Difference between revisions of "Publications/le-quoc.08.ispec"
From LRDE
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{{Publication |
{{Publication |
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− | | date = 2008-01- |
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| authors = Cuong Le Quoc, Patrick Bellot, Akim Demaille |
| authors = Cuong Le Quoc, Patrick Bellot, Akim Demaille |
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| title = Towards the World-Wide Quantum Network |
| title = Towards the World-Wide Quantum Network |
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| abstract = Quantum Key Distribution (QKD) networks are of much interest due to their capacity of providing extremely high security keys to network participants. Most QKD network studies so far focus on trusted models where all the network nodes are assumed to be perfectly secured. This restricts QKD networks to be small. In this paper, we first develop a novel model dedicated to large-scale QKD networks, some of whose nodes could be eavesdropped secretly. Then, we investigate the key transmission problem in the new model by an approach based on percolation theory and stochastic routing. Analyses show that under computable conditions large-scale QKD networks could protect secret keys with an extremely high probability. Simulations validate our results. |
| abstract = Quantum Key Distribution (QKD) networks are of much interest due to their capacity of providing extremely high security keys to network participants. Most QKD network studies so far focus on trusted models where all the network nodes are assumed to be perfectly secured. This restricts QKD networks to be small. In this paper, we first develop a novel model dedicated to large-scale QKD networks, some of whose nodes could be eavesdropped secretly. Then, we investigate the key transmission problem in the new model by an approach based on percolation theory and stochastic routing. Analyses show that under computable conditions large-scale QKD networks could protect secret keys with an extremely high probability. Simulations validate our results. |
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| lrdepaper = http://www.lrde.epita.fr/dload/papers/le-quoc.08.ispec.pdf |
| lrdepaper = http://www.lrde.epita.fr/dload/papers/le-quoc.08.ispec.pdf |
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+ | | lrdenewsdate = 2008-01-25 |
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| type = inproceedings |
| type = inproceedings |
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| id = le-quoc.08.ispec |
| id = le-quoc.08.ispec |
Revision as of 16:45, 5 November 2013
- Authors
- Cuong Le Quoc, Patrick Bellot, Akim Demaille
- Where
- Proceedings of the 4th Information Security Practice and Experience Conference (ISPEC'08)
- Place
- Sydney, Australia
- Type
- inproceedings
- Date
- 2008-01-25
Abstract
Quantum Key Distribution (QKD) networks are of much interest due to their capacity of providing extremely high security keys to network participants. Most QKD network studies so far focus on trusted models where all the network nodes are assumed to be perfectly secured. This restricts QKD networks to be small. In this paper, we first develop a novel model dedicated to large-scale QKD networks, some of whose nodes could be eavesdropped secretly. Then, we investigate the key transmission problem in the new model by an approach based on percolation theory and stochastic routing. Analyses show that under computable conditions large-scale QKD networks could protect secret keys with an extremely high probability. Simulations validate our results.
Documents
Bibtex (lrde.bib)
@InProceedings{ le-quoc.08.ispec, author = {Cuong Le Quoc and Patrick Bellot and Akim Demaille}, title = {Towards the World-Wide Quantum Network}, booktitle = {Proceedings of the 4th Information Security Practice and Experience Conference (ISPEC'08)}, year = 2008, address = {Sydney, Australia}, month = april, abstract = {Quantum Key Distribution (QKD) networks are of much interest due to their capacity of providing extremely high security keys to network participants. Most QKD network studies so far focus on trusted models where all the network nodes are assumed to be perfectly secured. This restricts QKD networks to be small. In this paper, we first develop a novel model dedicated to large-scale QKD networks, some of whose nodes could be eavesdropped secretly. Then, we investigate the key transmission problem in the new model by an approach based on percolation theory and stochastic routing. Analyses show that under computable conditions large-scale QKD networks could protect secret keys with an extremely high probability. Simulations validate our results.}, keywords = {Quantum Key Distribution, QKD network, percolation theory, stochastic routing} }