Justus Rischke, Christian L. Vielhaus, Peter Sossalla, Sebastian Itting, Giang T. Nguyen, F. Fitzek
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引用次数: 4
Abstract
5G campus networks, whose advantages include flexible deployment, can be a promising candidate for production plants to complement existing Wifi-based networks. Toward that goal, 5G has to satisfy strict requirements about real-time communication to facilitate novel use cases. However, the realtime-capability of 5G is not well understood yet. In this work, we deliver insights into the functioning of 5G NR RAN Release 15, which includes actual one-way delay and Round-Trip Time (RTT) measurements for Downlink and Uplink in a private 5G Standalone campus network. The extensive measurement results reveal that these delays are correlated, and the corresponding RTT, i.e. the sum of Downlink and Uplink delays, is discreetly clustered, ranging between 12ms and 40ms. The measurements also show that the distribution of RTTs is mainly dependent on the packet rates and their inter-arrival times. Our study helps expand the current understanding of 5G used for latency-critical applications. We make the code and the measurement data traces publicly available as the IEEE DataPort 5G Campus Networks: Measurement Traces dataset (DOI 10.21227/xe3c-e968).
5G园区网络的优势包括灵活部署,可以成为生产工厂补充现有wifi网络的有希望的候选者。为了实现这一目标,5G必须满足对实时通信的严格要求,以促进新的用例。然而,5G的实时能力还没有得到很好的理解。在这项工作中,我们深入了解了5G NR RAN Release 15的功能,其中包括在专用5G独立校园网中下行链路和上行链路的实际单向延迟和往返时间(RTT)测量。广泛的测量结果表明,这些延迟是相关的,相应的RTT,即下行链路和上行链路延迟的总和,被谨慎地聚类,范围在12ms到40ms之间。测量结果还表明,rtt的分布主要取决于分组速率和它们的间隔到达时间。我们的研究有助于扩展目前对用于延迟关键应用的5G的理解。我们将代码和测量数据跟踪作为IEEE DataPort 5G校园网:测量跟踪数据集(DOI 10.21227/xe3c-e968)公开提供。
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