随机最后一英里运输与人群运输和移动仓库

Kianoush Mousavi, Merve Bodur, M. Roorda
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引用次数: 19

摘要

本文提出了一种两层最后一英里配送模型,该模型在充分了解人群托运人的可用性之前,最优地选择移动仓库位置,然后将包裹转移给人群托运人,以便最终运送到客户手中。通过将问题建模为两阶段随机整数规划,纳入了人群托运人可用性的不确定性。开发了改进的分解解算法,包括分支-切割和切割-项目框架。通过评估有条件的风险价值,将风险厌恶方法与风险中性方法进行比较。以多伦多市为例进行了详细的计算研究。该模型的确定性版本比有能力车辆路径问题的平均性能高出20%。对于随机模型,分解算法通常在两个小时内发现接近最优的解决方案,例如30个移动仓库位置,40个客户和120个人群运输船。在某些情况下,在规避风险的情况下,切割-项目方法比分支-切割方法的性能高出85%。随机模型提供的解比确定性模型的解好3.35% ~ 6.08%,并且随着人群运输可获得性不确定性的增加,改进效果被放大。规避风险的方法导致运营商派遣更多的移动仓库或推迟客户交付,以降低因未交付而遭受高额罚款的风险。
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Stochastic Last-Mile Delivery with Crowd-Shipping and Mobile Depots
This paper proposes a two-tier last-mile delivery model that optimally selects mobile depot locations in advance of full information about the availability of crowd-shippers and then transfers packages to crowd-shippers for the final shipment to the customers. Uncertainty in crowd-shipper availability is incorporated by modeling the problem as a two-stage stochastic integer program. Enhanced decomposition solution algorithms including branch-and-cut and cut-and-project frameworks are developed. A risk-averse approach is compared against a risk-neutral approach by assessing conditional-value-at-risk. A detailed computational study based on the City of Toronto is conducted. The deterministic version of the model outperforms a capacitated vehicle routing problem on average by 20%. For the stochastic model, decomposition algorithms usually discover near-optimal solutions within two hours for instances up to a size of 30 mobile depot locations, 40 customers, and 120 crowd-shippers. The cut-and-project approach outperforms the branch-and-cut approach by up to 85% in the risk-averse setting in certain instances. The stochastic model provides solutions that are 3.35%–6.08% better than the deterministic model, and the improvements are magnified with increased uncertainty in crowd-shipper availability. A risk-averse approach leads the operator to send more mobile depots or postpone customer deliveries to reduce the risk of high penalties for nondelivery.
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