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基于新瓦片的电路在量子点细胞自动机(QCA)纳米技术中实现将二进制编码十进制(BCD)码转换为格雷码、余3码和艾肯码。

New tile-based circuits converting BCD code to gray, excess-3, and aiken codes in quantum-dot cellular automata (QCA) nanotechnology.

作者信息

Fouladinia Farhad, Gholami Mohammad, Karimi Pardis

机构信息

Department of Electrical Engineering, Faculty of Electrical Engineering, Kermanshah University of Technology, Kermanshah, Iran.

Department of Electrical Engineering, Faculty of Engineering and Technology, University of Mazandaran, Babolsar, Iran.

出版信息

Heliyon. 2024 Nov 15;10(22):e40446. doi: 10.1016/j.heliyon.2024.e40446. eCollection 2024 Nov 30.

DOI:10.1016/j.heliyon.2024.e40446
PMID:39624312
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11609658/
Abstract

The development of new methods and technologies for improving the stability and reducing the power consumption of electronic devices is a crucial area of research. Quantum-dot Cellular Automata (QCA) has emerged as a promising alternative to the traditional Complementary Metal-Oxide-Semiconductor (CMOS) technology, offering superior optimization in terms of physical size and energy efficiency. This paper introduces three novel digital code converters, designed using the tile-based approach to simplify circuit implementation and enhance integration through optimized majority and inverter gate structures. The proposed converters include: (1) a BCD to gray code converter with 127 cells, 0.18 μm occupied area, 3 clock phases, and zero NOT gate achieving a 7.3 % and 100 % reduction in the number of cells and NOT gates, respectively, compared to the most similar design; (2) a BCD to excess-3 code converter with 190 cells, 0.25 μm occupied area, 7 clock phases, and 3 NOT gates, showing a 0.5 %, 13.8 %, 41.7 %, and 25 % reduction in cells, area, used clock phases, and NOT gates, respectively, compared to the closest alternative; and (3) a BCD to aiken (2421) code converter with 287 cells, 0.22 μm occupied area, zero NOT gate, and 5 clock phases. The energy dissipation for these converters is measured at 55.3 meV, 53.7 meV, and 102 meV, respectively. Simulations are performed using QCADesigner-E version 2.2, validating the functionality and performance of the designs. These results demonstrate the potential of the proposed converters to offer efficient, compact, and low-power solutions for digital systems.

摘要

开发用于提高电子设备稳定性和降低功耗的新方法和技术是一个关键的研究领域。量子点细胞自动机(QCA)已成为传统互补金属氧化物半导体(CMOS)技术的一种有前途的替代方案,在物理尺寸和能源效率方面提供了卓越的优化。本文介绍了三种新颖的数字代码转换器,它们采用基于瓦片的方法进行设计,以简化电路实现,并通过优化的多数门和反相器门结构增强集成度。所提出的转换器包括:(1)一个具有127个单元、占用面积0.18μm、3个时钟相位且无反相器门的BCD到格雷码转换器,与最相似的设计相比,单元数量和反相器门数量分别减少了7.3%和100%;(2)一个具有190个单元、占用面积0.25μm、7个时钟相位且有3个反相器门的BCD到余3码转换器,与最接近的替代方案相比,单元、面积、使用的时钟相位和反相器门分别减少了0.5%、13.8%、41.7%和25%;(3)一个具有287个单元、占用面积0.22μm、无反相器门且有5个时钟相位的BCD到艾肯(2421)码转换器。这些转换器的能量耗散分别测量为55.3meV、53.7meV和102meV。使用QCADesigner-E版本2.2进行了仿真,验证了设计的功能和性能。这些结果证明了所提出的转换器为数字系统提供高效、紧凑和低功耗解决方案的潜力。

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