Optimized Reversible Logic Multiplexer Designs for Energy-Efficient Nanoscale Computing

Q3 Mathematics Indonesian Journal of Electrical Engineering and Informatics Pub Date : 2023-08-15 DOI:10.52549/ijeei.v11i3.4367

C.Vijesh Joe, Haewon Byeon, Anand Kumar Singh, C. Ramesh Kumar, Aaquil Bunglowala, Anu Tonk

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Abstract

Nano- and quantum-based low-power applications are where reversible logic really shines. By using digitally equivalent circuits with reversible logic gates, energy savings may be achieved. Reducing garbage output and ancilla inputs is a primary emphasis of this study, which aims to lower power consumption in reversible multiplexers. Multiplexers with switchable 2:1, 4:1, and 8:1 ratios may be built using the SJ gate and other simple reversible logic gates. The number of ancilla inputs has been cut in half from four to zero, and the amount of garbage output has been cut in half as well, from eight to three, making the 2:1 multiplexer an improvement over the prior design. New 4:1 multiplexer has 10' ancilla inputs, up from 2' in the previous designs. The proposed 4:1 multiplexer also cuts waste production in half from the current 5-to-6 bins per day. The 8:1 multiplexer has two ancilla inputs and nine trash outputs, while the current architecture only has one of each. The functionality of the VHDL and Xilinx 14.7-coded designs is validated by ISIM simulations.

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节能纳米计算的优化可逆逻辑多路复用器设计

基于纳米和量子的低功耗应用是可逆逻辑真正闪耀的地方。通过使用带有可逆逻辑门的数字等效电路，可以实现节能。减少垃圾输出和辅助输入是本研究的主要重点，旨在降低可逆多路复用器的功耗。可切换2:1,4:1和8:1比率的多路复用器可以使用SJ门和其他简单的可逆逻辑门来构建。辅助输入的数量减少了一半，从4个减少到0个，垃圾输出的数量也减少了一半，从8个减少到3个，使得2:1多路复用器比以前的设计有了改进。新的4:1多路复用器具有10'辅助输入，高于之前设计的2'。拟议的4:1多路复用器还将垃圾产生量从目前的每天5到6箱减少一半。8:1多路复用器有两个辅助输入和九个垃圾输出，而当前的体系结构只有一个。通过ISIM仿真验证了VHDL和Xilinx 14.7编码设计的功能。

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来源期刊

Indonesian Journal of Electrical Engineering and Informatics Computer Science-Computer Science (miscellaneous)

CiteScore

1.50

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0.00%

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期刊介绍： The journal publishes original papers in the field of electrical, computer and informatics engineering which covers, but not limited to, the following scope: Electronics: Electronic Materials, Microelectronic System, Design and Implementation of Application Specific Integrated Circuits (ASIC), VLSI Design, System-on-a-Chip (SoC) and Electronic Instrumentation Using CAD Tools, digital signal & data Processing, , Biomedical Transducers and instrumentation. Electrical: Electrical Engineering Materials, Electric Power Generation, Transmission and Distribution, Power Electronics, Power Quality, Power Economic, FACTS, Renewable Energy, Electric Traction. Telecommunication: Modulation and Signal Processing for Telecommunication, Information Theory and Coding, Antenna and Wave Propagation, Wireless and Mobile Communications, Radio Communication, Communication Electronics and Microwave, Radar Imaging. Control: Optimal, Robust and Adaptive Controls, Non Linear and Stochastic Controls, Modeling and Identification, Robotics, Image Based Control, Hybrid and Switching Control, Process Optimization and Scheduling, Control and Intelligent Systems. Computer and Informatics: Computer Architecture, Parallel and Distributed Computer, Pervasive Computing, Computer Network, Embedded System, Human—Computer Interaction, Virtual/Augmented Reality, Computer Security, Software Engineering (Software: Lifecycle, Management, Engineering Process, Engineering Tools and Methods), Programming (Programming Methodology and Paradigm), Data Engineering (Data and Knowledge level Modeling, Information Management (DB) practices, Knowledge Based Management System, Knowledge Discovery in Data).