S
Samira Sayedsalehi
Researcher at Islamic Azad University
Publications - 25
Citations - 985
Samira Sayedsalehi is an academic researcher from Islamic Azad University. The author has contributed to research in topics: Quantum dot cellular automaton & Logic gate. The author has an hindex of 13, co-authored 25 publications receiving 819 citations. Previous affiliations of Samira Sayedsalehi include Shahid Beheshti University & Islamic Azad University South Tehran Branch.
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Journal ArticleDOI
Five-Input Majority Gate, a New Device for Quantum-Dot Cellular Automata
TL;DR: Simulation results demonstrate that the proposed design of majority gates and Full-Adder resulted in significant improvements in designing logical circuits.
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Designing efficient QCA logical circuits with power dissipation analysis
TL;DR: A comprehensive power dissipation analysis as well as a structural analysis over the previously published five-input majority gates is performed and reveals that the proposed designs have significant improvements in contrast to counterparts from implementation requirements and power consumption aspects.
Journal ArticleDOI
Design and evaluation of new majority gate-based RAM cell in quantum-dot cellular automata
TL;DR: A new robust five-input majority gate is first presented, which is appropriate for implementation of simple and efficient QCA circuits in single layer and has a simple and robust structure that helps achieving minimal area, as well as reduction in hardware requirements and clocking zone numbers.
Journal ArticleDOI
A symmetric quantum-dot cellular automata design for 5-input majority gate
TL;DR: A novel 5-input majority gate, an important fundamental building block in QCA circuits, is designed in a symmetric form and demonstrated to perform equally well or in many cases better than previous circuits.
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Efficient QCA Exclusive-or and Multiplexer Circuits Based on a Nanoelectronic-Compatible Designing Approach
TL;DR: This study presents a novel approach to designing efficient QCA-based circuits based on Boolean expressions achieved from reconfiguration of five-input and three-input majority gates, and simple and dense multiplexer and Exclusive-or structures are implemented.