The Energy Efficiency Of Iram Architectures

Conference Proceedings. The 24th Annual International Symposium on Computer Architecture Pub Date : 1997-06-01 DOI:10.1145/264107.264214

R. Fromm, S. Perissakis, N. Cardwell, C. Kozyrakis, B. McGaughy, D. Patterson, Thomas E. Anderson, K. Yelick

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引用次数: 128

Abstract

Portable systems demand energy efficiency in order to maximize battery life. IRAM architectures, which combine DRAM and a processor on the same chip in a DRAM process, are more energy efficient than conventional systems. The high density of DRAM permits a much larger amount of memory on-chip than a traditional SRAM cache design in a logic process. This allows most or all IRAM memory accesses to be satisfied on-chip. Thus there is much less need to drive high-capacitance off-chip buses, which contribute significantly to the energy consumption of a system. To quantify this advantage we apply models of energy consumption in DRAM and SRAM memories to results from cache simulations of applications reflective of personal productivity tasks on low power systems. We find that IRAM memory hierarchies consume as little as 22% of the energy consumed by a conventional memory hierarchy for memory-intensive applications, while delivering comparable performance. Furthermore, the energy consumed by a system consisting of an IRAM memory hierarchy combined with an energy efficient CPU core is as little as 40% of that of the same CPU core with a traditional memory hierarchy.

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伊朗建筑的能源效率

便携式系统需要能源效率，以最大限度地延长电池寿命。IRAM架构将DRAM和处理器结合在同一芯片上的DRAM进程中，比传统系统更节能。在逻辑过程中，DRAM的高密度允许比传统的SRAM缓存设计更大的片上内存。这允许大部分或所有的IRAM存储器访问在片上得到满足。因此，驱动高电容片外总线的需求要少得多，这对系统的能耗有很大的贡献。为了量化这一优势，我们将DRAM和SRAM存储器的能耗模型应用于反映低功耗系统上个人生产力任务的应用的缓存模拟结果。我们发现，对于内存密集型应用程序，IRAM内存层次结构消耗的能量仅为传统内存层次结构消耗的能量的22%，同时提供相当的性能。此外，由IRAM存储器层次结构和节能CPU核心组成的系统所消耗的能量仅为具有传统存储器层次结构的相同CPU核心的40%。

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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Conference Proceedings. The 24th Annual International Symposium on Computer Architecture

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