This paper introduces an architecture for quantumdot cellular automata (QCA) systems with the potential for high throughput and low power dissipation. The combination of regions with Bennett clocking and of regions used for memory storage combines the low power advantages of reversible computing and the high throughput advantages of pipelining. A simple case study is employed to evaluate the pr...

In this paper we introduce and characterize a novel circuit design for low power clock distribution for quantumdot cellular automata (QCA) systems. The characterization of the clocking circuitry includes an evaluation of: the coupling capacitances among the wires and with the ground plane; the dissipative effects of the wires and the substrate; the phase shift between neighboring wires; and the...

This article describes the design of ultra-low-power multipliers on quantumdot cellular automata (QCA) nanotechnology, promising very dense circuits and high operating frequencies, using a single homogeneous layer of the basic cells. We construct structures without the earlier noise problems, verified by the QCADesigner coherence vector simulation. Our results show that the wiring overhead of t...

recently testing of quantum-dot cellular automata (qca) circuits has attracted a lot of attention. in this paper, qca is investigated for testable implementations of reversible logic. to amplify testability in reversible qca circuits, a test method regarding to built in self test technique is developed for detecting all simulated defects. a new reversible qca mux 2×1 design is proposed for the ...

quantum-dot cellular automata (qca) has low power consumption and high density and regularity. qca widely supports the new devices designed for nanotechnology. application of qca technology as an alternative method for cmos technology on nano-scale shows a promising future. this paper presents successful designing, layout and analysis of multiplexer with a new structure in qca technique. in thi...

quantum-dot cellular automata (qca) are a promising nanotechnology to implement digital circuits at the nanoscale. devices based on qca have the advantages of faster speed, lower power consumption, and greatly reduced sizes. in this paper, we are presented the circuits, which generate random numbers in qca. random numbers have many uses in science, art, statistics, cryptography, gaming, gamblin...

Quantum-dot Cellular Automata (QCA) is a promising, emerging nanotechnology based on single electron effects in quantum dots and molecules. While many logic implementations based on QCA devices have been proposed in literature [6, 7, 8], the inherent cellular structure of QCA cells make it a natural candidate for Cellular Automata (CA) implementation. CA offers regularity and modularity to the ...

Quantum-dot cellular automata (QCA) are a promising nanotechnology to implement digital circuits at the nanoscale. Devices based on QCA have the advantages of faster speed, lower power consumption, and greatly reduced sizes. In this paper, we are presented the circuits, which generate random numbers in QCA.  Random numbers have many uses in science, art, statistics, cryptography, gaming, gambli...

Quantum-dot Cellular Automata (QCA) has low power consumption and high density and regularity. QCA widely supports the new devices designed for nanotechnology. Application of QCA technology as an alternative method for CMOS technology on nano-scale shows a promising future. This paper presents successful designing, layout and analysis of Multiplexer with a new structure in QCA technique. In thi...

I. Outline 1 II. Glossary 2 III. Definition of the subject and its importance 2 IV. Introduction 2 V. Cellular Automata 3 A. Reversible Cellular Automata 4 VI. Early proposals 4 VII. Definition 6 VIII. Models of QCA 6 A. Reversible QCA 6 B. Local unitary QCA 7 C. Block-partitioned and nonunitary QCA 7 D. Continuous-time QCA 8 E. Examples of QCA 8 IX. Computationally universal QCA 9 X. Modeling ...