Statistical timing analysis of nonzero clock skew circuits

2008 51st Midwest Symposium on Circuits and Systems Pub Date : 2008-09-03 DOI:10.1109/MWSCAS.2008.4616872

S. Kurtas, B. Taskin

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Abstract

Statistical static timing analysis (SSTA) methods, which model process variations statistically as probability distribution functions (PDFs) rather than deterministically, have emerged to more accurately portray integrated circuit performance. This analysis has been thoroughly performed on traditional zero clock skew circuits where the synchronizing clock signal is assumed to arrive in phase with respect to each register. However, designers will often schedule the clock skew to different registers in order to decrease the minimum clock period of the entire circuit. Clock skew scheduling (CSS) imparts very different timing constraints that are based, in part, on the topology of the circuit. In this paper, SSTA is applied to nonzero clock skew circuits in order to determine the accuracy improvement relative to their zero skew counterparts, and also to assess how the results of skew scheduling might be impacted with more accurate statistical modeling. For 99.7% timing yield (3sigma variation), SST is observed to improve the accuracy of measurement, thereby increasing the average clock period improvement to 38.25% as compared to zero clock skew circuits.

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非零时钟偏差电路的统计时序分析

统计静态时序分析(SSTA)方法以概率分布函数(pdf)而不是确定性的方式对过程变化进行统计建模，以更准确地描述集成电路的性能。这种分析已经在传统的零时钟偏斜电路上进行了彻底的执行，其中同步时钟信号被假设相对于每个寄存器在相位上到达。然而，为了减少整个电路的最小时钟周期，设计人员通常会将时钟倾斜安排到不同的寄存器上。时钟偏差调度(CSS)赋予了非常不同的时序约束，这些约束部分基于电路的拓扑结构。本文将SSTA应用于非零时钟偏差电路，以确定相对于零偏差电路的精度改进，并评估更精确的统计建模对偏差调度结果的影响。对于99.7%的时序良率(3sigma变化)，观察到SST提高了测量精度，从而将平均时钟周期提高到38.25%，与零时钟偏差电路相比。

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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2008 51st Midwest Symposium on Circuits and Systems

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