Improving Parameter Estimation of Entropic Uncertainty Relation in Continuous-Variable Quantum Key Distribution
Abstract
:1. Introduction
2. Composable Security and Description of the Protocol
- State preparation: Alice holds the squeezed states with squeezed variance before the protocol begins, where . In every run of the protocol, Alice uses Gaussian random numbers to encode the displacement of quadratures by using modulators (generally containing amplitude and phase modulators), and the total modulation variance is denoted by .
- State transmission: Alice sends the modulated state in the quantum channel, which is treated as a totally untrusted channel and controlled by Eve.
- State measurement: Bob receives the quantum state and randomly measures x or p quadrature by an ideal homodyne detector. Resulting from the fact that the practical measurement phase is always discrete, the ideal measurement outcomes should be discretized by the analogue-to-digital converter (ADC). The final discretized results are denoted by .
- Parameter estimation: Alice and Bob repeat the above steps many times until they have enough raw data (e.g., N). Then, Alice or Bob reveals some of the raw data (with length m) through the classical channel to estimate the key parameters of the channel, especially the data distance between Alice’s and Bob’s data, the transmittance , and the excess noise . See Section 3 for a detailed explanation of the parameter estimation step.
- Error correction: According to the estimation parameters and , the communication parts estimate the leakage information during the error correction phase and choose an appropriate classical error reconciliation algorithm, e.g., low-density-parity-check (LDPC) code, to correct Alice’s error (in reverse reconciliation cases) or Bob’s error (in direct reconciliation cases).
- Privacy amplification: Alice and Bob randomly choose a universal hash function [45] and apply it to their respective keys to get the final private keys and with length ℓ, which are only known to themselves.
3. Channel Parameter Estimation with Finite-Size
3.1. Estimation of Smooth Min-Entropy
3.2. Ideal Estimation of Leakage Information with Infinite-Size
3.3. Practical Estimation of Leakage Information with Finite-Size
4. Double-Data Modulation Method and the Modified Estimation Process
5. Numerical Simulation and Discussion
6. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
Abbreviations
CV | Continuous-variable |
DV | Discrete-variable |
QKD | Quantum key distribution |
EUR | Entropic uncertainty relation |
CM | Covariance matrix |
DR | Direct reconciliation |
RR | Reverse reconciliation |
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Chen, Z.; Zhang, Y.; Wang, X.; Yu, S.; Guo, H. Improving Parameter Estimation of Entropic Uncertainty Relation in Continuous-Variable Quantum Key Distribution. Entropy 2019, 21, 652. https://doi.org/10.3390/e21070652
Chen Z, Zhang Y, Wang X, Yu S, Guo H. Improving Parameter Estimation of Entropic Uncertainty Relation in Continuous-Variable Quantum Key Distribution. Entropy. 2019; 21(7):652. https://doi.org/10.3390/e21070652
Chicago/Turabian StyleChen, Ziyang, Yichen Zhang, Xiangyu Wang, Song Yu, and Hong Guo. 2019. "Improving Parameter Estimation of Entropic Uncertainty Relation in Continuous-Variable Quantum Key Distribution" Entropy 21, no. 7: 652. https://doi.org/10.3390/e21070652
APA StyleChen, Z., Zhang, Y., Wang, X., Yu, S., & Guo, H. (2019). Improving Parameter Estimation of Entropic Uncertainty Relation in Continuous-Variable Quantum Key Distribution. Entropy, 21(7), 652. https://doi.org/10.3390/e21070652