Dynamic Scheduling and Optimal Reconfiguration of UPF Placement in 5G Networks

Proceedings of the 23rd International ACM Conference on Modeling, Analysis and Simulation of Wireless and Mobile Systems Pub Date : 2020-11-16 DOI:10.1145/3416010.3423221

Irian Leyva-Pupo, C. Cervelló-Pastor, C. Anagnostopoulos, D. Pezaros

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引用次数: 10

Abstract

Multi-access Edge Computing (MEC) is a key technology in the road to 5G and beyond networks. Significant reductions in both latency and backhaul traffic can be achieved by placing server applications, and network functions at the network edge. However, this implies new challenges for their dynamic placement and management. In this paper, we tackle the problem of dynamic placement reconfiguration of 5G User Plane Functions (UPFs) in a MEC ecosystem to adapt to changes in user locations while ensuring QoS and network operator expenditures reduction. In this vein, an Integer Linear Programming (ILP) solution is proposed to determine the optimal UPF placement configuration (e.g., number of UPFs and user-UPF mapping) by considering several cost components along with service requirements. Moreover, a scheduling technique based on Optimal Stopping Theory (OST) is presented to decide the optimal reconfiguration time according to instantaneous values of latency violations and established QoS thresholds. Extensive simulation results demonstrate their effectiveness, achieving significant improvements in metrics such as number of re-computation events, reconfiguration costs, and number of latency violations over time.

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5G网络中UPF布局的动态调度与最优重构

多接入边缘计算(MEC)是通往5G及以后网络的关键技术。通过将服务器应用程序和网络功能放在网络边缘，可以显著减少延迟和回程流量。然而，这对他们的动态安置和管理意味着新的挑战。在本文中，我们解决了在MEC生态系统中5G用户平面功能(upf)的动态布局重新配置问题，以适应用户位置的变化，同时确保QoS和网络运营商支出的减少。在这种情况下，提出了一个整数线性规划(ILP)解决方案，通过考虑几个成本组成部分以及服务需求来确定最佳的UPF放置配置(例如，UPF的数量和用户-UPF映射)。此外，提出了一种基于最优停止理论(OST)的调度技术，根据时延违规的瞬时值和已建立的QoS阈值确定最优重构时间。大量的模拟结果证明了它们的有效性，在诸如重新计算事件的数量、重新配置成本和随时间变化的延迟违规数量等指标上取得了显著的改进。

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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Proceedings of the 23rd International ACM Conference on Modeling, Analysis and Simulation of Wireless and Mobile Systems

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