Fast Traffic Engineering by Gradient Descent with Learned Differentiable Routing

2022 18th International Conference on Network and Service Management (CNSM) Pub Date : 2022-09-21 DOI:10.23919/CNSM55787.2022.9964923

Krzysztof Rusek, Paul Almasan, José Suárez-Varela, P. Chołda, P. Barlet-Ros, A. Cabellos-Aparicio

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引用次数: 2

Abstract

Emerging applications such as the metaverse, telesurgery or cloud computing require increasingly complex operational demands on networks (e.g., ultra-reliable low latency). Likewise, the ever-faster traffic dynamics will demand network control mechanisms that can operate at short timescales (e.g., sub-minute). In this context, Traffic Engineering (TE) is a key component to efficiently control network traffic according to some performance goals (e.g., minimize network congestion).This paper presents Routing By Backprop (RBB), a novel TE method based on Graph Neural Networks (GNN) and differentiable programming. Thanks to its internal GNN model, RBB builds an end-to-end differentiable function of the target TE problem (MinMaxLoad). This enables fast TE optimization via gradient descent. In our evaluation, we show the potential of RBB to optimize OSPF-based routing (≈25% of improvement with respect to default OSPF configurations). Moreover, we test the potential of RBB as an initializer of computationally-intensive TE solvers. The experimental results show promising prospects for accelerating this type of solvers and achieving efficient online TE optimization.

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基于学习可微路由的梯度下降快速交通工程

新兴的应用，如元宇宙、远程手术或云计算，对网络的操作要求越来越复杂(例如，超可靠的低延迟)。同样，越来越快的流量动态将要求网络控制机制能够在短时间尺度(例如，分分钟)内运行。在这种情况下，流量工程(TE)是根据某些性能目标(例如，最小化网络拥塞)有效控制网络流量的关键组件。本文提出了一种基于图神经网络(GNN)和可微规划的路由回溯算法(Routing By Backprop, RBB)。由于其内部GNN模型，RBB构建了目标TE问题(MinMaxLoad)的端到端可微函数。这可以通过梯度下降实现快速TE优化。在我们的评估中，我们展示了RBB优化基于OSPF路由的潜力(相对于缺省OSPF配置的改进≈25%)。此外，我们测试了RBB作为计算密集型TE求解器的初始化器的潜力。实验结果表明，该算法在加速求解和实现高效在线TE优化方面具有广阔的应用前景。

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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2022 18th International Conference on Network and Service Management (CNSM)

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