{"title":"具有随机客户和需求的一致车辆路由问题","authors":"Aldair Alvarez, Jean-François Cordeau, Raf Jans","doi":"10.1016/j.trb.2024.102968","DOIUrl":null,"url":null,"abstract":"<div><p>This paper introduces the consistent vehicle routing problem with stochastic customers and demands. We consider driver consistency as customer-driver assignments that remain fixed when the realizations of the random variables are observed. We study the problem in a two-stage scenario-based stochastic programming framework. In the first stage, customers are assigned to drivers, while in the second stage, customers are selected and delivery routes are designed for each of the scenarios. We assume that the realization of the random variables becomes known before the vehicles depart from the depot. The routes are then optimized according to the observed customers and their demands. The first-stage driver-customer assignments can violate the consistency requirement, which is modeled as a desired maximum number of drivers assigned to each customer. This is modeled as a soft constraint with a penalty in the objective function. It is hence possible to assign multiple drivers to a specific customer in the first stage. In the second stage, a customer can only be visited by one of the preassigned drivers. Our problem, therefore, consists in finding assignments that minimize the consistency violation penalties, the expected routing costs, and the penalties for unserved customers when the uncertain parameters are revealed. We present a mathematical formulation and a sample average approximation (SAA) approach for the problem. We introduce a branch-and-cut and a Benders decomposition method to solve the sample problems in our SAA algorithm. Computational experiments show that SAA allows finding good-quality solutions for instances with large sets of scenarios. We also analyze the cost-consistency trade-offs and the impact of the uncertainty on the problem. In particular, we observe that consistency can be promoted through a flexible approach that does not compromise excessively on other operational metrics. Furthermore, we analyze the impact of not considering the problem uncertainties during the planning stage.</p></div>","PeriodicalId":54418,"journal":{"name":"Transportation Research Part B-Methodological","volume":"186 ","pages":"Article 102968"},"PeriodicalIF":5.8000,"publicationDate":"2024-06-04","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"The consistent vehicle routing problem with stochastic customers and demands\",\"authors\":\"Aldair Alvarez, Jean-François Cordeau, Raf Jans\",\"doi\":\"10.1016/j.trb.2024.102968\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><p>This paper introduces the consistent vehicle routing problem with stochastic customers and demands. We consider driver consistency as customer-driver assignments that remain fixed when the realizations of the random variables are observed. 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引用次数: 0
摘要
本文介绍了具有随机客户和需求的一致性车辆路由问题。我们将驾驶员一致性视为在观察随机变量的实现时保持固定的客户-驾驶员分配。我们在基于场景的两阶段随机编程框架中研究该问题。在第一阶段,将客户分配给司机,而在第二阶段,为每个场景选择客户并设计配送路线。我们假设,在车辆从仓库出发之前,随机变量的实现情况就已为人所知。然后根据观察到的客户及其需求优化路线。第一阶段的驾驶员-客户分配可能会违反一致性要求,该要求被模拟为分配给每个客户的驾驶员的期望最大数量。在目标函数中,这一要求被模拟为带有惩罚的软约束。因此,在第一阶段,可以为特定客户分配多个司机。在第二阶段,一个客户只能被其中一个预先分配的司机访问。因此,我们的问题在于,当不确定参数被揭示时,如何找到最小化违反一致性惩罚、预期路由成本和未服务客户惩罚的分配方案。我们提出了该问题的数学公式和样本平均近似(SAA)方法。我们在 SAA 算法中引入了分支切割法和 Benders 分解法来解决样本问题。计算实验表明,SAA 可以为具有大量场景集的实例找到高质量的解决方案。我们还分析了成本与一致性的权衡以及不确定性对问题的影响。特别是,我们发现可以通过一种灵活的方法来促进一致性,而不会过度损害其他运行指标。此外,我们还分析了在规划阶段不考虑问题不确定性的影响。
The consistent vehicle routing problem with stochastic customers and demands
This paper introduces the consistent vehicle routing problem with stochastic customers and demands. We consider driver consistency as customer-driver assignments that remain fixed when the realizations of the random variables are observed. We study the problem in a two-stage scenario-based stochastic programming framework. In the first stage, customers are assigned to drivers, while in the second stage, customers are selected and delivery routes are designed for each of the scenarios. We assume that the realization of the random variables becomes known before the vehicles depart from the depot. The routes are then optimized according to the observed customers and their demands. The first-stage driver-customer assignments can violate the consistency requirement, which is modeled as a desired maximum number of drivers assigned to each customer. This is modeled as a soft constraint with a penalty in the objective function. It is hence possible to assign multiple drivers to a specific customer in the first stage. In the second stage, a customer can only be visited by one of the preassigned drivers. Our problem, therefore, consists in finding assignments that minimize the consistency violation penalties, the expected routing costs, and the penalties for unserved customers when the uncertain parameters are revealed. We present a mathematical formulation and a sample average approximation (SAA) approach for the problem. We introduce a branch-and-cut and a Benders decomposition method to solve the sample problems in our SAA algorithm. Computational experiments show that SAA allows finding good-quality solutions for instances with large sets of scenarios. We also analyze the cost-consistency trade-offs and the impact of the uncertainty on the problem. In particular, we observe that consistency can be promoted through a flexible approach that does not compromise excessively on other operational metrics. Furthermore, we analyze the impact of not considering the problem uncertainties during the planning stage.
期刊介绍:
Transportation Research: Part B publishes papers on all methodological aspects of the subject, particularly those that require mathematical analysis. The general theme of the journal is the development and solution of problems that are adequately motivated to deal with important aspects of the design and/or analysis of transportation systems. Areas covered include: traffic flow; design and analysis of transportation networks; control and scheduling; optimization; queuing theory; logistics; supply chains; development and application of statistical, econometric and mathematical models to address transportation problems; cost models; pricing and/or investment; traveler or shipper behavior; cost-benefit methodologies.
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