MadQCI: a heterogeneous and scalable SDN-QKD network deployed in production facilities

Vicente Martin; Juan Pedro Brito; Laura Ortíz; Ruben Brito-Mendez; Jaime Saez de Buruga; Rafael Vicente; Alberto Sebastian-Lombrana; David Rincon; Fernando Perez; Cesar Sanchez; Momtchil Peev; Hans H.  Brunner; Chi-Hang Fred Fung; Andreas Poppe; Florian Fröwis; Andrew Shields; Robert Woodward; Helmut Grießer; Stefan Röhrich; Fernando de la Iglesia; Carlos Abellan; Michael Hentschel; Jose Manuel Rivas-Moscoso; Antonio Pastor-Perales; Jesus Folgueira; Diego Lopez

doi:10.1038/s41534-024-00873-2

MadQCI: a heterogeneous and scalable SDN-QKD network deployed in production facilities

Vicente Martin
, Juan Pedro Brito
, Laura Ortíz
, Ruben Brito-Mendez
, Jaime Saez de Buruga
, Rafael Vicente
, Alberto Sebastian-Lombrana
, David Rincon
, Fernando Perez
, Cesar Sanchez
, Momtchil Peev
, Hans H. Brunner
, Chi-Hang Fred Fung
, Andreas Poppe
, Florian Fröwis
, Andrew Shields
, Robert Woodward
, Helmut Grießer
, Stefan Röhrich
, Fernando de la Iglesia

Carlos Abellan, Michael Hentschel, Jose Manuel Rivas-Moscoso, Antonio Pastor-Perales, Jesus Folgueira, Diego Lopez

Research output: Contribution to journal › Article › peer-review

Abstract

Current quantum key distribution (QKD) networks focus almost exclusively on transporting secret keys at the highest possible rate. Consequently, they are built as mostly fixed, ad hoc, logically, and physically isolated infrastructures designed to avoid any penalty to the quantum channel. This architecture is neither scalable nor cost-effective and future, real-world deployments will differ considerably. The structure of the MadQCI QKD network presented here is based on disaggregated components and modern paradigms especially designed for flexibility, upgradability, and facilitating the integration of QKD in the security and telecommunications-networks ecosystem. These underlying ideas have been tested by deploying many QKD systems from several manufacturers in a real-world, multi-tenant telecommunications network, installed in production facilities and sharing the infrastructure with commercial traffic. Different technologies have been used in different links to address the variety of situations and needs that arise in real networks, exploring a wide range of possibilities. Finally, a set of realistic use cases has been implemented to demonstrate the validity and performance of the network. The testing took place during a period close to three years, where most of the nodes were continuously active.

Original language	English
Article number	80
Pages (from-to)	1-11
Number of pages	11
Journal	npj Quantum Information
Volume	10
Issue number	1
DOIs	https://doi.org/10.1038/s41534-024-00873-2
Publication status	Published - 2 Sept 2024

Research Field

Former Research Field - Enabling Digital Technologies

Keywords

Fiber optics
Information and communication technologies
Quantum cryptography
quantum information

Access to Document

10.1038/s41534-024-00873-2

Cite this

Martin, V., Brito, J. P., Ortíz, L., Brito-Mendez, R., Saez de Buruga, J., Vicente, R., Sebastian-Lombrana, A., Rincon, D., Perez, F., Sanchez, C., Peev, M., Brunner , H. H., Fung, C.-H. F., Poppe, A., Fröwis, F., Shields, A., Woodward, R., Grießer, H., Röhrich, S., ... Lopez, D. (2024). MadQCI: a heterogeneous and scalable SDN-QKD network deployed in production facilities. npj Quantum Information, 10(1), 1-11. Article 80. https://doi.org/10.1038/s41534-024-00873-2

@article{7ca2d25229c84112b7c4ac11df491c63,

title = "MadQCI: a heterogeneous and scalable SDN-QKD network deployed in production facilities",

abstract = "Current quantum key distribution (QKD) networks focus almost exclusively on transporting secret keys at the highest possible rate. Consequently, they are built as mostly fixed, ad hoc, logically, and physically isolated infrastructures designed to avoid any penalty to the quantum channel. This architecture is neither scalable nor cost-effective and future, real-world deployments will differ considerably. The structure of the MadQCI QKD network presented here is based on disaggregated components and modern paradigms especially designed for flexibility, upgradability, and facilitating the integration of QKD in the security and telecommunications-networks ecosystem. These underlying ideas have been tested by deploying many QKD systems from several manufacturers in a real-world, multi-tenant telecommunications network, installed in production facilities and sharing the infrastructure with commercial traffic. Different technologies have been used in different links to address the variety of situations and needs that arise in real networks, exploring a wide range of possibilities. Finally, a set of realistic use cases has been implemented to demonstrate the validity and performance of the network. The testing took place during a period close to three years, where most of the nodes were continuously active.",

keywords = "Fiber optics, Information and communication technologies, Quantum cryptography, quantum information",

author = "Vicente Martin and Brito, \{Juan Pedro\} and Laura Ort{\'i}z and Ruben Brito-Mendez and \{Saez de Buruga\}, Jaime and Rafael Vicente and Alberto Sebastian-Lombrana and David Rincon and Fernando Perez and Cesar Sanchez and Momtchil Peev and Brunner, \{Hans H.\} and Fung, \{Chi-Hang Fred\} and Andreas Poppe and Florian Fr{\"o}wis and Andrew Shields and Robert Woodward and Helmut Grie{\ss}er and Stefan R{\"o}hrich and \{de la Iglesia\}, Fernando and Carlos Abellan and Michael Hentschel and Rivas-Moscoso, \{Jose Manuel\} and Antonio Pastor-Perales and Jesus Folgueira and Diego Lopez",

year = "2024",

month = sep,

day = "2",

doi = "10.1038/s41534-024-00873-2",

language = "English",

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Martin, V, Brito, JP, Ortíz, L, Brito-Mendez, R, Saez de Buruga, J, Vicente, R, Sebastian-Lombrana, A, Rincon, D, Perez, F, Sanchez, C, Peev, M, Brunner , HH, Fung, C-HF, Poppe, A, Fröwis, F, Shields, A, Woodward, R, Grießer, H, Röhrich, S, de la Iglesia, F, Abellan, C, Hentschel, M, Rivas-Moscoso, JM, Pastor-Perales, A, Folgueira, J & Lopez, D 2024, 'MadQCI: a heterogeneous and scalable SDN-QKD network deployed in production facilities', npj Quantum Information, vol. 10, no. 1, 80, pp. 1-11. https://doi.org/10.1038/s41534-024-00873-2

TY - JOUR

T1 - MadQCI: a heterogeneous and scalable SDN-QKD network deployed in production facilities

AU - Martin, Vicente

AU - Brito, Juan Pedro

AU - Ortíz, Laura

AU - Brito-Mendez, Ruben

AU - Saez de Buruga, Jaime

AU - Vicente, Rafael

AU - Sebastian-Lombrana, Alberto

AU - Rincon, David

AU - Perez, Fernando

AU - Sanchez, Cesar

AU - Peev, Momtchil

AU - Brunner , Hans H.

AU - Fung, Chi-Hang Fred

AU - Poppe, Andreas

AU - Fröwis, Florian

AU - Shields, Andrew

AU - Woodward, Robert

AU - Grießer, Helmut

AU - Röhrich, Stefan

AU - de la Iglesia, Fernando

AU - Abellan, Carlos

AU - Hentschel, Michael

AU - Rivas-Moscoso, Jose Manuel

AU - Pastor-Perales, Antonio

AU - Folgueira, Jesus

AU - Lopez, Diego

PY - 2024/9/2

Y1 - 2024/9/2

N2 - Current quantum key distribution (QKD) networks focus almost exclusively on transporting secret keys at the highest possible rate. Consequently, they are built as mostly fixed, ad hoc, logically, and physically isolated infrastructures designed to avoid any penalty to the quantum channel. This architecture is neither scalable nor cost-effective and future, real-world deployments will differ considerably. The structure of the MadQCI QKD network presented here is based on disaggregated components and modern paradigms especially designed for flexibility, upgradability, and facilitating the integration of QKD in the security and telecommunications-networks ecosystem. These underlying ideas have been tested by deploying many QKD systems from several manufacturers in a real-world, multi-tenant telecommunications network, installed in production facilities and sharing the infrastructure with commercial traffic. Different technologies have been used in different links to address the variety of situations and needs that arise in real networks, exploring a wide range of possibilities. Finally, a set of realistic use cases has been implemented to demonstrate the validity and performance of the network. The testing took place during a period close to three years, where most of the nodes were continuously active.

AB - Current quantum key distribution (QKD) networks focus almost exclusively on transporting secret keys at the highest possible rate. Consequently, they are built as mostly fixed, ad hoc, logically, and physically isolated infrastructures designed to avoid any penalty to the quantum channel. This architecture is neither scalable nor cost-effective and future, real-world deployments will differ considerably. The structure of the MadQCI QKD network presented here is based on disaggregated components and modern paradigms especially designed for flexibility, upgradability, and facilitating the integration of QKD in the security and telecommunications-networks ecosystem. These underlying ideas have been tested by deploying many QKD systems from several manufacturers in a real-world, multi-tenant telecommunications network, installed in production facilities and sharing the infrastructure with commercial traffic. Different technologies have been used in different links to address the variety of situations and needs that arise in real networks, exploring a wide range of possibilities. Finally, a set of realistic use cases has been implemented to demonstrate the validity and performance of the network. The testing took place during a period close to three years, where most of the nodes were continuously active.

KW - Fiber optics

KW - Information and communication technologies

KW - Quantum cryptography

KW - quantum information

U2 - 10.1038/s41534-024-00873-2

DO - 10.1038/s41534-024-00873-2

M3 - Article

SN - 2056-6387

VL - 10

SP - 1

EP - 11

JO - npj Quantum Information

JF - npj Quantum Information

IS - 1

M1 - 80

ER -

MadQCI: a heterogeneous and scalable SDN-QKD network deployed in production facilities

Abstract

Research Field

Keywords

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