Data-driven Distributionally Robust Optimization For Vehicle Balancing of Mobility-on-Demand Systems

IF 2 Q3 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
Fei Miao, Sihong He, Lynn Pepin, Shuo Han, Abdeltawab M. Hendawi, Mohamed E. Khalefa, J. Stankovic, G. Pappas
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引用次数: 15

Abstract

With the transformation to smarter cities and the development of technologies, a large amount of data is collected from sensors in real time. Services provided by ride-sharing systems such as taxis, mobility-on-demand autonomous vehicles, and bike sharing systems are popular. This paradigm provides opportunities for improving transportation systems’ performance by allocating ride-sharing vehicles toward predicted demand proactively. However, how to deal with uncertainties in the predicted demand probability distribution for improving the average system performance is still a challenging and unsolved task. Considering this problem, in this work, we develop a data-driven distributionally robust vehicle balancing method to minimize the worst-case expected cost. We design efficient algorithms for constructing uncertainty sets of demand probability distributions for different prediction methods and leverage a quad-tree dynamic region partition method for better capturing the dynamic spatial-temporal properties of the uncertain demand. We then derive an equivalent computationally tractable form for numerically solving the distributionally robust problem. We evaluate the performance of the data-driven vehicle balancing algorithm under different demand prediction and region partition methods based on four years of taxi trip data for New York City (NYC). We show that the average total idle driving distance is reduced by 30% with the distributionally robust vehicle balancing method using quad-tree dynamic region partitions, compared with vehicle balancing methods based on static region partitions without considering demand uncertainties. This is about a 60-million-mile or a 8-million-dollar cost reduction annually in NYC.
数据驱动的按需移动系统车辆平衡分布鲁棒优化
随着智慧城市的转型和技术的发展,传感器实时收集大量数据。出租车、按需自动驾驶汽车、共享单车等共享出行系统提供的服务也很受欢迎。这种模式提供了改善交通系统性能的机会,通过主动分配拼车车辆来预测需求。然而,如何处理预测需求概率分布中的不确定性以提高系统的平均性能仍然是一个具有挑战性和未解决的任务。针对这一问题,本文提出了一种数据驱动的分布式鲁棒车辆平衡方法,以最小化最坏情况下的期望成本。我们设计了有效的算法来构建不同预测方法的需求概率分布的不确定性集,并利用四叉树动态区域划分方法来更好地捕获不确定需求的动态时空特性。然后,我们导出了一个等价的计算易于处理的形式,用于数值求解分布鲁棒问题。基于纽约市4年的出租车出行数据,评估了数据驱动的车辆平衡算法在不同需求预测和区域划分方法下的性能。研究表明,与不考虑需求不确定性的基于静态区域划分的车辆平衡方法相比,采用四叉树动态区域划分的分布鲁棒车辆平衡方法平均总空闲行驶距离减少了30%。这相当于纽约市每年减少6000万英里或800万美元的成本。
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
ACM Transactions on Cyber-Physical Systems
ACM Transactions on Cyber-Physical Systems COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS-
CiteScore
5.70
自引率
4.30%
发文量
40
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