Recognition and interpretation of aggressive driving behavior for heavy-duty vehicles based on artificial neural network and SHAP

IF 2.2 3区 工程技术 Q3 ENGINEERING, MANUFACTURING
Chuangang Cheng, Shuyan Chen, Yongfeng Ma, Aemal J. Khattak, Ziyu Zhang
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Abstract

Aggressive driving significantly impacts traffic safety, and heavy-duty vehicle drivers are more liable for causing serious crashes. This paper analyzes drivers' aggressive driving behavior from the vehicle type perspective and identifies the influencing factors of aggressive driving behavior through artificial neural network (ANN) and Shapley additive explanations (SHAPs). Using Kaggle's open-source aggressive driving data, we establish an ANN model to identify driving styles, where road conditions, environmental conditions, and vehicle parameters are independent variables and driving style is a dependent variable. The following measurements, including accuracy, recall, precision, and F1 score, are used to evaluate the model's performance, and the neural network got 85.33%, 82.32%, 84.16%, and 0.8308, respectively. To illustrate the influence of independent variables, the SHAP algorithm is used to analyze the model's feature importance. It was found that illumination and weather conditions influenced the model's performance along with the vehicle length. The number of lanes relates to driving style, and there were more aggressive driving behaviors on two-lane roads than on single-lane roads. Besides, heavy-duty vehicle drivers were more likely to drive aggressively in wet road conditions and indulge in aggressive driving behaviors at night. Particularly, drivers of heavy-duty vehicles were more likely to drive aggressively, provided that the vehicle in front was also a heavy-duty vehicle. These findings inform heavy-duty vehicle drivers to reduce aggressive driving behavior. The information is suitable for inclusion in driver education programs, thus improving traffic safety.

基于人工神经网络和 SHAP 的重型车辆攻击性驾驶行为的识别和解释
攻击性驾驶严重影响交通安全,而重型车辆驾驶员在造成严重交通事故方面责任更大。本文从车辆类型的角度分析了驾驶员的攻击性驾驶行为,并通过人工神经网络(ANN)和夏普利加法解释(SHAPs)识别了攻击性驾驶行为的影响因素。利用 Kaggle 的开源攻击性驾驶数据,我们建立了一个 ANN 模型来识别驾驶风格,其中道路条件、环境条件和车辆参数是自变量,驾驶风格是因变量。我们用准确率、召回率、精确率和 F1 分数等指标来评估模型的性能,结果发现神经网络的准确率、召回率、精确率和 F1 分数分别为 85.33%、82.32%、84.16% 和 0.8308。为了说明自变量的影响,使用 SHAP 算法分析模型的特征重要性。结果发现,光照和天气条件与车辆长度一起影响了模型的性能。车道数与驾驶风格有关,双车道道路上的驾驶行为比单车道道路上更激进。此外,重型车辆驾驶员在湿滑路面上更容易激烈驾驶,在夜间也更容易做出激烈驾驶行为。特别是,如果前方车辆也是重型车辆,重型车辆的驾驶员更有可能激烈驾驶。这些发现为重型车辆驾驶员减少攻击性驾驶行为提供了参考。这些信息适合纳入驾驶员教育计划,从而提高交通安全。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
5.20
自引率
8.30%
发文量
37
审稿时长
6.0 months
期刊介绍: The purpose of Human Factors and Ergonomics in Manufacturing & Service Industries is to facilitate discovery, integration, and application of scientific knowledge about human aspects of manufacturing, and to provide a forum for worldwide dissemination of such knowledge for its application and benefit to manufacturing industries. The journal covers a broad spectrum of ergonomics and human factors issues with a focus on the design, operation and management of contemporary manufacturing systems, both in the shop floor and office environments, in the quest for manufacturing agility, i.e. enhancement and integration of human skills with hardware performance for improved market competitiveness, management of change, product and process quality, and human-system reliability. The inter- and cross-disciplinary nature of the journal allows for a wide scope of issues relevant to manufacturing system design and engineering, human resource management, social, organizational, safety, and health issues. Examples of specific subject areas of interest include: implementation of advanced manufacturing technology, human aspects of computer-aided design and engineering, work design, compensation and appraisal, selection training and education, labor-management relations, agile manufacturing and virtual companies, human factors in total quality management, prevention of work-related musculoskeletal disorders, ergonomics of workplace, equipment and tool design, ergonomics programs, guides and standards for industry, automation safety and robot systems, human skills development and knowledge enhancing technologies, reliability, and safety and worker health issues.
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