Dataset "TRYOUT" for Drowsiness Detection in Drivers
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MotivationDrowsiness is an intermediate condition that fluctuates between alertness and sleep. It reduces the consciousness level and hinders a person from responding quickly to important road safety issues [1]. The American Automobile Association (AAA) has reported that about 24% of 2,714 drivers that participated in a survey revealed being extremely drowsy while driving, at least once in the last month [2]. In 2017, the National Highway Transportation Safety Administration (NHTSA) also reported that 795 fatalities in motor vehicle crash involving drowsy drivers [3]. Drowsy driving has caused about 2.5% of fatal accidents from 2011 through 2015 in the USA, and it is estimated to produce an economic loss of USD 230 billion annually [4]. Klauer et al. have found in their study that drowsy drivers contributed to 22-24% of crashes or near-crash risks [5]. The German Road Safety Council (DVR) has reported that one out of four fatal highway crashes has been caused by drowsy drivers [6]. In a study carried out in 2015, it has been reported that the average prevalence of falling asleep while driving in the previous two years was about 17% in 19 European countries [6]. The results of these studies emphasize the importance of detecting drowsiness early enough to initiate preventive measures. Drowsiness detection systems are intended to warn the drivers before an upcoming level of drowsiness gets critical to prevent drowsiness-related accidents.Intelligent Systems that automate motor vehicle driving on the roads are being introduced to the market step-wise. The Society of Automotive Engineers (SAE) issued a standard defining six levels ranging from no driving automation (level 0) to full driving automation (level 5) [7]. While the SAE levels 0-2 require that an attentive driver carries out or at least monitors the dynamic driving task, in the SAE level 3 of automated driving, drivers will be allowed to do a secondary task allowing the system to control the vehicle under limited conditions, e.g., on a motorway. Still, the automation system has to hand back the vehicle guidance to the driver whenever it cannot control the state of the vehicle any more. However, the handover of vehicle control to a drowsy driver is not safe. Therefore, the system should be informed about the state of the driver.To date, different Advanced Driver Assistance Systems (ADAS) have been made by car manufactures and researchers to improve driving safety and manage the traffic flow. ADAS systems have been benefited from advanced machine perception methods, improved computing hardware systems, and intelligent vehicle control algorithms. By recently increasing the availability of huge amounts of sensor data to ADAS, data-driven approaches are extensively exploited to enhance their performance. The driver drowsiness detection systems have gained much attention from researchers. Before its use in the development of driving automation, drowsiness warning systems have been produced for the direct benefit of avoiding accidents.The aim of the WACHSens project was to collect a big data set to detect the different levels of driver drowsiness during performing two different driving modes: manual and automated. References:[1] M. Awais, N. Badruddin, and M. Drieberg, "A Hybrid Approach to Detect Driver Drowsiness Utilizing Physiological Signals to Improve System Performance and Wearability,"Sensors, vol. 17, no. 9, 2017, doi: 10.3390/s17091991.[2] AAA Foundation for Traffic Safety, "2019 Traffic Safety Culture Index (Technical Report), June 2020," Washington, D.C., Jun. 2020. [Online]. Available: https://aaafoundation.org/2019-traffic-safety-culture-index/[3] National Highway Traffic Safety Administration, "Traffic Safety Facts: 2017 Fatal Motor Vehicle Crashes: Overview," NHTSA's National Center for Statistics and Analysis, 1200 New Jersey Avenue SE., Washington DOT HS 812 603, Oct. 2018. Accessed: Apr. 14 2021. [Online]. Available: https://crashstats.nhtsa.dot.gov/Api/Public/ViewPublication/812603[4] Agustina Garcés Correa, Lorena Orosco, and Eric Laciar, "Automatic detection of drowsiness in EEG records based on multimodal analysis," Medical Engineering & Physics, vol. 36, no. 2, pp. 244–249, 2014, doi: 10.1016/j.medengphy.2013.07.011.[5] S. Klauer, V. Neale, T. Dingus, Jeremy Sudweeks, and D. J. Ramsey, "The Prevalence of Driver Fatigue in an Urban Driving Environment : Results from the 100-Car Naturalistic Driving Study," in 2006.[6] Fraunhofer-Gesellschaft,Eyetracker warns against momentary driver drowsiness - Press Release Oktober 12, 2010. [Online]. Available: https://www.fraunhofer.de/en/press/research-news/2010/10/eye-tracker-driver-drowsiness.html (accessed: Apr. 14 2021).[7] T. Inagaki and T. B. Sheridan, "A critique of the SAE conditional driving automation definition, and analyses of options for improvement," Cogn Tech Work, vol. 21, no. 4, pp. 569–578, 2019, doi: 10.1007/s10111-018-0471-5.
驾驶嗜睡是介于清醒与睡眠之间的过渡状态,其意识水平会出现波动,会降低个体意识程度,妨碍其快速响应重要的道路安全问题[1]。美国汽车协会(American Automobile Association, AAA)的调查显示,在2714名受访驾驶员中,约24%的人在过去一个月内至少出现过一次驾车时极度嗜睡的情况[2]。2017年,美国国家公路交通安全管理局(National Highway Transportation Safety Administration, NHTSA)同样发布数据称,涉及疲劳驾驶员的机动车碰撞事故共造成795人死亡[3]。2011年至2015年间,美国约2.5%的致命事故由疲劳驾驶引发,据估算其每年造成的经济损失高达2300亿美元[4]。Klauer等人的研究表明,22%~24%的碰撞事故或临界碰撞风险均由疲劳驾驶员所致[5]。德国道路安全委员会(German Road Safety Council, DVR)发布报告称,四分之一的高速公路致命事故由疲劳驾驶引发[6]。2015年的一项研究显示,在19个欧洲国家中,过去两年内驾车时睡着的平均患病率约为17%[6]。上述研究结果均强调了尽早检测驾驶员嗜睡状态并采取预防措施的重要性。嗜睡检测系统的设计目标是在驾驶员嗜睡程度达到临界值前发出预警,以避免与疲劳驾驶相关的事故发生。
可实现道路机动车自动驾驶的智能系统正逐步推向市场。美国汽车工程师学会(Society of Automotive Engineers, SAE)发布了一项标准,将自动驾驶等级划分为六级,从无自动驾驶功能(0级)到完全自动驾驶功能(5级)[7]。SAE 0至2级要求驾驶员保持专注,亲自执行或至少监控动态驾驶任务;而在SAE 3级自动驾驶场景中,驾驶员可进行次要任务,系统可在有限条件(如高速公路)下控制车辆。但当系统无法再管控车辆状态时,需将车辆操控权交回驾驶员。然而,将车辆控制权移交至处于嗜睡状态的驾驶员并不安全,因此系统需要获取驾驶员的状态信息。
迄今为止,车企与研究者已开发出多种先进驾驶辅助系统(Advanced Driver Assistance Systems, ADAS),用于提升驾驶安全性并优化交通流。ADAS系统得益于先进的机器感知方法、高性能计算硬件与智能车辆控制算法。近年来,随着ADAS可获取的传感器数据量大幅提升,数据驱动方法被广泛用于提升系统性能。驾驶员嗜睡检测系统也因此受到研究者的广泛关注。在应用于自动驾驶开发之前,嗜睡预警系统便已被用于直接避免交通事故的发生。
WACHSens项目的目标是收集大规模数据集,用于在两种不同驾驶模式(手动驾驶与自动驾驶)下检测驾驶员不同程度的嗜睡状态。
参考文献:
[1] M. Awais、N. Badruddin与M. Drieberg,《利用生理信号检测驾驶员嗜睡以提升系统性能与可穿戴性的混合方法》,《Sensors》,2017年,第17卷第9期,DOI: 10.3390/s17091991。
[2] 美国公路安全保险协会(AAA Foundation for Traffic Safety),《2019年道路安全文化指数(技术报告)》,2020年6月,华盛顿特区,2020年6月。[在线]. 可获取:https://aaafoundation.org/2019-traffic-safety-culture-index/
[3] 美国国家公路交通安全管理局,《道路安全事实:2017年致命机动车碰撞事故综述》,NHTSA国家统计与分析中心,新泽西大道东南1200号,华盛顿特区,DOT HS 812 603,2018年10月。访问时间:2021年4月14日。[在线]. 可获取:https://crashstats.nhtsa.dot.gov/Api/Public/ViewPublication/812603
[4] Agustina Garcés Correa、Lorena Orosco与Eric Laciar,《基于多模态分析的脑电信号嗜睡自动检测方法》,《Medical Engineering & Physics》,2014年,第36卷第2期,第244-249页,DOI: 10.1016/j.medengphy.2013.07.011。
[5] S. Klauer、V. Neale、T. Dingus、Jeremy Sudweeks与D. J. Ramsey,《城市驾驶环境下驾驶员疲劳患病率:100车自然驾驶研究结果》,2006年。
[6] 弗劳恩霍夫协会,《眼动追踪仪可预警驾驶员瞬时嗜睡——2010年10月12日新闻稿》。[在线]. 可获取:https://www.fraunhofer.de/en/press/research-news/2010/10/eye-tracker-driver-drowsiness.html(访问时间:2021年4月14日)。
[7] T. Inagaki与T. B. Sheridan,《对SAE有条件自动驾驶定义的批判与改进方案分析》,《Cogn Tech Work》,2019年,第21卷第4期,第569-578页,DOI: 10.1007/s10111-018-0471-5。
创建时间:
2022-04-08
搜集汇总
数据集介绍

背景与挑战
背景概述
该数据集名为'TRYOUT',专注于驾驶员疲劳检测,由格拉茨科技大学于2021年发布。它旨在通过收集手动和自动驾驶模式下的数据,支持开发早期疲劳预警系统,以减少交通事故。数据集包含3.6 GB的文件,需遵守非商业研究的数据传输协议,并已有多篇相关研究引用。
以上内容由遇见数据集搜集并总结生成



