环境能量收集非易失性处理器的架构探索

2015 IEEE 21st International Symposium on High Performance Computer Architecture (HPCA) Pub Date : 2015-03-09 DOI:10.1109/HPCA.2015.7056060

Kaisheng Ma, Yang Zheng, Shuangchen Li, Karthik Swaminathan, Xueqing Li, Yongpan Liu, J. Sampson, Yuan Xie, N. Vijaykrishnan

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引用次数: 225

摘要

能量收集作为一种很有前途的超低功耗供电方法已经得到了广泛的研究。这些能源包括太阳能、射频(RF)辐射、压电、热梯度等。然而，这些电源提供的电力是高度不可靠的，并依赖于周围环境因素。因此，有必要开发能够容忍这种功率变化的专用系统，并且能够在计算任务上取得进展。本文中的仿真平台使用制造的非易失性处理器的测量结果进行校准，并用于探索具有不同架构，不同输入电源和最大化前进策略的非易失性处理器的设计空间。

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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Architecture exploration for ambient energy harvesting nonvolatile processors

Energy harvesting has been widely investigated as a promising method of providing power for ultra-low-power applications. Such energy sources include solar energy, radio-frequency (RF) radiation, piezoelectricity, thermal gradients, etc. However, the power supplied by these sources is highly unreliable and dependent upon ambient environment factors. Hence, it is necessary to develop specialized systems that are tolerant to this power variation, and also capable of making forward progress on the computation tasks. The simulation platform in this paper is calibrated using measured results from a fabricated nonvolatile processor and used to explore the design space for a nonvolatile processor with different architectures, different input power sources, and policies for maximizing forward progress.

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2015 IEEE 21st International Symposium on High Performance Computer Architecture (HPCA)

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