存在工艺变异的NBTI建模与分析

IEEE International Symposium on Quality Electronic Design Pub Date : 2011-03-14 DOI:10.1109/ISQED.2011.5770699

Taniya Siddiqua, S. Gurumurthi, M. Stan

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引用次数: 37

摘要

随着每一代技术中晶体管的不断缩小，NBTI和工艺变化(PV)已经成为微处理器工业中非常重要的硅可靠性问题。在本文中，我们开发了一个分析模型来捕捉在PV存在下NBTI的影响，用于建筑模拟。我们在模型中捕获了以下方面:i)与工作负荷有关的压力和恢复的NBTI变化，ii)由于随机电荷波动(RCF)引起的NBTI时间变化，iii)由于工艺变化引起的随机掺杂波动(RDF)。我们使用这个模型来分析NBTI和PV对存储结构(寄存器文件)和逻辑结构(Kogge-Stone加法器)的综合影响。我们表明，由于NBTI和PV的阈值电压变化对标称降解的影响会损害结构的产率。由于NBTI和PV在不同基准测试中的综合影响，在8Kb大小的寄存器文件中有26到117位失效，Kogge-Stone加法器的执行延迟增加了18%到28%。然后我们讨论这些结果对架构级可靠性技术的影响。

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Modeling and analyzing NBTI in the presence of Process Variation

With continuousscaling of transistors in each technology generation, NBTI and Process Variation (PV) have become very important silicon reliability problems for the microprocessor industry. In this paper, we develop an analytical model to capture the impact of NBTI in the presence of PV for use in architecture simulations. We capture the following aspects in the model: i) variation in NBTI related to stress and recovery due to workloads, ii) temporal variation in NBTI due to Random Charge Fluctuation (RCF) and iii) Random Dopant Fluctuation (RDF) due to process variation. We use this model to analyze the combined impact of NBTI and PV on a memory structure (register file) and a logic structure (Kogge-Stone adder). We show that the impact of the threshold voltage variations due to NBTI and PV over the nominal degradation can hurt the yield of the structures. Due to the combined effect of NBTI and PV across different benchmarks, 26 to 117 bits fail in a 8Kb size register file and the execution delay increases by 18% to 28% in a Kogge-Stone adder. We then discuss the implications of these results for architecture-level reliability techniques.

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IEEE International Symposium on Quality Electronic Design

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