基于深度强化学习的软件自定义SGIN路由优化方法

Zhe Tu, Huachun Zhou, Kun Li, Guanglei Li, Qihui Shen
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引用次数: 11

摘要

随着空间网络的日益重要,地空一体化网络(SGIN)受到了前所未有的重视。然而,卫星网络拓扑结构和链路状态的动态变化给SGIN中的路由优化带来了许多挑战。传统的路由优化方法没有考虑拓扑和链路状态的变化以及流之间的关联,性能不佳。由于机器学习(ML)技术在动态路由优化方面显示出显着优势,我们提出了一个基于机器学习的空间-地面集成网络(ML- ssgin)框架,该框架结合了软件定义网络(SDN)技术来解决这一挑战。为了评估所提出框架的可行性,部署了深度确定性策略梯度(DDPG),一种深度强化学习(DRL)算法来进行路由优化,该算法可以根据实时链路状态做出路由决策。特别是,我们利用一个集成了长短期记忆网络(LSTM)和密集层的神经网络作为其参与者和批评者部分,以提高流之间上下文相关性的感知能力。我们将所提出的DDPG神经网络与仅具有Dense层的DDPG神经网络进行了比较。结果表明,所提出的结构是可行和有效的。此外,与开放最短路径优先(OSPF)算法相比,所提出的路由优化方法能够适应不断变化的流量和链路状态,提高了端到端吞吐量和时延。
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A Routing Optimization Method for Software-Defined SGIN Based on Deep Reinforcement Learning
As space networks become more and more important, the Space-ground Integration network (SGIN) has received unprecedented attention. However, dynamic changes of topology and link status of satellite networks bring many challenges to routing optimization in the SGIN. Traditional routing optimization methods do not perform well, as they do not consider changes of topology and link status, as well as the association between flows. Since the Machine Learning (ML) technologies have shown significant advantages in dynamic routing optimization, we proposed a Machine Learning-based Space-ground Integration Networking (ML-SSGIN) framework that combines Software-Defined Networking (SDN) technologies to solve this challenge. To evaluate the feasibility of the proposed framework, the Deep Deterministic Policy Gradient (DDPG), a Deep Reinforcement Learning (DRL) algorithm, is deployed to perform routing optimization, which can make routing decisions based on real-time link status. In particular, we utilize a neural network that integrates Long Short-Term Memory Network (LSTM) and Dense layers for its actor and critic part to improve perceptual capabilities of contextual correlations between flows. We compared the proposed DDPG neural network with the one only having the Dense layers. The results show that the proposed architecture is feasible and effective. What's more, compared to Open Shortest Path First (OSPF) algorithm, our proposed routing optimization method can adapt to continuously change flows, and link status, which improves end-to-end throughput and latency.
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