Estimation method of operational safety risk for mixed traffic flow on expressway
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摘要:
基于收费数据,考虑车流构成和安全风险成因,确定了车流饱和度、重型货车混入率为影响事故率的2个关键参数,提出了每个参数的算法、阈值及生成流程;模型采用Pearson相关系数法分析了参数之间的独立性,引入变异系数分析了参数与事故率之间的离散度;通过模拟昆虫在不同食物密度下的进食特征,结合多项式拟合方法,提出了高速公路混行车流运行安全风险评估模型;采用Taylor级数展开法和Levenberg-Marquardt算法分别完成模型求解和迭代过程;基于四川省域684个实例路段的数据确定了模型的待标定参数,验证了模型的可行性。研究结果表明:安全风险评估模型能够有效反映各路段事故率的特征;模型迭代523次后离散统计量达到1%的误差要求,耗时1.42 s;车流饱和度、重型货车混入率对事故率的致因分别符合Peal-Reed模型、三次多项式的特征;当车流饱和度为33%且重型货车混入率为71%时,混行车流运行安全风险达到最大值;以路段事故率在[0.01,1.03]内按10.20%递增且通过合并分组后发现,路段事故率划分为5个等级且搭配5种配色可清晰地表达路网安全风险状况;以85%、15%分位数划分重型货车混入率、车流饱和度可实现对参数取值范围的全覆盖。安全风险评估方法对动态监测高速公路交通安全、指导应急资源选址配额、配置警力与路政、疏散车流等研究有重要价值。
Abstract:Based on toll collection data, this study identified two key parameters affecting accident rates by considering traffic flow composition and the causes of safety risks: traffic flow saturation and the mixing rate of heavy-duty trucks. The algorithm, threshold values, and generation process for each parameter were proposed. The Pearson correlation coefficient method was employed to analyze the independence between the two parameters, and the coefficient of variation was introduced to examine their dispersion relative to the accident rate. By simulating insect feeding characteristics under varying food densities and incorporating polynomial fitting, a safety risk assessment model for mixed traffic flow on expressways was developed. The model was solved using the Taylor series expansion method and iteratively optimized with the Levenberg-Marquardt algorithm. The model's parameters were calibrated using data from 684 expressway sections in Sichuan Province, and its feasibility was verified. The research results indicate that the proposed safety risk assessment model effectively captures the accident rate characteristics of different sections. After 523 iterations, the model achieves a discrete statistical error of 1%, requiring only 1.42 s. The influence of traffic flow saturation and the mixing rate of heavy-duty trucks on the accident rate aligns with the Peal-Reed model and a cubic polynomial model, respectively. The safety risk of mixed traffic flow peaks when traffic flow saturation reaches 33% and the mixing rate of heavy-duty trucks reaches 71%. By incrementally increasing the accident rate by 10.20% within [0.01, 1.03] and subsequently merging groups, it is found that dividing the accident rate into five levels, each represented by a distinct color scheme, can clearly illustrate the safety risk status of the expressway network. Using the 85th and 15th percentiles to define the mixing rate of heavy-duty trucks and traffic flow saturation, respectively, ensures comprehensive coverage of the parameter ranges. The proposed safety risk assessment method holds significant value for dynamically monitoring expressway traffic safety, guiding the allocation of emergency resources, optimizing the deployment of police and road administration personnel, and facilitating evacuation strategies.
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表 1 行车安全风险参数计算方法
Table 1. Calculation method for driving safety risk parameters
关键参数 计算方法 TCD约束条件 符号定义 车流饱和度Sj $ \begin{gathered} S_j=\sum\limits_{i=1}^{10} k_i Q_{i j} /\left(m_{j 1} C_{j \mathrm{~d} 1}+m_{j 2} C_{j \mathrm{~d} 2}\right) \\ C_{j \mathrm{~d} 1}=0.99 C_1 f_{\mathrm{c} j} \\ C_{j \mathrm{~d} 2}=0.99 C_2 f_{\mathrm{c} j} \\ f_{\mathrm{c} j}=1 /\left[1+\sum\limits_{i=1}^{10} P_{i j}\left(k_i-1\right)\right] \end{gathered}$ C1=2 200 pcu·h-1·车道-1
C2=2 100 pcu·h-1·车道-1
mj1=1, 2
mj2=1, 2, 3mj1为j路段120 km·h-1设计时速的车道数;
mj2为j路段100 km·h-1设计时速的车道数;
Cjd1为j路段120 km·h-1设计时速的通行能力;
Cjd2为j路段100 km·h-1设计时速的通行能力;
fcj为j路段的交通组成系数;
Pij为i类车j路段的交通量比例;
Qij为i类车j路段的自然交通量。重型货车混入率Mj $ M_j=\sum\limits_{i=7}^{10} k_i Q_{i j} /\left(\sum\limits_{i=1}^{10} k_i Q_{i j}\right)$ Mj∈(0, 100%]
t∈(0, 1 440] min
Vjk∈[60, 140] km·h-1
Vjh∈[40, 100] km·h-1Vjk为客车j路段的车速;
Vjh为货车j路段的车速;
t为通行时间。表 2 安全评估风险标准的等级与配色方案
Table 2. Level and color scheme for estimation standard of driving safety risk
Pj/% Zj/[次·(d·100 km)-1] 颜色标记 路段示例 Pj≤25.00 0.01≤Zj≤0.26 绿色G 
25.00<Pj≤54.69 0.26<Zj≤0.57 黄色Y 54.69<Pj≤80.39 0.57<Zj≤0.83 橙色O 80.39<Pj≤90.78 0.83<Zj≤0.94 鲜红R 90.78<Pj≤100.00 0.94<Zj≤1.03 深红C 表 3 Sj与Mj分区间的Zj安全风险分布
Table 3. Distribution for safety risk of Zj by dividing Sj and Mj
Sj Mj [0, 15%] (15%, 40%] (40%, 60%] (60%, 85%] (85%, 100%] [0, 15%] [0.201, 0.607] G→O (0.405, 0.687] Y→O (0.374, 0.676] Y→O (0.225, 0.579] G→Y→O (0.188, 0.432] G→Y (15%, 40%] (0.195, 0.602] G→O (0.399, 0.682] Y→O (0.368, 0.671] Y→O (0.219, 0.574] G→Y→O (0.182, 0.427] G→Y (40%, 60%] (0.423, 0.894] Y→O (0.627, 0.973] O→C (0.596, 0.963] O→C (0.447, 0.866] Y→O→R (0.410, 0.718] Y→O (60%, 85%] (0.606, 0.953] O→R→C (0.810, 1.030] O→R→C (0.780, 1.023] O→R→C (0.630, 0.925] O→R (0.594, 0.778] O (85%, 100%] (0.028, 0.778] G→Y→O (0.232, 0.857] G→Y→O→R (0.202, 0.847] G→Y→O→R (0.053, 0.750] G→Y→O (0.016, 0.602] G→Y→O -
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