Integrated Thermal Analysis for Processing In Die-Stacking Memory

Proceedings of the Second International Symposium on Memory Systems Pub Date : 2016-10-03 DOI:10.1145/2989081.2989093

Yuxiong Zhu, Borui Wang, Dong Li, Jishen Zhao

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引用次数: 25

Abstract

Recent application and technology trends bring a renaissance of the processing-in-memory (PIM), which was envisioned decades ago. In particular, die-stacking and silicon interposer technologies enable the integration of memory, PIMs, and the host CPU in a single chip. Yet the integration substantially increases system power density. This can impose substantial thermal challenges to the feasibility of such systems. In this paper, we comprehensively study the thermal feasibility of integrated systems consisting of the host CPU, die-stacking DRAMs, and various types of PIMs. Compared with most previous thermal studies that only focus on the memory stack, we investigate the thermal distribution of the whole processor-memory system. Furthermore, we examine the feasibility of various cooling solutions and feasible scale of various PIM designs under given thermal and area constraints. Finally, we demonstrate system run-time thermal feasibility by executing two high-performance computing applications with PIM-based systems. Based on our experimental studies, we reveal a set of thermal implications for PIM-based system design and configuration.

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叠模存储器加工的集成热分析

最近的应用和技术趋势带来了内存中处理(PIM)的复兴，这是几十年前设想的。特别是，芯片堆叠和硅中间层技术可以将存储器、pim和主机CPU集成到单个芯片中。然而，集成大大提高了系统的功率密度。这对此类系统的可行性提出了实质性的热挑战。在本文中，我们全面研究了由主机CPU、模堆叠dram和各种类型的pim组成的集成系统的热可行性。与以往大多数仅关注存储堆栈的热研究相比，我们研究了整个处理器-存储系统的热分布。此外，我们研究了在给定的热和面积限制下各种冷却解决方案的可行性和各种PIM设计的可行规模。最后，我们通过使用基于pim的系统执行两个高性能计算应用程序来演示系统运行时热可行性。基于我们的实验研究，我们揭示了一组基于pim的系统设计和配置的热影响。

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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Proceedings of the Second International Symposium on Memory Systems

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