Bounded Latency with Bridge-Local Stream Reservation and Strict Priority Queuing

2020 11th International Conference on Network of the Future (NoF) Pub Date : 2020-10-12 DOI:10.1109/NoF50125.2020.9249224

Alexej Grigorjew, Florian Metzger, T. Hossfeld, Johannes Specht, Franz-Josef Götz, Feng Chen, Jürgen Schmitt

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引用次数: 8

Abstract

Bridge-local latency computation is often regarded with caution, while new shaping mechanisms and timed gates are developed to achieve deterministic guarantees. However, these new concepts require additional hardware support in the forwarding devices, and many of them are based on assumptions of central control and network-wide information being available. This document presents a per-hop latency bound for individual streams in a class-based network that applies the IEEE 802.1Q strict priority transmission selection algorithm. It does not rely on shaping or timed gates and uses the accumulated latency fields during the reservation process to provide upper bounds with bridge-local information. The presented delay bound is proven formally and then evaluated with respect to its accuracy. It shows that deterministic latency with priority queuing is indeed feasible, and it indicates the required information that must be provided during resource reservation, e.g., to protocols developed in IEEE 802.1Qdd. This document presents a per-hop latency bound for individual streams in a class-based network that applies the IEEE 802.1Q strict priority transmission selection algorithm. It does not rely on shaping or timed gates and uses the accumulated latency fields during the reservation process to provide upper bounds with bridge-local information. The presented delay bound is proven formally and then evaluated with respect to its accuracy. It shows that deterministic latency with priority queuing is indeed feasible, and it indicates the required information that must be provided during resource reservation, e.g., to protocols developed in IEEE 802.1Qdd.

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具有桥接本地流保留和严格优先级排队的有限延迟

桥本地延迟计算通常被认为是谨慎的，而新的整形机制和时间门被开发来实现确定性保证。然而，这些新概念需要转发设备中额外的硬件支持，其中许多都是基于中央控制和网络范围信息可用的假设。本文介绍了在基于类的网络中应用IEEE 802.1Q严格优先级传输选择算法的单个流的每跳延迟绑定。它不依赖于整形门或定时门，而是在保留过程中使用累积的延迟字段来提供桥本地信息的上界。对所提出的延迟界进行了形式化证明，并对其精度进行了评价。这表明了优先级排队的确定性延迟确实是可行的，并且它指出了在资源预留过程中必须提供的所需信息，例如IEEE 802.1Qdd中开发的协议。本文介绍了在基于类的网络中应用IEEE 802.1Q严格优先级传输选择算法的单个流的每跳延迟绑定。它不依赖于整形门或定时门，而是在保留过程中使用累积的延迟字段来提供桥本地信息的上界。对所提出的延迟界进行了形式化证明，并对其精度进行了评价。这表明了优先级排队的确定性延迟确实是可行的，并且它指出了在资源预留过程中必须提供的所需信息，例如IEEE 802.1Qdd中开发的协议。

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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2020 11th International Conference on Network of the Future (NoF)

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