动态电源管理使用自适应学习树

Eui-Young Chung, L. Benini, G. Micheli
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引用次数: 175

摘要

动态电源管理(DPM)是一种通过选择性关闭空闲组件来降低电子系统功耗的技术。关机控制算法(电源管理策略)的质量主要取决于对用户行为的了解,在许多情况下,用户行为最初是未知的或非平稳的。因此,DPM策略应该能够适应用户行为的变化。本文提出了一种基于空闲期聚类和自适应学习树的DPM方案。我们还提供了将我们的技术应用于具有多个睡眠状态的组件的设计指南。实验结果表明,我们的技术优于其他先进的DPM方案和简单的超时策略。所提出的方法表明,对于具有不同特征的各种工作负载,效率偏差很小,而其他策略表明,它们的效率会根据跟踪数据特征发生巨大变化。实验结果表明,该算法性能稳定,收敛速度快。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Dynamic power management using adaptive learning tree
Dynamic power management (DPM) is a technique to reduce the power consumption of electronic systems by selectively shutting down idle components. The quality of the shutdown control algorithm (the power management policy) mostly depends on knowledge of the user's behavior, which in many cases is initially unknown or non-stationary. For this reason, DPM policies should be capable of adapting to changes in user behavior. In this paper, we present a novel DPM scheme based on idle period clustering and adaptive learning trees. We also provide a design guide for applying our technique to components with multiple sleep states. Experimental results show that our technique outperforms other advanced DPM schemes as well as simple time-out policies. The proposed approach shows little deviation of efficiency for various workloads having different characteristics, while other policies show that their efficiency changes drastically depending on the trace data characteristics. Furthermore, experimental evidence indicates that our workload learning algorithm is stable and has fast convergence.
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