32nm工艺下稳健双阈值CMOS全加法器电路的设计与分析

2010 International Conference on Advances in Recent Technologies in Communication and Computing Pub Date : 2010-10-16 DOI:10.1109/ARTCOM.2010.20

A. Islam, M. W. Akram, S. Pable, M. Hasan

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引用次数: 17

摘要

在低压低功耗应用中，功率和速度的优化是一个非常重要的问题。本文成功地分析了一个1位全加法器单元，方法是给一些晶体管分配高阈值电压，给另一些晶体管分配低阈值电压。此外，还提出了一种采用双阈值电压mosfet (DT-MOS)的鲁棒全加法器电路。该设计具有低功耗(0.11%)，高计算速度(4.23%)和低能量(功率延迟积)(4.33%)的特点。提出的设计还提供了4.2%的延迟可变性改进和3.7%的PDP可变性改进，其代价是过程、电压和温度(PVT)变化的功率可变性降低2.5%。在HSPICE电路模拟器上进行了大量的仿真，对其功率、速度和能量进行了评估。仿真结果基于32nm Berkeley Predictive Technology Model (BPTM)。

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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Design and Analysis of Robust Dual Threshold CMOS Full Adder Circuit in 32nm Technology

Optimization of power and speed is a very important issue in low-voltage and low-power applications. In this paper, a 1-bit full adder cell has been successfully analyzed by assigning high-threshold voltage to some transistors and low-threshold voltage to others. Moreover, a robust full adder circuit using dual threshold voltage MOSFETs (DT-MOS) has been proposed. The proposed design features lower power dissipation (by 0.11%), higher computing speed (by 4.23%) and lower energy (power delay product) (by 4.33%). The proposed design also offers 4.2% improvement in delay variability and 3.7% improvement in PDP variability at the expense of 2.5% reduction in power variability against process, voltage, and temperature (PVT) variation. The power, speed and energy evaluation has been carried out using extensive simulation on HSPICE circuit simulator. The simulation results are based on 32nm Berkeley Predictive Technology Model (BPTM).

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2010 International Conference on Advances in Recent Technologies in Communication and Computing

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