深亚微米P/G网络设计中红外降标度分析

Fourth International Symposium on Quality Electronic Design, 2003. Proceedings. Pub Date : 2003-03-24 DOI:10.1109/ISQED.2003.1194706

A. Ajami, K. Banerjee, A. Mehrotra, Massoud Pedram

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引用次数: 71

摘要

本文详细分析了需求侧管理技术中电源电压(IR)降标问题。本文首次考虑了温度、电迁移和互连技术尺度的影响(包括电子表面散射和有限势垒厚度导致的Cu互连电阻率增加)。研究表明，电源/地(P/G)网络中的ir下降效应随着技术规模的扩大而迅速增加，使用众所周知的对策，如目前设计中通常使用的线尺寸和去耦电容器插入资源分配方案，可能不足以限制未来技术中电网上的电压波动。还表明，时钟网络中开关设备电源线上的这种电压降会引入大量的倾斜，从而降低信号的完整性。

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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Analysis of IR-drop scaling with implications for deep submicron P/G network designs

This paper presents a detailed analysis of the power-supply voltage (IR) drop scaling in DSM technologies. For the first time, the effects of temperature, electromigration and interconnect technology scaling (including resistivity increase of Cu interconnects due to electron surface scattering and finite barrier thickness) are taken into consideration during this analysis. It is shown that the IR-drop effect in the power/ground (P/G) network increases rapidly with technology scaling, and using well-known counter measures such as wire-sizing and decoupling capacitor insertion with resource allocation schemes that are typically used in the present designs may not be sufficient to limit the voltage fluctuations over the power grid for future technologies. It is also shown that such voltage drops on power lines of switching devices in a clock network can introduce significant amount of skew which in turn degrades the signal integrity.

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Fourth International Symposium on Quality Electronic Design, 2003. Proceedings.

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