Design and development of hybrid integrated thermal aware job scheduling on computational grid environment

2015 International Symposium on Mathematical Sciences and Computing Research (iSMSC) Pub Date : 2015-05-19 DOI:10.1109/ISMSC.2015.7594020

Ahmad Abba Haruna, L. T. Jung, N. Zakaria

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引用次数: 7

Abstract

Over the decades people have seen a change from large mainframe computing to commodity, off-the-shelf clusters of high performance computers. Currently data centers have thousands or tens of thousands of high performance computers that provides services as well as computation for tens or hundreds of thousands of users. Traditional IT challenges such as scheduling, resource allocation and now data centers are dealing with power consumption, it is the most expensive operational cost factor in data centers. Inefficient cooling leads to high temperature and this in turn leads to hardware failure. In this paper a Hybrid Integrated Thermal Aware Scheduling Algorithms are proposed based on baseline approaches. The aim of this paper is to minimize cooling energy consumption in data center labs when assigning jobs for computation. These algorithms avoid high thermal stress situations such as large hotspots and thermal violations events. The results show that the Hybrid Integrated Thermal aware scheduling algorithms (TFCFS and TRR) reduces cooling electricity by 7000KW compared to the baseline job scheduling algorithms, First Come First Serve (FCFS) and Round Robin (RR).

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计算网格环境下混合集成热感知作业调度的设计与开发

在过去的几十年里，人们看到了从大型主机计算到商品、现成的高性能计算机集群的变化。目前，数据中心拥有数千或数万台高性能计算机，为数万或数十万用户提供服务和计算。传统的IT挑战，如调度、资源分配和现在的数据中心正在处理的电力消耗，它是数据中心最昂贵的运营成本因素。冷却效率低下导致温度过高，进而导致硬件故障。本文提出了一种基于基线法的混合集成热感知调度算法。本文的目的是在分配计算任务时，最大限度地减少数据中心实验室的冷却能耗。这些算法避免了大热点和热破坏事件等高热应力情况。结果表明，与先到先服务(FCFS)和轮循(RR)等基准作业调度算法相比，混合集成热感知调度算法(TFCFS和TRR)可减少7000KW的冷却电力。

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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2015 International Symposium on Mathematical Sciences and Computing Research (iSMSC)

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