Circuit design for multi-body interactions in superconducting quantum annealing systems with applications to a scalable architecture

Quantum computing: Superconducting multi-qubit interaction circuits A new method to build devices which implement interactions between more than two qubits in quantum annealing systems similar to those produced by D-Wave Systems has been proposed by a collaboration from UCL, Durham University, and t...

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Autores principales: N. Chancellor, S. Zohren, P. A. Warburton
Formato: article
Lenguaje:EN
Publicado: Nature Portfolio 2017
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Acceso en línea:https://doaj.org/article/0bc8928e5c4c48d98ab4d2f252bd0274
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spelling oai:doaj.org-article:0bc8928e5c4c48d98ab4d2f252bd02742021-12-02T12:33:55ZCircuit design for multi-body interactions in superconducting quantum annealing systems with applications to a scalable architecture10.1038/s41534-017-0022-62056-6387https://doaj.org/article/0bc8928e5c4c48d98ab4d2f252bd02742017-06-01T00:00:00Zhttps://doi.org/10.1038/s41534-017-0022-6https://doaj.org/toc/2056-6387Quantum computing: Superconducting multi-qubit interaction circuits A new method to build devices which implement interactions between more than two qubits in quantum annealing systems similar to those produced by D-Wave Systems has been proposed by a collaboration from UCL, Durham University, and the University of Oxford led by Paul Warburton. Such interactions occur naturally in many real world optimization problems. They demonstrate that constructing these circuits is experimentally feasible in the near term, and discuss how additional degrees of freedom included in their technique could help solve problems more efficiently. This new coupler design opens up a wide array of new architectural possibilities for these devices, as well as new ways in which they could solve problems, potentially leading to a new generation of more efficient quantum annealers.N. ChancellorS. ZohrenP. A. WarburtonNature PortfolioarticlePhysicsQC1-999Electronic computers. Computer scienceQA75.5-76.95ENnpj Quantum Information, Vol 3, Iss 1, Pp 1-7 (2017)
institution DOAJ
collection DOAJ
language EN
topic Physics
QC1-999
Electronic computers. Computer science
QA75.5-76.95
spellingShingle Physics
QC1-999
Electronic computers. Computer science
QA75.5-76.95
N. Chancellor
S. Zohren
P. A. Warburton
Circuit design for multi-body interactions in superconducting quantum annealing systems with applications to a scalable architecture
description Quantum computing: Superconducting multi-qubit interaction circuits A new method to build devices which implement interactions between more than two qubits in quantum annealing systems similar to those produced by D-Wave Systems has been proposed by a collaboration from UCL, Durham University, and the University of Oxford led by Paul Warburton. Such interactions occur naturally in many real world optimization problems. They demonstrate that constructing these circuits is experimentally feasible in the near term, and discuss how additional degrees of freedom included in their technique could help solve problems more efficiently. This new coupler design opens up a wide array of new architectural possibilities for these devices, as well as new ways in which they could solve problems, potentially leading to a new generation of more efficient quantum annealers.
format article
author N. Chancellor
S. Zohren
P. A. Warburton
author_facet N. Chancellor
S. Zohren
P. A. Warburton
author_sort N. Chancellor
title Circuit design for multi-body interactions in superconducting quantum annealing systems with applications to a scalable architecture
title_short Circuit design for multi-body interactions in superconducting quantum annealing systems with applications to a scalable architecture
title_full Circuit design for multi-body interactions in superconducting quantum annealing systems with applications to a scalable architecture
title_fullStr Circuit design for multi-body interactions in superconducting quantum annealing systems with applications to a scalable architecture
title_full_unstemmed Circuit design for multi-body interactions in superconducting quantum annealing systems with applications to a scalable architecture
title_sort circuit design for multi-body interactions in superconducting quantum annealing systems with applications to a scalable architecture
publisher Nature Portfolio
publishDate 2017
url https://doaj.org/article/0bc8928e5c4c48d98ab4d2f252bd0274
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AT szohren circuitdesignformultibodyinteractionsinsuperconductingquantumannealingsystemswithapplicationstoascalablearchitecture
AT pawarburton circuitdesignformultibodyinteractionsinsuperconductingquantumannealingsystemswithapplicationstoascalablearchitecture
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