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Hauptverfasser: Chaudhary, Sumit, Vallespir, Pere Munar, Jasso, Alonso Viladomat, Nötzel, Janis
Format: Preprint
Veröffentlicht: 2026
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2604.12982
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author Chaudhary, Sumit
Vallespir, Pere Munar
Jasso, Alonso Viladomat
Nötzel, Janis
author_facet Chaudhary, Sumit
Vallespir, Pere Munar
Jasso, Alonso Viladomat
Nötzel, Janis
contents While QKD has been proven in lab environments, large-scale implementation requires integration with existing infrastructure. This paper proposes an opportunistic QKD framework that takes advantage of idle spectral capacity, that is, unused channels in classical fibers, to perform QKD while prioritizing classical traffic. To mitigate crosstalk during the co-propagation of classical and quantum signals, we require a guardband of unused channels between classical and quantum signals. We propose a stochastic traffic model, with a deterministic day-night cycle and fractional Gaussian noise. Monte-Carlo simulations of an 80-channel WDM system with our stochastic traffic model demonstrate that 45-65\% of unused spectrum can be repurposed for QKD, depending on the traffic conditions. We also model a key reservoir, with available and recovery states. We define the Reliability Horizon as the 3σ depletion threshold. We find a trade-off between buffer reset levels: increasing the buffer reset level extends the reliability horizon but linearly increases recovery time, resulting in longer service "dark windows". Furthermore, simulations indicate that the first-passage time follows a heavy-tailed distribution, which is accurately characterized by a composite model combining a diurnal trend and a Bihill transition function. This framework enables network operators to optimize buffer parameters for specific Service Level Agreements (SLAs) in real-world environments.
format Preprint
id arxiv_https___arxiv_org_abs_2604_12982
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Opportunistic QKD: Exploiting Idle Capacity of Classical WDM Systems
Chaudhary, Sumit
Vallespir, Pere Munar
Jasso, Alonso Viladomat
Nötzel, Janis
Quantum Physics
While QKD has been proven in lab environments, large-scale implementation requires integration with existing infrastructure. This paper proposes an opportunistic QKD framework that takes advantage of idle spectral capacity, that is, unused channels in classical fibers, to perform QKD while prioritizing classical traffic. To mitigate crosstalk during the co-propagation of classical and quantum signals, we require a guardband of unused channels between classical and quantum signals. We propose a stochastic traffic model, with a deterministic day-night cycle and fractional Gaussian noise. Monte-Carlo simulations of an 80-channel WDM system with our stochastic traffic model demonstrate that 45-65\% of unused spectrum can be repurposed for QKD, depending on the traffic conditions. We also model a key reservoir, with available and recovery states. We define the Reliability Horizon as the 3σ depletion threshold. We find a trade-off between buffer reset levels: increasing the buffer reset level extends the reliability horizon but linearly increases recovery time, resulting in longer service "dark windows". Furthermore, simulations indicate that the first-passage time follows a heavy-tailed distribution, which is accurately characterized by a composite model combining a diurnal trend and a Bihill transition function. This framework enables network operators to optimize buffer parameters for specific Service Level Agreements (SLAs) in real-world environments.
title Opportunistic QKD: Exploiting Idle Capacity of Classical WDM Systems
topic Quantum Physics
url https://arxiv.org/abs/2604.12982