Dynamic network provisioning for data intensive applications in the cloud

2012 IEEE 8th International Conference on E-Science Pub Date : 2012-10-08 DOI:10.1109/eScience.2012.6404461

P. Ruth, A. Mandal, Yufeng Xin, I. Baldine, Chris Heermann, J. Chase

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引用次数: 4

Abstract

Advanced networks are an essential element of data-driven science enabled by next generation cyberinfrastructure environments. Computational activities increasingly incorporate widely dispersed resources with linkages among software components spanning multiple sites and administrative domains. We have seen recent advances in enabling on-demand network circuits in the national and international backbones coupled with Software Defined Networking (SDN) advances like OpenFlow and programmable edge technologies like OpenStack. These advances have created an unprecedented opportunity to enable complex scientific applications to run on specially tailored, dynamic infrastructure that include compute, storage and network resources, combining the performance advantages of purpose-built infrastructures, but without the costs of a permanent infrastructure. This work presents an experience deploying scientific workflows on the ExoGENI national test bed that dynamically allocates computational resources with high-speed circuits from backbone providers. Dynamically allocated bandwidth-provisioned high-speed circuits increase the ability of scientific applications to access and stage large data sets from remote data repositories or to move computation to remote sites and access data stored locally. The remainder of this extended abstract is a brief description of the test bed and several scientific workflow applications that were deployed using bandwidth-provisioned high-speed circuits.

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为云中的数据密集型应用程序提供动态网络配置

先进的网络是下一代网络基础设施环境下数据驱动科学的重要组成部分。计算活动越来越多地将广泛分散的资源与跨越多个站点和管理域的软件组件之间的联系结合起来。我们已经看到了在国内和国际主干网中实现按需网络电路的最新进展，以及OpenFlow等软件定义网络(SDN)的进步和OpenStack等可编程边缘技术。这些进步创造了一个前所未有的机会，使复杂的科学应用程序能够在专门定制的动态基础设施上运行，包括计算、存储和网络资源，结合了专用基础设施的性能优势，但没有永久性基础设施的成本。这项工作展示了在ExoGENI国家测试平台上部署科学工作流程的经验，该测试平台可以通过骨干提供商的高速电路动态分配计算资源。动态分配带宽的高速电路增加了科学应用程序从远程数据存储库访问和处理大型数据集的能力，或者将计算移动到远程站点并访问本地存储的数据的能力。这个扩展摘要的其余部分是对测试平台和几个使用带宽预置高速电路部署的科学工作流应用程序的简要描述。

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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2012 IEEE 8th International Conference on E-Science

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