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引用次数: 3
摘要
高端微处理器的功耗增长非常迅速。高功耗也会导致芯片温度的快速升高。如果温度超过一定水平,芯片的工作就会变得缓慢或不可靠。因此,人们提出了各种动态热管理(DTM)方法。本文提出了一种面向应用的基于学习的多核系统动态热管理(LDTM)技术。通过应用程序的重复执行,我们了解芯片的热模式,并通过DTM控制未来的温度。当预测温度可能超过某个阈值时,我们通过降低相应芯的工作频率来降低温度。我们在配备数字热传感器(DTS)的英特尔双核系统上实现了基于学习的热管理。动态频率缩放(DFS)在Linux内核上实现了三个频率步骤。我们在Linux上使用Phoronix Test Suite基准测试进行了实验。使用我们的LDTM,峰值温度平均降低了7摄氏度,整体平均温度从72摄氏度降低到65摄氏度。
On-line learning based dynamic thermal management for multicore systems
Power consumption of a high-end microprocessor increases very rapidly. High power consumption will lead to rapid increase in chip temperature as well. If temperature reaches beyond a certain level, chip operation becomes either slow or unreliable. Therefore various approaches for dynamic thermal management (DTM) have been proposed. In this paper, we propose a new application-oriented learning-based dynamic thermal management (LDTM) technique for a multi-core system. From repetitive executions of an application, we learn the thermal patterns of the chip, and we control the future temperature through DTM. When the predicted temperature may rise above a threshold value, we reduce the temperature by decreasing the operation frequency of the corresponding core. We implement our learning-based thermal management on an Intel's dual core system which is equipped with digital thermal sensors (DTS). The dynamic frequency scaling (DFS) is implemented to have three frequency steps on a Linux kernel. We carried out experiments using Phoronix Test Suite benchmarks for Linux. The peak temperature has been reduced by on average 7degC using our LDTM, and the overall average temperature reduced from 72degC to 65degC.
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