使用体偏置岛的WID泄漏功率变异性的系统级缓解

S. Garg, Diana Marculescu
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引用次数: 8

摘要

自适应体偏置(ABB)是一种广泛使用的技术,用于减轻制造工艺变化对泄漏功耗的影响。ABB技术的效率可以通过将设计划分为许多“体偏置岛”来提高,每个岛都有其单独的体偏置电压。在本文中,我们提出了一个系统级泄漏可变性缓解框架,以在设计时将多处理器系统按处理元素(PE)粒度划分为体偏岛,并在制造后为每个岛最佳地分配体偏电压。与先前限制系统全局时钟频率的门级和电路级分区技术相反,我们允许每个岛以不同的速度运行,并仅约束相关的系统性能指标——在我们的示例中是执行截止日期。实验结果表明,与没有ABB的基线系统相比,所提出的框架在降低泄漏功耗的平均值和标准差方面的有效性。同时,与先前提出的基于蒙特卡罗的技术相比,所提出的技术在运行时间上有显著改善,同时也提供了类似的泄漏功耗降低。
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System-level mitigation of WID leakage power variability using body-bias islands
Adaptive Body Biasing (ABB) is a popularly used technique to mitigate the increasing impact of manufacturing process variations on leakage power dissipation. The efficacy of the ABB technique can be improved by partitioning a design into a number of "body-bias islands," each with its individual body-bias voltage. In this paper, we propose a system-level leakage variability mitigation framework to partition a multiprocessor system into body-bias islands at the processing element (PE) granularity at design time, and to optimally assign body-bias voltages to each island post-fabrication. As opposed to prior gate- and circuit-level partitioning techniques that constrain the global clock frequency of the system, we allow each island to run at a different speed and constrain only the relevant system performance metrics - in our case the execution deadlines. Experimental results show the efficacy of the proposed framework in reducing the mean and standard deviation of leakage power dissipation compared to a baseline system without ABB. At the same time, the proposed techniques provide significant runtime improvements over a previously proposed Monte-Carlo based technique while providing similar reductions in leakage power dissipation.
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