Transport efficiency for data-intensive science: deployment experiences and bottleneck analysis

IF 2.2 4区计算机科学 Q3 TELECOMMUNICATIONS

Annals of Telecommunications Pub Date : 2025-04-24 DOI:10.1007/s12243-025-01094-0

Vitor F. Zanotelli, Edgard C. Pontes, Magnos Martinello, Jordi Ros-Giralt, Everson S. Borges, Giovanni Comarela, Moisés R. N. Ribeiro, Harvey Newman

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引用次数: 0

Abstract

Transferring massive datasets in data-intensive science (DIS) systems often relies on physical WAN infrastructure for network connectivity. This infrastructure is typically provided by various National Research and Education Networks (NRENs), including ESnet, GÉANT, Internet2, and RNP. Studying these systems presents significant challenge due to their complexity, scale, and the numerous factors influencing data transport. Traditionally, network performance studies focus on a single bottleneck. In contrast, the Quantitative Theory of Bottlenecks Structures (QTBS) provides a mathematical framework that analyzes performance through the network’s entire bottleneck structure, offering valuable insights for optimizing and understanding overall network performance. This paper tackles such challenges by employing QTBS and by deploying and evaluating a virtual infrastructure for data transport within a national-scale WAN. Our approach focuses on three key aspects: (i) assessing flow completion times related to bandwidth allocation for interdependent transfers within a network slice, (ii) evaluating the performance of TCP congestion control algorithms (BBR versus Cubic) for data transport, and (iii) conducting QTBS analysis to compute flow allocation shares, ultimately aiming for an optimal design. Results show BBR outperforming Cubic in scenarios with high number of threads and data volume and the high influence of the number of threads.

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数据密集型科学的传输效率：部署经验和瓶颈分析

在数据密集型科学（DIS）系统中传输大量数据集通常依赖于物理广域网基础设施的网络连接。这种基础设施通常由各种国家研究和教育网络（NRENs）提供，包括ESnet、GÉANT、Internet2和RNP。由于这些系统的复杂性、规模和影响数据传输的众多因素，研究这些系统提出了重大挑战。传统上，网络性能研究主要集中在单个瓶颈上。相比之下，瓶颈结构定量理论（QTBS）提供了一个数学框架，通过网络的整个瓶颈结构来分析性能，为优化和理解整体网络性能提供了有价值的见解。本文通过采用QTBS以及在全国范围的广域网内部署和评估用于数据传输的虚拟基础设施来解决此类挑战。我们的方法侧重于三个关键方面：(i)评估与网络片内相互依赖传输的带宽分配相关的流量完成时间，（ii）评估TCP拥塞控制算法（BBR与Cubic）用于数据传输的性能，以及（iii）进行QTBS分析以计算流量分配份额，最终旨在实现最佳设计。结果表明，在线程数和数据量大、线程数影响大的场景下，BBR的性能优于Cubic。

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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来源期刊

Annals of Telecommunications 工程技术-电信学

CiteScore

5.20

自引率

5.30%

发文量

审稿时长

4.5 months

期刊介绍： Annals of Telecommunications is an international journal publishing original peer-reviewed papers in the field of telecommunications. It covers all the essential branches of modern telecommunications, ranging from digital communications to communication networks and the internet, to software, protocols and services, uses and economics. This large spectrum of topics accounts for the rapid convergence through telecommunications of the underlying technologies in computers, communications, content management towards the emergence of the information and knowledge society. As a consequence, the Journal provides a medium for exchanging research results and technological achievements accomplished by the European and international scientific community from academia and industry.