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 -