The alleviation of low power Schmitt trigger using FinFET technology

2015 International Conference on Communication Networks (ICCN) Pub Date : 2015-11-01 DOI:10.1109/ICCN.2015.62

Nilotpal Arjun, Aushi Marwah, S. Akashe

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引用次数: 1

Abstract

In this paper, we designed Schmitt trigger using CMOS low power design technique at 45nm technology. With the advancement of technology, different parameters have been calculated and analyzed to determine the performance of the circuit. With the change in technology, the aspect ratio of transistor sizing, variation in parameters also takes place. Different techniques are applied for the reduction in power consumption at the trade off with delay and area. In this paper we use novel FinFET technique to decrease the leakage power in the circuit. Schmitt trigger is a positive feedback amplifier that converts any continuous time varying signal to pulse wave. It forms the comparator of modern analog to digital convertor circuits, and it provides good noise immunity, thus it is used in communication. Parameters like slew rate, propagation delay, energy delay product etc of the circuit are calculated in both CMOS and FinFET technique and compared. Leakage power obtained using FinFET is 12.08PW which is very less to that of bulk CMOS. Designing is done with variable voltage supply and the performance of the circuit is observed at different points. The circuit is simulated in Cadence virtuoso tool version 6.1 output of all is compared.

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利用FinFET技术缓解低功率施密特触发器

本文采用45纳米工艺的CMOS低功耗设计技术设计了施密特触发器。随着技术的进步，计算和分析了不同的参数来确定电路的性能。随着技术的变化，晶体管尺寸的长宽比、参数也会发生变化。在权衡延迟和面积的同时，采用了不同的技术来降低功耗。本文采用新颖的FinFET技术来降低电路的漏功率。施密特触发器是一种正反馈放大器，可将任何连续时变信号转换为脉冲波。它构成了现代模数转换电路的比较器，具有良好的抗噪性，因此可用于通信。计算了该电路在CMOS和FinFET两种技术下的转换速率、传输延迟、能量延迟积等参数，并进行了比较。使用FinFET获得的泄漏功率为12.08PW，与本体CMOS相比非常小。采用变压电源进行了设计，并在不同的点上观察了电路的性能。在Cadence virtuoso工具6.1版中对电路进行了仿真，并对输出结果进行了比较。

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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2015 International Conference on Communication Networks (ICCN)

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