Characteristics of Driving Behavior and Performance Caused by Plateau Environment of Young and Middle-aged Drivers
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摘要: 为了量化分析高原环境导致的驾驶行为特征差异,寻找驾驶绩效下降时间窗,运用驾驶模拟器和低氧发生器在平原地区模拟海拔3 900 m高原驾驶环境,开展驾驶模拟试验分别收集驾驶人在平原环境和模拟高原环境的驾驶行为数据和心电图(electrocardiogram,ECG)信号数据。通过对比高原实车试验环境驾驶人的心率指标变化,运用雷达图、数值排序图和单因素方差分析方法对平原、高原环境下的驾驶行为特征进行对比分析,引入Jensen-Shannon散度(JS散度)量化2种环境下横向偏移距离、横向加速度、转向盘旋转率和速度这4个指标的概率密度拟合分布之间的差异,使用差分法确定高原环境下的驾驶绩效下降时间,验证了模拟高海拔环境驾驶模拟试验的有效性研究。结果表明:高原环境下横向偏移距离标准差、横向加速度标准差、转向盘旋转率标准差、速度标准差比平原环境下分别增加了0.094 3 m,0.119 0 m/s2,0.000 9 °/s,0.651 3 km/h,车辆整体稳定性降低;借助JS散度发现横向偏移距离、横向加速度、转向盘旋转率和速度这4个指标在2种环境下的数值分布存在较大距离,分别为0.23,0.11,0.01,0.02,其中车辆的横向运动受负面影响更大;在进入海拔3 900 m的高原地区时,驾驶绩效约在6 min后显著下降。Abstract: To analyze effects of a hypoxic environment on driving performance, a driving simulator experiment is conducted in this study. Both drivers' behavioral data and physiological data are collected by simulating a plateau scenario (3 900 m). The driver behavior characteristics in the plateau scenario and plain scenario are analyzed using a radar map, a numerical ranking map, and one-way ANOVA. The probability density fitting distribution differences between the two scenarios for road offset, steering velocity, lateral acceleration, and speed are quantified using the Jensen-Shannon divergence. The difference method is employed to identify time windows when driving performance decreased in the plateau area. The validity of the simulated hypoxic driving environment is verified by comparing the heart rate trend of the pilot test data in the plateau. The results indicated that: ① the standard deviation of road offset, lateral acceleration, steering velocity, and speed in the plateau scenario increase by 0.094 3 m, 0.119 0 m/s2, 0.000 9 °/s, and 0.651 3 km/h, respectively, compared to the plain scenario; ② the fitted probability density distribution differences between the plateau and plain scenarios for road offset, lateral acceleration, steering velocity, and speed are 0.23, 0.11, 0.01, and 0.02, respectively (thus, it could be inferred that vehicle lateral movement is more affected by the high-altitude factor); ③ driving performance decrease significantly after 6 minutes upon entering the plateau area at 3 900 m altitude.
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Key words:
- traffic safety /
- plateau environment /
- driver behavior /
- Jensen-Shannon divergence /
- driving performance
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图 2 2种环境下24位被试的总行驶里程
Figure 2. Total driving distance of twenty-four subjects in two environments
图 3 2种环境下车辆指标个体差异
Figure 3. The individual differences of vehicle indicators under the two environments
图 4 2种环境下车辆指标群体差异
Figure 4. Group differences of vehicle indicators under the two environments
表 1 横向加速度指标缩小前后对比
Table 1. Comparison before and after reduction of lateral acceleration
行驶里程/m 原始加速度/(m/s2) 缩小加速度/(m/s2) 1 384 2.156 8 0.007 0 1 386 2.156 9 0.007 0 1 388 2.413 1 0.003 9 1 390 -3.028 4 -0.000 9 1 392 -3.026 7 -0.000 9 1 394 -2.200 0 -0.006 3 
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表 2 转向盘旋转率指标变换前后对比
Table 2. Comparison before and after reduction of steering velocity
行驶里程/m 原始旋转率/(°/s) 变换后旋转率/(°/s) 2 202 -0.022 7 2.799 7 2 204 -0.045 4 3.100 8 2 206 -0.109 4 3.482 7 2 208 0.102 3 -3.749 7 2 210 0.042 6 -3.598 0 2 212 0.104 1 -3.753 7
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表 3 各指标在2种环境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 the two environments
指标 平原环境 高原环境 F p 横向偏移距离_标准差/m 0.272 7 0.367 0 162.238 <0.001 横向加速度_标准差/(m/s2) 0.211 4 0.330 4 175.911 <0.001 转向盘旋转率_标准差/(°/s) 0.004 3 0.005 2 41.573 <0.001 速度_标准差/(km/h) 6.459 9 7.111 2 14.481 <0.001
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表 4 心率指标在2种环境下的描述性统计和方差分析结果
Table 4. Results of descriptive statistics and analysis of heart rate under the two environments
指标 心率/(次/min) 平原环境 75.62 高原环境 95.6 F 1 007.94 P <0.001
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表 5 分组情况
Table 5. Grouping
对比分析 组内 交叉 组间 对比组1 P-1 G-1 P-1与G-1混合 P 对比组2 P-2 G-2 P-2与G-2混合 G
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表 6 分组概率密度分布的JS散度值
Table 6. JS divergence calculation results of probability density distribution
指标 组内对比的JS散度值 交叉对比的JS散度值 组间对比的JS散度值 平原环境 高原环境 横向偏移距离 0.00 0.00 0.00 0.23 横向加速度 0.00 0.00 0.00 0.11 转向盘旋转率 0.00 0.00 0.00 0.01 速度 0.00 0.00 0.00 0.02
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