Atmospheric effects on continuous-variable quantum key distribution

Wang, Shiyu; Huang, Peng; Wang, Tao; Zeng, Guihua

doi:10.1088/1367-2630/aad9c4

Cited by 67 publications

(60 citation statements)

References 42 publications

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“…Here, we assume that the receiver is approximately as a point receiver and the interruption probability P due to angle of arrival fluctuations is not considered. All variables needed in SKR analysis are consistent with those in References 15 and 23. The parameter‐estimation‐based achievable SKR under atmospheric weak and moderate‐to‐strong turbulence channel are depicted in Figures 4A, 5A and 4B, 5B, respectively.…”

Section: Skr Based On Bpesupporting

confidence: 59%

“…Thus, the MSE of BPE and MPE can be respectively calculated as follows

MSE = \frac{1}{M} \sum_{i = 1}^{M} {({\hat{T}}_{i} - {\overline{T}}_{i})}^{2},

where

{\hat{T}}_{i}

is the estimated channel transmittance, and

{\overline{T}}_{i}

is the average channel transmittance on the basis of the historical data, approximates to practical channel transmittance. Based on Reference 15, 23, and 24, the statistical analysis of MSE of BPE and MPE is shown in Table 1. Suppose that there exist 10 subchannels with transmittance of T 1 , T 2 ,…, T 10 , respectively, in the atmospheric channel and there are N /10 states transmission in each subchannel.…”

Section: Bpe For Atmospheric Gmcs Cvqkdmentioning

confidence: 99%

“…In the finite‐size regime, the BPE‐based achievable SKR K B under reconciliation efficiency β R is given as 15,23

K_{B} = (1 - P) [β_{R} I_{A B}^{B} - S_{B E}^{ϵ_{BPE}} - Δ (N)],

where P stands for interruption probability due to angle of arrival fluctuations under considering the high directivity of laser transmission, and N is the total number of variables propagated from Alice to Bob. And Δ( N ) is related to the security of the privacy amplification 24 …”

Section: Skr Based On Bpementioning

confidence: 99%

“…Thus, the mutual information of Alice and Bob can be obtained by, 15,23

I_{A B} = \frac{1}{2} \log_{2} \frac{〈 T 〉 (V + χ_{t o t})}{〈 T 〉 (V + χ_{t o t}) - {⟨\sqrt{T}⟩}^{2} V_{A}} .

…”

Section: Skr Based On Bpementioning

confidence: 99%

“…Since the effect of BPE cannot be evaluated intuitively, we turn to employ the approximate atmospheric channel model described in References 15 and 23 to demonstrate its results. Therefore, the achievable SKR

\hat{K} (\hat{〈 T 〉}, \hat{ε})

based on parameter estimation with reconciliation efficiency β R can be expressed as 15

\hat{K} (\hat{〈 T 〉}, \hat{ε}) = (1 - P) [β_{R} Î_{A B}^{B} (\hat{〈 T 〉}, \hat{ε}) - Ŝ_{B E}^{ϵ_{BPE}} (\hat{〈 T 〉}, \hat{ε}) - Δ (N)],

where

\hat{〈 T 〉}

and

\hat{ε}

are the estimated value which can be calculated using Equations () and ().…”

Section: Skr Based On Bpementioning

confidence: 99%

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Blind channel estimation for continuous‐variable quantum key distribution

Chai

Cao

et al. 2020

Quantum Engineering

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Summary For the maximum‐likelihood parameter estimation (MPE) of continuous‐variable quantum key distribution (CVQKD), it sacrifices partial key when estimating the channel parameters, and when the channel is varying, even slowly, legitimate communication parties must constantly exchange partial input signal and output signal to update the channel estimation. Therefore, the MPE leads to the following problems in practical application: (a) MPE achieved by randomly sampling the states can not accurately reflect the dynamic channel; (b) there exist a trade‐off between the secret key rate (SKR) and the accuracy of parameter estimation in the finite‐size regime; and (c) information leakage may be caused by the correlation between key variables. In this article, a novel parameter estimation method for CVQKD is proposed without affecting the security, and the consistency between the method and the physical model is given. Experimental simulation results show that the method can effectively improve the SKR and secure propagation distance. The experimental verification of the proposed method is given through the fiber system. Besides, the security analysis demonstrates that the method is secure against entanglement‐distillation attack.

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Section: Skr Based On Bpesupporting

confidence: 59%

“…Thus, the MSE of BPE and MPE can be respectively calculated as follows

MSE = \frac{1}{M} \sum_{i = 1}^{M} {({\hat{T}}_{i} - {\overline{T}}_{i})}^{2},

where

{\hat{T}}_{i}

is the estimated channel transmittance, and

{\overline{T}}_{i}

Section: Bpe For Atmospheric Gmcs Cvqkdmentioning

confidence: 99%

“…In the finite‐size regime, the BPE‐based achievable SKR K B under reconciliation efficiency β R is given as 15,23

K_{B} = (1 - P) [β_{R} I_{A B}^{B} - S_{B E}^{ϵ_{BPE}} - Δ (N)],

Section: Skr Based On Bpementioning

confidence: 99%

“…Thus, the mutual information of Alice and Bob can be obtained by, 15,23

I_{A B} = \frac{1}{2} \log_{2} \frac{〈 T 〉 (V + χ_{t o t})}{〈 T 〉 (V + χ_{t o t}) - {⟨\sqrt{T}⟩}^{2} V_{A}} .

…”

Section: Skr Based On Bpementioning

confidence: 99%

\hat{K} (\hat{〈 T 〉}, \hat{ε})

based on parameter estimation with reconciliation efficiency β R can be expressed as 15

\hat{K} (\hat{〈 T 〉}, \hat{ε}) = (1 - P) [β_{R} Î_{A B}^{B} (\hat{〈 T 〉}, \hat{ε}) - Ŝ_{B E}^{ϵ_{BPE}} (\hat{〈 T 〉}, \hat{ε}) - Δ (N)],

where

\hat{〈 T 〉}

and

\hat{ε}

are the estimated value which can be calculated using Equations () and ().…”

Section: Skr Based On Bpementioning

confidence: 99%

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Blind channel estimation for continuous‐variable quantum key distribution

Chai

Cao

et al. 2020

Quantum Engineering

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Finite‐Size Analysis of Thermal States Quantum Cryptography with the Optimal Noise

Yang

Qiu

Chen³

et al. 2021

Annalen der Physik

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A modified thermal states quantum cryptography is proposed by adding the noise at Bob's side and the impact of finite-size effects focused on by performing the channel estimation. An optimal noise which can maximize the key rate is demonstrated to exist and, by using numeric simulations, is shown to vary with the transmission distance. Adding the optimal noise can enhance the effectiveness of the thermal states quantum cryptography protocol under noisy and lossy channel in terms of secret key rate, the maximum transmission distance and the tolerable channel noise. Although finite-size effects deteriorate the performance of thermal quantum cryptography, this approach can compensate the impact of this degradation, and even make the performance of the modified protocol in the finite-size regime better than that of the original protocol in the ideal asymptotic regime.

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Feasibility assessment for practical continuous variable quantum key distribution over the satellite‐to‐Earth channel

Kish

Villaseñor

Malaney

et al. 2020

Quantum Engineering

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Summary Currently, quantum key distribution (QKD) using continuous variable (CV) technology has only been demonstrated over short‐range terrestrial links. Here, we attempt to answer whether CV‐QKD over the much longer satellite‐to‐Earth channel is feasible. To this end, we first review the concepts and technologies that will enable CV‐QKD over the satellite‐to‐Earth channels. We then consider, in the infinite key limit, the simplest‐to‐deploy QKD protocols, the coherent state (CS) QKD protocol with homodyne detection and the CS‐QKD protocol with heterodyne detection. We then focus on the CS‐QKD protocol with heterodyne detection in the pragmatic setting of finite keys, where complete security against general attacks is known. We pay particular attention to the relevant noise terms in the satellite‐to‐Earth channel and their impact on the secret key rates. In system set‐ups where diffraction dominates losses, we find that the main components of the total excess noise are the intensity fluctuations due to scintillation, and the time‐of‐arrival fluctuations between signal and local oscillator. We conclude that for a wide range of pragmatic system models, CS‐QKD with information‐theoretic security in the satellite‐to‐Earth channel is feasible.

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Atmospheric effects on continuous-variable quantum key distribution

Cited by 67 publications

References 42 publications

Blind channel estimation for continuous‐variable quantum key distribution

Blind channel estimation for continuous‐variable quantum key distribution

Finite‐Size Analysis of Thermal States Quantum Cryptography with the Optimal Noise

Feasibility assessment for practical continuous variable quantum key distribution over the satellite‐to‐Earth channel

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