Operations Design of Modular Vehicles on an Oversaturated Corridor with First-in, First-out Passenger Queueing

Xiaowei Shi, X. Li
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引用次数: 24

Abstract

Although urban transit systems (UTS) often have fixed vehicle capacity and relatively constant departure headways, they may need to accommodate dramatically fluctuating passenger demands over space and time, resulting in either excessive passenger waiting or vehicle capacity and energy waste. Therefore, on the one hand, optimal operations of UTS rely on accurate modeling of passenger queuing dynamics, which is particularly complex on a multistop transit corridor. On the other hand, capacities of transit vehicles can be made variable and adaptive to time-variant passenger demand so as to minimize energy waste, especially with the emergence of modular vehicle technologies. This paper investigates operations of a multistop transit corridor in which vehicles may have different capacities across dispatches. We specify skewed time coordinates to simplify the problem structure while incorporating traffic congestion. Then, we propose a mixed integer linear programming model that determines the optimal dynamic headways and vehicle capacities over the study time horizon to minimize the overall system cost for the transit corridor. In particular, the proposed model considers a realistic multistop first-in, first-out (MSFIFO) rule that gives the same boarding priority to passengers arriving at a station in the same time interval yet with different destinations. A customized dynamic programming (DP) algorithm is proposed to solve this model efficiently. To circumvent the rapid increase of the state space of a typical DP algorithm, we analyze the theoretical properties of the investigated problem and identify upper and lower bounds to a feasible solution. The bounds largely reduce the state space during the DP iterations and greatly improve the efficiency of the proposed DP algorithm. The state dimensions are also reduced with the MSFIFO rule such that all queues with different destinations at the same origin can be tracked with a single boarding position state variable at each stage. A hypothetical example and a real-world case study show that the proposed DP algorithm greatly outperforms a state-of-the-art commercial solver (Gurobi) in both solution quality and time.
过饱和通道中先入先出的模块化车辆运行设计
虽然城市交通系统(UTS)通常具有固定的车辆容量和相对恒定的发车速度,但它们可能需要适应乘客在空间和时间上急剧波动的需求,从而导致乘客等待时间过长或车辆容量和能源浪费。因此,一方面,UTS的优化运行依赖于对乘客排队动态的准确建模,这在多站公交走廊上尤为复杂。另一方面,随着模块化车辆技术的出现,公交车辆的容量可以根据时变的乘客需求进行可变调整,从而最大限度地减少能源浪费。本文研究了一个多站点交通走廊的运行情况,其中车辆在不同的调度中可能具有不同的能力。在考虑交通拥堵的同时,我们指定了倾斜的时间坐标来简化问题结构。然后,我们提出了一个混合整数线性规划模型,该模型确定了在研究时间范围内最优的动态车头和车辆容量,以最小化公交走廊的总体系统成本。特别是,该模型考虑了一种现实的多站先进先出(MSFIFO)规则,该规则使到达同一站点的乘客在相同的时间间隔内具有相同的上车优先权,但目的地不同。针对该模型,提出了一种自定义动态规划(DP)算法。为了避免典型DP算法状态空间快速增长的问题,我们分析了所研究问题的理论性质,并确定了可行解的上界和下界。边界极大地减少了DP迭代过程中的状态空间,提高了算法的效率。状态维度也通过MSFIFO规则减少,这样在同一原点具有不同目的地的所有队列可以在每个阶段使用单个登机位置状态变量进行跟踪。一个假设的例子和一个现实世界的案例研究表明,所提出的DP算法在解决质量和时间上都大大优于最先进的商业求解器(robi)。
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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