一种全数字、高度可扩展的结构，用于测量数字电路中的空间变化

2008 IEEE Asian Solid-State Circuits Conference Pub Date : 2008-12-12 DOI:10.1109/ASSCC.2008.4708810

N. Drego, A. Chandrakasan, D. Boning

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引用次数: 7

摘要

由于缩放导致CMOS工艺的变化增加，因此在开发电路方法时更依赖于精确的变化模型来减轻变化。本文研究了在这种模型中使用的特定变化参数及其测量方法，导致了侵略性电压缩放系统中的关键考虑因素。我们描述了一种90nm CMOS测试芯片，其中包含能够提取准确变化数据的全数字测量电路。具体来说，我们使用了复制的64位Kogge-Stone加法器、可变门类型和级长的环振荡器(ROs)和一个全数字的亚皮秒分辨率延迟测量电路，为数字电路提供空间变化数据。来自测试芯片的测量数据表明，1)在低压域中相对变化显著较大，2)模内变化在空间上不相关，3)模间(或整体)变化具有强相关性，但随着电源电压的降低而退化为不相关。

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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An all-digital, highly scalable architecture for measurement of spatial variation in digital circuits

Increased variation in CMOS processes due to scaling results in greater reliance on accurate variation models in developing circuit methods to mitigate variation. This paper investigates specific variation parameters and their measurement approach for use in such models, leading to critical considerations in aggressive voltage scaling systems. We describe a test-chip in 90 nm CMOS containing all-digital measurement circuits capable of extracting accurate variation data. Specifically, we use replicated 64-bit Kogge-Stone adders, ring-oscillators (ROs) of varying gate type and stage length and an all-digital, sub-picosecond resolution delay measurement circuit to provide spatial variation data for digital circuits. Measurement data from the test-chips indicate that 1) relative variation is significantly larger in low-voltage domains, 2) within-die variation is spatially uncorrelated, and 3) die-to-die (or global) variation is strongly correlated, but degrades toward uncorrelated as the power-supply voltage is lowered.

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2008 IEEE Asian Solid-State Circuits Conference

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