基于多任务深度强化学习的自适应服务功能链映射

IF 6.7 2区计算机科学 Q1 ENGINEERING, MULTIDISCIPLINARY

IEEE Transactions on Network Science and Engineering Pub Date : 2025-04-01 DOI:10.1109/TNSE.2025.3556390

Wenting Wei;Qingyi Wang;Huaxi Gu;Danyang Zheng;Ning Zhang;Celimuge Wu

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引用次数: 0

摘要

网络功能虚拟化（Network function virtualization， NFV）是将不同的虚拟网络功能（virtual Network functions， VNF）按顺序动态链接起来，以灵活、可扩展和经济高效的方式提供新的业务。近年来，不断增加的新应用带来了越来越多样化的服务需求，这对vnf的高效和顺序执行以实现特定目标提出了重大挑战，特别是在共享资源的条件下。为应对这些挑战，我们致力提高资源利用率，并尽量减少与服务功能链有关的成本，同时保持高质素的服务。然而，过分强调降低成本有时会导致网络拥塞，最终降低网络性能和服务质量。考虑到SFC的时变和不可预测的特征，利用它们的时间特征以及网络状态特征来进行自适应SFC映射是必不可少的。本文介绍了一种自适应在线SFC映射算法，以降低运行成本和缓解网络拥塞。这是通过vnf的自适应分配和它们之间的流量路由控制来实现的。我们的方法结合了多任务深度强化学习来管理具有不同资源需求的多个SFC请求的共存。具体来说，我们将长短期记忆（LSTM）层集成到我们的模型中，以捕获网络状态和资源需求的时间动态，从而实现更有效的长期规划。为了解决奖励稀疏性问题，我们实现了分层奖励机制和奖励塑造技术。实验结果表明，该算法在优化服务延迟、带宽消耗和网络拥塞方面达到了接近最优的性能，同时保证了用户请求的高接受率。

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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An Adaptive Service Function Chains Mapping With Multi-Task Deep Reinforcement Learning

Network function virtualization (NFV) facilitates different virtual network functions (VNF) to be dynamically chained in sequence to offer new services in a flexible, scalable, and cost-effective manner. Recent years have witnessed the increasing diverse service demands from the ever-increasing new applications, which has posed significant challenges to the efficient and sequential execution of VNFs to achieve specific objectives, especially under conditions of shared resources. To address these challenges, substantial efforts have been dedicated to enhancing resource utilization and minimizing the costs associated with service function chains (SFCs), while maintaining high quality of service. However, an overemphasis on cost reduction can sometimes result in network congestion, which ultimately degrades both network performance and service quality. Given the time-varying and unpredictable characteristics of SFCs, it is essential to leverage their temporal features, along with those of network states, for adaptive SFC mapping. In this paper, we introduce an adaptive online SFC mapping algorithm to reduce operational costs and alleviate network congestion. This is achieved through the adaptive allocation of VNFs and the control of traffic routing between them. Our approach incorporates multi-task deep reinforcement learning to manage the coexistence of multiple SFC requests with varying resource requirements. Specifically, we integrate a long short-term memory (LSTM) layer into our model to capture the temporal dynamics of network states and resource demands, thereby enabling more effective long-term planning. To address the issue of reward sparsity, we implement a hierarchical reward mechanism and reward shaping techniques. Experimental results demonstrate that our algorithm achieves near-optimal performance in optimizing service delay, bandwidth consumption, and network congestion, while also ensuring a high acceptance rate for user requests.

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来源期刊

IEEE Transactions on Network Science and Engineering Engineering-Control and Systems Engineering

CiteScore

12.60

自引率

9.10%

发文量

393

期刊介绍： The proposed journal, called the IEEE Transactions on Network Science and Engineering (TNSE), is committed to timely publishing of peer-reviewed technical articles that deal with the theory and applications of network science and the interconnections among the elements in a system that form a network. In particular, the IEEE Transactions on Network Science and Engineering publishes articles on understanding, prediction, and control of structures and behaviors of networks at the fundamental level. The types of networks covered include physical or engineered networks, information networks, biological networks, semantic networks, economic networks, social networks, and ecological networks. Aimed at discovering common principles that govern network structures, network functionalities and behaviors of networks, the journal seeks articles on understanding, prediction, and control of structures and behaviors of networks. Another trans-disciplinary focus of the IEEE Transactions on Network Science and Engineering is the interactions between and co-evolution of different genres of networks.