设置排阵式预信号的干线交通信号协调控制优化

李岩; 史旋; 南斯睿; 朱才华

doi:10.19818/j.cnki.1671-1637.2024.02.017

设置排阵式预信号的干线交通信号协调控制优化

doi: 10.19818/j.cnki.1671-1637.2024.02.017

李岩^1,,
史旋¹,
南斯睿²,
朱才华^{1, 3}

1.
长安大学运输工程学院，陕西西安 710064
2.
东南大学交通学院，江苏南京 211189
3.
河南农业大学机电工程学院，河南郑州 450002

基金项目:

国家自然科学基金项目 72371035

陕西省自然科学基础研究计划项目 2020JM-237

详细信息

作者简介:
李岩(1983-)，男，河北衡水人，长安大学教授，工学博士，从事交通信号控制与智能交通系统研究

中图分类号: U491.54
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- 文章访问数: 391
- HTML全文浏览量: 35
- PDF下载量: 48
- 被引次数: 0
出版历程
- 收稿日期: 2023-11-27
- 网络出版日期: 2024-05-16
- 刊出日期: 2024-04-30

Optimization of arterial traffic signal coordinated control with tandem pre-signal

LI Yan^1
,,
SHI Xuan¹,
NAN Si-rui²,
ZHU Cai-hua^{1, 3}

1.
School of Transportation Engineering, Chang'an University, Xi'an 710064, Shaanxi, China
2.
School of Transportation, Southeast University, Nanjing 211189, Jiangsu, China
3.
College of Mechanical and Electrical Engineering, Henan Agricultural University, Zhengzhou 450002, Henan, China

Funds:

National Natural Science Foundation of China 72371035

Natural Science Basic Research Project of Shaanxi Province 2020JM-237

More Information

Author Bio:
LI Yan(1983-), male, professor, PhD, lyan@chd.edu.cn

摘要

摘要: 为提升干线道路整体的车流运行效率，建立了一种优化设置排阵式预信号的干线交通信号协调控制系统配时方案的双层模型，并提出对应求解算法；双层模型的上层模型为主信号间相位差优化模型，采用遍历搜索算法优化主信号各交叉口间的相位差；下层模型是以通过车辆数、车均延误为优化目标的多目标优化模型，建立了多目标花朵授粉算法(FPA)对其求解；双层模型中的交通参数通过冲击波建模进行关联，通过上下层模型的迭代求得参数的最优解；以设置排阵式预信号后3个连续交叉口为研究对象，应用提出模型优化高、低2种交通需求下的干线道路交通信号协调配时方案，通过SUMO软件测试所选方案的有效性。研究结果表明：该双层模型能够优化设置排阵式预信号的干线交通信号协调配时方案，与传统干线信号协调控制方案相比，提出方法的配时方案在高、低交通需求下系统通过车辆数可分别增加16%~35%与8%~17%，延误分别降低7%~17%与2%~16%；相较于粒子群优化(PSO)算法与二代非支配排序遗传算法(NSGA-Ⅱ)，FPA达到指定精度要求的迭代次数分别减少13和24次。通过仿真结果可知，所提出模型可进一步提升高需求状况下道路的运行效率。
- 交通控制 /
- 排阵式预信号 /
- 干线道路 /
- 交通信号协调控制 /
- 双层模型 /
- 花朵授粉算法
Abstract: To improve the overall traffic flow efficiency, a bi-level model was established for optimizing the timing plans of arterial traffic signal coordinated control system with tandem pre-signals, and its solving algorithm was proposed. The upper-level model of the bi-level model was an optimization model of the offset between main signals, and the traversal search algorithm was employed to solve it between intersections. The lower-level model was a multi-objective optimization model, which selected the throughput vehicles and the average delay time as the optimization objectives. The flower pollination algorithm(FPA) was established to solve the proposed multi-objective optimization model. The traffic parameters in the bi-level model were connected by using the shockwave model. The optimal solutions of the parameters were obtained through the iterations between the upper-level and lower-level models. Three consecutive intersections after setting up tandem pre-signals were chosen to test. The proposed method was applied to optimize the traffic signal coordination timing plan on arterial roads under both high and low traffic demands. The effectiveness of the selected scheme was tested by software SUMO. Research results indicate that the bi-level model can optimize the arterial traffic signal coordination timing plan with tandem pre-signals. Compared with the traditional arterial signal coordinated control plan, the timing plans obtained from the proposed methods can increase the throughput vehicles through the system by 16%-35% and 8%-17%, respectively. Under high and low traffic demands, and the delays reduce by 7%-17% and 2%-16%, respectively. Compared to the particle swarm optimization (PSO) algorithm and non-dominated sorting genetic algorithm-Ⅱ (NSGA-Ⅱ), the FPA requires 13 and 24 fewer iterations to achieve the specified accuracy requirements, respectively. The simulation results indicate that the proposed model can further improve the operational efficiency of road under high demand conditions.
- traffic control /
- tandem pre-signal /
- arterial road /
- traffic signal coordinated control /
- bi-level model /
- flower pollination algorithm

HTML全文

图 1 各排队状态下绿波带宽的时空图

Figure 1. Time-space diagram of green wave bandwidth under various queue conditions

下载: 全尺寸图片幻灯片

图 2 主、预信号系统的车辆到达累计

Figure 2. Cumulative arrival of vehicles in main and pre-signal systems

下载: 全尺寸图片幻灯片

图 3 预信号干线道路系统的几何设计方案

Figure 3. Geometric design scenarios for per-signal arterial road system

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图 4 各交通需求下的主、预信号配时方案

Figure 4. Timing plans at both main signal and pre-signal under various traffic demands

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图 5 各交通需求下的相位差优化结果

Figure 5. Optimization results of offsets under various traffic demands

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图 6 各交通需求下算法的运行效果

Figure 6. Operational effectivenesses of algorithm under various traffic demands

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图 7 算法有效性检验

Figure 7. Algorithms validity check

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表 1 各进口道的交通流量

Table 1. Traffic flow at each entrance

进口道	流向	高(低)交通需求/(pcu·h^-1)(按车道计)
进口道	流向	交叉口1	交叉口2	交叉口3
东	左转	504(252)	548(274)	494(247)
	直行	768(192)	742(371)	776(388)
	右转	562(281)	484(242)	482(241)
西	左转	512(256)	532(266)	502(251)
	直行	762(381)	826(413)	812(406)
	右转	558(279)	478(239)	498(249)
南	左转	542(271)	562(281)	480(240)
	直行	854(427)	842(421)	838(419)
	右转	520(260)	538(269)	546(273)
北	左转	542(271)	562(281)	480(240)
	直行	854(427)	842(421)	938(469)
	右转	522(261)	538(269)	546(273)

下载: 导出CSV

表 2 各算法参数取值

Table 2. Parameter values of each algorithm

算法	参数名称	参数取值
PSO算法	惯性权重γ, 学习因子c₁、c₂, 粒子最大速度v_max	γ=0.9, c₁=c₂=2, v_max=0.5 m·s^-1
NSGA-Ⅱ	变异概率p₁，交叉分布指数p₂	p₁=0.1，p₂=1
FPA	转换概率p，伽马函数Γ(λ)，控制步长比例因子μ	p=0.8，λ=1.5，μ=1

下载: 导出CSV

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