publication . Article . Other literature type . Preprint . 2018

SimulaQron—a simulator for developing quantum internet software

Axel Dahlberg; Stephanie Wehner;
English
  • Published: 12 Sep 2018 Journal: Quantum Science and Technology, volume 4, issue 1, page 15,001 (eissn: 2058-9565, Copyright policy)
  • Country: Netherlands
Abstract
Comment: 13 pages, For online documentation see http://www.simulaqron.org
Subjects
ACM Computing Classification System: ComputerSystemsOrganization_MISCELLANEOUSTheoryofComputation_GENERAL
free text keywords: quantum network, simulator, software development, quantum internet, Quantum Physics, Computer Science - Networking and Internet Architecture, Computer Science - Software Engineering, Computer science, Application software, computer.software_genre, computer, Qubit, Quantum information science, Quantum information, Quantum computer, Simulation, Quantum entanglement, business.industry, business
Funded by
EC| QINTERNET
Project
QINTERNET
Quantum communication networks
  • Funder: European Commission (EC)
  • Project Code: 679924
  • Funding stream: H2020 | ERC | ERC-STG
17 references, page 1 of 2

[1] Charles H Bennett and Gilles Brassard. Quantum Cryptography: Public Key Distribution, and Coin-Tossing. In Proc. 1984 IEEE International Conference on Computers, Systems, and Signal Processing, pages 175{179, 1984.

[2] Artur K. Ekert. Quantum cryptography based on Bell's theorem. Physical Review Letters, 67(6):661{663, aug 1991.

[3] Ivan Damgard, Serge Fehr, Louis Salvail, and Christian Scha ner. Secure identi cation and QKD in the boundedquantum-storage model. Theoretical Computer Science, 560(P1):12{26, dec 2014.

[4] Jedrzej Kaniewski and Stephanie Wehner. Deviceindependent two-party cryptography secure against sequential attacks. New Journal of Physics, 18(5), 2016.

[5] Richard Jozsa, Daniel S. Abrams, Jonathan P. Dowling, and Colin P. Williams. Quantum Clock Synchronization Based on Shared Prior Entanglement. pages 0{3, 2000.

[6] Andrew M Childs. Secure assisted quantum computation. Quantum Information & Computation, 5(6):456{466, nov 2001.

[7] A. Kellerer. Quantum telescopes. Astronomy and Geophysics, 55(3):1{12, 2014.

[8] NetSQUID: Currently in preparation.

[9] Damian S. Steiger, Thomas Haner, and Matthias Troyer. ProjectQ: An Open Source Software Framework for Quantum Computing. 2016.

[10] Dave Wecker and Krysta M. Svore. LIQUi|>: A Software Design Architecture and Domain-Speci c Language for Quantum Computing. 2014.

[11] N. Khammassi, I. Ashraf, X. Fu, C.G. Almudever, and K. Bertels. QX: A high-performance quantum computer simulation platform. Design, Automation & Test in Europe Conference & Exhibition (DATE), 2017, pages 464{ 469, 2017.

[12] J. R. Johansson, P. D. Nation, and Franco Nori. QuTiP: An open-source Python framework for the dynamics of open quantum systems. Computer Physics Communications, 183(8):1760{1772, 2012.

[13] Python. https://www.python.org/.

[14] Twisted. https://twistedmatrix.com/trac/.

[15] SimulaQron. http://www.simulaqron.org.

17 references, page 1 of 2
Abstract
Comment: 13 pages, For online documentation see http://www.simulaqron.org
Subjects
ACM Computing Classification System: ComputerSystemsOrganization_MISCELLANEOUSTheoryofComputation_GENERAL
free text keywords: quantum network, simulator, software development, quantum internet, Quantum Physics, Computer Science - Networking and Internet Architecture, Computer Science - Software Engineering, Computer science, Application software, computer.software_genre, computer, Qubit, Quantum information science, Quantum information, Quantum computer, Simulation, Quantum entanglement, business.industry, business
Funded by
EC| QINTERNET
Project
QINTERNET
Quantum communication networks
  • Funder: European Commission (EC)
  • Project Code: 679924
  • Funding stream: H2020 | ERC | ERC-STG
17 references, page 1 of 2

[1] Charles H Bennett and Gilles Brassard. Quantum Cryptography: Public Key Distribution, and Coin-Tossing. In Proc. 1984 IEEE International Conference on Computers, Systems, and Signal Processing, pages 175{179, 1984.

[2] Artur K. Ekert. Quantum cryptography based on Bell's theorem. Physical Review Letters, 67(6):661{663, aug 1991.

[3] Ivan Damgard, Serge Fehr, Louis Salvail, and Christian Scha ner. Secure identi cation and QKD in the boundedquantum-storage model. Theoretical Computer Science, 560(P1):12{26, dec 2014.

[4] Jedrzej Kaniewski and Stephanie Wehner. Deviceindependent two-party cryptography secure against sequential attacks. New Journal of Physics, 18(5), 2016.

[5] Richard Jozsa, Daniel S. Abrams, Jonathan P. Dowling, and Colin P. Williams. Quantum Clock Synchronization Based on Shared Prior Entanglement. pages 0{3, 2000.

[6] Andrew M Childs. Secure assisted quantum computation. Quantum Information & Computation, 5(6):456{466, nov 2001.

[7] A. Kellerer. Quantum telescopes. Astronomy and Geophysics, 55(3):1{12, 2014.

[8] NetSQUID: Currently in preparation.

[9] Damian S. Steiger, Thomas Haner, and Matthias Troyer. ProjectQ: An Open Source Software Framework for Quantum Computing. 2016.

[10] Dave Wecker and Krysta M. Svore. LIQUi|>: A Software Design Architecture and Domain-Speci c Language for Quantum Computing. 2014.

[11] N. Khammassi, I. Ashraf, X. Fu, C.G. Almudever, and K. Bertels. QX: A high-performance quantum computer simulation platform. Design, Automation & Test in Europe Conference & Exhibition (DATE), 2017, pages 464{ 469, 2017.

[12] J. R. Johansson, P. D. Nation, and Franco Nori. QuTiP: An open-source Python framework for the dynamics of open quantum systems. Computer Physics Communications, 183(8):1760{1772, 2012.

[13] Python. https://www.python.org/.

[14] Twisted. https://twistedmatrix.com/trac/.

[15] SimulaQron. http://www.simulaqron.org.

17 references, page 1 of 2
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