Nanosensor Data Processor in Quantum-Dot Cellular Automata

Yao, Fenghui; Zein-Sabatto, M. Saleh; Shao, Guifeng; Bodruzzaman, M.; Malkani, Mohan

doi:10.1155/2014/259869

Cited by 20 publications

(9 citation statements)

References 27 publications

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“…In the past few years, works are done in the field of nano communication, image processing, and data security, utilizing QCA. The works explored in [27][28][29][30][31] are related to the field of nano-communication. In [27] a nano-sensor processor has been produced.…”

Section: Related Workmentioning

confidence: 99%

Reversible Palm Vein Authenticator Design With Quantum Dot Cellular Automata for Information Security in Nanocommunication Network

Debnath

Das

et al. 2020

IEEE Access

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Palm vein pattern recognition is one of the most promising and rapidly developing fields of study in biometrics, which makes it an important solution for identity security in biometrics-based user identification systems. Quantum-dot Cellular Automata is one of the developing fields of nanotechnology which facilitates the creation of nano-scale logical circuits. Irreversible technology has faced some difficulties, such as higher heat energy dissipation. Reversible logic is therefore essential where heat dissipation is almost insignificant. This article proposes QCA design of a reversible circuit for palm vein authentication utilizing the Feynman gate. To produce reversible Feynman gate is designed and used to design the palm vein authenticator circuit. The theoretical values and the results of the simulation correspond to the credibility of the planned circuit. Circuit complexity and the circuit cost, of the circuit, are also estimated. Validation of authenticated users by the proposed authenticator shows its design accuracy as per theoretical values. Energy dissipation is calculated to prove that the proposed design dissipates energy within Lauderer"s limit. Comparison with recent QCA state of the art architectures explores its characteristics.

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Section: Related Workmentioning

confidence: 99%

Reversible Palm Vein Authenticator Design With Quantum Dot Cellular Automata for Information Security in Nanocommunication Network

Debnath

Das

et al. 2020

IEEE Access

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“…In Table 8, a reasonable analysis has been formulated and outlined study with 2-dot 1-electron has been assessed with the present effort using 4-dot 2-electron QCA [12,[25][26][27][28][29][30][31][32][33][34][35][36][37][38][39][40][41][42] considering the figures of cell, extent coverage and energy utilized. From [8], we acquire x = 13 nm and y = 5 nm.…”

Section: Energy and Power Utilization For The Proposed Designmentioning

confidence: 99%

Designing majority gate-based nanoscale two-dimensional two-dot one-electron parity generator and checker for nano-communication

Abdullah-Al-Shafi

Bahar

2019

Int Nano Lett

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At the present time, logic circuits design prototypes with quantum-dot cellular automata (QCA) have been comprehensively researched. The confines of orthodox CMOS technology induce to the breakthroughs of different technologies, one of which is QCA. Thoughtlessly, because of the deficiency of advance assembly support, QCA circuits frequently agonize from several sorts of manufacture shortcomings and variations and, hence, are error prone and defective. QCA technology is forming its aspect due to extreme effectiveness and rapidity with lesser area requirement. This study, a novel architecture of parity generator and checker, is proposed based on two-dot one-electron cells. Parity generator and checker assist in impeccable binary information communication from point to point. With the outlined parity generator and checker circuit, a nano-communication architecture is designed. The designed architecture is rationalized with a competently established standard mathematical operation based on Coulomb's theory. All the outlined design contains a minimum number of cells, extent, and energy compared to existing four-dot two-electron QCA designs. The outlined designs comprehend minimum majority gate and latency. Besides, power depletion by the designs is measured and it is perceived that the total energy and power required to operate these designs are incredibly low.

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“…As a result, the two stable polarization states for a QCA cell are achieved, as shown in Figure 1. The instantaneous polarization of a cell is denoted as either -1 or +1 [2], which are encoded to represent a binary "1" value and In order to create any digital including wire, NOT gate, AND gate, OR gate and majority gate are required to Since no electrons tunnel between cells, QCA provides a mechanism for transferring information without current flow [6]. , five QCA cells that realize in equation 1, and its QCA design is ܾܿ ܽܿ ሺ1ሻ…”

Section: Qca Design Xor Logic Gate Usingmentioning

confidence: 99%

“…In order to create any digital logic, basic elements including wire, gate, OR gate and majority g implement that logic [1,3]. Since no electrons tunnel between cells, QCA provides a mechanism for transferring information without current flow [6].…”

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confidence: 99%

Performance Improvement of QCA Design XOR Logic Gate using Bistable Simulation Engine Vector

Hajari¹,

Satle²

2018

IJTSRD

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Among the emerging technologies recently proposed as alternatives to the CMOS technology, the quantum dot cellular automata is one of the promising solutions to design very high speed and ultralow power digital circuits. In this paper we used QCA simulator tool for simulation of the proposed XOR design. The QCA Designer tools used to simulate the circuits and calculate the area as well as number of cells.

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Nanosensor Data Processor in Quantum-Dot Cellular Automata

Cited by 20 publications

References 27 publications

Reversible Palm Vein Authenticator Design With Quantum Dot Cellular Automata for Information Security in Nanocommunication Network

Reversible Palm Vein Authenticator Design With Quantum Dot Cellular Automata for Information Security in Nanocommunication Network

Designing majority gate-based nanoscale two-dimensional two-dot one-electron parity generator and checker for nano-communication

Performance Improvement of QCA Design XOR Logic Gate using Bistable Simulation Engine Vector

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