吉林大学学报(工学版) ›› 2023, Vol. 53 ›› Issue (7): 2043-2052.doi: 10.13229/j.cnki.jdxbgxb.20211007

• 交通运输工程·土木工程 • 上一篇    

设置自动驾驶小客车专用车道的六车道高速公路交通流特性

杨柳1,2(),王创业1,2,王梦言1,2,程阳3   

  1. 1.长沙理工大学 公路养护技术国家工程实验室,长沙 410114
    2.长沙理工大学 交通运输工程学院,长沙 410114
    3.美国威斯康辛大学麦迪逊分校 土木与环境工程系,麦迪逊 53706,美国
  • 收稿日期:2021-10-05 出版日期:2023-07-01 发布日期:2023-07-20
  • 作者简介:杨柳(1980-),男,讲师,博士.研究方向:自动驾驶道路设计理论与方法.E-mail: yangliuemail@163.com
  • 基金资助:
    湖南省教育厅科学研究项目(20A009);长沙理工大学公路养护技术国家工程实验室开放基金项目(KFJ190102);长沙理工大学“双一流”国际合作项目(2019IC09)

Traffic flow characteristics of six⁃lane freeways with a dedicated lane for automatic cars

Liu YANG1,2(),Chuang-ye WANG1,2,Meng-yan WANG1,2,Yang CHENG3   

  1. 1.National Engineering Laboratory of Highway Maintenance Technology,Changsha University of Science & Technology,Changsha 410114,China
    2.School of Traffic and Transportation Engineering,Changsha University of Science & Technology,Changsha 410114,China
    3.Department of Civil and Environmental Engineering,University of Wisconsin?Madison,Madison 53706,United States
  • Received:2021-10-05 Online:2023-07-01 Published:2023-07-20

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摘要:

为解决未来高速公路上自动驾驶小客车(AC)、人类驾驶小客车和人类驾驶大货车混行所带来的安全和效率问题,研究了在六车道高速公路上设置AC专用车道的方法及其对交通流的影响。提出了内侧式AC专用车道的隔离方式和出入口布设方法。基于VISSIM建立了包含入口和出口匝道的高速公路模型、车辆模型和驾驶行为模型,高速公路设计速度取120 km/h,货车混入率取0.2。通过模拟实验,研究了设置内侧式AC专用车道后AC渗透率和AC安全车头时距对交通流特性的影响,探讨了AC专用车道对各车型和各车道运行的影响。结果表明:AC渗透率对交通流特性的影响是显著的和非线性的,存在一个最优AC渗透率,使设置了AC专用车道的高速公路具有最大的通行能力、临界密度和平均速度;AC安全车头时距对交通流特性的影响是非线性的,AC安全车头时距越小,对高速公路通行能力的改善效果越显著;AC渗透率对各车型和各车道的流量和平均速度都有显著影响,对AC流量和内侧车道流量的影响最大。

关键词: 道路工程, 高速公路, 自动驾驶小客车, 专用车道, 交通流, 渗透率, 安全车头时距

Abstract:

In order to solve the safety and efficiency problems caused by the mixed operation of automatic cars (AC), human-driving cars and human-driving trucks on freeways in the future, the method of setting an AC dedicated lane on six-lane freeways and its impact on traffic flow are studied. The separation mode and the entrances and exits layout method for inside AC dedicated lane are proposed. The models of vehicles, driving behaviors and freeway sections with entrance and exit ramps are established based on VISSIM. Through simulation experiments in which the freeway design speed is 120 km/h and the truck ratio is 0.2, the effects of AC penetration rate and AC safe headway on traffic flow characteristics after setting an AC dedicated lane are studied, and the effects of the AC dedicated lane on the operation of each vehicle type and each lane are discussed. The results show that the influence of AC penetration rate on traffic flow characteristics is significant and nonlinear; There is an optimal AC penetration rate, which can maximize the capacity, critical density and average speed of the freeway with an AC dedicated lane; The influence of AC safe headway on traffic flow characteristics is nonlinear; The smaller the AC safe headway, the more significant the improvement effect on freeway capacity; The AC penetration rate has significant impacts on the flow rate and average speed of each vehicle type and each lane, especially on the flow rate of AC and inside lane.

Key words: road engineering, freeway, automatic car, dedicated lane, traffic flow, penetration rate, safe headway

中图分类号: 

  • U412

图1

高速公路内侧式AC专用车道布置图"

图2

无AC专用车道高速公路示意图"

图3

设置AC专用车道高速公路示意图"

表1

车辆参数取值"

车辆类型

车辆尺寸(长×宽)/

(m×m)

最大速度/

(km·h-1

加速度/(m·s-2减速度/(m·s-2
最大期望最大期望
AC6×1.81203.01.04.52.5
HC6×1.81203.01.04.52.5
HT18.1×2.55800.60.33.01.0

表2

AC专用车道跟驰模型参数取值"

参数数值参数数值
s0(α)/m2.0α(α)/(m?s-2)4.00
s1(α)/m0.0v0?/(m?s-1)33.33
T/s1.5b(α)/(m?s-2)2.00

表3

HV车道跟驰模型参数说明和标定"

参数名称合理区间标定值
CC0/m

停车时的平均期望

车辆间距

0.5~2.52
CC1/s期望保持的车头时距0.7~21.5
CC2/m跟车变量2~84
CC3进入跟驰状态的阈值-10~-2-4
CC4跟车状态的阈值10.05~20.35
CC5跟车状态的阈值20.05~22
CC6车速震动0~2011.44
CC7/(m·s-2震动加速度0~20.25
CC8/(m·s-2停车加速度2~3.53.5
CC9/(m·s-280 km/h时的加速度0.5~21.5

表4

换道模型参数标定"

车道变换参数前车后车
最大减速度/(m·s-2-4-3
增加-1 m/s2加速度需要的距离/m300200
可接受的减速度/(m·s-2-1-0.5
消散前的等待时间/s9999
最小车头距离(前/后)/m0.5
在慢速车道上超车所需的最小时间间隔/s0
安全距离折减系数0.6
协调刹车的最大减速度/(m·s-2-3

表5

输入流量分配表"

道路类型

入口匝道

输入流量

HV车道

输入流量

AC专用车道输入流量
无AC专用 车道1/4AC+1/4HC+1/4HT3/4AC+3/4HC+3/4HT-
有AC专用 车道1/2AC+1/3HC+1/3HT2/3HC+2/3HT1/2AC

图4

AC渗透率P对交通流特性的影响"

图5

AC安全车头时距T对交通流特性的影响"

图6

设置AC专用车道对各车型的影响"

图7

设置AC专用车道对各车道的影响"

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