Predictive dynamic thermal and power management for heterogeneous mobile platforms

2015 Design, Automation & Test in Europe Conference & Exhibition (DATE) Pub Date : 2015-03-09 DOI:10.7873/DATE.2015.1036

G. Singla, Gurinderjit Kaur, Ali K. Unver, Ümit Y. Ogras

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引用次数: 104

Abstract

Heterogeneous multiprocessor systems-on-chip (MPSoCs) powering mobile platforms integrate multiple asymmetric CPU cores, a GPU, and many specialized processors. When the MPSoC operates close to its peak performance, power dissipation easily increases the temperature, hence adversely impacts reliability. Since using a fan is not a viable solution for hand-held devices, there is a strong need for dynamic thermal and power management (DTPM) algorithms that can regulate temperature with minimal performance impact. This paper presents a DTPM algorithm based on a practical temperature prediction methodology using system identification. The DTPM algorithm dynamically computes a power budget using the predicted temperature, and controls the types and number of active processors as well as their frequencies. Experiments on an octa-core big. LITTLE processor and common Android apps demonstrate that the proposed technique predicts temperature within 3% accuracy, while the DTPM algorithm provides around 6× reduction in temperature variance, and as large as 16% reduction in total platform power compared to using a fan.

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异构移动平台的预测动态热与电源管理

支持移动平台的异构多处理器片上系统(mpsoc)集成了多个非对称CPU内核、一个GPU和许多专用处理器。当MPSoC工作在接近其峰值性能时，功耗容易升高温度，从而对可靠性产生不利影响。由于对于手持设备来说，使用风扇并不是一个可行的解决方案，因此非常需要动态热与电源管理(DTPM)算法，该算法可以在对性能影响最小的情况下调节温度。本文提出了一种基于系统识别的实际温度预测方法的DTPM算法。DTPM算法使用预测的温度动态计算功率预算，并控制活动处理器的类型和数量及其频率。在八核大型计算机上进行实验。LITTLE处理器和常见的Android应用程序表明，所提出的技术预测温度的准确度在3%以内，而DTPM算法与使用风扇相比，可以将温度差异降低约6倍，并将平台总功耗降低16%。

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 Design, Automation & Test in Europe Conference & Exhibition (DATE)

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