精确和局部动态热管理的控制理论技术和热rc建模

Proceedings Eighth International Symposium on High Performance Computer Architecture Pub Date : 2002-02-02 DOI:10.1109/HPCA.2002.995695

K. Skadron, T. Abdelzaher, M. Stan

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引用次数: 426

摘要

本文提出使用形式反馈控制理论作为在处理器体系结构中实现自适应技术的一种方法。动态热管理(DTM)被用作测试工具，并开发和测试了PID控制器(比例-积分-微分)的变化，以自适应控制抓取“切换”。为了准确地测试所提出的DTM机制，本文还建立了基于集总热阻和热容的热模型。该模型计算效率高，并以处理器内单个功能块的粒度跟踪温度。由于局部加热比整个芯片加热要快得多，处理器的某些部分比其他部分更有可能成为“热点”。使用watch和SPEC2000基准测试的实验表明，热触发阈值可以设置在最高温度的0.2/spl°/范围内，而不会进入热紧急状态。与之前描述的使用固定幅度响应的抓取切换技术相比，这将DTM的性能损失减少了65%。

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Control-theoretic techniques and thermal-RC modeling for accurate and localized dynamic thermal management

This paper proposes the use of formal feedback control theory as a way to implement adaptive techniques in the processor architecture. Dynamic thermal management (DTM) is used as a test vehicle, and variations of a PID controller (Proportional-Integral-Differential) are developed and tested for adaptive control of fetch "toggling." To accurately test the DTM mechanism being proposed, this paper also develops a thermal model based on lumped thermal resistances and thermal capacitances. This model is computationally efficient and tracks temperature at the granularity of individual functional blocks within the processor. Because localized heating occurs much faster than chip-wide heating, some parts of the processor are more likely, to be "hot spots" than others. Experiments using Wattch and the SPEC2000 benchmarks show that the thermal trigger threshold can be set within 0.2/spl deg/ of the maximum temperature and yet never enter thermal emergency. This cuts the performance loss of DTM by 65% compared to the previously described fetch toggling technique that uses a response of fixed magnitude.

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Proceedings Eighth International Symposium on High Performance Computer Architecture

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