Abstract
The ability to measure drivers’ physiological responses is important for understanding their state and behavior under different driving conditions. Such measurements can be used in the development of novel user interfaces, driver profiling, advanced driver assistance systems, etc. In this paper, we present a user study in which we performed an evaluation of two commercially available wearable devices for assessment of drivers’ physiological signals. Empatica’s E4 wristband measures blood volume pulse (BVP), inter-beat interval (IBI), galvanic skin response (GSR), temperature, and acceleration. Bittium’s Faros 360 is an electrocardiographic (ECG) device that can record up to 3-channel ECG signals. The aim of this study was to explore the use of such devices in a dynamic driving environment and their ability to differentiate between different levels of driving demand. Twenty-two participants (eight female, 14 male) aged between 18 and 45 years old participated in the study. The experiment compared three phases: Baseline (no driving), easy driving scenario, and demanding driving scenario. Mean and median heart rate variability (HRV), standard deviation of R–R intervals (SDNN), HRV variables for shorter time frames (standard deviation of the average R–R intervals over a shorter period—SDANN and mean value of the standard deviations calculated over a shorter period—SDNN index), HRV variables based on successive differences (root mean square of successive differences—RMSSD and percentage of successive differences, greater than 50 ms—pNN50), skin temperature, and GSR were observed in each phase. The results showed that motion artefacts due to driving affect the GSR recordings, which may limit the use of wrist-based wearable devices in a driving environment. In this case, due to the limitations of the photoplethysmography (PPG) sensor, E4 only showed differences between non-driving and driving phases but could not differentiate between different levels of driving demand. On the other hand, the results obtained from the ECG signals from Faros 360 showed statistically significant differences also between the two levels of driving demand.
Highlights
The human factor is still one of the leading causes for road traffic accidents
Intervals over a shorter period—SDANN and mean value of the standard deviations calculated over a shorter period—standard deviation of R–R intervals (SDNN) index), heart rate variability (HRV) variables based on successive differences, skin temperature, and galvanic skin response (GSR) were observed in each phase
The results of HRV measurements are presented in four groups: Mean, standard deviation, shorter time-frame variables and successive differences, followed by skin temperature and GSR measurements
Summary
The human factor is still one of the leading causes for road traffic accidents. It has been reported that more years of life were lost due to traffic accidents than due to most human diseases [1]. Driving is a demanding process, mostly relying on the driver’s visual and manual senses, and largely to their auditory and cognitive capabilities. Vehicle manufactures have been constantly working on reducing the driver’s role and improving the driving experience by adding a number of advanced driver-assistance systems (ADAS) and including user-friendly in-vehicle information systems (IVIS). The driver’s role is changing, people spend more time in a vehicle compared to ever before, Appl.
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