Simplification of master power expression and effective power detection of QCA device (Wave nature tunneling of electron in QCA device)

2016 IEEE Students’ Technology Symposium (TechSym) Pub Date : 2016-09-01 DOI:10.1109/TECHSYM.2016.7872695

S. Roy

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引用次数: 8

Abstract

Usages of QCA device, leads the technology, towards the avoiding of the traditional semiconductor devices in a wide scale. Where the area consumption and speed of the device can be extended beyond of the semiconductor technologies such as CMOS, by means of quantum tunneling devices. By the quantum nanoparticle tunneling, several logic gates and several digital logic circuits have ever been implemented by QCAD designer. This paper presents the power and the tunneling rate computation methodology of the QCA devices in wave nature of electrons, in terms of some mathematical expressions. The computed and simplified expressions provide a congenial way to detect the device power instantaneously at a precise position inside the tunneling junction. The most significant factors for tunneling are tunneling power, dissipated power and the total power of a QCA cell at tunneling time is computed do with Schrödinger wave equations. This paper summarizes on the QCA device power computational technique, by the help of Schrödinger wave equations. This paper presents a new computational methodology of QCA device power, to the modern Nanoelectronics science.

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QCA装置主功率表达式简化及有效功率检测(QCA装置中电子的波性隧穿)

QCA器件的使用，使该技术在很大程度上避免了传统半导体器件的使用。通过量子隧道器件，器件的面积消耗和速度可以超越CMOS等半导体技术。利用量子纳米粒子隧穿，QCAD设计人员已经实现了多个逻辑门和多个数字逻辑电路。本文用数学表达式给出了电子波性质下QCA器件的功率和隧穿速率的计算方法。计算和简化表达式为在隧道结内精确位置瞬时检测器件功率提供了一种合适的方法。通过Schrödinger波动方程，计算了QCA单元隧穿时的隧穿功率、耗散功率和总功率。本文借助Schrödinger波动方程对QCA器件功率的计算技术进行了综述。本文为现代纳米电子学提供了一种新的QCA器件功率计算方法。

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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来源期刊

2016 IEEE Students’ Technology Symposium (TechSym)

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