System level power-performance trade-offs in embedded systems using voltage and frequency scaling of off-chip buses and memory

15th International Symposium on System Synthesis, 2002. Pub Date : 2002-10-02 DOI:10.1145/581199.581249

A. Chatterjee, P. Ellervee, V. Mooney, Jun-Cheol Park, Kyu-won Choi, Kiran Puttaswamy

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引用次数: 27

Abstract

In embedded systems, off-chip buses and memory (i.e., L2 memory as opposed to the L1 memory which is usually on-chip cache) consume significant power often more than the processor itself. In this paper for the case of an embedded system with one processor chip and one memory chip, we propose frequency and voltage scaling of the off-chip buses and the memory chip and use a known micro-architectural enhancement called a store buffer to reduce the resulting impact on execution time. Our benchmarks show a system (processor + off-chip bus + off-chip memory) power savings of 28% to 36%, an energy savings of 13% to 35%, all while increasing the execution time in the range of 1% to 29%. Previous work in power-aware computing has focused on frequency and voltage scaling of the processors or selective power-down of sub-sets of off-chip memory chips. This paper quantitatively explores voltage/frequency scaling of off-chip buses and memory as a means of trading off performance for power/energy at the system level in embedded systems.

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使用片外总线和存储器的电压和频率缩放的嵌入式系统中的系统级功率性能权衡

在嵌入式系统中，片外总线和内存(即L2内存，与L1内存相反，L1内存通常是片上缓存)消耗的功率通常比处理器本身要大。在本文中，对于一个带有一个处理器芯片和一个存储芯片的嵌入式系统，我们提出了片外总线和存储芯片的频率和电压缩放，并使用称为存储缓冲区的已知微架构增强来减少对执行时间的影响。我们的基准测试显示，系统(处理器+片外总线+片外存储器)的功耗节省了28%到36%，能源节省了13%到35%，同时执行时间增加了1%到29%。以前在功率感知计算方面的工作主要集中在处理器的频率和电压缩放或片外存储芯片子集的选择性断电。本文定量地探讨了片外总线和存储器的电压/频率缩放，作为在嵌入式系统级别上权衡功率/能量性能的一种手段。

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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15th International Symposium on System Synthesis, 2002.

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