EPC-TE: Explicit Path Control in Traffic Engineering with Deep Reinforcement Learning

2021 IEEE Global Communications Conference (GLOBECOM) Pub Date : 2021-12-01 DOI:10.1109/GLOBECOM46510.2021.9685792

Zeyu Luan, Lie Lu, Qing Li, Yong Jiang

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引用次数: 2

Abstract

Segment Routing (SR) provides Traffic Engineering (TE) with Explicit Path Control (EPC) by steering data flows passing through a list of SR routers along a desired path. However, large-scale migration from a pure IP network to a full SR one requires prohibitive hardware replacement and software update. Therefore, network operators prefer to upgrade a subset of IP routers into SR routers during a transitional period. This paper proposes EPC-TE to optimize TE performance in hybrid IP/SR networks where partially deployed SR routers coexist with legacy IP routers. We propose a concept of key nodes to achieve EPC over desired paths and a criterion to select which IP routers to upgrade first under a pre-defined upgrading ratio. EPC-TE leverages Deep Reinforcement Learning (DRL) to inference the optimal traffic splitting ratio across multiple controllable paths between source-destination pairs. EPC-TE can achieve comparable TE performance as a full SR network with an upgrading ratio less than 30%. Extensive experimental results with real-world topologies show that EPC-TE significantly outperforms other baseline TE solutions in minimizing maximum link utilization.

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基于深度强化学习的交通工程显式路径控制

分段路由(SR)为流量工程(TE)提供了显式路径控制(EPC)，它引导数据流沿着期望的路径通过一系列SR路由器。然而，从纯IP网络到完整SR网络的大规模迁移需要大量的硬件更换和软件更新。因此，网络运营商倾向于在过渡时期将一部分IP路由器升级为SR路由器。本文提出EPC-TE来优化IP/SR混合网络中部分部署的SR路由器与传统IP路由器共存的TE性能。我们提出了在期望路径上实现EPC的关键节点概念，以及在预定义的升级比率下选择首先升级哪些IP路由器的标准。EPC-TE利用深度强化学习(DRL)来推断源-目的对之间多条可控路径的最佳流量分割比率。EPC-TE可以达到与全SR网络相当的TE性能，升级率不超过30%。实际拓扑的大量实验结果表明，EPC-TE在最小化最大链路利用率方面显著优于其他基线TE解决方案。

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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2021 IEEE Global Communications Conference (GLOBECOM)

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