末班车调度问题的双目标优化模型

Jia Ning , Qiyuan Peng , Yongqiu Zhu , Yu Jiang , Otto Anker Nielsen
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引用次数: 7

摘要

在城市轨道交通(URT)系统不提供24小时服务的城市,如果最后一班火车服务在乘客到达转运站时已经关闭,乘客可能无法到达目的地。本文旨在寻求一个协调良好的末班车时刻表,既可以将尽可能多的乘客运送到目的地(称为可到达的乘客),又可以将无法到达目的地的乘客(称为不可到达的乘客)运送到尽可能靠近目的地的车站。提出了一种双目标混合整数线性规划(MILP)模型,以最大化可达乘客数量和最小化所有乘客的总剩余行程。应用增广ε约束方法生成双目标MILP模型的所有Pareto最优解。在成都轨道交通网络中进行了数值实验。结果表明,与现有列车时刻表相比,优化后的列车时刻表可达乘客数量显著增加,不可达乘客的平均剩余出行距离显著缩短。此外,我们还讨论了两种提高乘客目的地可达性的可能策略,即鼓励乘客尽早到达始发站,同时优化末班车和非末班车的时刻表。
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A Bi-objective optimization model for the last train timetabling problem

In cities where the urban rail transit (URT) systems do not provide 24-h services, passengers may not be able to reach their destinations if the last train services have closed by the time they arrive at the transfer stations. This paper aims to seek a well-coordinated last train timetable that can transport as many passengers as possible to their destinations (referred to as reachable passengers) and also transport those passengers who cannot reach their destinations (referred to as unreachable passengers) to the stations as close as possible to their destinations. A bi-objective mixed-integer linear programming (MILP) model is developed to maximize the number of reachable passengers and minimize the total remaining travel distance of all passengers. The augmented ε-constraint method is applied to generate all Pareto optimal solutions of the bi-objective MILP model. Numerical experiments were implemented in the Chengdu URT network. Results indicate that compared to the current-in-use timetable, the optimized timetable by our methods significantly increased the number of reachable passengers and meanwhile reduced the average remaining travel distance of unreachable passengers. In addition, we discussed two possible strategies to improve passengers’ destination reachability, which are encouraging passengers to arrive early at their origin stations, and optimizing the timetable of last trains and non-last trains at the same time.

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来源期刊
CiteScore
7.10
自引率
8.10%
发文量
41
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