利用气象信息进行可靠的无人机投递

Chun Cheng, Yossiri Adulyasak, Louis-Martin Rousseau
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引用次数: 0

摘要

问题定义:由于无人机送货具有比其他送货方式更快、成本更低的潜力,因此最近备受关注。当调度无人机从仓库出发送货到不同目的地时,调度员必须考虑到不确定的风力条件,因为风力条件会影响无人机送货到目的地的时间,从而导致送货延迟。方法/结果:为了降低风力不确定性导致的交货延迟风险,我们提出了一个两期无人机调度模型,以稳健地优化交货计划。在这一框架中,上午做出调度决策,下午根据中午获得的最新天气信息制定不同的交货计划。我们的方法最大限度地降低了基本风险指数,该指数可同时考虑延迟交货的概率和延迟的程度。利用风力观测数据,我们通过集群式模糊集来描述不确定的飞行时间,这样做的好处是在避免过度拟合经验分布的同时,还具有可操作性。我们为这一自适应分布框架开发了分支-切割(B&C)算法,以提高其可扩展性。与其他经典模型相比,我们的自适应分布稳健模型能有效减少样本外测试的延迟。与一般建模工具箱相比,所提出的 B&C 算法能在更短的时间内解决最优化实例。管理意义:决策者可以利用自适应鲁棒模型和聚类模糊集,有效减少无人机送货系统在客户处的服务延迟:本研究得到了国家自然科学基金[72101049 和 72232001]、辽宁省自然科学基金[2023-BS-091]、中央高校基本科研业务费[DUT23RC(3)045]和国家社会科学基金重大项目[22&ZD151]的资助:在线附录见 https://doi.org/10.1287/msom.2022.0339 。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Robust Drone Delivery with Weather Information
Problem definition: Drone delivery has recently garnered significant attention due to its potential for faster delivery at a lower cost than other delivery options. When scheduling drones from a depot for delivery to various destinations, the dispatcher must take into account the uncertain wind conditions, which affect the delivery times of drones to their destinations, leading to late deliveries. Methodology/results: To mitigate the risk of delivery delays caused by wind uncertainty, we propose a two-period drone scheduling model to robustly optimize the delivery schedule. In this framework, the scheduling decisions are made in the morning, with the provision for different delivery schedules in the afternoon that adapt to updated weather information available by midday. Our approach minimizes the essential riskiness index, which can simultaneously account for the probability of tardy delivery and the magnitude of lateness. Using wind observation data, we characterize the uncertain flight times via a cluster-wise ambiguity set, which has the benefit of tractability while avoiding overfitting the empirical distribution. A branch-and-cut (B&C) algorithm is developed for this adaptive distributionally framework to improve its scalability. Our adaptive distributionally robust model can effectively reduce lateness in out-of-sample tests compared with other classical models. The proposed B&C algorithm can solve instances to optimality within a shorter time frame than a general modeling toolbox. Managerial implications: Decision makers can use the adaptive robust model together with the cluster-wise ambiguity set to effectively reduce service lateness at customers for drone delivery systems.Funding: This work was supported by the National Natural Science Foundation of China [Grants 72101049 and 72232001], the Natural Science Foundation of Liaoning Province [Grant 2023-BS-091], the Fundamental Research Funds for the Central Universities [Grant DUT23RC(3)045], and the Major Project of the National Social Science Foundation [Grant 22&ZD151].Supplemental Material: The online appendices are available at https://doi.org/10.1287/msom.2022.0339 .
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