双开口式逆流左转车道几何设计及信号配时优化

宋浪; 王健; 杨滨毓; 朱湧

doi:10.3963/j.jssn.1674-4861.2022.03.008

双开口式逆流左转车道几何设计及信号配时优化

doi: 10.3963/j.jssn.1674-4861.2022.03.008

宋浪^{1, 2,},
王健^1, ,,
杨滨毓¹,
朱湧²

1.
哈尔滨工业大学交通科学与工程学院哈尔滨 150090
2.
招商局重庆交通科研设计院有限公司重庆 400067

基金项目:

国家自然科学基金重大研究计划项目 91846301

重庆市技术创新与应用发展专项重点项目 cstc2019jscx-tjsbX0013

详细信息

作者简介:
宋浪（1996—），博士研究生. 研究方向：交通控制、智能交通. E-mail：lang_song@qq.com

通讯作者:
王健（1974—），博士，教授. 研究方向：交通运输规划与管理. E-mail：wang_jian@hit.edu.cn

中图分类号: U491.5
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- 文章访问数: 1042
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- 被引次数: 0
出版历程
- 收稿日期: 2021-12-24
- 网络出版日期: 2022-07-25

A Method for Optimizing Geometric Design and Signal Timing for Contraflow Left-turn Lanes with Double-exits

SONG Lang^{1, 2
,},
WANG Jian^{1
, ,},
YANG Binyu¹,
ZHU Yong²

1.
School of Transportation Science and Engineering, Harbin Institute of Technology, Harbin 150090, China
2.
China Merchants Chongqing Communications Technology Research & Design Institute Co., Ltd, Chongqing 400067, China

摘要

摘要: 为解决单开口式（即仅有1个预信号开口）逆流左转车道（即通过预信号控制动态借用的出口车道）的长度与左转交通需求匹配效果不佳的问题，通过对单开口式逆流左转车道的设计进行分析，提出1种双开口式（即设置2个预信号开口）逆流左转车道的设计及控制方法。结合逆流左转车道的车辆运行规则，分析单开口式、双开口式逆流左转车道上车辆排队行为特征差异，构建逆流左转车道通行能力计算模型和延误计算模型。考虑主预信号协调控制、饱和度、交通波传递等约束条件，以车均延误最小为优化目标，采用0-1变量表示各个预信号开口是否启用，将常规设计、单开口式、双开口式信号配时整合到1个统一的混合整数非线性规划优化模型中，并给出逆流左转车道长度的设计依据。通过案例分析发现：①在逆流左转车道长度为80 m时，交叉口通行能力提升幅度最大；②当通行能力满足需求时，逆流左转车道长度越短，交叉口延误降低越明显；③若为保证通行能力而采用较长的逆流左转车道时，双开口式逆流左转车道通行效率优于单开口式；④综合考虑延误、通行能力等因素，单开口式逆流左转车道长度宜设置为40~60 m，而双开口式宜设置为80 m左右；⑤双开口式逆流左转车道可根据需要选择是否启用每个预信号开口，应用较为灵活，适用于各种流量场景。
- 交通工程 /
- 逆流左转车道 /
- 车道几何设计 /
- 信号优化配时 /
- 出口道左转交叉口 /
- 借道左转车道
Abstract: To solve the problem of ineffective match between the lengths of contraflow left-turn lanes(i.e., dynamic borrowed exit lines through pre-signal control)with single-exit(i.e., one pre-signal exit only)and corresponding traffic demand, a method for optimizing the geometric design and signal timing for contraflow left-turn lanes with double-exits(i.e., two pre-signal exits)is proposed after analyzing the design of contraflow left-turn lanes with single-exit. Based on the observed maneuvers of vehicles in the contraflow left-turn lanes and queuing behaviors of vehicles in left-turn lanes with single-exit and double-exits, their capacity and delay estimation models are developed, respectively. The conventional design methods for signal timing of single-exit and double-exits are integrated into a unified optimization model by introducing a dummy variable to indicate whether each pre-signal exit is enabled. Considering the constraints of coordination between main and pre-signals, saturation and traffic wave transfer, the objective of the model is to minimize the delay per vehicle. Through this model, the basis for designing the length of contraflow left-turn lanes can be obtained. Finally, a case study is carried out, the results indicate that: ①the improvement of intersection capacity is largest when the length of contraflow left-turn lanes is 80 m.②When the capacity of the roads meets traffic demand, the shorter the length of contraflow left-turn lanes, the more significant the reduction of traffic delay at the intersection.③If longer contraflow left-turn lanes are adopted to maintain road capacity, the benefit of contraflow left-turn lanes with double-exits are better than lanes with single-exit.④Considering traffic delay, capacity, and other factors, the length of contraflow left-turn lanes with single-exit is suggested to be 40 to 60 m, while lanes with double-exits should be set around 80 m. ⑤The contraflow left-turn lanes with double-exits are able to control pre-signal exits as requested, which is flexible and suitable for various traffic scenarios.
- traffic engineering /
- contraflow left-turn lane /
- geometric design /
- signal timing optimization /
- exit lanes for left-turn intersection /
- reversible left-turn lane

HTML全文

图 1 单开口式逆流左转车道

Figure 1. Single -exit contraflow left-turn lane

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图 2 双开口式逆流左转车道

Figure 2. Double-exit contraflow left-turn lanes

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图 3 相位方案

Figure 3. Phase scheme

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图 4 逆流左转车道排队行为特征

Figure 4. Queuing characteristics of contraflow left-turn lane

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图 5 逆流左转车道排队间隙现象

Figure 5. Queuing gap phenomenon of contraflow left-turn lane

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图 6 中国重庆市南滨路-烟雨路交叉口

Figure 6. intersection of Nanbin Road and Yanyu Road in Chongqing，China

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图 7 车均延误仿真对比

Figure 7. Comparison of vehicle delay simulation

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图 8 综合功能区总长度影响分析

Figure 8. Influence analysis for total length of comprehensive functional area

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表 1 逆流左转车道长度设置梳理

Table 1. Contraflow left-turn lane length setting

文献	推荐或使用长度/m	设置依据
[6]	70	通行能力
[7]	50
[8]	43, 50, 53	实地调查数据
[9]	60	通行能力、延误
[11]	40, 50	实地调查数据
[12]	40	排队长度、几何特征
[13]	50, 0	实地调查数据
[14]	50
[17]	43, 0, 3	实地调查数据
[18]	50	排队长度、几何特征
[20]	61~91	通行能力
[23]	40, 0	排队长度、几何特征
[24]	40, 45, 50, 55, 60	实地调查数据
[25]	40, 0	排队长度、几何特征
[26]	60	通行能力、延误
[27]	50, 0	实地调查数据
[28]	55	排队长度
[29]	50	排队长度、几何特征
[30]	40~60
[31]	60
[32]	50	排队长度、几何特征
[33]	55	实地调查数据

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表 2 对比方案

Table 2. Schemes for comparison

方案编号	δ₁	δ₂	类型	L_il^p/m	L_il^p₁/m	L_il^p₂/m
1	0	0	常规交叉口
2	1	0	单开口式	13	40	30
3	0	1	单开口式
4	1	1	双开口式
5	0	0	常规交叉口
6	1	0	单开口式	13	50	40
7	0	1	单开口式
8	1	1	双开口式

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表 3 信号配时结果

Table 3. Signal timing result 单位: s

方案编号	流量场景	东西				南北				周期时长
方案编号	流量场景	左转相位时长	直行相位时长	预信号1 启亮/关闭	预信号2 启亮/关闭	左转相位时长	直行相位时长	预信号1 启亮/关闭	预信号2 启亮/关闭	周期时长
	低流量	29	19			29	19			96
1	中流量					过饱和
	高流量					过饱和
	低流量	19	19	66/6		19	19	28/44		76
2	中流量	19	19	66/6		19	19	28/44		76
	高流量					过饱和
	低流量	20	19		73/1	20	19		34/40	78
3	中流量	24	21		84/6	24	21		39/51	90
	高流量	29	29		102/11	29	29		44/69	116
	低流量	20	19	68/78	73/1	20	19	29/39	34/40	78
4	中流量	24	21	79/89	84/6	24	21	34/44	39/51	90
	高流量	29	29	97/107	102/11	29	29	39/49	44/69	116
	低流量	29	19			29	19			96
5	中流量					过饱和
	高流量					过饱和
	低流量	19	19	67/4		19	19	29/42		76
6	中流量	19	19	67/4		19	19	29/42		76
	高流量					过饱和
	低流量	23	19		81/2	23	19		39/44	84
7	中流量	28	23		96/7	28	23		45/58	102
	高流量					过饱和
	低流量	23	19	75/4	81/2	23	19	33/46	39/44	84
8	中流量	28	23	89/102	96/7	28	23	38/51	45/58	102
	高流量					过饱和

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表 4 仿真结果对比

Table 4. Comparison of simulation results

方案编号	流量场景	交叉口输入流量（/ pcu/h）	交叉口通过车辆数/(pcu/h)			车均延误/s
方案编号	流量场景	交叉口输入流量（/ pcu/h）	左转	直行	交叉口	左转	直行	交叉口
	低流量	3 200	1 624	1 581	3 205	34.76	37.55	36.14
1	中流量				过饱和
	高流量				过饱和
	低流量	3 200	1 627	1 583	3 210	29.46	26.64	28.07
2	中流量	4 400	2 228	2 171	4 399	33.86	28.34	31.14
	高流量				过饱和
	低流量	3 200	1 617	1 583	3 201	39.16	27.82	33.56
3	中流量	4 400	2 225	2 171	4 396	46.63	34.34	40.58
	高流量	5 280	2 661	2 605	5 266	56.54	42.84	49.78
	低流量	3 200	1 618	1 583	3 201	31.97	27.82	29.92
4	中流量	4 400	2 224	2 171	4 395	39.74	34.33	37.08
	高流量	5 280	2 662	2 605	5 267	53.39	42.83	48.18
	低流量	3 200	1 624	1 581	3 205	34.76	37.55	36.14
5	中流量				过饱和
	高流量				过饱和
	低流量	3 200	1 627	1 583	3 210	30.24	26.64	28.47
6	中流量	4 400	2 227	2 171	4 398	36.95	28.34	32.71
	高流量				过饱和
	低流量	3 200	1 626	1 582	3 209	37.28	31.01	34.19
7	中流量	4 400	2 227	2 175	4 401	49.37	39.34	44.43
	高流量				过饱和
	低流量	3 200	1 628	1 582	3 210	31.53	31.01	31.27
8	中流量	4 400	2 219	2 175	4 394	39.32	39.34	39.33
	高流量				过饱和

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