基于骑手众包的共享微移动系统中的车辆再平衡

Ziliang Jin, Yulan Wang, Yun Fong Lim, Kai Pan, Z. Shen
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引用次数: 2

摘要

问题定义:共享微型交通工具在城市区域内提供了一种环保的短途出行方式。由于客户在任何服务区都可以随时接送车辆,这种便利性往往会导致不同服务区的车辆供需严重失衡。为了克服这一问题,微移动运营商除了与第三方物流提供商(3PL)合作重新安置车辆外,还可以通过奖励激励的方式将个人乘客众包。方法/结果:构建了一个具有多个服务区域的时空网络,并在考虑客户需求不确定的情况下,制定了一个两阶段随机混合整数规划。在第一阶段,操作员决定区域的初始车辆分配,而在第二阶段,操作员决定在操作范围内跨区域的后续车辆重新安置。我们开发了一种有效的解决方案方法,它结合了基于场景和基于时间的分解技术。我们的方法在解决基于真实数据的大规模问题实例的解决方案质量和计算时间方面优于商业求解器。管理意义:购买车辆和骑手众包的预算对车辆的初始分配和随后的重新安置有重大影响。在第三方物流之外引入骑手众包可以显著增加利润,减少需求损失,提高系统的车辆利用率,而不会影响与第三方物流的任何现有承诺。第三方物流在大规模搬迁方面比骑手众包更有效,而后者在处理零星搬迁需求方面更有效。为了服务一个地区,第三方物流通常会在一天的高峰时段从遥远的低需求地区批量调运车辆,而骑手众包则每天从邻近地区调运少量车辆。此外,骑手众包在单峰客户到达模式下比双峰模式下重新安置更多的车辆,而对于第三方物流则相反。基金资助:本研究得到香港研究资助局[资助项目:15501319和15505318]和中国国家自然科学基金[资助项目:71931009]的资助。Jin博士获香港博士奖学金计划资助。林毅峰获新加坡管理大学李光前商学院[海事及港务管理局研究奖学金]资助。补充材料:在线附录可在https://doi.org/10.1287/msom.2023.1199上获得。
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Vehicle Rebalancing in a Shared Micromobility System with Rider Crowdsourcing
Problem definition: Shared micromobility vehicles provide an eco-friendly form of short-distance travel within an urban area. Because customers pick up and drop off vehicles in any service region at any time, such convenience often leads to a severe imbalance between vehicle supply and demand in different service regions. To overcome this, a micromobility operator can crowdsource individual riders with reward incentives in addition to engaging a third-party logistics provider (3PL) to relocate the vehicles. Methodology/results: We construct a time-space network with multiple service regions and formulate a two-stage stochastic mixed-integer program considering uncertain customer demands. In the first stage, the operator decides the initial vehicle allocation for the regions, whereas in the second stage, the operator determines subsequent vehicle relocation across the regions over an operational horizon. We develop an efficient solution approach that incorporates scenario-based and time-based decomposition techniques. Our approach outperforms a commercial solver in solution quality and computational time for solving large-scale problem instances based on real data. Managerial implications: The budgets for acquiring vehicles and for rider crowdsourcing significantly impact the vehicle initial allocation and subsequent relocation. Introducing rider crowdsourcing in addition to the 3PL can significantly increase profit, reduce demand loss, and improve the vehicle utilization rate of the system without affecting any existing commitment with the 3PL. The 3PL is more efficient for mass relocation than rider crowdsourcing, whereas the latter is more efficient in handling sporadic relocation needs. To serve a region, the 3PL often relocates vehicles in batches from faraway, low-demand regions around peak hours of a day, whereas rider crowdsourcing relocates a few vehicles each time from neighboring regions throughout the day. Furthermore, rider crowdsourcing relocates more vehicles under a unimodal customer arrival pattern than a bimodal pattern, whereas the reverse holds for the 3PL. Funding: This work was supported by the Research Grants Council of Hong Kong [Grants 15501319 and 15505318] and the National Natural Science Foundation of China [Grant 71931009]. Z. Jin was supported by the Hong Kong PhD Fellowship Scheme. Y. F. Lim was supported by the Lee Kong Chian School of Business, Singapore Management University [Maritime and Port Authority Research Fellowship]. Supplemental Material: The online appendices are available at https://doi.org/10.1287/msom.2023.1199 .
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