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动态出口左转车道控制优化研究

杨晓芳 王影

杨晓芳, 王影. 动态出口左转车道控制优化研究[J]. 交通信息与安全, 2021, 39(5): 85-92. doi: 10.3963/j.jssn.1674-4861.2021.05.011
引用本文: 杨晓芳, 王影. 动态出口左转车道控制优化研究[J]. 交通信息与安全, 2021, 39(5): 85-92. doi: 10.3963/j.jssn.1674-4861.2021.05.011
YANG Xiaofang, WANG Ying. Optimization Control of Dynamic Use of Exit-lanes for Left-turn Traffic[J]. Journal of Transport Information and Safety, 2021, 39(5): 85-92. doi: 10.3963/j.jssn.1674-4861.2021.05.011
Citation: YANG Xiaofang, WANG Ying. Optimization Control of Dynamic Use of Exit-lanes for Left-turn Traffic[J]. Journal of Transport Information and Safety, 2021, 39(5): 85-92. doi: 10.3963/j.jssn.1674-4861.2021.05.011

动态出口左转车道控制优化研究

doi: 10.3963/j.jssn.1674-4861.2021.05.011
详细信息
    通讯作者:

    杨晓芳(1975—),博士,副教授.研究方向:智能交通、交通设计、交通规划与管理. E-mail: herryfuyang@126.com

  • 中图分类号: U491.5+4

Optimization Control of Dynamic Use of Exit-lanes for Left-turn Traffic

  • 摘要:

    动态出口左转车道(EFL)设计现已应用于多个城市道路交叉口。为解决该类交叉口在实际运行过程中存在的车流量在各个车道分布不均衡,逆流车道在某些时段使用率不高等问题,对现有的EFL设计及交通控制方案进行改进。研究1种非常规的EFL设计以及动态出口车道灵活配置的方法,并对改进后动态出口左转车道的长度进行优化。基于此,研究驱动信号控制策略,建立非常规EFL设计下的延误计算模型。运用Matlab对常规、改进前、改进后这3种情况下的交叉口信号控制方案进行了对比分析。结果表明:当左转流量为400辆/h时常规交叉口最佳信号周期为130 s,同周期下改进后与常规、改进前的交叉口相比车均延误下降比例分别为39.68%和29.48%;当左转流量为500辆/h时常规交叉口最佳周期为174 s,同周期下改进后较常规、改进前的交叉口车均延误下降比例分别为12.90%和12.02%。

     

  • 图  1  改进后的动态出口左转车道设计

    Figure  1.  Improved left-turn lane design for dynamic exits

    图  2  动态出口左转车道时空图

    Figure  2.  Time-space map of left-turn lane for dynamic exit

    图  3  情况1:动态出口左转车道累计排队长度变化图

    Figure  3.  Scenario 1: variation of cumulative queue length of dynamic EFL

    图  4  情况2:动态出口左转车道累计排队长度变化图

    Figure  4.  Scenario 2: variation of cumulative queue length of dynamic EFL

    图  5  情况3:动态出口左转车道累计排队长度变化图

    Figure  5.  Scenario 3: variation of cumulative queue length of dynamic EFL

    图  6  改进后非常规直行车道累计长度变化图

    Figure  6.  Cumulative length change of the improved straight lane

    图  7  改进前的动态出口左转车道设计

    Figure  7.  Design of dynamic EFL before improvement

    图  8  改进后不同流量左转延误随周期时长变化图

    Figure  8.  The delay of left-turn under different flow rates varying with the cycle length after improvement

    图  9  改进后不同周期长度下左转延误随流量变化图

    Figure  9.  The delay of left-turn under different cycle lengths with the flow rate after improvement

    图  10  不同流量下左转延误随周期变化图

    Figure  10.  The delay of left-turn under different flow rates varying with the cycle

    表  1  参数说明

    Table  1.   Parameter description

    符号 符号意义 下标意义
    Gopt 主信号处最佳左转绿灯时长,s opt代表最优,Optimal
    Qp 高峰时期每个周期的左转需求量,辆/h p代表车辆,pcu
    v 自由流车速,km/h
    ql 进口道左转车辆到达率,辆/h l代表左转,left
    qs 进口道直行车辆到达率辆/h s代表直行,straight
    Z 封闭图形的面积
    S1 上游预交叉口饱和流率,辆/h
    S2 交叉口饱和流率,辆/h
    kj 交叉口的阻塞密度,辆/km j代表拥挤,jam
    ht 交叉口车辆的饱和车头时距,s/辆 t代表时间, time
    hd 交叉口车辆的饱和车头间距,m/辆 d代表距离,distance
    ns 改进前直行车道数,ns=2 s代表直行,straight
    nl 改进前左转车道数,nl=2 l代表左转,left
    nll 改进后动态出口左转车道数,nll=2 ll代表改进后动态出口左转
    rl 交叉口左转红灯时长,s l代表左转,left
    gl 交叉口左转绿灯时长,s l代表左转,left
    tg1 上游预信号绿灯提前启亮时间,s g1代表预信号绿灯提前启亮,green
    tg2 上游预信号绿灯提前关闭时间,s g2代表预信号绿灯提前关闭,green
    l 动态出口左转车道的长度,m
    Qmax 动态出口左转车道所能容纳的最大车辆数,辆 max代表最大
    Dli 改进后情况i下动态出口左转车道的延误,s;i= 1, 2, 3 li代表情况i下的动态出口左转车道
    Ds 改进后动态出口左转车道设计下直行车道的延误,s s代表直行,straight
    下载: 导出CSV

    表  2  不同控制方案下交通流车均延误

    Table  2.   Average vehicle delays under different control plans

    左转流量/(辆/h) 周期/s 车均延误/s 车均延误下降比例/%
    常规 改进前 改进后 较常规 较改进前
    400 130 49.8 42.61 30.05 39.68 29.48
    500 174 64.76 64.12 12.9 12.9 12.02
    下载: 导出CSV
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  • 收稿日期:  2021-01-19

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