Parity Generators for Nanocommunication Systems Using QCA Nanotechnology

Q3 Computer Science Periodica polytechnica Electrical engineering and computer science Pub Date : 2023-03-02 DOI:10.3311/ppee.20602

V.K. Sharma

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引用次数: 1

Abstract

Quantum-dot cellular automata (QCA) nanotechnology has the capability to design highly-dense, ultra-low power, and high-speed digital circuits at ultra-deep sub-micron (ultra-DSM) level. QCA nanostructure provides a transistor-free operation that saves large energy dissipation as compared to the conventional metal oxide semiconductor field effect transistor (MOSFET) technology. In this paper, 3-input exclusive-OR (XOR) and exclusive-NOR (XNOR) gates are presented using QCA cells. XOR and XNOR (XOR-XNOR) gates are further utilized to design the 2-, 3-, 4-, and 5-bit even and odd parity generators. The QCA-based 3-input XNOR gate is constructed using only 10 QCA cells and two clock phases. The target of the presented designs is to use the minimum count of QCA cells in a simplistic way to form the higher bit-size parity generators. The comparative analyses for the different performance metrics are showing that the developed designs are performing well for the cell count, latency, area, and layout cost as compared to the existing designs. Energy dissipation for the designs is calculated to check the energy efficiency by using the QCA Designer-E and QCA Pro tools.

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使用QCA纳米技术的纳米通信系统奇偶校验发生器

量子点元胞自动机(QCA)纳米技术能够在超深亚微米(ultra-DSM)水平上设计高密度、超低功耗和高速的数字电路。与传统的金属氧化物半导体场效应晶体管(MOSFET)技术相比，QCA纳米结构提供了一个无晶体管的操作，节省了大量的能量消耗。本文采用QCA单元设计了三输入异或门(XOR)和异或门(XNOR)。XOR和XNOR (XOR-XNOR)门进一步用于设计2位、3位、4位和5位奇偶校验发生器。基于QCA的3输入XNOR门仅使用10个QCA单元和两个时钟相构建。所提出的设计的目标是以一种简单的方式使用最小数量的QCA单元来形成更高位大小的奇偶校验生成器。对不同性能指标的比较分析表明，与现有设计相比，开发的设计在单元数、延迟、面积和布局成本方面表现良好。通过使用QCA Designer-E和QCA Pro工具计算设计的能量耗散以检查能源效率。

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

Periodica polytechnica Electrical engineering and computer science Engineering-Electrical and Electronic Engineering

CiteScore

2.60

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0.00%

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期刊介绍： The main scope of the journal is to publish original research articles in the wide field of electrical engineering and informatics fitting into one of the following five Sections of the Journal: (i) Communication systems, networks and technology, (ii) Computer science and information theory, (iii) Control, signal processing and signal analysis, medical applications, (iv) Components, Microelectronics and Material Sciences, (v) Power engineering and mechatronics, (vi) Mobile Software, Internet of Things and Wearable Devices, (vii) Solid-state lighting and (viii) Vehicular Technology (land, airborne, and maritime mobile services; automotive, radar systems; antennas and radio wave propagation).

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