Talking Trucks: Decentralized Collaborative Multi-Agent Order Scheduling for Self-Organizing Logistics

International Conference on Automated Planning and Scheduling Pub Date : 2022-06-13 DOI:10.1609/icaps.v32i1.19834

Geert L. J. Pingen, C. R. V. Ommeren, C. J. V. Leeuwen, Ruben Fransen, Tijmen Elfrink, Yorick C. de Vries, Janarthanan Karunakaran, Emir Demirovic, N. Yorke-Smith

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Abstract

Logistics planning is a complex optimization problem involving multiple decision makers. Automated scheduling systems offer support to human planners; however state-of-the-art approaches often employ a centralized control paradigm. While these approaches have shown great value, their application is hindered in dynamic settings with no central authority. Motivated by real-world scenarios, we present a decentralized approach to collaborative multi-agent scheduling by casting the problem as a Distributed Constraint Optimization Problem (DCOP). Our model-based heuristic approach uses message passing with a novel pruning technique to allow agents to cooperate on mutual agreement, leading to a near-optimal solution while offering low computational costs and flexibility in case of disruptions. Performance is evaluated in three real-world field trials with a logistics carrier and compared against a centralized model-free Deep Q-Network (DQN)-based Reinforcement Learning (RL) approach, a Mixed-Integer Linear Programming (MILP)-based solver, and both human and heuristic baselines. The results demonstrate that it is feasible to have virtual agents make autonomous decisions using our DCOP method, leading to an efficient distributed solution. To facilitate further research in Self-Organizing Logistics (SOL), we provide a novel real-life dataset.

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会说话的卡车:自组织物流的分散协作多智能体订单调度

物流规划是一个涉及多个决策者的复杂优化问题。自动调度系统为人类计划者提供支持;然而，最先进的方法通常采用集中控制范式。虽然这些方法显示出巨大的价值，但它们的应用在没有中央权威的动态环境中受到阻碍。受现实场景的启发，我们提出了一种分散的多智能体协作调度方法，将该问题转换为分布式约束优化问题(DCOP)。我们基于模型的启发式方法使用消息传递和一种新颖的修剪技术，允许代理在相互协议的基础上进行合作，从而在提供低计算成本和灵活性的情况下获得接近最优的解决方案。在三次现实世界的现场试验中，对物流承运人的性能进行了评估，并与基于集中式无模型深度q -网络(DQN)的强化学习(RL)方法、基于混合整数线性规划(MILP)的求解器以及人类和启发式基线进行了比较。结果表明，使用我们的DCOP方法让虚拟代理自主决策是可行的，从而产生了一个高效的分布式解决方案。为了促进自组织物流(SOL)的进一步研究，我们提供了一个新的现实生活数据集。

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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International Conference on Automated Planning and Scheduling

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