Optimizing Policy on Artery Signal Control of Dual Separated Roads

Journal of Transportation Systems Engineering and Information Technology ›› 2010, Vol. 10 ›› Issue (1): 59-66 .

• Intelligent Transportation System and Information Technology • Previous Articles Next Articles

Optimizing Policy on Artery Signal Control of Dual Separated Roads

LIANG Xiao¹; PENG Hong-qin¹; SUN Zhuang-zhi²; GUO Ji-fu²

1.MOE Key Laboratory for Urban Transportation Complex Systems Theory and Technology, Beijing Jiaotong University, Beijing 100044, China；2.Beijing Transport Research Center, Beijing 100055, China

Received:2009-08-15 Revised:2009-10-06 Online:2010-02-25 Published:2010-02-25
Contact: PENG Hong-qin

双向有隔离路段干线交通信号优化实施策略

梁肖¹;彭宏勤^*1;孙壮志2;郭继孚²

1.北京交通大学城市交通复杂系统理论与技术教育部重点实验室，北京 100044； 2.北京交通发展研究中心，北京 100055

通讯作者: 彭宏勤
作者简介:梁肖(1984-)，女，山东省德州市人，博士生
基金资助:
国家重点基础研究发展计划项目(2006CB705507)；国家自然科学基金项目(70631001)；北京市教委产学研联合博士生培养基地建设项目(BJ2009-04)

Abstract

Abstract: The artery traffic signal control system is one of the most effective ways to reduce automobile running delay. In this paper, an artery traffic signal control optimization model is proposed based on the optimal system period and signal skewing, aiming at achieving the minimum of system delays and maximum of passing bandwidth. Taking the example of Zaojunmiao Road and Daliushu Road, an arterial dual separated road with four signalized intersections in Beijing, the paper proposes two optimization strategies of the artery signal control. The software VISSIM is used to simulate and evaluate the situations, including previous conditions and optimization. Simulation results show that the usage of overlapping signal phase generates better solutions for artery traffic control system, especially in the city like Beijing with more pedestrian volume and closer intersection layout. With the optimization control strategies advanced in the paper, it may expect that the total intersection signal delays of the roads decrease by 59.6％, and the average travel speed increases by 140.0％ and 51.7％ into and out of town respectively, where the traffic congestion has been greatly released.

Key words: urban traffic, artery traffic signal control system, traffic simulation, offset optimization, phase sequence

摘要： 干线交通控制系统能有效减少机动车运行延误. 本文以系统延误最小和绿波带宽最大为目标，构建了基于系统周期和相位差最优的干线交通控制模型，以双向有隔离的北京城市主干路——皂君庙路—大柳树路（含4个信控交叉口）为实例，提出了两种线控优化方案，通过VISSIM仿真对该交叉口及其所在路段优化前后的交通状况进行了比较. 结果表明：在北京市这类行人流量较大、交叉口布局紧凑的道路条件下，采用重叠相位能更好地优化线控系统；应用本文提出的控制策略对该路段进行线控优化后，交叉口总信控延误减小了59.6％，主线上的南向北和北向南平均行程速度分别提高了140.0％和51.7％，交通运行效率显著提高.

关键词: 城市交通, 线控交通系统, 交通仿真, 相位差优化, 相位相序

CLC Number:

U491

LIANG Xiao, PENG Hong-qin, SUN Zhuang-zhi, GUO Ji-fu. Optimizing Policy on Artery Signal Control of Dual Separated Roads[J]. Journal of Transportation Systems Engineering and Information Technology, 2010, 10(1): 59-66 .

梁肖,彭宏勤,孙壮志2,郭继孚. 双向有隔离路段干线交通信号优化实施策略[J]. 交通运输系统工程与信息, 2010, 10(1): 59-66 .

Add to citation manager EndNote|Ris|BibTeX

URL: http://www.tseit.org.cn/EN/abstract/abstract17919.shtml

http://www.tseit.org.cn/EN/Y2010/V10/I1/59

References

［1］万绪军, 陆化普. 线控系统中相位差优化模型的研究［J］. 中国公路学报, 2001, 14(2):99-102.［WAN X J, LU H P. An optimal offset model for artery traffic signal control system［J］. China Journal of Highway and Transport, 2001, 14(2):99-102.］

［2］Pappis C P, Mamdani E H. A fuzzy logic controller for a traffic junction［J］. IEEE Transactions on Systems Man and Cybernetics, 1977, 1(10):707-717.

［3］Teply S, Hunt J D. Reviewing the basic of signal coordination, through bands, green bands and cyclic flow profiles［J］. Management and Control of Urban Traffic System, 1987: 197-15.

［4］Lee J H, LEE K H. Distributed and cooperative fuzzy controllers for traffic intersections group［J］. IEEE Transactions on Systems Man and Cybernetics Part C. Applications and Reviews, 1999, 29(2): 263-271.

［5］陈森发, 毛岚. 城市交通信号灯模糊线控制及其仿真［J］. 系统仿真学报, 2000,12(6): 668-670.［CHEN S F, MAO L. Fuzzy line control and simulation for urban traffic lights［J］. Journal of System Simulation, 2000, 12(6): 668-670.］

［6］陈丕刚. 多交叉口信号模糊线控制模型研究［J］. 交通运输系统工程与信息, 2003, 3(5): 43-46.［CHEN P G. Study of fuzzy line control for multiple intersections［J］. Transportation Systems Engineering and Information Technologe, 2003, 3(5): 43-46.］

［7］周力, 唐诗忠. 城市交通干线智能线控系统研究［J］. 电子科技大学学报, 2007, 36(4): 744-747.［ZHOU L, TANG S Z. Research on the intelligent line control system of the city traffic trunk line［J］. Journal of University of Electronic Science and Technology of China, 2007, 36(4): 744-747.］

［8］毛保华, 杨肇夏, 陈海波. 道路交通仿真技术与系统综述［J］. 北方交通大学学报, 2002,26(5):37-46.［MAO B H, YANG Z X, CHEN H B. Review of simulation technologies and systems［J］. Journal of Northern Jiaotong University, 2002,26(5):37-46.］

［9］Little J D C. The synchronization of traffic signals by mixed-integer linear programming［J］. Operations Research, 1996, 14:568-594 ［10］Gartner N. H and Chronis Stamatiadis. Progression optimization featuring arterial and route-based priority signal networks［J］. Intelligent Transportation System, 2004, 8:77-86.

［11］郭谨一,刘爽,陈绍宽,等.基于Synchro的感应信号控制交叉口仿真研究［J］. 交通运输系统工程与信息, 2004, 4(4):68-71,85.［GUO J Y, LIU S, CHEN S K, et al. Study on actuated signal controlled intersection a synchro-based［J］. Transportation Systems Engineering and Information Technologe, 2004, 4(4):68-71, 85.］

［12］全永燊.控制［M］. 北京:人民交通出版社,1989.［QUAN Y S. Urban traffic control［M］. Beijing: China Communications Press, 1989.］

[1]	LIU Xiao-bing , LI Feng-xiao , TIAN Xin-mei, YAN Xue-dong. Identifying Metropolitan Center Structure Based on Commuting Patterns [J]. Journal of Transportation Systems Engineering and Information Technology, 2022, 22(2): 17-28.
[2]	XU Qi, CHEN Yue , HUANG Jing-ru , GAO Shun-xiang , ZHANG Zhi-jian. Job Accessibility Analysis Considering Travel Cost [J]. Journal of Transportation Systems Engineering and Information Technology, 2022, 22(2): 37-44.
[3]	LIU Chun-yu , LIU Yong-hong , LUO Xia , ZHU Ying. Trajectory Optimization of Connected Vehicles at Isolated Intersection in Mixed Traffic Environment [J]. Journal of Transportation Systems Engineering and Information Technology, 2022, 22(2): 154-162.
[4]	ZHANG Xiao-yu , SHAO Chun-fu , WANG Bo-bin , HUANG Shi-chen. Travel Mode Choice Analysis with Shared Mobility in Context of COVID-19 [J]. Journal of Transportation Systems Engineering and Information Technology, 2022, 22(2): 186-196.
[5]	LI Xin , DAI Zhang , LI Huai-yue, HU Jia. Joint Optimization of Urban Rail Transit and Local Bus Transit: Continuous Approximation Approach [J]. Journal of Transportation Systems Engineering and Information Technology, 2022, 22(2): 206-213.
[6]	HAO Yan-xi, LIU Rong-yang, HU Hua , FANG Yong, LIU Zhi-gang. One-way Pedestrian-bicycle Mixed Flow Model and Self-organization Phenomenon [J]. Journal of Transportation Systems Engineering and Information Technology, 2022, 22(2): 223-229.
[7]	ZHAO Chuan-lin , HE Shao-song, SUN Shu-min, WANG Yu-han. Bi-level Optimization Model in Transportation Evacuation Network Based on Rational Inattention [J]. Journal of Transportation Systems Engineering and Information Technology, 2022, 22(2): 239-246.
[8]	CHEN Xiao-hong , LAN Qiu-yu. Interval Optimization Model of Intersection Signal Timing Under Uncertain Traffic Demand [J]. Journal of Transportation Systems Engineering and Information Technology, 2022, 22(2): 247-256.
[9]	LI Bing, WANG Zheng-hui, MA Ming-wei, YANG Hong-yu, FENG Yue. Capacity and Delay of Right-turn Vehicles at Signalized Intersections Under Influence of Pedestrian Two-stage Crossing [J]. Journal of Transportation Systems Engineering and Information Technology, 2022, 22(2): 257-267.
[10]	ZHU Tong , QIN Dan, DONG Ao-ran, DU Yu-meng, WEI Wen. Relational Analysis Between Bus Drivers' Violation Type and Traffic Accident [J]. Journal of Transportation Systems Engineering and Information Technology, 2022, 22(2): 322-329.
[11]	MAO Bao-hua , WANG Min , HO Tin-kin , CHEN Hai-bo. A Review and Prospect of Urban Public Transit Level-of-Service Research [J]. Journal of Transportation Systems Engineering and Information Technology, 2022, 22(1): 2-13.
[12]	ZONG Fang , WANG Meng, HE Zheng-bing. A Molecular Dynamics-based Car-following Model for Connected and Automated Vehicles Considering Impact of Multiple Vehicles [J]. Journal of Transportation Systems Engineering and Information Technology, 2022, 22(1): 37-48.
[13]	WANG Zi-jia , JIA Hui-hui, ZHU Ya-di , CHEN Feng. Commuting Mode Choice Behavior in Rail and Bus Composite Network Based on Smart Card Data [J]. Journal of Transportation Systems Engineering and Information Technology, 2022, 22(1): 67-73.
[14]	JIA Bin , ZHU Ling, LI Shu-kai, LIU Jia-lin. Collaborative Optimization Strategy of Short-turning Plan and Passenger Flow Control in Urban Rail Transit [J]. Journal of Transportation Systems Engineering and Information Technology, 2022, 22(1): 124-132.
[15]	MOU Zhen-hua , WANG Han-bing , LIN Ben-jiang , CHEN Yi-qun, JIN Cheng-cheng , CHEN Yan-yan. Utility Simulation Evaluation of Dynamic Fines Strategy for Illegal Parking Based on Evolutionary Game [J]. Journal of Transportation Systems Engineering and Information Technology, 2022, 22(1): 152-162.

Optimizing Policy on Artery Signal Control of Dual Separated Roads

双向有隔离路段干线交通信号优化实施策略

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics