计算连续体中边缘节点的能量消耗和工作负载预测

IF 3.8 3区计算机科学 Q1 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE

Sustainable Computing-Informatics & Systems Pub Date : 2025-01-28 DOI:10.1016/j.suscom.2025.101088

Sergio Laso , Pablo Rodríguez , Juan Luis Herrera , Javier Berrocal , Juan M. Murillo

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引用次数: 0

摘要

Computing Continuum范例为开发人员提供了一个分布式基础设施，用于通过网络部署应用程序，从而提高性能和能耗。然而，为了保持应用程序的效率，它们在计算连续体中的部署必须不断适应网络中不同节点的不同负载。在实践中，现有的支持框架允许开发人员根据基础设施状态自动确定如何部署应用程序。但是，由于部署应用程序需要时间，因此所选的部署一旦通过网络应用就会过时，因为工作负载会随时间变化。为了应对这一实际工程挑战，并规划可预见能源消耗和工作负载变化的部署，需要预测性解决方案。为了满足这一需求，本工作提出了微服务能耗和工作负载预测器（MEWF），这是一个利用人工智能技术精确预测不同情况下CPU使用情况和能耗的预测系统。我们对多个真实微服务的实际评估表明，MEWF将预测精度提高了55%，达到了最先进的基准，实现了高效的资源管理，并为现实世界的部署展示了重要价值。

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Energy consumption and workload prediction for edge nodes in the Computing Continuum

The Computing Continuum paradigm provides developers with a distributed infrastructure for deploying applications through the network, improving performance and energy consumption. However, to maintain applications’ efficiency, their deployment in the Computing Continuum has to be continuously adapted to the varying load of different nodes of the network. In practice, existing support frameworks allow developers to automatically identify how to deploy applications based on the infrastructure status. However, as the application takes time to be deployed, the chosen deployment is outdated once it is applied through the network, as workloads change over time. To address this practical engineering challenge and plan deployments that foresee changes in energy consumption and workload, predictive solutions are needed. To fulfill this need, this work presents the Microservice Energy consumption and Workload Forecaster (MEWF), a prediction system that leverages artificial intelligence techniques to precisely predict CPU usage and energy consumption in varying circumstances. Our practical evaluation over multiple real microservices shows that MEWF improves prediction precision by up to 55% w.r.t. state-of-the-art benchmarks, enabling efficient resource management and demonstrating significant value for real-world deployments.

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来源期刊

Sustainable Computing-Informatics & Systems COMPUTER SCIENCE, HARDWARE & ARCHITECTUREC-COMPUTER SCIENCE, INFORMATION SYSTEMS

CiteScore

10.70

自引率

4.40%

发文量

142

期刊介绍： Sustainable computing is a rapidly expanding research area spanning the fields of computer science and engineering, electrical engineering as well as other engineering disciplines. The aim of Sustainable Computing: Informatics and Systems (SUSCOM) is to publish the myriad research findings related to energy-aware and thermal-aware management of computing resource. Equally important is a spectrum of related research issues such as applications of computing that can have ecological and societal impacts. SUSCOM publishes original and timely research papers and survey articles in current areas of power, energy, temperature, and environment related research areas of current importance to readers. SUSCOM has an editorial board comprising prominent researchers from around the world and selects competitively evaluated peer-reviewed papers.