COVID-19 transmission risk minimization at public transportation stops using Differential Evolution algorithm

IF 2.1 4区 工程技术 Q3 TRANSPORTATION
M. M. Mutlu, İ̇̇lyas Cihan Aksoy, Y. Alver
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引用次数: 4

Abstract

Public transportation vehicles, with their confined spaces and limited ventilation, are considered among the primary factors in the spread of COVID-19. As a measure to slow the spread of the virus during the pandemic, governments have applied passenger capacity restrictions to ensure physical distancing. On the other hand, the increase in the risk of disease transmission associated with passengers waiting together at stops is omitted. In this study, we consider the risk of disease transmission as a travel cost and formulate a risk minimization problem as a transit network frequency setting problem. We develop a bi-level optimization model minimizing the total infection risk occurring at stops, namely, the cumulative disease transmission risk cost. The Differential Evolution algorithm is employed to cope with the NP-hard bi-level transportation network design problem. We propose a novel objective function for the upper-level model, considering the infection risk cost based on passenger traffic at public transportation stops. A congested user-equilibrium transit assignment model is utilized to determine passenger movement. The proposed model is applied to a small-size hypothetical network, and a mid-size test network. Experimental studies provide evidence that the model can produce optimal solutions. Optimization results show significant improvements in the reduction of disease transmission risk compared to the optimizations depending on the traditional practice of transportation network planning based on user and operator costs. The proposed model provides risk cost reductions of 51% and 22% compared to the optimal solutions based on user cost minimization in the hypothetical network and Mandl’s network, respectively.
使用差分进化算法最小化公共交通站点的新冠肺炎传播风险
公共交通工具空间狭窄,通风有限,被认为是新冠肺炎传播的主要因素之一。作为在疫情期间减缓病毒传播的一项措施,各国政府实施了乘客容量限制,以确保保持物理距离。另一方面,省略了与在车站一起等待的乘客相关的疾病传播风险的增加。在这项研究中,我们将疾病传播的风险视为旅行成本,并将风险最小化问题公式化为公交网络频率设置问题。我们开发了一个双层优化模型,最小化站点发生的总感染风险,即累积疾病传播风险成本。采用差分进化算法来解决NP难的双层交通网络设计问题。我们为上层模型提出了一个新的目标函数,考虑了基于公共交通站点客运量的感染风险成本。利用拥挤用户均衡公交分配模型来确定乘客流动。将所提出的模型应用于小型假设网络和中型测试网络。实验研究证明,该模型可以产生最优解。优化结果显示,与基于用户和运营商成本的交通网络规划传统做法的优化相比,在降低疾病传播风险方面有显著改进。与假设网络和Mandl网络中基于用户成本最小化的最优解决方案相比,所提出的模型分别降低了51%和22%的风险成本。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
3.80
自引率
0.00%
发文量
0
审稿时长
30 weeks
期刊介绍: The European Journal of Transport and Infrastructure Research (EJTIR) is a peer-reviewed scholarly journal, freely accessible through the internet. EJTIR aims to present the results of high-quality scientific research to a readership of academics, practitioners and policy-makers. It is our ambition to be the journal of choice in the field of transport and infrastructure both for readers and authors. To achieve this ambition, EJTIR distinguishes itself from other journals in its field, both through its scope and the way it is published.
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