可通用的 5G RAN/MEC 分片和接入控制,实现可靠的网络运行

IF 4.7 2区 计算机科学 Q1 COMPUTER SCIENCE, INFORMATION SYSTEMS
Mahdieh Ahmadi;Arash Moayyedi;Muhammad Sulaiman;Mohammad A. Salahuddin;Raouf Boutaba;Aladdin Saleh
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引用次数: 0

摘要

5G 无线接入网(RAN)功能在无线单元(RU)、分布式单元(DU)和集中式单元(CU)之间的虚拟化和分布与多接入边缘计算(MEC)相结合,能够为具有不同服务质量(QoS)需求的各种应用创建量身定制的网络切片。然而,考虑到切片请求的动态性和有限的网络资源,通过实时接纳和嵌入切片请求来优化基础设施提供商(InPs)的长期收入是一项重大挑战。之前的研究采用了深度强化学习(DRL)来解决这一问题,但这些方法需要在节点/链路故障导致拓扑发生细微变化时重新训练,或者忽略了切片接纳和嵌入问题的共同考虑。本文提出了一种利用多代理 DRL 和图注意网络 (GAT) 的新方法,以克服这些局限性。具体来说,我们开发了与拓扑无关的接入和分片代理,这些代理可在不同的城域网中扩展和通用。结果表明,与启发式方法相比,我们获得了高达 35.2% 的收入收益,与其他基于 DRL 的方法相比,我们获得了 19.5% 的收入收益。此外,我们的方法在不同的网络故障场景和训练过程中未见的基质网络中都表现出了强大的性能,无需重新训练或调整。此外,我们还通过分析注意力图带来了可解释性,这使 InPs 能够识别网络瓶颈,提高关键节点的容量,并清楚地了解模型的决策过程。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Generalizable 5G RAN/MEC Slicing and Admission Control for Reliable Network Operation
The virtualization and distribution of 5G Radio Access Network (RAN) functions across radio unit (RU), distributed unit (DU), and centralized unit (CU) in conjunction with multi-access edge computing (MEC) enable the creation of network slices tailored for various applications with distinct quality of service (QoS) demands. Nonetheless, given the dynamic nature of slice requests and limited network resources, optimizing long-term revenue for infrastructure providers (InPs) through real-time admission and embedding of slice requests poses a significant challenge. Prior works have employed Deep Reinforcement Learning (DRL) to address this issue, but these approaches require re-training with the slightest topology changes due to node/link failure or overlook the joint consideration of slice admission and embedding problems. This paper proposes a novel method, utilizing multi-agent DRL and Graph Attention Networks (GATs), to overcome these limitations. Specifically, we develop topology-independent admission and slicing agents that are scalable and generalizable across diverse metropolitan networks. Results demonstrate substantial revenue gains-up to 35.2% compared to heuristics and 19.5% when compared to other DRL-based methods. Moreover, our approach showcases robust performance in different network failure scenarios and substrate networks not seen during training without the need for re-training or re-tuning. Additionally, we bring interpretability by analyzing attention maps, which enables InPs to identify network bottlenecks, increase capacity at critical nodes, and gain a clear understanding of the model decision-making process.
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来源期刊
IEEE Transactions on Network and Service Management
IEEE Transactions on Network and Service Management Computer Science-Computer Networks and Communications
CiteScore
9.30
自引率
15.10%
发文量
325
期刊介绍: IEEE Transactions on Network and Service Management will publish (online only) peerreviewed archival quality papers that advance the state-of-the-art and practical applications of network and service management. Theoretical research contributions (presenting new concepts and techniques) and applied contributions (reporting on experiences and experiments with actual systems) will be encouraged. These transactions will focus on the key technical issues related to: Management Models, Architectures and Frameworks; Service Provisioning, Reliability and Quality Assurance; Management Functions; Enabling Technologies; Information and Communication Models; Policies; Applications and Case Studies; Emerging Technologies and Standards.
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