Probabilistic Observation Prediction Model based E4 Scheduling Mechanism in Peer to Peer Grid Computing

2006 Fifth International Conference on Grid and Cooperative Computing (GCC'06) Pub Date : 2006-10-21 DOI:10.1109/GCC.2006.74

EunJoung Byun, Hongsoo Kim, SungJin Choi, C. Hwang

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引用次数: 1

Abstract

Peer to peer (P2P) grid computing is an Internet-based parallel computing paradigm to achieve tremendous computing power by voluntary peers. Since peers are not dedicated to a system, peers are free to leave and join autonomously during computation in this computing environment. A scheduling mechanism must cover the volatility of peers to support a reliable P2P grid computing system. Most existing P2P grid computing systems, however, suffer from blocked job execution and delayed makespan because they do not consider the volatile features of peers in the scheduling procedure. In order to improve system reliability, we propose a probabilistic observation prediction (POP) -based EA scheduling mechanism supporting three advanced scheduling policies: loose time constraint policy (LTCP), strict time constraint policy (STCP), and hybrid time constraint policy (HTCP). LTCP is for general use, STCP aims at minimizing makespan, and HTCP attempts to improve efficiency, and performance-to-cost ratio. All policies are based on stochastic modeling of peer state transition while endeavoring to manage the volatile features of peers

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点对点网格计算中基于概率观测预测模型的E4调度机制

点对点(P2P)网格计算是一种基于internet的并行计算范式，通过自愿的对等体实现巨大的计算能力。由于对等点并不专用于系统，因此在此计算环境中，对等点可以在计算期间自由离开并自主加入。调度机制必须覆盖节点的不稳定性，以支持可靠的P2P网格计算系统。然而，现有的P2P网格计算系统由于在调度过程中没有考虑节点的易变特性，存在作业执行阻塞和最大时间跨度延迟的问题。为了提高系统可靠性，提出了一种基于概率观测预测(POP)的EA调度机制，支持三种高级调度策略:松散时间约束策略(LTCP)、严格时间约束策略(STCP)和混合时间约束策略(HTCP)。LTCP用于一般用途，STCP旨在最小化完工时间，而HTCP试图提高效率和性能成本比。所有策略都是基于对等体状态转移的随机建模，同时努力管理对等体的波动性特征

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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2006 Fifth International Conference on Grid and Cooperative Computing (GCC'06)

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