Wavelength division multiplexing of continuous variable quantum key distribution and 18.3 Tbit/s data channels

Eriksson, Tobias A.; Hirano, Takuya; Puttnam, Benjamin J.; Rademacher, Georg; Luís, Ruben S.; Fujiwara, Mikio; Namiki, Ryo; Awaji, Yoshinari; Takeoka, Masahiro; Wada, Naoya; Sasaki, Masahide

doi:10.1038/s42005-018-0105-5

Cited by 129 publications

(64 citation statements)

References 62 publications

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“…Furthermore, in the case when untrusted additive Gaussian channel noise can be ruled out by trusted device calibration, the trusted parties can group the transmitted data according to estimated stable transmittance windows corresponding to non-fluctuating noiseless channels [50], apply shot-noise-limited modulation of squeezed signal states hence preventing an unauthorized party from gaining any information on the key [58] and improve the resulting key rate by channel multiplexing [59][60][61]. In the presence of channel noise the protocol optimization along with the post-selection techniques [19,62] and Gaussian error correction aimed at overcoming low-frequency additive Gaussian noise [63], can significantly improve the performance of Gaussian CV QKD protocols in atmospheric links, enabling efficient and robust free-space quantum key distribution, fully applicable in daylight conditions.…”

Section: Discussionmentioning

confidence: 99%

Squeezing-enhanced quantum key distribution over atmospheric channels

2020

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We propose the Gaussian continuous-variable quantum key distribution using squeezed states in the composite channels including atmospheric propagation with transmittance fluctuations. We show that adjustments of signal modulation and use of optimal feasible squeezing can be sufficient to significantly overcome the coherent-state protocol and drastically improve the performance of quantum key distribution in atmospheric channels, also in the presence of additional attenuating and noisy channels. Furthermore, we consider examples of atmospheric links of different lengths, and show that optimization of both squeezing and modulation is crucial for reduction of protocol downtime and increase of secure atmospheric channel distance. Our results demonstrate unexpected advantage of fragile squeezed states of light in the free-space quantum key distribution applicable in daylight and stable against atmospheric turbulence.Quantum key distribution (QKD) [1-5] is one of the major practical applications of quantum information theory, which provides trusted parties (Alice and Bob) with the methods (protocols) for provably secure distribution of secret cryptographic keys so that security of the key can be verified using fundamental principles of quantum physics. One of the main requirements of QKD is the availability of a dedicated quantum channel capable of transmitting coherent quantum signals between the sending and receiving stations. In the case of fiber-optical channels, being the typical media for QKD implementations, this means a dedicated optical fiber, possibly with co-existing classical or quantum signals. However, the dedicated fiber-optical infrastructure can be unavailable, e.g., in the case of movable stations, necessity of quick channel deployment or in hostile environments. Moreover, the extra-long-distance inter-continental quantum communication over satellites relies on the free-space channels [6]. Therefore, the free-space channels are an important physical medium for QKD implementations.The main issue faced by the discrete-variable (DV) QKD protocols, based on single-photon states or weak coherent pulses and the direct photon counting, is the sensitivity of the detectors to the background light, which adds noise to the measured data. This renders standard DV QKD protocols practically unusable in the daylight conditions unless spectral filtering is applied, which adds unwanted additional loss and complexity to the set-up. At the same time, applicability and efficiency are crucial for QKD as they directly affect the secret communication, based on the quantum-secure keys. Alternatively, continuous-variable (CV) QKD protocols [7-10], based on the multiphoton coherent [11][12][13][14][15] or squeezed states [16] and homodyne quadrature detection using off-the-shelf equipment, can overcome this limitation. Indeed, a homodyne detector, which matches a signal to a narrow-band local oscillator (LO) beam, being the phase reference for the measurement, can intrinsically filter out the background radiation and make CV Q...

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Section: Discussionmentioning

confidence: 99%

Squeezing-enhanced quantum key distribution over atmospheric channels

2020

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“…In recent years, the desire to reduce the capital expenditures of QKD network deployment has motivated the research of QKD integration with classical networks, where both of physical-layer performance and network-layer performance are taken into account. In order to improve the physical-layer performance such as secret-key rate and achievable distance, a number of analytical studies [30], [43], system experiments [31], [34], [36], and field trials [33], [44] have been carried out. On the other hand, several resource assignment strategies have been proposed to optimize the network-layer performance such as blocking probability and resource utilization when QKD coexists with the classical networks [32], [35].…”

Section: A Qkd Network Deploymentmentioning

confidence: 99%

Multi-Tenant Provisioning for Quantum Key Distribution Networks With Heuristics and Reinforcement Learning: A Comparative Study

Cao

Zhao

et al. 2020

IEEE Trans. Netw. Serv. Manage.

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Quantum key distribution (QKD) networks are potential to be widely deployed in the immediate future to provide long-term security for data communications. Given the high price and complexity, multi-tenancy has become a cost-effective pattern for QKD network operations. In this work, we concentrate on addressing the online multi-tenant provisioning (On-MTP) problem for QKD networks, where multiple tenant requests (TRs) arrive dynamically. On-MTP involves scheduling multiple TRs and assigning non-reusable secret keys derived from a QKD network to multiple TRs, where each TR can be regarded as a high-security-demand organization with the dedicated secret-key demand. The quantum key pools (QKPs) are constructed over QKD network infrastructure to improve management efficiency for secret keys. We model the secret-key resources for QKPs and the secret-key demands of TRs using distinct images. To realize efficient On-MTP, we perform a comparative study of heuristics and reinforcement learning (RL) based On-MTP solutions, where three heuristics (i.e., random, fit, and best-fit based On-MTP algorithms) are presented and a RL framework is introduced to realize automatic training of an On-MTP algorithm. The comparative results indicate that with sufficient training iterations the RL-based On-MTP algorithm significantly outperforms the presented heuristics in terms of tenant-request blocking probability and secret-key resource utilization.Index Terms-Quantum key distribution networks, online multi-tenant provisioning, heuristics, reinforcement learning.

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“…CV-QKD has an intrinsically high tolerance to noise from Raman scattering, due to homodyne detection acting like a filter and thus can endure high-classical laser launch powers. 35 Nevertheless, DV-QKD has been proven to operate in the presence of up to +5 dBm launch powers 18 and up to +20 dBm when the quantum channel is moved to O-band. 20 Furthermore, the full security of the DV-QKD protocol adopted in this paper has been well established for a number of years, even in the finite-size scenario.…”

Section: Introductionmentioning

confidence: 99%

Cambridge quantum network

et al. 2019

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Future-proofing current fibre networks with quantum key distribution (QKD) is an attractive approach to combat the ever growing breaches of data theft. To succeed, this approach must offer broadband transport of quantum keys, efficient quantum key delivery and seamless user interaction, all within the existing fibre network. However, quantum networks to date either require dark fibres and/or offer bit rates inadequate for serving a large number of users. Here we report a city wide high-speed metropolitan QKD network-the Cambridge quantum network-operating on fibres already populated with high-bandwidth data traffic. We implement a robust key delivery layer to demonstrate essential network operation, as well as enabling encryption of 100 Gigabit per second (Gbps) simultaneous data traffic with rapidly refreshed quantum keys. Network resilience against link disruption is supported by high-QKD link rates and network link redundancy. We reveal that such a metropolitan network can support tens of thousands of users with key rates in excess of 1 kilobit per second (kbps) per user. Our result hence demonstrates a clear path for implementing quantum security in metropolitan fibre networks.npj Quantum Information (2019) 5:101 ; https://doi.

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Wavelength division multiplexing of continuous variable quantum key distribution and 18.3 Tbit/s data channels

Cited by 129 publications

References 62 publications

Squeezing-enhanced quantum key distribution over atmospheric channels

Squeezing-enhanced quantum key distribution over atmospheric channels

Multi-Tenant Provisioning for Quantum Key Distribution Networks With Heuristics and Reinforcement Learning: A Comparative Study

Cambridge quantum network

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