用于纳米技术应用的低成本QCA XOR-XNOR拓扑

2021 International Conference on Computing, Communication, and Intelligent Systems (ICCCIS) Pub Date : 2021-02-19 DOI:10.1109/ICCCIS51004.2021.9397215

D. Tripathi, Subodh Wairya

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引用次数: 1

摘要

量子点元胞自动机(Quantum-dot cellular automata, QCA)是一种创新的纳米级计算方法，它具有更小的维度，更低的功耗，更快的速度，并预先考虑作为CMOS方法缩放障碍的放大。目前使用的最新和正在兴起的纳米技术之一是基于库仑斥力的QCA。目前使用的最新和正在兴起的纳米技术之一是基于库仑斥力的QCA。推测计算是纳米级节能硬件设计的成功范例。在本文中，我们提出了一种精通的，低复杂度的2位和3位QCA异或门。此外，建议的QCA异或门被用来设计异或/异或门和成本高效的4:2编码器和4:1编码器使用QCA设计器工具。所提出的QCA异或门包含的量子单元数量非常少，以及与之前最佳的现有QCA布局相关的区域。仿真结果表明，所建议的架构在量子单元数、面积、延迟和量子成本方面优于现有的最佳对应布局。

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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A Cost-Efficient QCA XOR-XNOR Topology for Nanotechnology Applications

Quantum-dot cellular automata (QCA) is an inventive nano level computation that suggests less dimension, less power consumption, with more speed and premeditated as an amplification to the scaling obstacle with CMOS methodology. One of the newest and rising nanotechnologies used today is QCA based on the repulsion of Coulomb. One of the newest and rising nanotechnologies used today is QCA based on the repulsion of Coulomb. Surmised computing is a successful paradigm for energy efficient hardware design in nano-scale. In this article, we proposed a proficient, low complex 2-bit and 3-bit QCA XOR gate has been suggested. Further the suggested QCA XOR gates are utilized to design XOR/XNOR gates and cost efficient 4:2 Encoder and 4:1 Encoder using QCA Designer tool. The proposed QCA XOR gate contains very less number of quantum cells as well as areas as related to its best previous existing QCA layouts. The simulation outcomes illustrate that the suggested architecture outperforms in comparison to best existing counterpart layouts in terms of quantum cell count, area, latency and quantum cost.

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来源期刊

2021 International Conference on Computing, Communication, and Intelligent Systems (ICCCIS)

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