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Algorithms for Embedding Quantum-Dot Cellular Automata Networks onto a Quantum Annealing Processor

Jacob Retallick, M. Babcock, Miguel Aroca-Ouellette, Shane McNamara, S. Wilton, Aidan Roy, Mark Johnson, Konrad Walus The University of British Columbia, Vancouver, Canada, Diodes Inc, Burnaby·September 14, 2017
PhysicsMathematics

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Abstract

Advancements in computing based on qubit networks, and in particular the flux-qubit processor architecture developed by D-Wave System's Inc., have enabled the physical simulation of quantum-dot cellular automata (QCA) networks beyond the limit of classical methods. However, the embedding of QCA networks onto the available processor architecture is a key challenge in preparing such simulations. In this work, two approaches to embedding QCA circuits are characterized: a dense placement algorithm that uses a routing method based on negotiated congestion; and a heuristic method implemented in D-Wave's Solver API package. A set of benchmark QCA networks is used to characterise the algorithms and a stochastic circuit generator is employed to investigate the performance for different processor sizes and active flux-qubit yields.

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