Sensitivity of Lane Position and Steering Angle Measurements to Driver Fatigue

Zhang, Hui; Wu, Chaozhong; Huang, Zhen; Yan, Xinping; Qiu, Tony Z.

doi:10.3141/2585-08

Cited by 20 publications

(41 citation statements)

References 19 publications

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“…Three behavioral indices were calculated to indicate performance in a Go/NoGo tasks: the reaction time (RT) for correct trials, the miss rate for Go stimuli, and the false alarm rate for the NoGo stimuli. Subjective ratings of mental fatigue before and after fatigue manipulation task and the percentage of eye closure (PERCLOS) [ 38 ] and standard deviation of the lane position (SDLP) [ 39 ] in the first and last 30 mins of the simulated driving task were also calculated to reflect the level of mental fatigue. The formulas of reaction time, miss rate, PERCLOS and SDLP are shown in the following: Here, RT was the mean value of the reaction time on Go stimuli, RT k is the reaction time on Go stimuli at number k , n 1 is the amount of Go stimuli that corresponding to correctly.…”

Section: Methodsmentioning

confidence: 99%

The impairing effects of mental fatigue on response inhibition: An ERP study

et al. 2018

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Mental fatigue is one of the main reasons for the decline of response inhibition. This study aimed to explore the impairing influence of mental fatigue on a driver’s response inhibition. The effects of mental fatigue on response inhibition were assessed by comparing brain activity and behavioral indices when performing a Go/NoGo task before and after a 90-min fatigue manipulation task. Participants in the driving group performed a simulated driving task, while individuals in the control group spent the same time watching movies. We found that participants in the driving group reported higher levels of mental fatigue and had a higher percentage of eye closure and larger lateral deviations from their lane positions, which indicated there was effective manipulation of mental fatigue through a prolonged simulated driving task. After manipulation of mental fatigue, we observed increased reaction time and miss rates, delayed NoGo-N2 latency and Go-P3 latency, and decreased NoGo-P3 amplitude, which indicated that mental fatigue may slow down the speed of the inhibition process, delay the evaluation of visual stimuli and reduce the availability of attentional resources. These findings revealed the underlying neurological mechanisms of how mental fatigue impaired response inhibition.

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Section: Methodsmentioning

confidence: 99%

The impairing effects of mental fatigue on response inhibition: An ERP study

et al. 2018

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“…Sahayadhas et al [37] summarize that many studies stated that vehiclebased only measures should not be used as a reliable fatigue predictor. Zhang et al [73] confirmed that lane position and steering features are inconsistent. Krajewski et al [74] describe large inter-and intra-individual differences in fatigued driving patterns, based on literature review.…”

Section: A Vehicle Datamentioning

confidence: 99%

Multimodal Features for Detection of Driver Stress and Fatigue: Review

Němcová

Svozilová

Bucsuházy

et al. 2021

IEEE Trans. Intell. Transport. Syst.

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Driver fatigue and stress significantly contribute to higher number of car accidents worldwide. Although, different detection approaches have been already commercialized and used by car producers (and third party companies), research activities in this field are still needed in order to increase the reliability of these alert systems. Also, in the context of automated driving, the driver mental state assessment will be an important part of cars in future. This paper presents state-of-the-art review of different approaches for driver fatigue and stress detection and evaluation. We describe in details various signals (biological, car and video) and derived features used for these tasks and we discuss their relevance and advantages. In order to make this review complete, we also describe different datasets, acquisition systems and experiment scenarios.

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“…Driving performance is another valuable measurement to confirm the drivers' fatigue status; in this study, the standard deviation of lateral position (SDLP) is used as a verification indicator parameter [47,50,51]; it reflects the driver's ability to avoid unintentional lane departure or lane crossing. e lane line position was collected by Mobileye at a frequency of 10 Hz, the average of SDLP data in one second was processed into new data after filtering and used as a verification indicator, and the SDLP is computed by…”

Section: Journal Of Advanced Transportationmentioning

confidence: 99%

Driving Fatigue Prediction Model considering Schedule and Circadian Rhythm

Zhang

2020

Journal of Advanced Transportation

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Driver fatigue level was considered an accumulated result contributed by circadian rhythms, hours of sleep before driving, driving duration, and break time during driving. This article presents an investigation into the regression model between driver fatigue level and the above four time-related variables. With the cooperation of one commercial transportation company, a Naturalistic Driving Study (NDS) was conducted, and NDS data from thirty-four middle-aged drivers were selected for analysis. With regard to the circadian rhythms, commercial drivers operated the vehicle and started driving at around 09:00, 14:00, and 21:00, respectively. Participants’ time of sleep before driving is also surveyed, and a range from 4 to 7 hours was selected. The commercial driving route was the same for all participants. After getting the fatigue level of all participants using the Karolinska Sleepiness Scale (KSS), the discrete KSS data were converted into consecutive value, and curve fitting methods were adopted for modeling. In addition, a linear regression model was proposed to represent the relationship between accumulated fatigue level and the four time-related variables. Finally, the prediction model was verified by the driving performance measurement: standard deviation of lateral position. The results demonstrated that fatigue prediction results are significantly relevant to driving performance. In conclusion, the fatigue prediction model proposed in this study could be implemented to predict the risk driving period and the maximum consecutive driving time once the driving schedule is determined, and the fatigue driving behavior could be avoided or alleviated by optimizing the driving and break schedule.

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Sensitivity of Lane Position and Steering Angle Measurements to Driver Fatigue

Cited by 20 publications

References 19 publications

The impairing effects of mental fatigue on response inhibition: An ERP study

The impairing effects of mental fatigue on response inhibition: An ERP study

Multimodal Features for Detection of Driver Stress and Fatigue: Review

Driving Fatigue Prediction Model considering Schedule and Circadian Rhythm

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