Making sense of thermoelectrics for processor thermal management and energy harvesting

2015 IEEE/ACM International Symposium on Low Power Electronics and Design (ISLPED) Pub Date : 2015-07-22 DOI:10.1109/ISLPED.2015.7273486

S. Jayakumar, S. Reda

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引用次数: 15

Abstract

A thermoelectric (TE) device can be used as a heat pump that consumes electric power to cool a processor chip, or it can be used as a heat engine that generates electricity from the heat dissipated during processor operation. To better understand the use of TE devices, we develop a fully instrumented processor-based system with controllable TE devices. We first examine the use of TE devices for energy harvesting. We identify a pitfall in previous works that can lead to wrong conclusions for TEG use by demonstrating that TEGs increase the processor's leakage power which offsets their harvested power. For thermoelectric cooling (TEC), we elucidate the intricate relationships between the processor power, thermoelectric power, and fan power. We propose a dynamic thermal management scheme (DTM) that maximizes performance under thermal constraints and given total power budgets by controlling the processor's dynamic frequency and voltage scaling (DVFS), TEC current, and fan speed. For the evaluated thermal constraints, our results demonstrate good improvements to performance at the cost of additional cooling power compared to standard DVFS+fan DTM techniques.

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为处理器热管理和能量收集理解热电

热电(TE)装置可以用作消耗电力的热泵来冷却处理器芯片，也可以用作热机，利用处理器运行过程中散发的热量发电。为了更好地理解TE设备的使用，我们开发了一个完全仪表化的基于处理器的系统，其中包含可控的TE设备。我们首先检查TE设备用于能量收集的使用。我们在以前的工作中发现了一个陷阱，通过证明TEG会增加处理器的泄漏功率，从而抵消其收获的功率，从而导致对TEG使用的错误结论。对于热电冷却(TEC)，我们阐明了处理器功率、热电功率和风扇功率之间的复杂关系。我们提出了一种动态热管理方案(DTM)，通过控制处理器的动态频率和电压缩放(DVFS)、TEC电流和风扇速度，在热约束和给定的总功率预算下最大化性能。对于评估的热约束，我们的结果表明，与标准的DVFS+风扇DTM技术相比，在额外冷却功率的代价下，性能得到了良好的改善。

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 IEEE/ACM International Symposium on Low Power Electronics and Design (ISLPED)

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