RU2566335C1 - Method of generating private keys using time-entangled photon pairs - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention relates to quantum cryptography and more specifically to methods of generating private keys using time-entangled photon pairs. The method of generating private keys using time-entangled photon pairs includes allocating, between two private key transmission participants, photons from time-entangled photon pairs, converting said photons with interferometers of the participants, detection thereof with single-photon detectors and processing the measurement results with a computer, which includes communication between participants over a public link. Further, the method includes establishing a time interval coordinated between the participants, dividing the time interval into M equal subintervals and determining subintervals during which single-photon detectors of the participants are triggered, after which the number of said subintervals is used as key elements.

EFFECT: faster allocation of private keys between communication participants and longer range of transmitting private keys.

2 cl, 1 dwg

Description

FIELD OF THE INVENTION

The invention relates to the field of quantum cryptography - quantum distribution systems of cryptographic keys, and can be used to generate secret keys used to encrypt information in quantum data transmission systems, and in particular to methods for generating secret keys using time-reversed pairs of photons.

State of the art

The closest analogue of the claimed invention is a method for generating secret keys using time-reversed photon pairs, in which photons from these pairs are distributed between two transmission participants that convert these photons with interferometers; transmission participants change the lengths of the arms of the interferometers using phase modulators introduced into one of the arms of the interferometers. Further, measurements are made by single photon detectors and process the measurement results using a computer, including communication between participants through an open communication channel [G. Ribordy et al., Long distance entanglement-based quantum key distribution, Phys. Rev. A, v. 63, 012300 (2001)].

The disadvantages of this method include the low generation rate of entangled photon pairs and, as a result, the low distribution rate of secret keys.

SUMMARY OF THE INVENTION

The technical result of the invention is to accelerate the distribution of private keys between participants in communication and increase the range of transmission of private keys.

The specified technical result is ensured by the fact that in the method for generating secret keys using time-confused photon pairs, including distributing between the two participants transmitting secret keys of photons from time-confused photon pairs, further converting these photons by interferometers of the participants, their detection by single photon detectors and subsequent processing of the measurement results using a computer, including communication between participants through an open communication channel, moreover, I agree the invention further comprises establishing an agreed between the parties to the time interval within which the separation is carried out on M equal subintervals and the subintervals determined in which participants are triggered single photon detectors, after which the numbers of the sub-slots are used as parts of keys.

As open channels use telephone communication and / or the Internet and / or acoustic communication channels.

Communication participants set the duration of the time interval, which they divide into equal sub-intervals. Communication participants count time slots in a synchronized manner, the number of times determined by them. Photons from time-confused photon pairs are distributed between participants who convert these photons on their interferometers and measure them with single photon detectors. Within the predetermined intervals, the participants of the transmission store information about the subintervals in which their detectors and the numbers of triggered detectors were triggered, after which, within each of the counted intervals, the participants use the identification signs of the subintervals as key elements, and the numbers of the triggered detectors as carriers of information on the secrecy of the transmission . Subsequent processing of the measurement results to retrieve the secret keys involves communication between participants through an open communication channel using a computer.

Brief Description of the Drawings

The invention is illustrated in FIG. 1, which shows an example of the implementation of the proposed method for generating private keys between two participants, where the following notation is used: 1 - laser, 2 - nonlinear optical crystal, 3 - frequency filter, 4-polarization beam splitter, 5, 6, 7, 8 - balanced beam splitters, 9, 10 - phase modulators, 11, 12, 13, 14 - single-photon detectors, 15, 16 - computers, 17, 18 - random electric pulse generators, 19 - open communication channel.

Disclosure of invention

The proposed method is as follows.

The continuous radiation of laser 1 pumps a nonlinear crystal 2, in which the phase-matching conditions are fulfilled for the use of a parametric optical process that implements the generation of time-mixed photon pairs with different polarizations. The generated pair of beams of time-confused photons enters the spectral filter 3, which selects narrow lines in the frequency spectrum near the carrier frequencies. Different polarization of entangled photons allows you to separate the corresponding beams in space by a polarizing beam splitter 4. Next, each of the beams is sent to the participants of communication.

Each participant has one interferometer composed of two balanced beam splitters - 5, 6 and 7, 8, which spatially divide the incident beams into two parts of equal intensity regardless of their polarization, and optical paths (arms of the interferometer) realized by free propagation or using fiber optic propagation from one beam splitter to another. In each of the interferometers, the lengths of the two paths connecting the output and input ports of the respective beam splitters are strictly fixed. Modulators of phases 9 and 10 are introduced into one of the arms of each interferometer, which change the phase of the beam entering it by an amount proportional to the voltage applied to it. At the exits from the interferometers, single photon detectors 11, 12, 13, 14 are placed, which are triggered if one photon falls on them. The signals from the detectors in the form of electrical pulses are sent to the computers of participants 15, 16. Random phase pulses from the random pulse generators 17 and 18, respectively, are supplied to the phase 9 and 10 modulators, with such voltage that the modulators change the phases to -π or π, thus the effective length of each of the arms is randomly modulated over time. The generators 17 and 18 are connected to the computers of the participants, which set the frequency and time of generating random pulses for modulators of phase 9, 10.

Each of the computers has a clock, which makes it possible to put time reports in accordance with the pulses from the detectors. The clock in the computer device has an accuracy sufficient to resolve in time all incoming pulses from the detectors. Let τ denote the minimum time between successive pulses that a computer clock can resolve. Then the maximum signal refresh rate that participants can work with is f = 1 / τ. The devices of the subscribers' clocks are synchronized with each other using communication over an open communication channel 19.

The pump level of nonlinear crystal 2 is such that time-confused photon pairs are generated on average with a frequency f _PAIRS = 1 / T, where T is the average time between the events of photon pair production, and T >> τ (f _PAIRS << f). At the same time, the moments of time of birth of photon pairs are random, i.e. they do not follow each other regularly at approximately equal intervals. According to the proposed method, participants pre-select the length of the time interval T ₀ > τ, a multiple of τ: T ₀ = Mτ, where M is the number of sub-intervals. When implementing the method in the circuit depicted in FIG. 1, the computers of the participants synchronously, one after the other, count time intervals T ₀ and measure the time of arrival of pulses from the detectors within each of these intervals. In order to generate no more than one entangled pair on the selected interval T ₀ , it is advisable to choose T ₀ ≥T.

Consider the actions of subscribers in the interval of one time window T ₀ . When a photon is detected and an electric pulse arrives at a computer at some random time t = lτ within T ₀ (l≤M), the corresponding subscriber writes the key number value equal to 1. The number of the triggered detector is also recorded in the table. After the lapse of the time T ₀ begins a new time window length T _0, and the procedure is repeated again. Thus, sequences of numbers are formed, which are then involved in the formation of secret keys by mathematical methods from known methods of quantum key distribution using computers and communication over an open communication channel 19.

In the proposed method, the processing of information to obtain secret keys is carried out in two stages. Firstly, the correlation between the triggered detectors of different participants is analyzed, as in the well-known methods of KRC (quantum key distribution), this allows you to determine the level of information leakage to third parties, i.e. allows you to evaluate the secrecy of the transfer - based on these estimates, at the second stage, mathematical algorithms with optimal parameters are used. Secondly, on the basis of the obtained estimates, mathematical procedures for correcting errors and increasing secrecy are carried out. Both of these stages of the proposed method are carried out with the exchange of information between participants through an open channel 19. As a result, in the proposed method, absolutely secret keys are distributed between the participants.

Due to the entanglement between the photons of the entangled pairs, the proposed method has a) a correlation between the triggering of pairs of detectors belonging to different participants, b) a correlation of the response times of the detectors of different participants due to the simultaneous production of pairs, and c) randomness of the response times of the detectors due to the random generation of the pairs. In the known CRC methods based on time-reversed photon pairs, only circumstances a) and b) are used to generate the key, while circumstance c) is also used in the proposed method. So, in the closest analogue of the proposed method, information about the keys is obtained only on the basis of information about which detector of each pair has worked. In this method, the triggering of a specific detector for each participant corresponds to the corresponding key element, and the transmission secrecy analysis is also carried out using this information about the triggering of the detectors.

The proposed method allows to increase the speed of distribution of secret keys, because in the proposed method, each of the measured photon pairs carries M bits of information, while in the known method a photon pair carries no more than 1 bit of information. Thus, when using the same sources of time-confused photons in the proposed method, the generation rate is M times higher in comparison with the known close analogue. As parametric optical processes for obtaining time-mixed pairs of photons, for example, processes of spontaneous parametric scattering (SPR) and four-wave mixing can be used. Known modern methods for producing time-confused photon pairs allow the generation of photon pairs with speeds of ~ 1 MHz [C.-S. Chuu, S.E. Harris, Ultrabright backward-wave biphoton source, Phys. Rev. A, v. 83, 061803 (2011)].

Consider a specific example of evaluating the effect of accelerating the generation of secret keys by the proposed method. Let the photons from the entangled pairs be distributed between the participants via fiber optic communication channels. It is known that the minimum loss in such communication channels is 0.2 dB / km. The length of each of the fiber optic channels going from the source of the photon pairs to the participant in the communication is 50 km. Assuming the intrinsic noise of single-photon detectors to be 500 Hz, and the length of each of the fiber-optic channels going from the source of the photon pairs to the participant in communication equal to 50 km, we obtain an estimate for the maximum possible M = 9.

Claims (2)

1. A method for generating secret keys using time-confused photon pairs, including distributing photons between time-confused photon pairs between two participants in transmitting secret keys, further converting these photons by participants' interferometers, detecting them with single photon detectors, and then processing the measurement results with a computer , including communication between participants through an open communication channel, characterized in that it further establish agreed between the participant and the time interval in which the separation is carried out on M equal subintervals and the subintervals determined in which participants are triggered single photon detectors, after which the numbers of the sub-slots are used as parts of keys. 2. The method according to p. 1, characterized in that as open channels using telephone communications and / or the Internet, and / or acoustic communication channels.