Investigation on a distributed SDN control plane architecture for heterogeneous time sensitive networks

S. Schriegel, Thomas Kobzan, J. Jasperneite
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引用次数: 40

Abstract

Data-driven services (optimization or condition monitoring) are often deployed using cloud architectures. The shop floor itself becomes more and more flexible and reconfigurable using modular machine design and Plug and Play services. These industrial use cases induce additional requirements to communication systems: scalable real-time communication from sensor to cloud as well as seamless and automatic network configuration on the shop floor. A promising data plane technology for the Industrial Internet of Things (IIoT) is IEEE 802.1 Ethernet TSN that allows convergent and time sensitive communication. The configuration of the IIoT is complex because the IIoT is often large, growing and changing over time and often consists of heterogeneous network domains because of the brownfield and manifold requirements from the applications. Software-defined Networking (SDN) has the potential to reduce the engineering effort and to increase the operation efficiency (monitoring, diagnosis, reconfiguration) of heterogeneous IIoT. SDN Control Planes can be implemented as physical-central, logic-central, distributed or hybrid architecture. The different architectures have specific advantages and disadvantages regarding QoS, throughput and engineering efforts. A key role takes the East-West interface that handles the communication between distributed SDN Controllers. SDN Data Plane agents can help to manage legacy Data Planes with SDN. A TSN Nano Profile with inverse and cooperative operating Time Aware Shaper is a migration solution to upgrade legacy communication controllers with TSN functions. The disadvantages are less throughput and increased latency for acyclic traffic.
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异构时敏网络分布式SDN控制平面体系结构研究
数据驱动的服务(优化或状态监控)通常使用云架构进行部署。使用模块化机器设计和即插即用服务,车间本身变得越来越灵活和可重构。这些工业用例对通信系统提出了额外的要求:从传感器到云的可扩展实时通信,以及车间的无缝和自动网络配置。工业物联网(IIoT)的一个有前途的数据平面技术是IEEE 802.1以太网TSN,它允许收敛和时间敏感通信。工业物联网的配置很复杂,因为工业物联网通常很大,随着时间的推移而增长和变化,并且由于棕地和应用程序的多种需求,通常由异构网络域组成。软件定义网络(SDN)有可能减少工程工作量,提高异构工业物联网的运行效率(监控、诊断、重新配置)。SDN控制平面可以实现为物理中心、逻辑中心、分布式或混合架构。不同的体系结构在QoS、吞吐量和工程工作方面具有特定的优点和缺点。一个关键角色负责东西向接口,处理分布式SDN控制器之间的通信。SDN数据平面代理可以通过SDN帮助管理遗留的数据平面。TSN纳米配置文件具有逆操作和协同操作的时间感知成形器是一种迁移解决方案,用于升级具有TSN功能的传统通信控制器。缺点是吞吐量较低,并且增加了非循环流量的延迟。
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