Methodology for calculating the average time of entry into synchronism of stations of the system of quantum key distribution with sequential polling of fiber-optic line sections with decreasing length by the graphic-analytical method

Y Mironov,K Rumyantsev,P Mironova,V Breskich,A Zheltenkov,Y Dreizis

doi:10.1051/e3sconf/202022401032

Y Mironov, K Rumyantsev + Show 4 more

Open Access

https://doi.org/10.1051/e3sconf/202022401032

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Journal: E3S Web of Conferences	Publication Date: Jan 1, 2020
License type: CC BY 4.0

Affiliation: Southern Federal University

Abstract

A method is proposed for calculating the average time of entry into synchronism of stations of the system of quantum key distribution (QKD) with sequential polling of sections of a fiber-optic communication line (FOCL) with decreasing length. A diagram of states and transitions for a sequential search for a photon pulse is constructed. Analytical expressions are obtained for finding the probability of detecting a photon pulse, the average number of steps for entry into synchronism of stations, the variance of the number of steps and the average time for entry into connection. It is noted that when the FOCL is divided into sections with decreasing length, the level of dark current pulses (DCP) significantly decreases from section to section. The latter allows to reduce the probability of false alarms of the photodetector. The analysis of the results obtained showed that the time of entry into synchronism for the proposed algorithm is 3 times less than the time required for entry into communication of stations in the case of an algorithm-analogue. The results obtained indicate the possibility of increasing the length of the FOCL while ensuring the value of the synchronization error probability at the level of 0.01.

Highlights

Ensuring the confidentiality of information during transmission between legitimate users is one of the main criteria for the security and efficiency of data transmission systems at present
One of the ways to increase the security of quantum key distribution (QKD) systems is to synchronize the stations of the system QKD at a single-photon level [2]
To find the average time required for entry into communication of the receiving-transmitting and coding stations, we will use the diagram of states and transitions presented in Figure 1 [16]

Summary

Introduction

Ensuring the confidentiality of information during transmission between legitimate users is one of the main criteria for the security and efficiency of data transmission systems at present. The equipment registers a photon pulse or dark current pulses (DCP) by analyzing the first time interval (section) in the first frame of the FOCL. When registering a photon pulse or DCP, the equipment switches to the testing mode The result of this stage is either confirmation of the presence of a photon pulse in the inspected section of the FOCL and, successful synchronization of the stations of the QKD system, or a negative testing result and transition to the analysis of the section of the FOCL. Let us calculate the average time required for entry into communication of the receivingtransmitting and coding stations of the QKD for the proposed algorithm and algorithmanalogue

Simulation of the synchronization process

Conclusions

Rumyansev K E and Pljonkin A P 2015 Radio engineering 2 125–134