Resource-effective quantum key distribution: a field trial in Padua city center

Avesani, Marco; Calderaro, Luca; Foletto, Giulio; Agnesi, Costantino; Picciariello, Francesco; Santagiustina, Francesco B. L.; Scriminich, Alessia; Stanco, Andrea; Vedovato, Francesco; Zahidy, Mujtaba; Vallone, Giuseppe; Villoresi, Paolo

doi:10.1364/ol.422890

Cited by 26 publications

(25 citation statements)

References 28 publications

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“…The iPOGNAC offers fast polarization modulation with longterm stability, and a low intrinsic error rate, and, contrary to previous solutions, generates predetermined polarization states with a fixed reference frame in freespace. Moreover, it has also been tested in a field trial in an urban environment [6]. This polarization encoder relies on an unbalanced Sagnac interferometer containing a lithium-niobate phase modulator, and with the BS replaced by a fiber-based PBS with a polarizationmaintaining (PM) optical fiber input and outputs.…”

Section: A Transmittermentioning

confidence: 99%

“…1), where N D (N A ) is the number of counts in the detector associated with |D (|A ). This algorithm, described in [14], was developed for polarization tracking in polarization-encoded fiber links, and was tested in an urban QKD field trial [6]. It starts operating without interrupting the QKD when the QBER exceeds 1%, and stops when it becomes smaller than 1%.…”

Section: B Receivermentioning

confidence: 99%

“…QKD is characterized by a consolidated composable security framework [1,2] and by rapid and continuous technical advancements [3]. In fact, several QKD field trials are being performed to demonstrate the real-world applicability of this technology [4][5][6][7] and several start-ups and university spin-offs are being created to intercept the growing market demands.…”

Section: Introductionmentioning

confidence: 99%

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Cross-encoded quantum key distribution exploiting time-bin and polarization states with qubit-based synchronization

Scalcon¹,

Agnesi²,

Avesani³

et al. 2021

Preprint

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Robust implementation of quantum key distribution requires precise state generation and measurements, as well as a transmission that is resistant to channel disturbances. However, the choice of the optimal encoding scheme is not trivial and depends on external factors such as the quantum channel. In fact, stable and low-error encoders are available for polarization encoding, suitable for free-space channels, whereas time-bin encoding represent a good candidate for fiber-optic channels, as birefingence does not perturb this kind of states. Here we present a cross-encoded scheme where high accuracy quantum states are prepared through a self-compensating, calibration-free polarization modulator and transmitted using a polarization-to-time-bin converter. A hybrid receiver performs both time-of-arrival and polarization measurements to decode the quantum states and successfully leaded to a transmission over 50 km fiber spool without disturbances. Temporal synchronization between the two parties is performed with a qubit-based method that does not require additional hardware to share a clock reference. The system was tested in a 12 hour run and demonstrated good and stable performance in terms of key and quantum bit error rates. The flexibility of our approach represents an important step towards the development of hybrid networks with both fiber-optic and free-space links.

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Section: A Transmittermentioning

confidence: 99%

Section: B Receivermentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Cross-encoded quantum key distribution exploiting time-bin and polarization states with qubit-based synchronization

Scalcon¹,

Agnesi²,

Avesani³

et al. 2021

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…However, this introduces additional hardware requirements and increases the cost and complexity of the setup. One way to avoid these additional resource requirements is to use the quantum channel itself to transmit the information necessary to perform the synchronization [17][18][19][20]. One such qubit-based synchronization protocol was introduced and demonstrated by Calderaro et al [17].…”

Section: Introductionmentioning

confidence: 99%

Qubit-Based Clock Synchronization for QKD Systems Using a Bayesian Approach

Cochran

Gauthier

2021

Entropy

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Quantum key distribution (QKD) systems provide a method for two users to exchange a provably secure key. Synchronizing the users’ clocks is an essential step before a secure key can be distilled. Qubit-based synchronization protocols directly use the transmitted quantum states to achieve synchronization and thus avoid the need for additional classical synchronization hardware. Previous qubit-based synchronization protocols sacrifice secure key either directly or indirectly, and all known qubit-based synchronization protocols do not efficiently use all publicly available information published by the users. Here, we introduce a Bayesian probabilistic algorithm that incorporates all published information to efficiently find the clock offset without sacrificing any secure key. Additionally, the output of the algorithm is a probability, which allows us to quantify our confidence in the synchronization. For demonstration purposes, we present a model system with accompanying simulations of an efficient three-state BB84 prepare-and-measure protocol with decoy states. We use our algorithm to exploit the correlations between Alice’s published basis and mean photon number choices and Bob’s measurement outcomes to probabilistically determine the most likely clock offset. We find that we can achieve a 95 percent synchronization confidence in only 4140 communication bin widths, meaning we can tolerate clock drift approaching 1 part in 4140 in this example when simulating this system with a dark count probability per communication bin width of 8×10−4 and a received mean photon number of 0.01.

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“…Since its first proposal, the decoy-state method [1] has had a major impact on the practicality of quantum key distribution (QKD), having eased many of its technical achievements [2,3] and, recently, its implementations in field trials [4,5]. By countering the photon-numbersplitting (PNS) attack [6], it has enabled the use of practical light sources in QKD and it has been object of many studies including implementation proposals and security proofs.…”

Section: Introductionmentioning

confidence: 99%

Security bounds for decoy-state QKD with arbitrary photon-number statistics

Foletto,

Picciariello,

Agnesi

et al. 2021

Preprint

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The decoy-state method is a standard enhancement to quantum key distribution (QKD) protocols that has enabled countless QKD experiments with inexpensive light sources. However, new technological advancements might require further theoretical study of this technique. In particular, the decoy-state method is typically described under the assumption of a Poisson statistical distribution for the number of photons in each QKD pulse. This is a practical choice, because prepare-andmeasure QKD is often implemented with attenuated lasers, which produce exactly this distribution. However, sources that do not meet this assumption are not guaranteed to be compatible with decoy states. In this work, we provide security bounds for decoy-state QKD using a source with an arbitrary photon emission statistic. We consider both the asymptotic limit of infinite key and the finite-size scenario, and evaluate two common decoy-state schemes: the vacuum+weak and onedecoy protocols. We numerically evaluate the performance of the bounds, comparing three realistic statistical distributions (Poisson, thermal, binomial), showing that they are all viable options for QKD.

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Resource-effective quantum key distribution: a field trial in Padua city center

Cited by 26 publications

References 28 publications

Cross-encoded quantum key distribution exploiting time-bin and polarization states with qubit-based synchronization

Cross-encoded quantum key distribution exploiting time-bin and polarization states with qubit-based synchronization

Qubit-Based Clock Synchronization for QKD Systems Using a Bayesian Approach

Security bounds for decoy-state QKD with arbitrary photon-number statistics

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