面向常发性拥堵的城市局部路网韧性评价与分析

陈思妤; 李洁; 胡演诚; 姜宇

doi:10.3963/j.jssn.1674-4861.2022.04.015

面向常发性拥堵的城市局部路网韧性评价与分析

doi: 10.3963/j.jssn.1674-4861.2022.04.015

陈思妤^1,,
李洁^1, ,,
胡演诚¹,
姜宇²

1.
湖南大学土木工程学院长沙 410082
2.
丹麦科技大学管理工程系丹麦灵比 2800Kgs

基金项目:

国家自然科学基金项目 51878264

河南省交通厅科技项目 2020G11

详细信息

作者简介:
陈思妤（1997—），硕士研究生. 研究方向：复杂交通系统建模与优化. E-mail：chens1@hnu.edu.cn

通讯作者:
李洁（1972—），博士，副教授. 研究方向：交通流理论、交通安全、驾驶行为等. E-mail：lijie_civil@hnu.edu.cn

中图分类号: U491
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出版历程
- 收稿日期: 2022-02-16
- 网络出版日期: 2022-09-17

An Evaluation and Analysis on the Resilience of the Urban Local Road Network for Recurrent Congestions

CHEN Siyu^1
,,
LI Jie^{1
, ,},
HU Yancheng¹,
JIANG Yu²

1.
College of Civil Engineering, Hunan University, Changsha 410082, China
2.
Department of Management Engineering, Technical University of Denmark, Lyngby 2800Kgs, Denmark

摘要

摘要: 为了缓解常发性拥堵引发的城市噪音、能源消耗和废气排放等现状，使路网具备抵抗短时激增车流的能力，将宏观基本图与性能时序图相结合对局部路网韧性进行量化。针对韧性属性，提出了鲁棒性指数、损失面积比、恢复快速性、流量峰值差和临界密度差5个评价指标，反映路网在性能下降、稳定和恢复阶段的韧性特性。引入Kendall法检验各赋权法的一致性，并基于CRITIC的多属性决策获得最优权重，提出了组合赋权和模糊逻辑相结合的城市局部路网韧性综合评价方法，结合李克特量表法对综合韧性得分进行分级。以长沙市局部路网为例，设计韧性改善方案，针对常发性拥堵路段上的交叉口进行信号配时优化；通过VISSIM仿真并计算得到各方案的韧性指标。研究结果显示：方案8，10和16能有效吸收短时激增车流并与路网状态相适应，所有方案中方案14的韧性得分最高。局部路网综合韧性得分具有随着优化路段数的增加而增长的趋势，但并不是线性递增。信号配时优化改变了路网韧性属性，并降低了部分路段对城市局部路网韧性的负面影响。不同评价方法下的韧性得分排名存在部分差异，流量峰值差与脆弱性指数的评价排名更接近，损失面积比与韧性损失值的评价排名更接近。所提出的指标不局限于单一韧性属性，能更全面、客观地反映干扰下路网的响应过程。
- 交通工程 /
- 城市局部路网 /
- 韧性评价 /
- 多属性决策 /
- 性能时序图 /
- 宏观基本图
Abstract: To alleviate the state of urban noise, energy consumption, and carbon emission caused by recurrent traffic congestions, and to improve the ability to resist impacts of a short-term surge in traffic flow, macroscopic fundamental diagrams and performance profiles are combined to quantify the resilience of the urban local road network. Five evaluation indices, including robustness index, ratio of loss areas, rapid recovery, difference of peak flows, and difference of critical densities, are proposed to reflect characteristics of the resilience in the stages of performance degradation, stability, and recovery. The Kendall method is used to test the consistency of each weighting method, and the optimal weight is obtained based on the CRITIC for multi-attribute decision making. Furthermore, a combined method using weighting method and fuzzy logic is proposed to evaluate the resilience of the urban local road network, and the resilience score is graded by the Likert scale. Taking a local road network in the city of Changsha as a case study. Improvement schemes for the resilience are designed, and schemes of traffic signal timing are carried out and optimized to improve the resilience of recurrently congested intersections on key road sections. The evaluation indices of the resilience of the local road network are calculated based on the outputs of VISSIM simulations. The results show that scheme 8, 10, and 16 can effectively absorb the short-term surge in traffic flowand adapt to traffic states on the road network. The scheme 14 has the best performance out of all schemes. The comprehensive resilience score of the urban local road network presents an upward trend of non-linear growth with the increasing number of signal optimized sections. The optimization of traffic signal timing improves resilience properties of the local road network, and then reduces the negative impacts of some key sections on the resilience of urban local road network. Besides, different methods for evaluating the resilience make distinct ranking results.The ranking results based on difference of peak flows are more similar to the results of vulnerability indices, while the ranking results based on ratio of loss areas are more similar to the results of loss of resilience. The proposed evaluation indices, not confined to a single attribute of resilience, can reflect the response process of road network under disruption more comprehensively and objectively.
- traffic engineering /
- urban local road network /
- resilience evaluation /
- multi-attribute decision making /
- performance profile /
- macroscopic fundamental diagram

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图 1 宏观基本图

Figure 1. Macroscopic fundamental diagram

下载: 全尺寸图片幻灯片

图 2 系统性能时序图

Figure 2. Performance profile of the system

下载: 全尺寸图片幻灯片

图 3 研究区域

Figure 3. Area for case study

下载: 全尺寸图片幻灯片

图 4 信号配时优化前后交通状况对比

Figure 4. Comparison of the traffic conditions before and after signal timing improvement

下载: 全尺寸图片幻灯片

表 1 城市局部路网韧性评价指标

Table 1. Indexes to evaluate urban local road network resilience

来源	响应指标	指标属性
时序图	鲁棒性指数RI	逆向
	恢复快速性RR	正向
	损失面积比RLA	逆向
宏观基本图	流量峰值差DPF	正向
宏观基本图	临界密度差DCD	正向

下载: 导出CSV

表 2 韧性等级及取值范围

Table 2. Resilence levels and the value ranges

韧性等级	取值范围
极弱	r≤20
弱	20<r≤40
中等	40<r≤60
较强	60<r≤80

下载: 导出CSV

表 3 基于互联网地图速度数据反推交通流量（样本2021-04-20 T18: 51）

Table 3. Estimated traffic flows based on the speed data from the internet map (Sample 2021-04-20 T18: 51)

路名	行车速度/ (km/h)	饱和度	机动车流/ (pcu/h)	密度/ (pcu/km)
五一大道	10	0.88	2 603	260
湘江中路	15	0.78	2 326	155
黄兴中路	10	0.84	2 389	239
芙蓉中路	15	0.78	2 326	155
解放西路	25	0.60	1 011	40

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表 4 指标权重及级别阈值

Table 4. Weights of indexes and their thresholds of grades

等级	极弱（20%）	弱（40%）	中（60%）	较强（80%）	权重
RI（/km/h）	0.041	0.114	0.616	0.886	0.256
RR（/km/h²）	0.020	0.288	0.366	0.405	0.224
RLA	0.113	0.254	0.512	0.826	0.226
DPF/[pcu/(h·ln)]	0.206	0.271	0.520	0.834	0.138
DCD /[pcu/(km·ln)]	0.209	0.335	0.560	0.631	0.156

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表 5 不同排列组合方案下路网的韧性指标

Table 5. Indexes of the road network resilience with different permutations and combination schemes

编号	优化路段ID	RR（/km/h²）	RI（/km/h）	RLA	DPF/ [pcu/(h·ln)]	DCD/ [pcu/(km·ln)]
1	未优化	8.650	7.154	0.154	0.000	0.000
2	492	10.184	6.341	0.185	2.626	1.004
3	-509	10.644	7.060	0.213	26.351	-0.455
4	683	6.024	6.546	0.201	-6.657	0.371
5	-568	21.886	2.119	0.085	2.287	-0.948
6	492、-509	8.582	6.861	0.189	26.513	0.435
7	492、683	8.015	6.386	0.159	1.536	0.538
8	492、-568	< 0.001	< 0.001	< 0.001	8.180	-0.084
9	-568、-509	6.313	2.744	0.104	11.789	-0.281
10	-568、683	< 0.001	< 0.001	< 0.001	4.121	0.561
11	-509、683	6.750	5.507	0.177	14.032	-0.158
12	683、-568、-509	0.443	0.816	0.037	33.112	-0.165
13	492、-509、683	7.573	6.878	0.198	30.041	1.407
14	492、-568、683	6.064	1.098	0.076	26.513	0.435
15	492、-509、-568	8.864	3.309	0.113	19.949	-0.514
16	492、-568、683、-509	< 0.001	< 0.001	< 0.001	-1.397	-0.627

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表 6 路网综合韧性评分与等级划分

Table 6. Comprehensive resilience scores and classifications of the road network resilience

编号	优化路段ID	b₁	b₂	^b3	b₄	综合韧性	等级
1	未优化	0.394	0.315	0.124	0.168	51	中韧性
2	492	0.276	0.344	0.000	0.380	60	中韧性
3	-509	0.638	0.000	0.002	0.360	52	中韧性
4	683	0.476	0.368	0.156	0.000	44	中韧性
5	-568	0.254	0.040	0.335	0.371	66	较强韧性
6	492，-509	0.482	0.000	0.171	0.347	58	中韧性
7	492，683	0.160	0.460	0.224	0.156	58	中韧性
8	492，-568	0.224	0.215	0.078	0.482	66	较强韧性
9	-568，-509	0.065	0.347	0.589	0.000	60	较强韧性
10	-568，683	0.224	0.138	0.000	0.638	71	较强韧性
11	-509，683	0.136	0.610	0.255	0.000	52	中韧性
12	683，-568，-509	0.228	0.152	0.000	0.620	70	较强韧性
13	492，-509，683	0.482	0.058	0.166	0.294	55	中韧性
14	492，-568，683	0.010	0.215	0.265	0.511	76	较强韧性
15	492，-509，-568	0.156	0.077	0.477	0.290	68	较强韧性
16	492，-568，683，-509	0.518	0.000	0.000	0.482	59	中韧性

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