共享单车重新定位操作的优化:被动实时方法

IF 2.1 Q2 OPERATIONS RESEARCH & MANAGEMENT SCIENCE
Enrique Jiménez-Meroño, Francesc Soriguera
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引用次数: 0

摘要

车辆共享系统运行中的一个关键问题是优化车队的重新定位移动。重新定位意味着人为地将车辆从车辆聚集的地方转移到车辆稀缺的地方。这样既能提高车辆的可用性,又不会使车队规模过大,同时还能提高车辆利用率。在共享单车系统的特殊情况下,重新定位意味着部署一支小型卡车或货车车队,将自行车群从一个地点移动到另一个地点,目的是最大限度地提高用户的服务水平,同时最大限度地降低运营机构的成本。以前,运筹学领域曾通过混合整数编程(MIP)及其变体来解决这一重新定位优化问题,但通常面临两个限制。首先是计算成本高,无法在现实的大型系统中直接求解。因此,有必要开发启发式方法和近似方法。其次,它对需求预测的依赖性和敏感性,以及其固有的不确定性。为了克服这些弱点,本文提出了一种基于重新定位卡车和任务之间实时配对分配的策略,以优化共享单车的重新定位操作。所提出的方法概念简单,对需求预测的依赖性较低,可以用任何编码语言轻松实现,并以较低的计算成本适用于大型系统。这些特性使得该方法在处理任何车辆共享系统中的重新定位任务分配时都很有吸引力。在基于巴塞罗那自行车共享系统 Bicing 的模拟案例研究中,我们实施了建议的策略,并与基于 MIP 的路由选择方法进行了比较。结果表明,建议的实时配对分配方法能够显著提高重新定位操作的性能,尤其是在需求预测不准确的情况下。基于实时信息,所提出的策略具有足够的灵活性,可以解决不可预测的情况。因此,建议的策略可以作为基于 MIP 的解决方案的替代方案,也可以作为长期静态解决方案动态实时调整的补充策略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Optimization of bike-sharing repositioning operations: A reactive real-time approach

One of the critical issues in the operation of vehicle-sharing systems is the optimization of the fleet repositioning movements. Repositioning implies the artificial movement of vehicles from places where they accumulate to others in which they are scarce. This yields a higher vehicle availability, without over dimensioning the vehicle fleet and while increasing the vehicle utilization rates. In the particular case of bike-sharing systems, repositioning implies to deploy a fleet of small trucks or vans able to move groups of bicycles from one location to another, with the purpose of maximizing the users’ level of service while minimizing the operating agency costs. This repositioning optimization problem has been previously addressed in the operations research field through Mixed Integer Programing (MIP) and its variants, generally facing two limitations. First, its high computational cost, which prevents achieving direct solutions in realistically large systems. So, it has been necessary to develop heuristics and approximations. And second, its reliance and sensitivity to demand forecasts, with its inherent level of uncertainty. Aiming to overcome these weaknesses, this paper presents a strategy based on a real-time pairwise assignment between repositioning trucks and tasks, in order to optimize the bike-sharing repositioning operations. The proposed method is conceptually simple, less dependent on demand predictions, easily implementable in any coding language and applicable to large systems at a low computational cost. These properties make the method appealing to address the repositioning task assignment in any vehicle-sharing system. On a simulated case study, based on Bicing, the bicycle-sharing system in Barcelona, the proposed strategy has been implemented and compared to the MIP-based routing approach. Results show that the proposed real-time pairwise assignment method is able to significantly improve the performance of the repositioning operations, especially in scenarios where the demand forecast is not accurate. Being based on real-time information, the proposed strategy is flexible enough to solve unpredictable situations. So, the proposed strategy can be implemented as an alternative to MIP-based solutions, or as a complementary strategy for dynamic real-time adaptation of static long-term solutions.

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来源期刊
CiteScore
4.60
自引率
0.00%
发文量
24
审稿时长
129 days
期刊介绍: The EURO Journal on Transportation and Logistics promotes the use of mathematics in general, and operations research in particular, in the context of transportation and logistics. It is a forum for the presentation of original mathematical models, methodologies and computational results, focussing on advanced applications in transportation and logistics. The journal publishes two types of document: (i) research articles and (ii) tutorials. A research article presents original methodological contributions to the field (e.g. new mathematical models, new algorithms, new simulation techniques). A tutorial provides an introduction to an advanced topic, designed to ease the use of the relevant methodology by researchers and practitioners.
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