在线热仿真:如何加快您的热控制器设计

2013 23rd International Workshop on Power and Timing Modeling, Optimization and Simulation (PATMOS) Pub Date : 2013-11-14 DOI:10.1109/PATMOS.2013.6662161

Francesco Beneventi, Andrea Bartolini, L. Benini

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引用次数: 3

摘要

动态热管理(DTM)是未来多核系统的关键技术。事实上，系统，作为服务器类和嵌入式芯片多处理器都是热约束的。DTM设计需要考虑硬件工作点、工作负载阶段、功耗、模具温度、硬件监控基础设施和控制策略之间的交互链。时间尺度差别很大，从微秒到小时都有。在合理的时间内模拟多核系统的DTM方案的性能是一个开放性问题。本文提出了一种基于英特尔单片云计算机的在线热仿真框架。在我们的框架中，核心的一个子集用于在线模拟基于实际工作负载使用和由模拟目标管理系统的其余核心选择的工作点的通用热平面图的演变。这使得动态热管理解决方案的设计空间探索能够以实际工作负载的执行速度进行。

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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On-line thermal emulation: How to speed-up your thermal controller design

Dynamic thermal management (DTM) is a key technology for future many-core systems. Indeed systems, as both server-class and embedded chip multiprocessors are thermally constrained. DTM design requires consideration for the chain of interactions between HW operating points, workload phases, power consumption, die temperature, HW monitor infrastructure, control policy. Hugely different time scales are involved, from microseconds to hours. Simulating performance of DTM solutions for a many-core system in a reasonable time is an open problem. In this paper we present an on-line thermal emulation framework based on the Intel Single-Chip-Cloud computer. In our framework a subset of the cores are used to on-line emulate the evolution of a generic thermal floorplan based on the real workload usage and operating point selected by the rest of the cores which emulate the target managed system. This enables design space exploration of dynamic thermal management solutions at the speed of real workload execution.

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2013 23rd International Workshop on Power and Timing Modeling, Optimization and Simulation (PATMOS)

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