WO2021096385A1 - Device for quantum sending of key on side frequencies - Google Patents

Abstract

The invention relates to optical communications, more particularly to photonic quantum communication systems. The technical problem addressed by the claimed device consists in decreasing the quantum error coefficient by reducing losses in a polarisation distortion compensation unit. The technical result of the claimed device consists in increasing the maximum distance for transferring quantum states. The technical result is achieved in that a receiving device comprises an electro-optical modulation unit with polarisation distortion compensation, which unit comprises a fibre polarisation beam splitter, two electro-optical phase modulators connected to two ports of the fibre polarisation beam splitter, and a fibre polarisation connector connected to the two electro-optical phase modulators.

Description

SIDE FREQUENCY QUANTUM KEY DISTRIBUTOR

The present invention relates to optical communication technology, namely, photonic quantum communication systems.

Known device for quantum distribution of symmetric bit sequences [US Patent 627 22 24 B1, priority date 07.04.2001. MKI: H04L 9/08; Н04К 1/00], containing a transmitting device connected by means of a fiber-optic communication line, including a source of monochromatic radiation, an electro-optical phase modulator and an attenuator located in series along the propagation of radiation, and a phase shift device, the output of which is connected to the control input of the electro-optical phase modulator, and the input of the phase shift device is connected to the output of the RF signal generator, and the receiving device including an electro-optical phase modulator, the output of which is optically coupled to a spectral filter, which is optically coupled to a classical radiation receiver and a single photon detector, the control input of the electro-optical phase modulator is connected to the output of the device phase shift, to the input of which the output of the RF signal generator is connected, the fiber-optic communication line is optically coupled with the attenuator of the transmitting device and with the input of the electro-optical phase module torus of the receiving device, the device contains a synchronization unit, the first and second outputs of which are connected to the inputs of the RF signal generator of the receiving and transmitting devices, respectively, as well as a phase shift control unit, the first and second outputs of which are connected to the synchronization inputs of the phase shifting device of the receiving and transmitting devices, respectively ...

Standard optical fiber used in fiber-optic communication lines exhibits birefringence, which is random in nature, including randomly depending on time. Electro-optical phase modulators used in fiber communication lines are sensitive to radiation polarization in a large number of cases. The sender unit can unambiguously inject phase into the signal directly emitted by its laser. However, when this signal is transmitted over a long fiber to the receiver unit, the polarization state may change unpredictably. In addition, the state of polarization can randomly depend on time. Since the electro-optical phase modulator in the receiver unit is also sensitive to the state of polarization of the radiation passing through it, the result of signal modulation from its side may randomly depend on time. Taking these circumstances into account, the presented device has the following disadvantages: a high rate of quantum errors, a low transmission rate of a secret cryptographic key and a low degree of security of a secret cryptographic key.

A device for quantum distribution of a cryptographic key is known, in which a polarization distortion compensation unit is implemented [Patent RU 2454810 C1]. In the receiving device, the polarization distortion compensation unit is made of two electro-optical phase modulators located along the radiation path, the control inputs of which are connected to the first and second outputs of the phase shift device, respectively, and the output of the first electro-optical phase modulator is optically coupled with the output of the second electro-optical phase modulator, after the modulators along In the course of radiation, a Faraday mirror is installed, which is optically coupled with the input of the second electro-optical phase modulator.

The presented device also has disadvantages. With a double pass of radiation in the polarization distortion compensation unit, losses are introduced, which, in turn, leads to an increase in the quantum error rate and to a decrease in the key distribution range.

The present invention solves the problem of reducing the quantum error rate, increasing the transmission rate of the secret cryptographic key and increasing the security of the secret cryptographic key by compensating for fiber birefringence and the polarization sensitivity of the modulator in the quantum key distribution system at modulated radiation subcarriers.

The task is solved in the following way. The new technical implementation of the receiver unit of the photonic quantum coupling device allows to reduce the rate of quantum errors by reducing losses in the polarization distortion compensation unit. The structure of the receiving unit between the electro-optical phase modulator and the spectral filter includes: a fiber polarizing beam splitter, a second electro-optical phase modulator, and fiber polarizing connector. The photonic quantum communication device is shown in the figure, 1 - laser, 2 - fiber optical isolator, 3, 6, 7 - electro-optical phase modulator, 4 - fiber optical attenuator, 5 - electronic control and synchronization unit of the sender unit, quantum channel - quantum communication channel , 8 - fiber polarizing beam splitter, 9 - fiber polarization connector, 10 - fiber spectral filter, 11 - single photon detector, 12 - electronic control and synchronization unit of the receiver unit, 13 - quantum channel for transmission of single photons, 14 - channel for transmission of classical synchronization signal from the radio-electronic unit of the transmitter to the radio-electronic unit of the receiver, 15 is an open communication channel for classical communication between the radio-electronic units of the receiver and the transmitter.

A fiber polarization beam splitter is installed in the polarization distortion compensation unit in the receiving device, the ports of which are coupled with two electro-optical phase modulators located along the radiation path, after which the modulated radiation is connected by means of a fiber polarization connector.

It should be noted that in the present disclosure, a sender unit may be called a transmitter, and a receiver unit may also be called a receiver, a receiver, or a receiver unit.

The principle of operation of the device: monochromatic radiation with a carrier frequency, generated by a source of monochromatic radiation, passing through a fiber optical isolator, enters an electro-optical modulator, where a light field is created at subcarriers with an arbitrarily specified phase offset relative to the phase of the carrier frequency. The phase offset is set in the electronic control and synchronization unit from a set of four basic states (for example, 0 °, 90 °, 180 °, 270 °) in two orthogonal bases. The phase offset contains the information transmitted from the transmitter to the receiver using single-photon states. Further, the radiation enters the attenuator, where it is attenuated to the level specified by the protocol (for example, 0.2 photons per phase modulation clock in total at the side frequencies). After passing through the quantum channel, the radiation enters the receiver unit and enters the polarization distortion compensation unit. The fundamental principle of this polarization distortion compensation unit is the separation of the signal coming from the communication line into two orthogonal polarization components for subsequent modulation of each polarization mode directly. This is achieved through the use of a 50/50 polarizing fiber beam splitter. The use of special polarization-preserving fibers in this device reduces the risk of polarization reversal of the separated signals. The connection of the polarizing beam splitter and the electro-optical modulators is performed in such a way that the polarization axes of the radiation emerging from the polarizing beam splitter coincide with the axes of the crystals of the electro-optical modulators. After re-modulation, interference occurs between the two states of the photon at the subcarriers created in the sender and receiver.

Then the radiation is collected by a fiber polarizing connector into one fiber and enters the spectral filter, where it is cleaned of the rest of the spectral components. After spectral cleaning, the result of interference at subcarriers, passing through a spectral filter, is recorded using a single photon detector and processed in the electronic control and synchronization unit of the receiver unit. Further, in accordance with the protocol, on the basis of the collected data, the electronic units of the sender and receiver, using an open channel, carry out a procedure for forming symmetric bit sequences, which includes the stage of sifting along the bases, in which the detector triggers that occurred during phase modulation in different bases are discarded, the formation a raw bit sequence based on the numbers of the bases in the time intervals when constructive interference occurred, the calculation of the error rate and the procedure for cleaning from errors and enhancing the secrecy. Also, electronic control and synchronization units provide synchronous operation of the sender and receiver units through the optical synchronization channel.

The technical problem of the proposed device is to reduce the quantum error rate by reducing losses in the polarization distortion compensation unit. The technical result of the proposed device is to increase the maximum transmission range of quantum states. The technical result is achieved by the fact that the receiver contains a fiber

four

ISA / RU

FIXED SHEET (RULE 91.1) a polarizing beam splitter, a second electro-optical modulator (when compared with known devices) and a fiber polarizing connector, i.e. is achieved by the fact that the receiving device contains an electro-optical modulation unit with compensation for polarization distortions, which contains a fiber polarizing beam splitter, two electro-optical phase modulators connected to two ports of the fiber polarizing beam splitter, and a fiber polarizing connector connected to two electro-optical phase modulators.

The present invention is not limited to the specific variants disclosed in the description for illustrative purposes, and covers all possible modifications and alternatives falling within the scope of the present invention defined by the claims.

Claims

CLAIM 1. A device for transferring quantum states with a polarization distortion compensation unit containing a transmitting device that contains a source of monochromatic radiation, a fiber optical isolator connected to a monochromatic radiation source, an electro-optical phase modulator connected to a fiber optical isolator, an optical attenuator connected to an electro-optical phase modulator, and an electronic control and synchronization unit connected to the electro-optical phase modulator, and a receiving device that contains a spectral filter connected to an electro-optical modulation unit with polarization distortion compensation, a single photon detector connected to a spectral filter, and the receiving device is connected to the transmitting device via a quantum channel, a synchronization channel and an open channel, and the receiving device also contains an electro-optical modulation unit with compensation for polarization x distortion, which contains a fiber polarizing beam splitter, two electro-optical phase modulators connected to two ports of the fiber polarizing beam splitter, and a fiber polarizing coupler connected to two electro-optical phase modulators. 2. The device according to claim. 1, in which the electronic control and synchronization unit is configured to set the phase offset from a set of four basic states in two orthogonal bases. 3. The device according to claim 1, in which the optical attenuator is configured to attenuate radiation to a level specified by the protocol per phase modulation clock in total at the side frequencies. 4. The device according to claim 1, in which the fiber polarizing beam splitter of the electro-optical modulation unit with compensation for polarization distortion has a division ratio of 50/50 for dividing the signal coming from the communication line into two orthogonal polarization components.