阅读说明：本技术 基于空间分集技术的自由空间连续变量量子密钥分发系统及其实现方法 (Free space continuous variable quantum key distribution system based on space diversity technology and implementation method thereof ) 是由 王一军 胡竣凯 黎胤 毛育昊 莫伟 周正春 郭迎 胡利云 于 2021-07-20 设计创作，主要内容包括：本发明公开了一种基于空间分集技术的自由空间连续变量量子密钥分发系统及其实现方法,所述系统包括发送端、传输信道和接收端,发送端将光信号进行振幅与相位调整,然后将光信号进行衰减,通过发送端准直器由光纤传输进入大气传输,所述接收端通过第二准直器、第四准直器、第六准直器接收光信号,并对其处理检测后,经过后续的反向协商和私密放大获得安全量子密钥,并检查是否被监听；通过采用多输入多输出(MIMO)的方法,可以同时发送多波段相同信息,保证信息传输,从而有效地改善大气湍流效应对系统所造成过噪声以及信号衰减的影响,提高了安全密钥率。(The invention discloses a free space continuous variable quantum key distribution system based on space diversity technology and a realization method thereof, wherein the system comprises a sending end, a transmission channel and a receiving end, the sending end adjusts the amplitude and the phase of an optical signal, then attenuates the optical signal, the optical signal is transmitted into the atmosphere through an optical fiber by a collimator of the sending end, the receiving end receives the optical signal through a second collimator, a fourth collimator and a sixth collimator, and after the optical signal is processed and detected, a safe quantum key is obtained through subsequent reverse negotiation and privacy amplification, and whether the safe quantum key is monitored or not is checked; by adopting a multiple-input multiple-output (MIMO) method, multiband same information can be sent simultaneously, and information transmission is ensured, so that the influence of excessive noise and signal attenuation caused by an atmospheric turbulence effect on a system is effectively improved, and the security key rate is improved.)

1. The free space continuous variable quantum key distribution system based on the space diversity technology is characterized by comprising a sending end, a transmission channel and a receiving end;

the transmitting end comprises:

the first laser, the second laser and the third laser are used for generating coherent light and sending the generated coherent light to the first electro-optic intensity modulator, the second electro-optic intensity modulator and the third electro-optic intensity modulator;

three FPGA data generating cards of a sending end generate Rayleigh distribution analog signals and uniform distribution analog signals, and then the Rayleigh distribution analog signals are respectively sent to three electro-optical intensity modulators of the sending end, and the uniform distribution analog signals are sent to three electro-optical phase modulators of the sending end;

the first electro-optical intensity modulator, the second electro-optical intensity modulator and the third electro-optical intensity modulator are used for receiving optical signals output by the first laser, the second laser and the third laser, performing pulse modulation on the optical signals, outputting pulse coherent optical signals with certain frequency and sending the pulse coherent optical signals to the corresponding first electro-optical phase modulator, the second electro-optical phase modulator and the third electro-optical phase modulator;

the first electro-optical phase modulator, the second electro-optical phase modulator and the third electro-optical phase modulator are used for carrying out phase modulation on optical signals output by the first electro-optical intensity modulator, the second electro-optical intensity modulator and the third electro-optical intensity modulator and then transmitting the optical signals to the corresponding attenuator of the transmitting end;

the transmitting end attenuator is used for further attenuating the optical signal output by the electro-optical phase modulator;

the first collimator, the third collimator and the fifth collimator are used for switching the optical signals in the optical fiber to be transmitted in a free space and adjusting light beams to be aligned to the second collimator, the fourth collimator and the sixth collimator at the receiving end;

the transmission channel is a transmission medium formed by free space and is based on quantum communication of space diversity in the free space;

the receiving end includes:

the second collimator, the fourth collimator and the sixth collimator are used for receiving optical signals, converting the collected optical signals into optical fibers for transmission and transmitting the optical fibers to corresponding homodyne detectors;

the homodyne detector is used for carrying out homodyne detection on the optical signals and inputting the detected optical signals with different frequencies into the electric combiner;

the electrical combiner combines the optical signals with different frequencies output by the homodyne detector and then inputs the optical signals into the quantizer;

the quantizer is used for converting the input optical signals into 0 and 1 logic signals and transmitting the logic signals to the FPGA data acquisition card at the receiving end;

and the receiving end FPGA data acquisition card is used for receiving the detection result generated by the detection end quantizer.

2. The free-space continuous variable quantum key distribution system based on the space diversity technology as claimed in claim 1, wherein the laser employs a Thorlabs OPG1015 picosecond optical pulse generator, which can generate laser pulses with a frequency of 10GHz and a frequency of less than or equal to 3 ps; the electro-optical intensity modulator is an electro-optical intensity modulator with the model number of MX-LN-10; the electro-optical phase modulator is an electro-optical phase modulator of model MPZ-LN-10; the attenuator adopts a polarization-maintaining adjustable laser attenuator of VOA780 PM-FC.

3. The free space continuous variable quantum key distribution system based on the space diversity technology as claimed in claim 1, wherein Xilinx VC707 is adopted by the sending end FPGA data generation card and the receiving end FPGA data acquisition card, and the sampling rate can reach up to 5 GSa/s; the collimator adopts a PAF2-7A fiber collimator with an aspheric lens.

4. The free-space continuous variable quantum key distribution system based on the space diversity technology as claimed in claim 1, wherein the homodyne detector is a balanced amplification photo-detector model PDA 435A; the electric combiner is a three-in one-out device with the model number of JCDUP-8024.

5. The implementation method of the free space continuous variable quantum key distribution system based on the space diversity technology is characterized by comprising the following steps:

step 1): a first laser, a second laser and a third laser at a sending end generate analog electric signals of modulation signals, and a first electro-optical intensity modulator, a second electro-optical intensity modulator and a third electro-optical intensity modulator receive the analog electric signals of the modulation signals output by a signal source and perform amplitude modulation on received coherent laser; the optical signal is modulated into a pulse optical signal by a first electro-optical intensity modulator, a second electro-optical intensity modulator and a third electro-optical intensity modulator;

step 2): the FPGA data generation card generates a uniform random number set {0,1,2,3, …, N-1}, and sends the random number set to the electro-optical phase modulator; the first electro-optic phase modulator, the second electro-optic phase modulator and the third electro-optic phase modulator perform phase modulation on the optical signals output by the electro-optic intensity modulator, and satisfy that V is more than or equal to 0 and less than or equal to 2V_πWhere V is the modulation variance of the optical signal, V_πFor the phase modulation threshold of optical signals passing through an electro-optic phase modulator, the optical phase of the signals is [0,2 pi ]]The electro-optical phase modulator obtains different types of discrete quantum state sets S by randomly selecting different random numbers k generated by the FPGA data generation card_N＝{|Ae^iπ/N>,…,|Ae^(2k+1)iπ/N>Wherein i is an imaginary number, A is an amplitude, the value of the phase component satisfies (2k +1) pi/N, e is a modulation phase of a discrete quantum state, and the modulation phase is subjected to electro-optical intensity modulationThe optical signal modulated by the modulator and the electro-optical phase modulator is in a Gaussian coherent state | X + jP>That is, the orthogonal component X and the orthogonal component P of the optical field of the signal light obey gaussian distribution, where j is an imaginary part of the modulated quantum state, X is Acos θ, P is Asin θ, X is the amplitude of the signal, P is the phase of the signal, and θ is the phase of the regular component;

step 3): then the first attenuator, the second attenuator and the third attenuator further attenuate the optical signal; the attenuated optical signals respectively aim at the first collimator, the third collimator and the fifth collimator to enter atmosphere for transmission, and enter atmosphere for transmission through optical fiber transmission;

step 4): detecting the signal light at a receiving end by using a homodyne detection technology, which specifically comprises the following steps:

the optical signal is received by a second collimator, a fourth collimator and a sixth collimator at a receiving end, then homodyne detection is carried out on the orthogonal component P by a homodyne detector, information post-processing is carried out by an electric combiner, and finally the optical signal is input into a quantization controller, an electric signal is converted into a digital signal, and finally an output signal is sent to a receiving end FPGA data acquisition card; after subsequent reverse negotiation and privacy amplification processes, a sending end and a receiving end can obtain a group of same keys, a part of the measured values of the orthogonal component X and the orthogonal component P is used for safety estimation to obtain the transmittance, the over-noise and the estimated value of the safety key rate of a channel, whether an eavesdropper exists or not is determined according to the transmittance and the over-noise of the channel, if not, key negotiation is carried out, and a group of safety quantum keys are respectively obtained at the sending end and the receiving end; and if the security key rate is lower than zero in the current communication distance, the system is determined to be insecure, an eavesdropper exists, the key establishment should be stopped, and the insecure information of the system is sent to the key negotiation module.

6. The method of claim 5, wherein the electro-optical intensity modulator modulates the pulsed optical signal to a frequency of 10 MHz.

7. The method of claim 5, wherein the attenuator attenuates photons per pulse to 10⁸A photon; and each signal received by the second collimator, the fourth collimator and the sixth collimator is required to be greater than 20 dB.

Technical Field

The invention belongs to the technical field of free space quantum key distribution, and relates to a free space continuous variable quantum key distribution system based on a space diversity technology and an implementation method thereof.

Background

There has been extensive research and study on the transmission of continuous quantum key distribution systems over fiber and over the air to submarine channels. In different transmission channels, the channel characteristics and the transmission characteristics are different, and at present, because of the dispersion and refraction effects of light in a free space, a continuous variable quantum key distribution system has small transmission transmissivity and low efficiency, so that the transmission distance of an actual system is short.

At present, methods widely adopted to solve the problem of air refractive index change include maximum ratio combination, equal gain combination and the like, wherein channel gain obtained by the maximum ratio combination method is in direct proportion to irradiance of received light, and then combined signal intensity is obtained by summing through a weighted signal method. The method is optimal at present, but because the state information of the channel is needed and the actual free space is often influenced by various factors such as weather, rainfall, temperature and the like, the estimation of the channel information is obviously difficult to realize; the equal gain combined output method does not need to estimate irradiance of each light path branch, and not only is the actual realization simpler, but also the performance is close to that of the maximum ratio combined method.

Disclosure of Invention

The invention provides a free space continuous variable quantum key distribution system based on a space diversity technology and a realization method thereof, which solve the problem that when the continuous variable quantum key distribution system transmits in a free space, the transmission transmissivity of the continuous variable quantum key distribution system is small due to light dispersion and refraction, the efficiency is low, and the transmission distance of an actual system is short; the invention also provides a solution for solving the problem of how to apply the diversity technology (MIMO) to the continuous variable quantum key distribution system and how to send multiple sending ends and multiple receiving ends to send the received optical signals simultaneously in the process, and solves the problems of low transmission efficiency in free space and low transmissivity caused by serious light scattering.

The technical scheme adopted by the invention is a free space continuous variable quantum key distribution system based on a space diversity technology, which comprises a sending end, a transmission channel and a receiving end;

the transmitting end comprises:

the first laser, the second laser and the third laser are used for generating coherent light and sending the generated coherent light to the first electro-optic intensity modulator, the second electro-optic intensity modulator and the third electro-optic intensity modulator;

three FPGA data generating cards of a sending end generate Rayleigh distribution analog signals and uniform distribution analog signals, and then the Rayleigh distribution analog signals are respectively sent to three electro-optical intensity modulators of the sending end, and the uniform distribution analog signals are sent to three electro-optical phase modulators of the sending end;

the first electro-optical intensity modulator, the second electro-optical intensity modulator and the third electro-optical intensity modulator are used for receiving optical signals output by the first laser, the second laser and the third laser, performing pulse modulation on the optical signals, outputting pulse coherent optical signals with certain frequency and sending the pulse coherent optical signals to the corresponding first electro-optical phase modulator, the second electro-optical phase modulator and the third electro-optical phase modulator;

the first electro-optical phase modulator, the second electro-optical phase modulator and the third electro-optical phase modulator are used for carrying out phase modulation on optical signals output by the first electro-optical intensity modulator, the second electro-optical intensity modulator and the third electro-optical intensity modulator and then transmitting the optical signals to the corresponding attenuator of the transmitting end;

the transmitting end attenuator is used for further attenuating the optical signal output by the electro-optical phase modulator;

the first collimator, the third collimator and the fifth collimator are used for switching the optical signals in the optical fiber to be transmitted in a free space and adjusting light beams to be aligned to the second collimator, the fourth collimator and the sixth collimator at the receiving end;

the transmission channel is a transmission medium formed by free space and is based on quantum communication of space diversity in the free space;

the receiving end includes:

the second collimator, the fourth collimator and the sixth collimator are used for receiving optical signals, converting the collected optical signals into optical fibers for transmission and transmitting the optical fibers to corresponding homodyne detectors;

the homodyne detector is used for carrying out homodyne detection on the optical signals and inputting the detected optical signals with different frequencies into the electric combiner;

the electrical combiner combines the optical signals with different frequencies output by the homodyne detector and then inputs the optical signals into the quantizer;

the quantizer is used for converting the input optical signals into 0 and 1 logic signals and transmitting the logic signals to the FPGA data acquisition card at the receiving end;

and the receiving end FPGA data acquisition card is used for receiving the detection result generated by the detection end quantizer.

Furthermore, the laser adopts a Thorlabs OPG1015 picosecond optical pulse generator, and can generate laser pulses with the frequency of 10GHz and the frequency of less than or equal to 3 ps; the electro-optical intensity modulator is an electro-optical intensity modulator with the model number of MX-LN-10; the electro-optical phase modulator is an electro-optical phase modulator of model MPZ-LN-10; the attenuator adopts a polarization-maintaining adjustable laser attenuator of VOA780 PM-FC.

Furthermore, Xilinx VC707 is adopted by the FPGA data generation card at the sending end and the FPGA data acquisition card at the receiving end, and the sampling rate can reach 5GSa/s at most; the collimator adopts a PAF2-7A fiber collimator with an aspheric lens.

Further, the homodyne detector adopts a balanced amplification photoelectric detector with the model number of PDA 435A; the electric combiner is a three-in one-out device with the model number of JCDUP-8024.

Another technical scheme adopted by the invention is a method for realizing a free space continuous variable quantum key distribution system based on a space diversity technology, which is characterized by comprising the following steps:

step 1): a first laser, a second laser and a third laser at a sending end generate analog electric signals of modulation signals, and a first electro-optical intensity modulator, a second electro-optical intensity modulator and a third electro-optical intensity modulator receive the analog electric signals of the modulation signals output by a signal source and perform amplitude modulation on received coherent laser; the optical signal is modulated into a pulse optical signal by a first electro-optical intensity modulator, a second electro-optical intensity modulator and a third electro-optical intensity modulator;

step 2): the FPGA data generation card generates a uniform random number set {0,1,2,3, …, N-1}, and sends the random number set to the electro-optical phase modulator; the first electro-optic phase modulator, the second electro-optic phase modulator and the third electro-optic phase modulator perform phase modulation on the optical signals output by the electro-optic intensity modulator, and satisfy that V is more than or equal to 0 and less than or equal to 2V_πWherein V is the modulation variance of the optical signal, V_πFor the phase modulation threshold of optical signals passing through an electro-optic phase modulator, the optical phase of the signals is [0,2 pi ]]The electro-optical phase modulator obtains different types of discrete quantum state sets S by randomly selecting different random numbers k generated by the FPGA data generation card_N＝{|Ae^iπ/N>,…,|Ae^(2k+1)iπ/N>And f, wherein i is an imaginary number, A is an amplitude, the value of the phase component meets (2k +1) pi/N, e is a modulation phase of a discrete quantum state, and the modulation phase is modulated by an electro-optic intensity modulator and an electro-optic phase modulatorThe optical signal after being processed is in Gaussian coherent state | X + jP>That is, the orthogonal component X and the orthogonal component P of the optical field of the signal light obey gaussian distribution, where j is an imaginary part of the modulated quantum state, X is Acos θ, P is Asin θ, X is the amplitude of the signal, P is the phase of the signal, and θ is the phase of the regular component;

step 3): then the first attenuator, the second attenuator and the third attenuator further attenuate the optical signal; the attenuated optical signals respectively aim at the first collimator, the third collimator and the fifth collimator to enter atmosphere for transmission, and enter atmosphere for transmission through optical fiber transmission;

step 4): detecting the signal light at a receiving end by using a homodyne detection technology, which specifically comprises the following steps:

the optical signal is received by a second collimator, a fourth collimator and a sixth collimator at a receiving end, then homodyne detection is carried out on the orthogonal component P by a homodyne detector, information post-processing is carried out by an electric combiner, and finally the optical signal is input into a quantization controller, an electric signal is converted into a digital signal, and finally an output signal is sent to a receiving end FPGA data acquisition card; after subsequent reverse negotiation and privacy amplification processes, a sending end and a receiving end can obtain a group of same keys, a part of the measured values of the orthogonal component X and the orthogonal component P is used for safety estimation to obtain the transmittance, the over-noise and the estimated value of the safety key rate of a channel, whether an eavesdropper exists or not is determined according to the transmittance and the over-noise of the channel, if not, key negotiation is carried out, and a group of safety quantum keys are respectively obtained at the sending end and the receiving end; and if the security key rate is lower than zero in the current communication distance, the system is determined to be insecure, an eavesdropper exists, the key establishment should be stopped, and the insecure information of the system is sent to the key negotiation module.

Further, the electro-optical intensity modulator is used for modulating the pulse optical signal to 10 MHz.

Further, the attenuator attenuates photons per pulse to 10⁸A photon; and each signal received by the second collimator, the fourth collimator and the sixth collimator is required to be greater than 20 dB.

The invention has the beneficial effects that: the invention provides a free space continuous variable quantum key distribution system based on a space diversity technology, which adopts a multi-input multi-output (MIMO) method, namely a multi-sending end and a multi-receiving end, specifically three sending ends and three receiving ends, wherein the receiving ends use a homodyne detector for detection, and can simultaneously send multi-band same information under the condition of fully utilizing each frequency spectrum resource, so that the information transmission is ensured, and the influence of over-noise and signal attenuation caused by an atmospheric turbulence effect on the system is effectively improved.

The amplitude or phase component of each optical fiber channel coherent state is simultaneously subjected to parameter estimation through a plurality of homodyne detectors, the fact that a traditional diversity technology lattice has extremely high spectrum utilization efficiency is guaranteed, on the basis of fully utilizing existing spectrum resources, gains in two aspects of reliability and effectiveness are obtained through utilizing space resources, the influence of various factors of the atmosphere on a system in a free space can be reduced through detecting the coherent states through the optical fiber channels in the MIMO technology, and therefore the method improves the safe secret key rate.

On the basis, the application of a method for selecting combination in a continuous variable quantum key system is provided, the received signal is sampled, and the branch with the highest signal-to-noise ratio is selected for signal detection. The output is then only equal to the signal on one of the branches, instead of a coherent superposition of the single light streams like the two methods described above.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic diagram of a free space continuous variable quantum key distribution system based on space diversity technology according to an embodiment of the present invention;

fig. 2 is a detailed schematic diagram of a quantum key transmitting end, a quantum key receiving end and a quantum key detecting end according to an embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1-2, the system for distributing a free space continuous variable quantum key based on a space diversity technique includes a transmitting end, a transmission channel, and a receiving end, where the transmitting end includes a first laser, a second laser, and a third laser, and the first laser, the second laser, and the third laser are used to generate coherent light and send the generated coherent light to a corresponding first electro-optical intensity modulator, a second electro-optical intensity modulator, and a third electro-optical intensity modulator;

the method comprises the steps that a sending end FPGA data generation card generates Rayleigh distribution analog signals and uniform distribution analog signals, then the Rayleigh distribution analog signals are sent to a sending end electro-optic intensity modulator, and the uniform distribution analog signals are sent to a sending end electro-optic phase modulator;

the first electro-optical intensity modulator, the second electro-optical intensity modulator and the third electro-optical intensity modulator are used for receiving optical signals output by the first laser, the second laser and the third laser, performing pulse modulation on the optical signals, outputting pulse coherent optical signals with a certain frequency and sending the pulse coherent optical signals to the corresponding first electro-optical phase modulator, the second electro-optical phase modulator and the third electro-optical phase modulator;

the first electro-optic phase modulator, the second electro-optic phase modulator and the third electro-optic phase modulator are used for carrying out phase modulation on optical signals output by the first electro-optic intensity modulator, the second electro-optic intensity modulator and the third electro-optic intensity modulator and then transmitting the optical signals to the attenuator at the transmitting end;

after being modulated by an electro-optic intensity modulator and an electro-optic phase modulator, an optical signal presents a Gaussian coherent state;

the transmitting end attenuator is used for further attenuating the optical signal output by the electro-optical phase modulator; then, the optical signals in the optical fiber are switched to be transmitted in a free space through a first collimator, a third collimator and a fifth collimator, and the light beams are adjusted to be aligned to a second collimator, a fourth collimator and a sixth collimator at a receiving end;

the receiving end comprises a second collimator, a fourth collimator and a sixth collimator and is used for receiving optical signals, converting the acquired optical signals into optical fibers for transmission and transmitting the optical fibers to the detection end homodyne detector;

the detection end homodyne detector is used for carrying out homodyne detection on the optical signals and inputting the detected optical signals with different frequencies into the electric combiner;

the electrical combiner combines the optical signals with different frequencies output by the homodyne detector and then inputs the optical signals into the quantizer;

the quantizer is used for converting the input optical signals into 0 and 1 logic signals and transmitting the logic signals to the FPGA data acquisition card at the receiving end;

and the receiving end FPGA data acquisition card is used for receiving the detection result generated by the detection end quantizer.

The first laser, the second laser and the third laser adopt Thorlabs OPG1015 picosecond optical pulse generators, and can generate laser pulses with the frequency of 10GHz and the frequency of less than or equal to 3 ps;

the electro-optical intensity modulator at the sending end is an electro-optical intensity modulator with the model number of MX-LN-10;

the electro-optical phase modulator at the sending end adopts an electro-optical phase modulator of model MPZ-LN-10, has low loss and high bandwidth, can meet the requirement of quantum key secret communication, and reduces the loss caused by actual devices;

xilinx VC707 is adopted by the FPGA data generation card at the sending end and the FPGA data acquisition card at the receiving end, and the sampling rate can reach 5GSa/s at most;

the attenuator at the transmitting end adopts a VOA780PM-FC polarization-maintaining adjustable laser attenuator;

the optical fiber collimator with the aspheric lens is PAF2-7A, can be used for optical wavelength of 350-700nm, and is suitable for optical signal transmission in an atmospheric channel;

the transmission channel is a transmission medium formed by free space and is based on quantum communication of space diversity under the free space; the classical channel is a transmission medium consisting of classical wireless, wired or light;

the detection end homodyne detector adopts a balanced amplification photoelectric detector with the model number of PDA435A, the bandwidth is high (>350MHz), and the common mode rejection ratio is >20 dB;

the electric combiner is a three-in one-out device with the model number of JCDUP-8024, and crosstalk between signals is avoided. The effect of combining the electric signals for the subsequent data post-processing is realized;

the implementation method of the free space continuous variable quantum key distribution system based on the space diversity technology is specifically carried out according to the following steps:

step 1): a first laser, a second laser and a third laser at a sending end generate analog electric signals of modulation signals, and a first electro-optical intensity modulator, a second electro-optical intensity modulator and a third electro-optical intensity modulator receive the analog electric signals of the modulation signals output by a signal source and perform amplitude modulation on received coherent laser; the optical signal is modulated into a pulse optical signal by the first electro-optical intensity modulator, the second electro-optical intensity modulator and the third electro-optical intensity modulator, the electric signal is provided by a signal source, and the voltage amplitude is as follows: [0V,5V ], the electric pulse frequency is 10MHz, the modulated pulse optical signal frequency is 10 MHz;

step 2): the FPGA data generation card generates a uniform random number set {0,1,2,3, …, N-1}, and sends the random number set to the electro-optical phase modulator; the first electro-optic phase modulator, the second electro-optic phase modulator and the third electro-optic phase modulator perform phase modulation on the optical signals output by the electro-optic intensity modulator, and satisfy that V is more than or equal to 0 and less than or equal to 2V_πWhere V is the modulation variance of the optical signal, V_πFor the phase modulation threshold of optical signals passing through an electro-optic phase modulator, the optical phase of the signals is [0,2 pi ]]Internal tuning by randomly selecting FPGA dataGenerating different random numbers k generated by the card, the electro-optic phase modulator will obtain different kinds of discrete quantum state sets S_N＝{|Ae^iπ/N>，…，|Ae^(2k+1)iπ/N>And f, wherein i is an imaginary number, A is an amplitude, the value of the phase component meets (2k +1) pi/N, e is a modulation phase of a discrete quantum state, and an optical signal modulated by the electro-optic intensity modulator and the electro-optic phase modulator is in a Gaussian coherent state | X + jP>That is, the orthogonal component X and the orthogonal component P of the optical field of the signal light follow a gaussian distribution, where j is an imaginary part of a modulated quantum state, X is Acos θ, P is Asin θ, X is the amplitude of the signal, P is the phase of the signal, θ is the phase of a regular component, and the voltage ranges of the electrical signals are all [0V,5V [ ]]；

Step 3): then the first attenuator, the second attenuator and the third attenuator further attenuate the optical signal to 10 photons per pulse⁸A photon; the attenuated optical signals respectively aim at the first collimator, the third collimator and the fifth collimator to enter atmosphere for transmission, and enter atmosphere for transmission through optical fiber transmission;

step 4): detecting the signal light at a receiving end by using a homodyne detection technology, which specifically comprises the following steps:

the optical signals are received by the second collimator, the fourth collimator and the sixth collimator at the receiving end, and each signal needs to be larger than 20dB to ensure that crosstalk phenomenon does not occur among the signals. Then, a homodyne detector is used for carrying out homodyne detection on the orthogonal component P, then the information is post-processed through an electric combiner, and finally the information is input into a quantization controller, an electric signal is converted into a digital signal, and finally an output signal is sent to a receiving end FPGA data acquisition card; after subsequent reverse negotiation and privacy amplification processes, a sending end and a receiving end can obtain a group of same keys, a part of the measured values of the orthogonal component X and the orthogonal component P is used for safety estimation to obtain the transmittance, the over-noise and the estimated value of the safety key rate of a channel, whether an eavesdropper exists or not is determined according to the transmittance and the over-noise of the channel, if not, key negotiation is carried out, and a group of safety quantum keys are respectively obtained at the sending end and the receiving end; and if the security key rate is lower than zero in the current communication distance, the system is determined to be insecure, an eavesdropper exists, the key establishment should be stopped, and the insecure information of the system is sent to the key negotiation module.

The above description is only for the preferred embodiment of the present invention, and is not intended to limit the scope of the present invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention shall fall within the protection scope of the present invention.