考虑丰富单元库的高电平面积和上电电流估计

ASP-DAC 2004: Asia and South Pacific Design Automation Conference 2004 (IEEE Cat. No.04EX753) Pub Date : 2004-01-27 DOI:10.5555/1015090.1015329

Fei Li, Lei He, J. Basile, Rakesh J. Patel, H. Ramamurthy

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引用次数: 3

摘要

降低日益增长的泄漏功率是节能设计的关键。诸如使用休眠晶体管插入的电源门控等减少泄漏的技术引入了大的上电电流，这可能会影响电路的可靠性以及引入性能损失。我们在一个具有丰富单元库的完整定制设计环境中对高级上电电流建模和估计进行了深入研究。我们提出了一种方法来估计电路面积的门数和最大上电电流为任何给定的逻辑功能。我们仅使用少量典型电路构建了基于逻辑综合和门电平分析的新型估计指标，但在我们的估计过程中不需要进一步的逻辑综合和门电平分析。与耗时的逻辑合成和门电平分析相比，一个领先的工业设计项目的电路面积平均误差为23.59%，最大上电电流平均误差为21.44%。相比之下，基于快速综合的估计导致Bbit加法器的栅极计数有llx的面积差。

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High-level area and power-up current estimation considering rich cell library

Reducing the ever-growing leakage power is critical to power efficient designs. Leakage reduction techniques such as power-gating using sleep transistor insertion introduces large power-up current that may affect circuit reliability as well as introduce performance loss. We present an in-depth study of high-level power-up current modeling and estimation in the context of a full custom design environment with a rich cell library. We propose a methodology to estimate the circuit area in terms of gate count and maximum power-up current for any given logic function. We build novel estimation metrics based on logic synthesis and gate level analysis using only a small number of typical circuits, but no further logic synthesis and gate level analysis are needed during our estimation. Compared to time-consuming logic synthesis and gate level analysis, the average errors for circuits from a leading industrial design project are 23.59% for area and 21.44% for maximum power-up current. In contrast, estimation based on quick synthesis leads to llx area difference in gate count for an Bbit adder.

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ASP-DAC 2004: Asia and South Pacific Design Automation Conference 2004 (IEEE Cat. No.04EX753)

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