An Extensive Literature Review on Reversible Logic Gates (original) (raw)
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A Review on Reversible Logic Gates and their Implementation
— Reversible logic is one of the most vital issue at present time and it has different areas for its application, those are low power CMOS, quantum computing, nanotechnology, cryptography, optical computing, DNA computing, digital signal processing (DSP), quantum dot cellular automata, communication, computer graphics. It is not possible to realize quantum computing without implementation of reversible logic. The main purposes of designing reversible logic are to decrease quantum cost, depth of the circuits and the number of garbage outputs. This paper provides the basic reversible logic gates, which in designing of more complex system having reversible circuits as a primitive component and which can execute more complicated operations using quantum computers. The reversible circuits form the basic building block of quantum computers as all quantum operations are reversible. This paper presents the data relating to the primitive reversible gates which are available in literature and helps researches in designing higher complex computing circuits using reversible gates.
An Extended Review on Reversible Logic Gates and their Implementation
In recent years, reversible logic circuits have applications in the emerging field of digital signal processing, computer graphics and cryptography. They are also a fundamental requirement in the field of quantum computation. We have investigated that the purposes of designing reversible logic are to decrease the number of reversible gates, garbage outputs, constant inputs, quantum cost, area, power, delay and hardware complexity of the reversible circuits. This paper provides some reversible logic gates, which can be used in designing more complex systems having reversible circuits and can execute more complicated operations using quantum computers. The reversible circuits form the basic building blocks of quantum computers as all quantum operations are inherently reversible. This paper presents the data relating to the reversible gates which helps in designing complex circuits.
Abstract— Reversible logic is one of the most vital issue at present time and it has different areas for its application, those are low power CMOS, quantum computing, nanotechnology, cryptography, optical computing, DNA computing, digital signal processing (DSP), quantum dot cellular automata, communication, computer graphics. It is not possible to realize quantum computing without implementation of reversible logic. The main purposes of designing reversible logic are to decrease quantum cost, depth of the circuits and the number of garbage outputs. This paper provides the basic reversible logic gates, which in designing of more complex system having reversible circuits as a primitive component and which can execute more complicated operations using quantum computers. The reversible circuits form the basic building block of quantum computers as all quantum operations are reversible. This paper presents the data relating to the primitive reversible gates which are available in literature and helps researches in designing higher complex computing circuits using reversible gates.
Reversible Gates: A Paradigm Shift in Computing
IEEE Open Journal of Circuits and Systems
The reversible gate has been one of the emerging research areas that ensure a continual process of innovation trends that explore and utilizes the resources. This review paper provides a comprehensive overview of reversible gates, including their fundamental principles, design methodologies, and various applications. It also analyzes the reversible gates, comparing them based on metrics such as Quantum Cost, Complexity, and other performance evaluation measures. The analysis of several reversible gates is presented in this paper and provides a comprehensive overview of reversible gates, encompassing their fundamental principles, design methodologies, and diverse applications. Reversible logic circuits allow for the production of both unique outputs and distinct input combinations. The majority of the findings about the reversible gates from previous research papers are discussed and contrasted. All the reversible gates that have been proposed till now are presented in tabular form and the parameters are discussed to help the researchers to find every detail related to the reversible gates. To highlight our understanding, we have ended most of the sections with questions. The inclusion of questions is likely intended to stimulate further discussion and promote a deeper understanding of the material presented in this paper. These questions can serve as prompts for readers to reflect on the content and potentially explore related research directions or areas of improvement. INDEX TERMS Reversible logic, quantum computing, mapping, energy loss, fault-tolerant gates, parity preserving gates.
Survey of Reversible Logic: A Review
A new study on reversible logic that ensures a continuous tendencies in the development of ideas discover and utilise resources. Researchers are looking on reversible logic to address the power dissipation issue. Design with low power is a desirable feature for a variety of applications, IoTs and quantum computing. The reversible gate offers a wide range of applications, including quantum computing, optical, low-power CMOS and so on. This paper gives a review of relative circuit study using various reversible gates. Each unique input combination, reversible logic circuits provide a unique output, and vice versa. This document includes a description of the work done as well as numerous factors. Reversible logic is used to increase speed, reduce energy consumption, lower quantum cost, and reduce the amount of trash outputs and circuit depth. And minimise the amount of trash outputs and circuit depth the logic is reversible.
Study of Reversible Logic Gates and their Designs
Reversible circuits that conserve information, has high-performance, release less amount of heat and it also improves the performance of the system; by uncomputing bits instead of deleting them, thus to improve the performance of the system this technique can be applied as physically possible way. Reversible logic design is also useful in improving energy efficiency. Since in new technology the main parameters to be focused on are speed power consumption and temperature; the Reversible logic can get a very important role in new technologies. Reversible computing also play vital role in portability of devices; it will let circuit element sizes to reduce to atomic size limits and hence devices will become more portable. Although the hardware design costs incurred in near future may be high but the power cost and performance being more dominant than logic hardware cost in today's computing era, the need of reversible computing cannot be ignored In day today's world, as the technology is developing so rapidly the designing of the systems are becoming more and more compact. In some systems even if the circuits are not compact; still there is a need of less power consumption.
Introduction to Reversible Logic Gates & its Application
In current scenario, the reversible logic design attracting more interest due to its low power consumption. Reversible logic is very important in low-power circuit design. The important reversible gates used for reversible logic synthesis are Feynman Gate, Fredkin gate, toffoli gate, New Gate sayem gate and peres gate etc. This paper present a basic reversible gate to build more complicated circuits which can be implemented in ALU, some sequential circuits as well as in some combinational circuits. It also gives brief idea to build adder circuits using the basic reversible gate like peres gate and TSG gate.
Introduction to Reversible Logic Gates and its Operations
International Journal for Research in Applied Science & Engineering Technology (IJRASET), 2022
Reversible logic is one of the most important issues at the moment and has a wide range of applications, such as low power CMOS, quantum computing, nanotechnol-ogy, cryptography, optical computing, DNA computing, and-digital signal processing (DSP), quantum Dot automata for mobile, communication, computer graphics. It is not possible to detect quantum computing without the implementation of a postponed brain operation. The main objectives of design are logical thinking to reduce quantum costs, circuit depths and the amount of waste disposal. This paper provides basic logical retrospective gates, which in the construction of a highly sophisticated system with retractable circuits as part of the old and unable to perform the most complex operations using quantum computers. Reversible circuits form the basic building block of quantum computers as all quantum functions are reversed. This paper presents data related to older retractable gates found in books and assists research in the design of complex computer circuits using retractable gates.
SURVEY: Reversible Logic Gates Implementation Using QCA
2019
In this paper we introduced a design and essential learning process basic in Quantum dot cellularautomata(QCA) and Reversible logic gates using QCA. QCA it is nanoscale computing technology that can represents binary information using spatial distribution of electrons.It has features like extremely small feature size, and high clock frequency make QCA an attractive solution for implementing nano-scale architectures. The power dissipation is the main limitation of all Nano electronics including QCA. The Reversible computing is considered as the reliable solution for power dissipation. The realization of quantum computation is not possible without reversible logic also, the Information’s are not loss in reversible circuits. Reversal gates are the main building blocks for reversible circuits.
A Review on Reversible Logic Gates and it's QCA Implementation
Quantum Dot Cellular Automata (QCA) is a rising innovation which seems to be a good competitor for the next generation of digital systems and widely utilized as a part of advanced frameworks. It is an appealing substitute to ordinary CMOS innovation because of diminutive size, faster speed, extremely scalable feature, ultralow power consumption and better switching frequency. The realization of quantum computation is not possible without reversible logic. Reversible logic has enlarged operations in quantum computation. Generally reversible computing is executed when system composes of reversible gates. It has numerous fields of use as applied science, quantum dot cellular automata as well as low power VLSI circuits, low power CMOS, digital signal processing, computer graphics. In this paper, the quantum implementation of primitive reversible gate has been presented. The proposed gates have been designed and simulated using QCADesigner.