Abstract
Continuous-variable quantum key distribution (CVQKD) is an important application of quantum technology, which enables long-distance communicating parties to establish a string of unconditionally secure keys in an insecure environment. However, in a practical CVQKD system, the finite sampling bandwidth of the analog-to-digital converter (ADC) at the receiver may create inaccurate sampling results, leading to errors in parameter estimation process and leaving a security loophole for eavesdroppers. In order to eliminate the finite sampling bandwidth effect, we propose a peak-compensation-based CVQKD scheme, which estimates the discrepancy between the maximum sampling value and the peak value of each pulse based on the characteristics of Gaussian pulse. The maximum sampling values are compensated by the estimated discrepancy, so that the legitimate parties can obtain correct sampling results. We analyze the influence of the finite sampling bandwidth on the security of the system, expounding the specific steps of peak-compensation, comparing the estimated excess noise before and after peak-compensation, and discussing the security of the system under Gaussian collective attacks. Simulation results show that this scheme can greatly improve the accuracy of pulse peak sampling and remove the finite sampling bandwidth effect. Moreover, the channel parameters estimated by the communicating parties are also corrected by using the compensated values. Compared with the scheme without peak-compensation, this scheme eliminates the limitation of the system repetition to the secret key bit rate, and has longer secure transmission distance and higher secret key bit rate. In addition, compared with other methods of solving the finite sampling bandwidth effect, the proposed scheme can be directly implemented in data processing stage after sampling without any additional devices, and thus increasing no complexity of the system.
Highlights
In order to eliminate the finite sampling bandwidth effect, we propose a peak-compensation-based Continuous-variable quantum key distribution (CVQKD) scheme, which estimates the discrepancy between the maximum sampling value and the peak value of each pulse based on the characteristics of Gaussian pulse
3) (Hunan Aerospace Construction Engineering Co., Ltd., Changsha 410205, China) 4) (School of Computer Science and Engineering, Central South University, Changsha 410083, China)
Summary
PBS 为偏振分 束器, BS 为光分束器, PM 为相位调制器, PIN 为光电二极 管, ADC 为模数转换器 Fig. 1. Structure of receiver’ s apparatus of a CVQKD system. PBS, polarization beam splitter; BS, beam splitter; PM, phase modulator; PIN, positive intrinsic-negative; ADC, analog-to-digital converter. 其中: k = Um/Up ; t = ηT , h 为零差探测器的探测 效率, T 为信道透射比; e 为系统的过噪声; t′ 和 ε′ 分别表示 t 和 e 的估计值. 因此, 在没有采到脉冲 的峰值时, Alice 和 Bob 会错误地估计系统的过噪 声, 给窃听者留下安全漏洞
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