基于全加法器设计的各种FINFET阈值逻辑性能分析

2019 3rd International Conference on Electronics, Materials Engineering & Nano-Technology (IEMENTech) Pub Date : 2019-08-01 DOI:10.1109/IEMENTech48150.2019.8981275

Mili Sarkar, Shagufta Talaat Nasir, I. Chakraborty, Sougata Maity, R. Chakraborty, G. S. Taki

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引用次数: 0

摘要

全加法器是所有计算系统的基本组成部分。这里介绍了各种全加法器电路，它们是使用基于FINFET的阈值逻辑门独特设计的。这些全加法器由基于Ganged/输出有线FINFET的逆变器，电容输出有线逻辑(COWL)和beta驱动阈值逻辑电路组成。设计的电路在几个重要参数上进行了比较，例如，时间延迟，单位电池消耗的功率和电池中使用的晶体管数量。本文使用LTSPICE对45纳米和32纳米技术进行了基于FINFET的模拟。在模拟中观察到一些有趣的性质。基于电容输出有线逻辑的全加法器单元在晶体管数、延迟、平均功率和功率延迟积方面表现出最佳性能。

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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Performance Analysis of Various FINFET Threshold Logic based Full Adder Design

Full adder is the basic building block of all computing systems. Various Full adder circuits have been presented here, which are uniquely designed using FINFET based Threshold Logic gates. These Full Adders consist of Ganged/ output wired FINFET based Inverter, Capacitive output wired logic (COWL) and Beta-driven threshold logic circuits. The designed circuits are compared on several important parameters e.g., time delay, power consumed by an unit cell and the number of transistor used in a cell. Here FINFET based simulations have been carried using LTSPICE for 45nm and 32nm technology. Some interesting properties have been observed in the simulations. Capacitive output wired logic based full adder cell shows the best performance with respect to transistor count, delay, average power and power delay product.

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2019 3rd International Conference on Electronics, Materials Engineering & Nano-Technology (IEMENTech)

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