Scalable Scheduling for Industrial Time-Sensitive Networking: A Hyper-Flow Graph-Based Scheme

IF 3 3区计算机科学 Q2 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE

IEEE/ACM Transactions on Networking Pub Date : 2024-08-01 DOI:10.1109/TNET.2024.3433599

Yanzhou Zhang;Cailian Chen;Qimin Xu;Shouliang Wang;Lei Xu;Xinping Guan

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引用次数: 0

Abstract

Industrial Time-Sensitive Networking (TSN) provides deterministic mechanisms for real-time and reliable flow transmission. Increasing attention has been paid to efficient scheduling for time-sensitive flows with stringent requirements such as ultra-low latency and jitter. In TSN, the fine-grained traffic shaping protocol, cyclic queuing and forwarding (CQF), eliminates uncertain delay and frame loss via traffic timing in and out of queues. However, it inevitably causes high scheduling complexity. Moreover, complexity is quite sensitive to flow attributes and network scale. The problem stems in part from the lack of an attribute mining mechanism in existing frame-based scheduling. For time-critical industrial networks with large-scale complex flows, a so-called hyper-flow graph based scheduling scheme is proposed to improve the scheduling scalability in terms of schedulability, scheduling efficiency and latency & jitter. The hyper-flow graph is built by aggregating similar flow sets as hyper-flow nodes and designing a hierarchical scheduling framework. The flow attribute-sensitive scheduling information is embedded into the condensed maximal cliques, and reverse maps them precisely to congestion flow portions for re-scheduling. Its parallel scheduling reduces network scale induced complexity. Further, this scheme is designed in its entirety as a comprehensive scheduling algorithm GH2. It improves the three criteria of scalability along a Pareto front. Extensive simulation studies demonstrate its superiority. Notably, GH2 is verified its scheduling stability with a runtime of less than 100 ms for 1000 flows and near 1/190 of the SOTA FITS method for 3000 flows.

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工业时间敏感型网络的可扩展调度：基于超流图的方案

工业时敏网络（TSN）为实时、可靠的流量传输提供了确定性机制。对于具有超低延迟和抖动等严格要求的时间敏感流的有效调度，人们越来越关注。在TSN中，细粒度的流量整形协议循环排队和转发（CQF）通过流量定时进出队列来消除不确定的延迟和帧丢失。然而，它不可避免地会导致较高的调度复杂性。此外，复杂度对流量属性和网络规模非常敏感。这个问题部分源于现有的基于框架的调度中缺乏属性挖掘机制。针对具有大规模复杂流的时间关键型工业网络，提出了一种基于超流图的调度方案，从可调度性、调度效率和延迟抖动等方面提高了调度的可扩展性。通过将相似流集聚合为超流节点，设计分层调度框架，构建超流图。将流属性敏感的调度信息嵌入到压缩的最大团中，并将其精确地反向映射到拥塞流部分以进行重新调度。它的并行调度降低了网络规模引起的复杂性。该方案整体上被设计为综合调度算法GH2。它沿着Pareto前沿改进了可伸缩性的三个标准。大量的仿真研究证明了其优越性。值得注意的是，GH2的调度稳定性得到了验证，对于1000个流，GH2的运行时间小于100 ms，对于3000个流，GH2的运行时间接近SOTA FITS方法的1/190。

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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来源期刊

IEEE/ACM Transactions on Networking 工程技术-电信学

CiteScore

8.20

自引率

5.40%

发文量

246

审稿时长

4-8 weeks

期刊介绍： The IEEE/ACM Transactions on Networking’s high-level objective is to publish high-quality, original research results derived from theoretical or experimental exploration of the area of communication/computer networking, covering all sorts of information transport networks over all sorts of physical layer technologies, both wireline (all kinds of guided media: e.g., copper, optical) and wireless (e.g., radio-frequency, acoustic (e.g., underwater), infra-red), or hybrids of these. The journal welcomes applied contributions reporting on novel experiences and experiments with actual systems.