A Study on the Correlation Between Vehicle Control Behaviors and Rear-end Collision Risk under Foggy Conditions
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摘要: 为分析驾驶人在雾天环境下的车辆操纵行为特性及其与追尾风险的内在关系,设计并开展驾驶模拟试验,采用方差分析,混合效应模型等对晴天、雾天2种环境下驾驶人的车辆操纵行为特性进行对比分析,并利用相关性分析及二元Logistics回归模型对避撞过程中行为间的相互作用及其与追尾风险间的关系进行挖掘。结果表明:雾天环境下驾驶人的车道偏移标准差比晴天环境下大20.8%,表明雾天环境下驾驶人的车辆保持能力较差;同时,驾驶人在雾天环境下为持续获得前车视野保持的车头时距比晴天条件下小0.423 s;雾天时驾驶人在追尾避撞阶段的平均减速度是晴天时的1.1倍;受到初始车头时距的影响,雾天时驾驶人在避撞过程中的最小车头时距相较于晴天减少了0.475 s,此时最小车头时距的减少导致雾天环境下发生追尾碰撞的风险较于晴天环境增加了4.93倍。Abstract: In order to analyze the characteristics of vehicle control behaviors and study its relationship with rear-end collision risk under foggy conditions, a driving simulationexperiment is conducted, and corresponding behaviors under foggy weather is compared with that under good visibility using ANONA and mixed-effect regression model. Further, the relationship between vehicle control behavior and rear-end collision risk is investigated by correlation analysis and a binary logistic regression model. The results show that the standard deviations of lane departure under foggy conditions are 20.8% higher than that under good visibility conditions, indicates poor vehicle control of drivers under foggy conditions. Besides, drivers prefer to keep shorter time headway, in order to maintain a good vision to the vehicles in front under foggy weather. It is also found that, during the process of avoiding rear-end collision, average deceleration underfoggy weather is 1.1 times of that under good weather. Moreover, study results show that the average minimum time headway under foggy conditions is 0.475 s shorter than that undergood visibility conditions, which results in the rear-end collision risk increases by 4.93 times.
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图 5 不同性别、职业以及性别和职业的交互作用下驾驶人的横向偏移标准差
Figure 5. Effect of gender and occupation and gender and occupation on standard deviation of lane position
图 6 不同职业驾驶人在不同天气下的横向平均加速度
Figure 6. Effect of weather and occupation on average lateral accelerations
图 7 不同天气下驾驶人在不同速度等级下的初始车头时距
Figure 7. Effect of weather and following vehicle's speed on initial time headway
图 8 不同天气下不同职业驾驶人的平均减速度
Figure 8. Effect of weather and vehicle's occupation on average decelerations
图 9 不同天气下驾驶人在不同速度等级下的初始车头时距
Figure 9. Effect of weather and following vehicle's speed on minimum headway
图 10 关联分析结果
注:“*”为0.01 < P ≤ 0.05;“**”为0.001 < P ≤ 0.01;“***”为 P<0.001
Figure 10. Correlation analyses between vehicle control behaviour and rear-end collision risk
表 1 变量定义及符号描述
Table 1. Variable definitions and symbolic descriptions
阶段 变量描述 符号/单位 跟驰阶段 车道偏移距离标准差(standard deviation of lane position)前车开始减速时刻前3 s内主车偏离车道中心线距离的标准差 SDLP/m 平均横向加速度(average lateral acceleration)前车开始减速时刻前3 s内主车横向速度变化快慢程度的平均值 AVELA/(m/s2) 初始车头时距(initial time headway)前车开始减速时刻2车的车头时距 THWB/s 避撞阶段 减速反应时间(brake response time)前车开始减速时刻到主车开始减速时刻的持续时间 BRT/s 平均减速度(average deceleration)主车避撞过程中减速度的平均值 AVED/(m/s2) 最小车头时距(minimum time headway)主车避撞过程中2车最小车头时距 MinTHW/s 
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表 2 跟驰阶段各变量在天气因素下的描述性统计和方差分析结果
Table 2. Results of descriptive statistics and analysis of variance of the variables in the car-following phase under weather factors
行为变量 分类 平均值 F值 Sig. 车道偏移标准差/m 晴天 0.024 4.388 0.037 雾天 0.029 横向平均加速度/(m/s2) 晴天 0.001 0.138 0.710 雾天 < 0.001 初始车头时距/s 晴天 2.814 19.921 < 0.001 雾天 2.391
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表 3 避撞阶段各变量在天气因素下的描述性统计和方差分析结果
Table 3. Results of descriptive statistics and analysis of variance of variables under weather factors during collision avoidance phase
行为变量 分类 平均值 F值 Sig. 减速反应时间/s 晴天 1.415 0.037 0.847 雾天 1.441 平均减速度/(m/s2) 晴天 3.882 8.475 0.004 雾天 4.289 最小车头时距/s 晴天 2.384 42.049 < 0.001 雾天 1.909
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表 4 减速反应时间的混合效应模型
Table 4. Mixed effect model of brake response time
参数 估算 标准误差 t 95% 置信区间 下限 上限 截距 0.120 0.076 1.575 -0.030 0.269 职业 0.111 0.046 -2.407 -0.201 -0.020 车头时距/s 0.475 0.025 19.199 0.427 0.524 主车速度/(m/s) 0.355 0.058 6.126 0.241 0.470
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