利用双深度 Q 网络在智能工厂中部署雾计算和边缘计算,实现分布式灵活作业车间调度

Chun-Cheng Lin, Yi-Chun Peng, Zhen-Yin Annie Chen, Yu-Hong Fan, Hui-Hsin Chin
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摘要

柔性作业车间调度(FJSP)在智能制造领域备受关注,除了作业排序,机器的选择也相当重要。随着智能工厂与物联网(IoT)和网络物理系统(CPS)的发展,调度方法正朝着智能分散的方向前进。然而,随着工厂规模的扩大,传统的云计算难以管理大量涌入的数据。为解决这一问题,本研究将雾计算和边缘计算框架纳入了分布式 FJSP 工作站。在该框架中,每个由多台机器组成的工作站根据所容纳机器的不同性质进行分类,并独立运行,以减少不必要的信息传输,其中每台机器都配备了边缘计算能力。雾计算与边缘计算的融合可以卸载云计算的计算任务,有效减少延迟。以往的 FJSP 解决方案主要依赖线性规划或元搜索算法,而本研究提出了一种基于双深度 Q 网络(dual DQN)架构的新型分布式方法,将深度学习(DL)与强化学习(RL)融为一体。在云中心内,初始神经网络决定雾计算的机器选择规则,而次级神经网络决定边缘计算设备的作业调度规则。边缘计算设备执行调度并向云中心提供反馈,云中心通过迭代训练过程完善结果,从而最大限度地减少时间跨度。实验结果表明,采用双 DQN 的效果优于只采用单一机器选择规则的方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Distributed Flexible Job Shop Scheduling through Deploying Fog and Edge Computing in Smart Factories Using Dual Deep Q Networks

Distributed Flexible Job Shop Scheduling through Deploying Fog and Edge Computing in Smart Factories Using Dual Deep Q Networks

Flexible job shop scheduling (FJSP) has garnered enormous attention within the realm of smart manufacturing, where, beyond job sequencing, the selection of machines holds considerable importance. As smart factories progress with the Internet of things (IoT) and cyber-physical systems (CPS), scheduling methodologies are advancing towards intelligent decentralization. However, with the expansion of factories, conventional cloud computing struggles to manage the substantial influx of data. To tackle this issue, this work incorporates a fog computing and edge computing framework into the distributed FJSP workstations. In this framework, the workstations each of which consists of multiple machines are categorized based on the different nature of the accommodated machines, and operate independently to reduce unnecessary information transmission, in which each machine is equipped with edge computing capacity. The fusion of fog computing and edge computing allows for the offloading of computational tasks from cloud computing, effectively reducing latency. While previous solutions for FJSP have predominantly relied on linear programming or metaheuristic algorithms, this work proposed a novel distributed approach based on a dual deep Q networks (dual DQN) architecture, integrating deep learning (DL) with reinforcement learning (RL). Within the cloud center, the initial neural network determines the machine selection rules for fog computing, while the secondary neural network decides the job dispatching rules for edge computing devices. Edge computing devices execute the schedule and provide feedback to the cloud, which refines the results through an iterative training process, so that to minimize the makespan. The experimental findings indicate that employing dual DQNs outperforms the methods of utilizing only one single machine selection rule.

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