Single-Electron Transistor Based Implementation of NOT, Feynman, and Toffoli Gates

2015 IEEE International Symposium on Multiple-Valued Logic Pub Date : 2015-05-18 DOI:10.1109/ISMVL.2015.12

Mozammel H. A. Khan

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引用次数: 13

Abstract

NOT, Feynman, and Toffoli gates are the practical building blocks of reversible circuit synthesis techniques. NOT and Feynman gates are primitive quantum gates. Toffoli gates are macro-level gates and realized using various primitive quantum gates. In reversible circuit design papers, logic level circuits are first realized using NOT, Feynman, and Toffoli gates and then the Toffoli gates are decomposed into primitive quantum gates. However, realizations of reversible circuits using electronic devices are not given adequate emphasis. In this paper, we propose preliminary ideas of implementations of NOT, Feynman, and Toffoli gates using single-electron transistor (SET), which is a nano-electronic quantum-tunneling device. NOT gate implementation requires one SET and one pull-up resistor. Feynman gate implementation requires two SETs and two pull-up resistors. Three-input Toffoli gate implementation requires three SETs and two pull-up resistors. The average static power consumptions of NOT, Feynman, and three-input Toffoli gate realizations are 0.091 nW, 0.497 nW, and 0.504 nW, respectively. The proposed implementations will open a facet of nano-electronic low-power realizations of reversible circuits.

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基于非、费曼和托佛利门的单电子晶体管实现

NOT, Feynman和Toffoli门是可逆电路合成技术的实用构建模块。非门和费曼门是原始量子门。Toffoli门是一种宏观级门，使用各种原始量子门来实现。在可逆电路设计论文中，首先使用非门、费曼门和托佛利门实现逻辑电平电路，然后将托佛利门分解为原始量子门。然而，利用电子器件实现可逆电路并没有得到足够的重视。在本文中，我们提出了使用单电子晶体管(SET)实现非、费曼和托佛利门的初步想法，这是一种纳米电子量子隧道器件。非门实现需要一个SET和一个上拉电阻。费曼栅极的实现需要两个set和两个上拉电阻。三输入Toffoli栅极的实现需要三个set和两个上拉电阻。NOT、Feynman和三输入Toffoli栅极实现的平均静态功耗分别为0.091 nW、0.497 nW和0.504 nW。提出的实现方案将为可逆电路的纳米电子低功耗实现开辟新的方向。

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 IEEE International Symposium on Multiple-Valued Logic

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