Design of efficient quantum Dot cellular automata (QCA) multiply accumulate (MAC) unit with power dissipation analysis

Gassoumi, Ismail; Touil, Lamjed; Ouni, Bouraoui

doi:10.1049/iet-cds.2018.5196

Cited by 18 publications

(6 citation statements)

References 48 publications

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“…The QCA circuit of 4-bit incrementer requires 245 cells, 0.4536 μm² total area, 0.07938 μm² cell area, 16 Comparison is done on XOR gate with previous designs and explored in Table 5.It is observed from Table 5 that the proposed XOR gate has higher design complexity than other existing designs. But, in the proposed work, we have tried to show the design of the n-bit Ripple Carry Incrementer and Ripple Carry Decrementer circuit.…”

Section: Design Complexitymentioning

confidence: 99%

QCA Based Design of Novel Low Power n-bit Ripple Carry Incrementer and Ripple Carry Decrementer

Debnath

Das

2022

Preprint

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This paper shows the design of the newly made ‘n’ bit incrementer and decrementer circuit using quantum-dot cellular automata (QCA). Ripple carry incrementer and decrementer are crucial for performing two numbers’ increment or decrement operation. This paper outlines the design of a novel low power ripple carry incrementer and ripple carry decrementer circuit based on QCA. The proposed ripple carry incrementer and ripple carry decrementer circuit are achieved with a new layout of the XOR gate, AND gate, and half adder circuit. This newly designed XOR and half adderare compared with state-of-the-artdesigns.QCA Designer 2.0.3 is used to design the circuits. The simulation results of 4-bit, 8-bit, and 16-bit incrementer and decrementer circuits are by the theoretical results.

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Section: Design Complexitymentioning

confidence: 99%

QCA Based Design of Novel Low Power n-bit Ripple Carry Incrementer and Ripple Carry Decrementer

Debnath

Das

2022

Preprint

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“…The layout shown in figure 7 is used for the fault analysis. The cell missing defect is possible for the cells 7, 8, 9, 10, 12, 13, and 16, while the cells 1, 2, 3,4,5,6,11,14,15,17,18,19, and 20 causes cell addition defects. It is assumed that input and output cells are unchanged due to any type of fault defect.…”

Section: Proposed Designsmentioning

confidence: 99%

“…The least value of QCA layout cost is desirable. Layout cost is derived as provided in equation (14).…”

Section: = ( ) Area Utilization Total Cell Area Total Covered Area 13mentioning

confidence: 99%

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Single layer adder/subtractor using QCA nanotechnology for nanocomputing operations

Sharma

2022

Eng. Res. Express

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Quantum-dot cellular automata (QCA) nanotechnology is a suitable replacement for the widely accepted complementary metal oxide semiconductor (CMOS) technology. CMOS technology faces the issues of high-leakage current and non-scalability in the ultra-deep submicron (ultra-DSM) regime. It motivates the researchers to explore new technologies for further advancement of the field. QCA nanotechnology is energy-efficient technology and it overcomes the issues of CMOS technology in ultra-DSM regime. In this paper, a novel 3-input XOR structure is presented using QCA nanotechnology. The full adder and the full subtractor circuits based on the 3-input XOR gate are developed. A circuit for the full adder/subtractor nanostructure is proposed in the paper. All the proposed designs are optimal, fault-tolerant and single-layered. The proposed full adder contains only 21 QCA cells, while 22 QCA cells are required for the proposed full subtractor. The proposed full adder/subtractor structure consists of only 30 QCA cells. The proposed designs are compared with the existing designs for the number of QCA cells, total cell area, total covered area, area utilization, clock latency, QCA layout cost, and crossover requirement. The energy-efficient behaviour of the proposed circuits is calculated using the QCA Designer-E and the QCA Pro tools.

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“…e QCA clocking system consists of four phases, as illustrated in Figure 4. e phases are switch, hold, release, and relax [14]. e barriers are raised during the switch phase, and a cell is influenced by the polarization of its adjacent cells.…”

Section: Preface To Quantum Dot Cellular Automatamentioning

confidence: 99%

Design and Implementation of Nanotechnology QCA Geometric Greedy Router

Touil

Gassoumi

Mtibaa

2021

Journal of Electrical and Computer Engineering

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This paper presents an optimized geometric greedy router (GGR) based on quantum dot cellular automata (QCA) technology. The proposed structure of GGR is based on a spanning tree of the network. This type of communication does not require an IP address. It uses only local information and can be used in many communication devices. In this paper, we first describe the principal components of the router and then we present their QCA architecture. The QCA technology is the most likely alternative to replace conventional circuits (CMOS) due to their very low power consumption and high processing speed. To consider integration with other complex circuit, we have utilized QCA clock-phase-based technique for the proposed design architecture. The results obtained using the QCA designer tool exhibit the superiority of the presented architecture over the existing designs. The proposed structure shows a reduction of 30% reduction in occupied space. The power dissipation rate of the proposed design is analyzed by QCAPro tool to approve its reliability.

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Design of efficient quantum Dot cellular automata (QCA) multiply accumulate (MAC) unit with power dissipation analysis

Cited by 18 publications

References 48 publications

QCA Based Design of Novel Low Power n-bit Ripple Carry Incrementer and Ripple Carry Decrementer

QCA Based Design of Novel Low Power n-bit Ripple Carry Incrementer and Ripple Carry Decrementer

Single layer adder/subtractor using QCA nanotechnology for nanocomputing operations

Design and Implementation of Nanotechnology QCA Geometric Greedy Router

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