Vector Machine
Depositing User: Mr Ahmad Suhairi UTP
Date Deposited: 09 Nov 2023 16:20
Last Modified: 09 Nov 2023 16:20
URI: https://khub.utp.edu.my/scholars/id/eprint/8417

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