Design of a 4-bit adder using reversible logic in quantum-dot cellular automata (QCA)

2014 IEEE International Conference on Semiconductor Electronics (ICSE2014) Pub Date : 2014-10-13 DOI:10.1109/SMELEC.2014.6920795

Darushini Kunalan, Chee Lee Cheong, C. F. Chau, Azrul bin Ghazali

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引用次数: 39

Abstract

Both quantum-dot cellular automata (QCA) and reversible logic are emerging technologies that are promising alternatives to overcoming the scaling and heat dissipation issues, respectively, in the current CMOS designs. Here, the fundamentals of QCA and reversible logic are studied; the feasibility of incorporating reversible logic in QCA designs is also demonstrated. Based on two existing designs, an improved version of the reversible gates, namely the Feynman Gate and the Toffoli Gate, were implemented in QCA technology using QCADesigner. The proposed design of the QCA-based Feynman Gate is faster by ½ cycle as compared to the existing design; while the proposed Toffoli Gate has the same latency as the existing design but it is readily to be cascaded into a more complex design. A 4-bit ripple carry adder in QCA is then designed using the proposed Feynman and Toffoli gates to realize a reversible QCA full adder. This 4-bit QCA adder with reversible logic consists of 2030 QCA cells, has a latency of 7 clock cycles and 8 garbage outputs.

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量子点元胞自动机(QCA)可逆逻辑4位加法器的设计

量子点元胞自动机(QCA)和可逆逻辑都是新兴技术，它们分别是克服当前CMOS设计中的缩放和散热问题的有希望的替代方案。本文研究了QCA和可逆逻辑的基本原理;并论证了在QCA设计中引入可逆逻辑的可行性。基于现有的两种设计，采用qcaddesigner在QCA技术中实现了一种改进版本的可逆门，即Feynman门和Toffoli门。与现有设计相比，基于qca的费曼门的设计速度快了½个周期;虽然所提出的Toffoli Gate具有与现有设计相同的延迟，但它很容易被级联到更复杂的设计中。然后利用所提出的费曼门和托佛利门设计了QCA中的4位纹波进位加法器，实现了可逆的QCA全加法器。该4位QCA加法器具有可逆逻辑，由2030个QCA单元组成，具有7个时钟周期的延迟和8个垃圾输出。

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

2014 IEEE International Conference on Semiconductor Electronics (ICSE2014)

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