温度感知统计静态定时分析

A. Rogachev, Lu Wan, Deming Chen
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引用次数: 12

摘要

随着技术的规模化,器件参数的可变性不断增加。这影响了模具的性能和温度分布,使它们成为统计分布。据我们所知,在对传播延迟进行统计分析时,还没有人考虑到统计热剖面的影响。我们提出了一个统计静态时序分析(SSTA)工具,它考虑了这种相互依赖性,并产生了准确的时序估计。与蒙特卡罗模拟相比,我们的平均值和标准差的平均误差分别为0.95%和3.5%。这是对假设确定性功率分布的SSTA的显著改进,其平均值和SD误差分别为3.7%和20.9%。然而,当考虑到>90%的性能良率时,与确定性功率情况相比,我们的算法的精度提高并不显着。因此,如果关注运行时间,可以通过假设标称功率来获得性能收益的合理估计。然而,为了达到最大的准确性,全面的统计分析是必要的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Temperature aware statistical static timing analysis
With technology scaling, the variability of device parameters continues to increase. This impacts both the performance and the temperature profile of the die turning them into a statistical distribution. To the best of our knowledge, no one has considered the impact of the statistical thermal profile during statistical analysis of the propagation delay. We present a statistical static timing analysis (SSTA) tool which considers this interdependence and produces accurate timing estimation. Our average errors for mean and standard deviation are 0.95% and 3.5% respectively when compared against Monte Carlo simulation. This is a significant improvement over SSTA that assumes a deterministic power profile, whose mean and SD errors are 3.7% and 20.9% respectively. However, when considering >90% performance yield, our algorithm's accuracy improvement was not as significant when compared to the deterministic power case. Thus, if one is concerned with the runtime, a reasonable estimate of the performance yield can be obtained by assuming nominal power. Nevertheless, a full statistical analysis is necessary to achieve maximum accuracy.
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