Gaussian entanglement distribution via satellite

Hosseinidehaj, Nedasadat; Malaney, Robert

doi:10.1103/physreva.91.022304

Cited by 46 publications

(48 citation statements)

References 40 publications

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“…We study only non-Gaussian operations at the transmitter side. 2 We consider two schemes, namely the T-PS and the T-PA schemes. As illustrated in Fig.…”

Section: B Cv-qkd Protocol and Secret Key Ratementioning

confidence: 99%

Photonic Engineering for CV-QKD Over Earth-Satellite Channels

Malaney

Green

2019

ICC 2019 - 2019 IEEE International Conference on Communications (ICC)

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Quantum Key Distribution (QKD) via satellite offers up the possibility of unconditionally secure communications on a global scale. Increasing the secret key rate in such systems, via photonic engineering at the source, is a topic of much ongoing research. In this work we investigate the use of photon-added states and photon-subtracted states, derived from two mode squeezed vacuum states, as examples of such photonic engineering. Specifically, we determine which engineered-photonic state provides for better QKD performance when implemented over channels connecting terrestrial receivers with Low-Earth-Orbit satellites. We quantify the impact the number of photons that are added or subtracted has, and highlight the role played by the adopted model for atmospheric turbulence and loss on the predicted key rates. Our results are presented in terms of the complexity of deployment used, with the simplest deployments ignoring any estimate of the channel, and the more sophisticated deployments involving a feedback loop that is used to optimize the key rate for each channel estimation. The optimal quantum state is identified for each deployment scenario investigated.

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“…We study only non-Gaussian operations at the transmitter side. 2 We consider two schemes, namely the T-PS and the T-PA schemes. As illustrated in Fig.…”

Section: B Cv-qkd Protocol and Secret Key Ratementioning

confidence: 99%

Photonic Engineering for CV-QKD Over Earth-Satellite Channels

Malaney

Green

2019

ICC 2019 - 2019 IEEE International Conference on Communications (ICC)

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“…We also find the T-PS and R-PS schemes can outperform the No-PS scheme in some parameter space (again we caution that optimisation of the initial squeezing can alter these conclusions). We next investigate the key rates of the three schemes in the variable Earth-satellite channel, calculating their average key rates under different average channel fluctuations, quantified using σ b within equations (1)- (2). These results are shown in Fig.…”

Section: Fixed Attenuation Channelmentioning

confidence: 99%

Quantum Communications via Satellite with Photon Subtraction

Malaney

Green

2018

2018 IEEE Globecom Workshops (GC Wkshps)

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Non-Gaussian continuous-variable quantum states represent a pivotal resource in many quantum information protocols. Production of such states can occur through photonic subtraction processes either at the transmitter side prior to sending a state through the channel, or at the receiver side on receipt of a state that has traversed the channel. In the context of quantum protocols implemented over communication channels to and from Low-Earth-Orbit (LEO) satellites it is unclear what photonic subtraction set-up will provide for the best performance. In this work we show that for a popular version of continuousvariable Quantum Key Distribution (QKD) between terrestrial stations and LEO satellites, photon subtraction at the transmitter side is the preferred set-up. Such a result is opposite to that found for fiber-based implementations. Our results have implications for all future space-based missions that seek to take advantage of the opportunities offered by non-Gaussian quantum states.

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“…In this case, the transmissivity η of the link between the two parties is not constant and may take values according to some probability distribution [43]. This description usually emerges from the fact that the parties use a free-space link [44] that is susceptible to the atmospheric turbulence [45][46][47][48][49][50][51]. Previous studies (e.g., see Ref.…”

Section: Introductionmentioning

confidence: 99%

“…Previous studies (e.g., see Ref. [52]) have considered the symmetric situation where both users and eavesdropper are subject to truly environmental fading. In this manuscript, we consider a different situation, i.e., the worst-case scenario where the eavesdropper is in complete control of the quantum channel, so that she may choose different instantaneous values of the transmissivity for each use of the channel.…”

Section: Introductionmentioning

confidence: 99%

Continuous-variable quantum key distribution in uniform fast-fading channels

2018

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Article:Papanastasiou, Panagiotis, Weedbrook, Christian and Pirandola, Stefano orcid.org/0000-0001- 6165-5615 (2018) We investigate the performance of several continuous-variable quantum key distribution protocols in the presence of fading channels. These are lossy channels whose transmissivity changes according to a probability distribution. This is typical in communication scenarios where remote parties are connected by free-space links subject to atmospheric turbulence. In this work, we assume the worst-case scenario where an eavesdropper has full control of a fast fading process, so that she chooses the instantaneous transmissivity of a channel, while the remote parties can only detect the mean statistical process. In our study, we consider coherent-state protocols run in various configurations, including the one-way switching protocol in reverse reconciliation, the measurementdevice-independent protocol in the symmetric configuration and a three-party measurement-deviceindependent network. We show that, regardless of the advantage given to the eavesdropper (full control of fading), these protocols can still achieve high rates.

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Gaussian entanglement distribution via satellite

Cited by 46 publications

References 40 publications

Photonic Engineering for CV-QKD Over Earth-Satellite Channels

Photonic Engineering for CV-QKD Over Earth-Satellite Channels

Quantum Communications via Satellite with Photon Subtraction

Continuous-variable quantum key distribution in uniform fast-fading channels

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