High performance quantum computing

Progress in Informatics

Volumn , Issue 8, 2011, Pages 49-55

  Devitt, Simon J ^a   Munro, William J ^b   Nemoto, Kae ^a  

^a NATIONAL INSTITUTE OF INFORMATICS   (Japan)

^b NTT Basic Research Laboratories   (Japan)

Author keywords

High performance computing; Quantum computing; Secure computing; Topological clusters

Indexed keywords

DEDICATED SERVERS; HIGH PERFORMANCE COMPUTING; OPTICAL ARCHITECTURES; QUANTUM COMPUTING; QUANTUM DATA; QUANTUM-INFORMATION PROCESSING; SCALING STRUCTURE; SECURE COMPUTING; SERVER-BASED; TOPOLOGICAL CLUSTERS;

COMPUTER ARCHITECTURE; COMPUTER SOFTWARE SELECTION AND EVALUATION; DATA PROCESSING; QUANTUM COMPUTERS; QUANTUM OPTICS; QUANTUM THEORY;

QUANTUM CRYPTOGRAPHY;

EID: 79960602495     PISSN: 13498614     EISSN: 13498606     Source Type: Journal    
DOI: 10.2201/NiiPi.2011.8.6     Document Type: Article

References (19)

1. D. Kielpinski, C. Monroe, and D. J. Wineland, "Architecture for a large-scale ion-trap quantum computer," Nature, vol.417, pp.709-711, 2002.
2. J. M. Taylor, et.al., "Fault-tolerant architecture for quantum computation using electrically controlled semiconductor spins," Nature Phys., vol.1, pp.177-183, 2005.
3. L. C. L. Hollenberg, A. D. Greentree, A. G. Fowler, and C. J. Wellard, "Two-dimensional architectures for donor-based quantum computing," Phys. Rev. B, vol.74, 045311, 2006.
4. A. G. Fowler et. al., "Long-range coupling and scalable architecture for superconducting flux qubits," Phys. Rev. B, vol.76, 174507, 2007.
5. S. J. Devitt, et. al., "Architectural design for a topological cluster state quantum computer," New. J. Phys., vol.11, 083032, 2009.
6. R. Stock and D. F. V. James, "Scalable, HighSpeed Measurement-Based Quantum Computer Using Trapped Ions," Phys. Rev. Lett., vol.102, 170501, 2009.
7. R. van Meter, T. D. Ladd, A. G. Fowler, and Y. Ya-mamoto, "Distributed Quantum Computer Architecture Using Semiconductor Nanophotonics," Int. J. Quant. Info., vol.8, pp.295-323, 2010.
8. D. A. Herrera-Marti, A. G. Fowler, D. Jennings, and T. Rudolph, "Photonic implementation for the topological cluster-state quantum computer," Phys. Rev. A., vol.82, 032332, 2010.
9. N. Cody Jones, et. al., "A Layered Architecture for Quantum Computing Using Quantum Dots," arXiv:1010.5022, 2010.
10. R. Raussendorf and J. Harrington, "Fault-Tolerant Quantum Computation with High Threshold in Two Dimensions," Phys. Rev. Lett., vol.98, 190504, 2007.
11. R. Raussendorf, J. Harrington, and K. Goyal, "Topo-logical fault-tolerance in cluster state quantum computation," New J. Phys., vol.9, p.199, 2007.
12. A. G. Fowler and K. Goyal, "Topological cluster state quantum computing", Quant. Inf. Comp., vol.9, no.9&10, pp.721-738, 2009.
13. S. J. Devitt, et. al., "Photonic module: An on-demand resource for photonic entanglement," Phys. Rev. A., vol.76, 052312, 2007.
14. R. Raussendorf and H. J. Briegel, "A One-Way Quantum Computer," Phys. Rev. Lett., vol.86, p.5188, 2001.
15. P. Villoresi, et. al., "Experimental verification of the feasibility of a quantum channel between space and Earth," New. J. Phys., vol.10, 033038, 2008.
16. R. Ursin, et. al. Proc. 2008 Microgravity Sciences and Process Symposium (2008); SECOQC, Project www.sqcoqc.net.
17. W. J. Munro, et. al., "From quantum multiplexing to high-performance quantum networking," Nature Photonics, vol.4, pp.792-796, 2010.
18. S. Bravyi and A. Kitaev, "Universal quantum computation with ideal Clifford gates and noisy ancillas," Phys. Rev. A., vol.71, 022316, 2005.
19. A. G. Fowler, "Towards Large-Scale Quantum Computation," quant-ph/0506126, 2005.