Failure Analysis Of Urban Rail Transit Networks Incorporating Ridership Patterns

Yalda Saadat, Bilal M. Ayyub, Yanjie Zhang, Dongming Zhang, Hongwei Huang
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Abstract

Abstract In any nonlinear system as complex as an urban rail transit network or metrorail network, some incidence of perturbations of its state is inevitable. These perturbations, such as natural hazards, can highly affect the networks' resilience. Increasing the ability of metrorail networks to withstand such perturbations requires robustness and vulnerability assessments as key attributes of resilience and necessary steps toward developing reliable networks. Most models developed for this purpose associate a network's failures to binary representations of the failure of its components without incorporating weight factors. Since ridership is a primary factor to define the metrorail network performance, this paper proposes a general ridership pattern, considers different failure cases, and uses a novel methodology to quantitatively measure the weighted-network resilience attributes incorporating ridership throughout the Washington, DC Metrorail as a case study. The proposed methodology has clear relationships to adjacency and link-weight matrices and defines a new expression for the weighted global network efficiency based on the sum of weights on each geodesic path. Results show that the most vulnerable stations and links hold critical positions in the network topological structure and/or bear larger amounts of ridership. For the case study, the most vulnerable components include transfer stations located in the city center as well as stations and links on the northwest section of the Red Line. The methodology presented herein provides insights for enhancing critical components during the planning and operation of a metrorail by mitigating the risks associated with failure events.
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考虑乘客模式的城市轨道交通网络失效分析
摘要对于像城市轨道交通网络或地铁网络这样复杂的非线性系统,其状态扰动的发生是不可避免的。这些扰动,如自然灾害,会严重影响网络的恢复能力。提高地铁网络抵御此类扰动的能力,需要将稳健性和脆弱性评估作为弹性的关键属性,并采取必要步骤发展可靠的网络。为此目的开发的大多数模型将网络的故障与其组件故障的二进制表示相关联,而不考虑权重因素。由于客流量是确定地铁网络性能的主要因素,本文提出了一个一般的客流量模式,考虑了不同的故障案例,并使用一种新的方法来定量测量加权网络弹性属性,并将整个华盛顿特区地铁的客流量作为案例研究。该方法明确了邻接矩阵和链路权矩阵之间的关系,并定义了基于各测地线路径权和的加权全局网络效率的新表达式。结果表明,最脆弱的站点和链路在网络拓扑结构中占据关键位置,并且/或承担更大的客流量。在案例研究中,最脆弱的部分包括位于城市中心的中转站以及红线西北段的车站和连接点。本文提出的方法通过降低与故障事件相关的风险,为地铁规划和运营过程中增强关键部件提供了见解。
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CiteScore
5.20
自引率
13.60%
发文量
34
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