CN117810803A - Microwave pulse generating system, method and storage medium - Google Patents

Abstract

The invention relates to the technical field of microwave photonics and discloses a microwave pulse generation system, method and storage medium. The system modulates the modulated microwave signal transmitted by the radio frequency signal source to an optical carrier through a modulator to form a modulated optical signal; through a saturable absorber Perform nonlinear absorption of the modulated optical signal and output the absorbed optical signal; feed back part of the filtered microwave signal to the modulator through the electrical coupler, and output the other part of the filtered microwave signal; after receiving the electrical coupling After the microwave signal fed back by the electrical coupler is modulated to the optical carrier through the modulator, a modulated optical signal is formed. Through the modulation of the modulator and the passive mode-locking nonlinear loss absorption of the saturable absorber, the response in the time domain is The pulse of the microwave signal is compressed to solve the problem of excessive pulse width in traditional photoelectric oscillators and achieve stable narrow pulse microwave output.

Description

Microwave pulse generation system, method and storage medium

Technical field

The present invention relates to the field of microwave photon technology, and in particular to a microwave pulse generation system, method and storage medium.

Background technique

The optoelectronic oscillator uses an optoelectronic hybrid resonant cavity to replace the traditional microwave resonant cavity. Thanks to the electro-optical modulation technology and the low loss characteristics of optical fiber, a closed-loop circuit with a high quality factor is achieved, and the quality factor of the optoelectronic hybrid resonant cavity does not increase with the increase of the oscillation frequency. Reduction is considered to be an excellent solution for future microwave signal generation. The working principle of the optoelectronic oscillator is based on the principle of positive feedback, that is, the oscillation signal is fed back to the input end through the optoelectronic hybrid path to form a closed loop. Specifically, the photodetector in the photoelectric oscillator converts the optical signal into an electrical signal. After the electrical signal is amplified by an electrical amplifier and filtered by an electrical bandpass filter, it is fed back to the input end through the electro-optical modulator, and is compared with the original oscillation signal. The coupling generates a new oscillating signal, thus forming a cycle of oscillation. When the open-loop gain of the optoelectronic oscillator is greater than 1 and the oscillation signal meets the phase matching conditions, a stable microwave signal can be obtained. However, traditional optoelectronic oscillators can only generate continuous microwave signals with a single frequency, which are not suitable for some special application scenarios such as Doppler radar. In order to meet the requirements for microwave narrow pulse sequences in applications such as Doppler radar, the Chinese invention patent with the publication number CN 111342332A discloses an active mode-locked optoelectronic oscillator, the publication number is CN 1 1 4 2 8 4 8 3 9A The Chinese invention patent discloses an active mode-locked optoelectronic oscillator based on injection locking to generate microwave pulses. However, the width of the microwave pulse signal generated by the above two schemes is limited by the frequency of the microwave signal injected externally into the optoelectronic oscillator. For high-resolution radar, the microwave pulses generated by the existing active mode-locked optoelectronic oscillator still have the problem that the pulse is too wide. problem, the existing technical solutions are in urgent need of optimization and improvement.

Summary of the invention

The present invention provides a microwave pulse generation system, method and storage medium, which can solve the problem of excessively wide pulse width of microwave pulses generated by existing photoelectric oscillators.

In a first aspect, a microwave pulse generating system is provided, the system comprising a laser, a modulator, a saturable absorber, a photodetector, an electric amplifier, an electric bandpass filter, an electric coupler and a radio frequency signal source, wherein the laser, the modulator, the saturable absorber, the photodetector, the electric amplifier, the electric bandpass filter and the electric coupler are connected in sequence, and the electric coupler is connected to the modulator to form a closed photoelectric oscillation loop, and the modulator is also connected to the radio frequency signal source; wherein,

The laser is used to generate optical carrier waves;

The radio frequency signal source is used to generate a modulated microwave signal to modulate the optical carrier;

The modulator is used to modulate the modulated microwave signal transmitted by the radio frequency signal source to the optical carrier to form a modulated optical signal;

The saturable absorber is used to perform nonlinear absorption on the modulated optical signal and output the optical signal after absorption processing;

The photodetector is used to photoelectrically convert the absorbed light signal to form a photocurrent and output a microwave signal;

The electrical amplifier is used to amplify the microwave signal output by the photodetector and output the amplified microwave signal;

The electrical bandpass filter is used to filter the amplified microwave signal and output the filtered microwave signal;

The electrical coupler is used to feed back a part of the filtered microwave signal to the modulator and output the other part of the filtered microwave signal;

The modulator is also configured to modulate the modulated microwave signal transmitted by the radio frequency signal source and the microwave signal fed back by the electrical coupler to the optical carrier after receiving the microwave signal fed back by the electrical coupler, A modulated light signal is formed.

In a second aspect, a method for generating microwave pulses is provided.

Applied to a microwave pulse generation system, the system includes a laser, a modulator, a saturable absorber, a photodetector, an electrical amplifier, an electrical bandpass filter, an electrical coupler and a radio frequency signal source, the laser, the modulator , the saturable absorber, the photodetector, the electrical amplifier, the electrical bandpass filter and the electrical coupler are connected in sequence, and the electrical coupler is connected to the modulator to form A closed optoelectronic oscillation circuit, the modulator is also connected to a radio frequency signal source; the method includes:

generating an optical carrier wave by means of the laser;

The radio frequency signal source generates a modulated microwave signal to modulate the optical carrier;

Modulate the modulated microwave signal transmitted by the radio frequency signal source to the optical carrier through the modulator to form a modulated optical signal;

performing nonlinear absorption on the modulated optical signal through the saturable absorber, and outputting the optical signal after absorption processing;

The photodetector conducts photoelectric conversion of the absorbed light signal to form a photocurrent, and outputs a microwave signal;

The microwave signal output by the photodetector is amplified through the electrical amplifier, and the amplified microwave signal is output;

Filter the amplified microwave signal through the electrical bandpass filter and output the filtered microwave signal;

Feed back a part of the filtered microwave signal to the modulator through the electrical coupler, and output the other part of the filtered microwave signal;

After receiving the microwave signal fed back by the electrical coupler, the modulated microwave signal transmitted by the radio frequency signal source and the microwave signal fed back by the electrical coupler are modulated to the optical carrier through the modulator to form modulated light. Signal.

In a third aspect, a computer-readable storage medium is provided. The computer-readable storage medium stores a computer program. When the computer program is executed by a processor, the steps of the above microwave pulse generation method are implemented.

In the solution implemented by the above microwave pulse generation system, method and storage medium, an optical carrier is generated through a laser; the modulated microwave signal transmitted by the radio frequency signal source is modulated into the optical carrier through a modulator to form a modulated optical signal; the modulated optical signal is formed through a saturable absorber. The optical signal is modulated for nonlinear absorption and the absorbed processed optical signal is output; the absorbed processed optical signal is photoelectrically converted through a photodetector to form a photocurrent and a microwave signal is output; the photodetector output is converted into a microwave signal through an electrical amplifier. The microwave signal is amplified and the amplified microwave signal is output; the amplified microwave signal is filtered through an electrical bandpass filter and the filtered microwave signal is output; a part of the filtered microwave signal is fed back to the modulator through the electrical coupler The other part of the filtered microwave signal is outputted by the modulator; after receiving the microwave signal fed back by the electrical coupler, the microwave signal fed back by the electrical coupler is modulated to the optical carrier through the modulator to form a modulated optical signal, which is passed through the modulator. Modulation and passive mode-locking nonlinear loss absorption of saturable absorbers compress the pulses of microwave signals in the time domain, solving the problem of excessive pulse width in traditional optoelectronic oscillators and achieving stable narrow-pulse microwave output. Compared with the traditional technical solution for generating microwave pulses by an active mode-locked photoelectric oscillator, the method provided by the present invention can further increase the duty cycle of microwave pulses and greatly compress the pulse width of the system at the same amplitude.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to explain the technical solutions of the embodiments of the present invention more clearly, the drawings needed to be used in the description of the embodiments of the present invention will be briefly introduced below. Obviously, the drawings in the following description are only some embodiments of the present invention. , for those of ordinary skill in the art, other drawings can also be obtained based on these drawings without exerting creative labor.

FIG1 is a schematic structural diagram of a microwave pulse generating system according to an embodiment of the present invention;

FIG2 is a microwave pulse generated by an existing active mode-locked optoelectronic oscillator method;

Figure 3 is a microwave pulse generation system based on an active-passive hybrid mode-locked optoelectronic oscillator according to an embodiment of the present invention;

FIG. 4 is a schematic flowchart of a microwave pulse generation method in an embodiment of the present invention.

Detailed ways

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. Obviously, the described embodiments are part of the embodiments of the present invention, not all of them. Based on the embodiments of the present invention, all other embodiments obtained by those of ordinary skill in the art without making creative efforts fall within the scope of protection of the present invention.

Please refer to Figure 1. Figure 1 is a schematic structural diagram of a microwave pulse generation system provided by an embodiment of the present invention. The microwave pulse generation system includes a laser 1, a modulator 2, a saturable absorber 3, a photodetector 5, an electrical amplifier 6, Electrical bandpass filter 7, electrical coupler 8 and radio frequency signal source 9, the laser 1, the modulator 2, the saturable absorber 3, the photodetector 5, the electrical amplifier 6, the The electrical bandpass filter 7 and the electrical coupler 8 are connected in sequence, and the electrical coupler 8 is connected to the modulator 2 to form a closed optoelectronic oscillation loop. The modulator 2 is also connected to a radio frequency signal source. 9 connections; among them,

The laser 2 is used to generate optical carrier waves;

The radio frequency signal source 9 is used to generate a modulated microwave signal to modulate the optical carrier;

The modulator 2 is used to modulate the modulated microwave signal transmitted by the radio frequency signal source 9 to the optical carrier to form a modulated optical signal;

The saturable absorber 3 is used to perform nonlinear absorption of the modulated optical signal and output the optical signal after absorption processing;

The photodetector 5 is used to photoelectrically convert the absorbed optical signal to form a photocurrent and output a microwave signal;

The electrical amplifier 6 is used to amplify the microwave signal output by the photodetector and output the amplified microwave signal;

The electrical bandpass filter 7 is used to filter the amplified microwave signal and output the filtered microwave signal;

The electrical coupler 8 is used to feed back a part of the filtered microwave signal to the modulator, and output the other part of the filtered microwave signal;

The modulator 2 is also used to modulate the microwave signal fed back by the electrical coupler 8 to the optical carrier to form a modulated optical signal after receiving the microwave signal fed back by the electrical coupler 8 .

Among them, the laser 1 can be a tunable continuous wave laser, and the modulator 2 can be a dual-drive Mach-Zehnder modulator.

The radio frequency signal source 9 is used to generate modulated microwave signals.

The output port of the laser 1 is connected to the optical input port of the modulator 2. The optical output port of the modulator 2 is connected to the input port of the saturable absorber 3. The third optical port of the modulator 2 is connected to the input port of the modulator 2. A microwave input port is connected to the output port of the radio frequency signal source 9, a second microwave input port of the modulator 2 is connected to the output port of the electrical coupler 8; the output of the saturable absorber 3 The port is connected to the optical input port of the photodetector 5; the input port of the electrical amplifier 6 is connected to the electrical output port of the photodetector 6, and the output port of the electrical amplifier 6 is connected to the electrical strip. The input port of the electrical bandpass filter 7 is connected; the input port of the electrical coupler 8 is connected to the output port of the electrical bandpass filter 7 .

An optical carrier is generated by a laser; the modulated microwave signal transmitted by the radio frequency signal source is modulated to the optical carrier by the modulator to form a modulated optical signal; the modulated optical signal is nonlinearly absorbed by a saturable absorber, and the absorbed optical signal is output; the absorbed optical signal is photoelectrically converted by a photodetector to form a photocurrent, and a microwave signal is output; the microwave signal output by the photodetector is amplified by an electrical amplifier, and the amplified microwave signal is output; the amplified microwave signal is filtered by an electrical bandpass filter, and the filtered microwave signal is output; a part of the filtered microwave signal is fed back to the modulator by an electrical coupler, and the other part of the filtered microwave signal is output; after receiving the microwave signal fed back by the electrical coupler, the microwave signal fed back by the electrical coupler is modulated to the optical carrier by the modulator to form a modulated optical signal, and the pulse of the microwave signal is compressed in the time domain by modulation of the modulator and passive mode-locked nonlinear loss absorption of the saturable absorber, so as to solve the problem of excessive pulse width existing in traditional optoelectronic oscillators and realize stable narrow pulse microwave output. Compared with the traditional technical solution of generating microwave pulses by an active mode-locked optoelectronic oscillator, the method provided by the present invention can further improve the duty cycle of microwave pulses and greatly compress the pulse width of the system under the same amplitude.

Optionally, the saturable absorber 3 is used to perform nonlinear absorption processing on the modulated optical signal and output the optical signal after absorption processing. The output power of the optical signal after absorption processing is:

Among them, α ₀ is the modulation depth of the saturable absorber, P _sat is the saturation power of the saturable absorber, V _π and V _B are the half-wave voltage and bias voltage of the modulator respectively, and P(t) is the modulator output. The output optical power of the modulated optical signal, V' _in is the signal input to the modulator, σ is the insertion loss of the modulator, and P ₀ is the input optical power of the optical signal received by the modulator.

The laser 1 is used to generate an optical carrier wave, and the power of the optical carrier wave is P ₀ ; the radio frequency signal source 9 is used to modulate the optical carrier wave, and the angular frequency of the modulated signal of the radio frequency signal source 9 is ω _RF ; The optical input port of the modulator 2 is connected to the output port of the laser 1, the electrical input port 1 of the modulator 2 is connected to the output port of the radio frequency signal source 9, the modulator 2 The electrical input port 2 is connected to the output port of the electrical coupler 8; the modulator 2 is used to modulate the microwave signal to the optical carrier to form a modulated optical signal, then the output optical power of the modulated optical signal can be Expressed as:

where σ is the insertion loss of modulator 2, eta is a parameter determined by the modulator extinction ratio, V _π and V _B are the half-wave voltage and bias voltage of modulator 2 respectively, _V'in is the input to modulator 2 signal, its expression is:

V′ _in (t)=[1+mcos(2πω _RF t)]V _in (t)

Among them, m is the modulation index, ω _RF is the angular frequency of the modulation signal, and V _in is the output voltage signal of the electrical coupler 8 . As can be seen from the above equation, the optical power is periodically modulated by the external modulation signal and changes with time. According to the active mode locking condition, when the frequency of the external modulation signal and the mode interval of the optoelectronic oscillator satisfy an integer multiple relationship, a phase locking relationship is formed between the longitudinal modes in the ring cavity, and finally they are coherently superimposed in the time domain to form a stable microwave pulse. Signal.

The input port of the saturable absorber 3 is connected to the light output port of the modulator 2. The saturable absorber 3 is used to nonlinearly absorb and process the modulated optical signal. According to the nonlinear transmission characteristics, The loss caused by the pulse will decrease as the optical pulse power increases, forming a processed modulated optical signal. The output optical power of the processed modulated optical signal can be expressed as:

Where α ₀ is the modulation depth of the saturable absorber, and P _sat is the saturation power of the saturable absorber.

Optionally, the microwave pulse generation system further includes a transmission module connected to the saturable absorber and the photodetector, and the transmission module is used to transmit the absorption-processed optical signal to the The photoelectric detector. The transmission module may include single-mode optical fiber.

Optionally, the output port of the laser 1 is connected to the optical input port of the modulator 2, and the optical output port of the modulator 2 is connected to the input port of the saturable absorber 3. The modulator The first microwave input port of the modulator 2 is connected to the output port of the radio frequency signal source 9, and the second microwave input port of the modulator 2 is connected to the output port of the electrical coupler 8; the transmission module 4 The input port is connected to the output port of the saturable absorber 3, the output port of the transmission module 4 is connected to the light input port of the photodetector 5; the input port of the electrical amplifier 6 is connected to the The electrical output port of the photodetector 6 is connected, the output port of the electrical amplifier 6 is connected to the input port of the electrical bandpass filter 7; the input port of the electrical coupler 8 is connected to the electrical bandpass filter. Connect to the output port of device 7.

The optical input port of the photodetector 5 is connected to the output port of the single-mode optical fiber 4. The photodetector 5 is used to photoelectrically convert the absorbed and processed optical signal to form a photocurrent, thereby restoring The microwave signal is output, and then input to the electrical amplifier 6 for amplification, and then input to the electrical bandpass filter 7 for filtering. The filtered microwave signal is obtained, and through the electrical coupler 8, part of it is output and part of it is input to the modulator. The electrical input port 2 of 2; let the responsivity of the photodetector 5 be ρ _PD , the impedance be R, and the gain of the electrical amplifier 6 be Ga, then the microwave signal output by the electrical bandpass filter 7 can be expressed as:

In the case of small signal approximation, the present invention increases the nonlinear absorption loss of the saturable absorber and compresses the pulse width compared with the active optoelectronic oscillator.

For example, in an experimental environment, the radio frequency signal source 9 is used to input a driving signal with a modulation frequency of 100 kHz, and a dual-drive Mach-Zehnder modulator 2 is used to modulate the microwave signal with a frequency of 100 kHz to the frequency generated by the tunable continuous wave laser 1 On the optical carrier, as shown in Figure 3, Figure 3 is the microwave pulse generated by the microwave pulse generation system based on the active and passive hybrid mode-locked photoelectric oscillator according to the embodiment of the present invention. Figure 2 is generated by the existing active mode-locked photoelectric oscillator method. Microwave pulse, the pulse duty cycle of the microwave pulse generation system based on the active and passive hybrid mode-locked optoelectronic oscillator in the embodiment of the present invention is 10%, which improves the pulse compression by 62.7% compared with the traditional active mode-locked optoelectronic oscillator technical solution.

Please refer to FIG4 , which is a flow chart of a microwave pulse generating method provided by an embodiment of the present invention. The method is applied to a microwave pulse generating system, wherein the system comprises a laser, a modulator, a saturable absorber, a photodetector, an electric amplifier, an electric bandpass filter, an electric coupler and a radio frequency signal source. The laser, the modulator, the saturable absorber, the photodetector, the electric amplifier, the electric bandpass filter and the electric coupler are connected in sequence, and the electric coupler is connected to the modulator to form a closed photoelectric oscillation loop. The modulator is also connected to the radio frequency signal source. The method comprises the following steps:

S10, generating an optical carrier by a laser;

S20. Use a radio frequency signal source to generate a modulated microwave signal to modulate the optical carrier;

S30. Modulate the modulated microwave signal transmitted by the radio frequency signal source to the optical carrier through a modulator to form a modulated optical signal;

S40. Perform nonlinear absorption of the modulated optical signal through a saturable absorber, and output the absorbed optical signal;

S50. Use a photodetector to photoelectrically convert the absorbed light signal to form a photocurrent and output a microwave signal;

S60. Amplify the microwave signal output by the photodetector through an electrical amplifier and output the amplified microwave signal;

S70, filtering the amplified microwave signal through an electrical bandpass filter, and outputting the filtered microwave signal;

S80. Feed back part of the filtered microwave signal to the modulator through an electric coupler, and output the other part of the filtered microwave signal;

S90. After receiving the microwave signal fed back by the electrical coupler, modulate the modulated microwave signal transmitted by the radio frequency signal source and the microwave signal fed back by the electrical coupler to the optical carrier through the modulator to form modulated light signal.

Among them, the laser 1 can be a tunable continuous wave laser, and the modulator 2 can be a dual-drive Mach-Zehnder modulator.

The radio frequency signal source 9 is used to generate modulated microwave signals. The laser 1 is used to generate an optical carrier wave, and the power of the optical carrier wave is P ₀ ; the radio frequency signal source 9 is used to modulate the optical carrier wave, and the angular frequency of the modulated signal of the radio frequency signal source 9 is ω _RF ; The optical input port of the modulator 2 is connected to the output port of the laser 1, the electrical input port 1 of the modulator 2 is connected to the output port of the radio frequency signal source 9, the modulator 2 The electrical input port 2 is connected to the output port of the electrical coupler 8; the modulator 2 is used to modulate the microwave signal to the optical carrier to form a modulated optical signal, then the output optical power of the modulated optical signal can be Expressed as:

where σ is the insertion loss of modulator 2, eta is a parameter determined by the modulator extinction ratio, V _π and V _B are the half-wave voltage and bias voltage of modulator 2 respectively, _V'in is the input to modulator 2 signal, its expression is:

V′ _in (t)=[1+mcos(2πω _RF t)]V _in (t)

Among them, m is the modulation index, ω _RF is the angular frequency of the modulation signal, and V _in is the output voltage signal of the electrical coupler 8 . As can be seen from the above equation, the optical power is periodically modulated by the external modulation signal and changes with time. According to the active mode locking condition, when the frequency of the external modulation signal and the mode interval of the optoelectronic oscillator satisfy an integer multiple relationship, a phase locking relationship is formed between the longitudinal modes in the ring cavity, and finally they are coherently superimposed in the time domain to form a stable microwave pulse. Signal.

The input port of the saturable absorber 3 is connected to the light output port of the modulator 2. The saturable absorber 3 is used to nonlinearly absorb and process the modulated optical signal. According to the nonlinear transmission characteristics, The loss caused by the pulse will decrease as the optical pulse power increases, forming an absorbed and processed optical signal. The output optical power of the absorbed and processed optical signal can be expressed as:

Where _α0 is the modulation depth of the saturable absorber, and _Psat is the saturation power of the saturable absorber.

In one embodiment, the microwave pulse generation system further includes a transmission module, wherein the transmission module connects the saturable absorber and the photodetector, and the method further includes: transmitting the absorbed optical signal to the photodetector via the transmission module.

The transmission module can be, for example, a single-mode optical fiber. The optical input port of the photodetector 5 is connected to the output port of the single-mode optical fiber 4. The photodetector 5 is used to photoelectrically convert the processed modulated optical signal to form a photocurrent, thereby recovering the The microwave signal is then input to the electrical amplifier 6 for amplification, and then input to the electrical bandpass filter 7 for filtering. The filtered microwave signal is obtained, and passes through the electrical coupler 8. Part of it is output, and part of it is input to the modulator 2. The electrical input port ₂ of

In the case of small signal approximation, the present invention increases the nonlinear absorption loss of the saturable absorber and compresses the pulse width compared with the active optoelectronic oscillator.

For example, in an experimental environment, the radio frequency signal source 9 is used to input a driving signal with a modulation frequency of 100 kHz, and a dual-drive Mach-Zehnder modulator 2 is used to modulate the microwave signal with a frequency of 100 kHz to the frequency generated by the tunable continuous wave laser 1 On the optical carrier, as shown in Figure 3, Figure 3 is the microwave pulse generated by the microwave pulse generation system based on the active and passive hybrid mode-locked photoelectric oscillator according to the embodiment of the present invention. Figure 2 is generated by the existing active mode-locked photoelectric oscillator method. Microwave pulse, the pulse duty cycle of the microwave pulse generation system based on the active and passive hybrid mode-locked optoelectronic oscillator in the embodiment of the present invention is 10%, which improves the pulse compression by 62.7% compared with the traditional active mode-locked optoelectronic oscillator technical solution.

This microwave pulse generation method modulates the modulated microwave signal transmitted by the radio frequency signal source to an optical carrier through the modulator to form a modulated optical signal; performs nonlinear absorption of the modulated optical signal through a saturable absorber, and outputs the absorbed light. signal; the photodetector is used to photoelectrically convert the absorbed light signal to form a photocurrent, and the microwave signal is output; the microwave signal output by the photodetector is amplified through an electrical amplifier, and the amplified microwave signal is output; through the electrical amplifier The bandpass filter filters the amplified microwave signal and outputs the filtered microwave signal; a part of the filtered microwave signal is fed back to the modulator through the electric coupler, and the other part of the filtered microwave signal is output; After receiving the microwave signal fed back by the electrical coupler, the microwave signal fed back by the electrical coupler is modulated to the optical carrier through the modulator to form a modulated optical signal, which is modulated by the modulator and passively mode-locked nonlinear loss absorption of the saturable absorber. , compressing the pulses of microwave signals in the time domain, solving the problem of excessive pulse width in traditional optoelectronic oscillators, and achieving stable narrow pulse microwave output. Compared with the traditional technical solution for generating microwave pulses by an active mode-locked photoelectric oscillator, the method provided by the present invention can further increase the duty cycle of microwave pulses and greatly compress the pulse width of the system at the same amplitude.

Embodiments of the present invention also provide a computer-readable storage medium. The computer-readable storage medium stores a computer program. When the computer program is executed by a processor, the steps of the above microwave pulse generation method are implemented.

Those of ordinary skill in the art can understand that all or part of the processes in the methods of the above embodiments can be completed by instructing relevant hardware through a computer program. The computer program can be stored in a non-volatile computer-readable storage medium. , when executed, the computer program may include the processes of the above method embodiments. Any reference to memory, storage, database or other media used in the embodiments provided in this application may include non-volatile and/or volatile memory. Non-volatile memory may include read-only memory (ROM), programmable ROM (PROM), electrically programmable ROM (EPROM), electrically erasable programmable ROM (EEPROM), or flash memory. Volatile memory may include random access memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in many forms, such as static RAM (SRAM), dynamic RAM (DRAM), synchronous DRAM (SDRAM), double data rate SDRAM (DDRSDRAM), enhanced SDRAM (ESDRAM), synchronous chain Synchlink DRAM (SLDRAM), memory bus (Rambus) direct RAM (RDRAM), direct memory bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM), etc.

Those skilled in the art can clearly understand that for the convenience and simplicity of description, only the division of the above-mentioned functional units and modules is used as an example. In actual applications, the above-mentioned functions can be distributed and completed by different functional units and modules as needed, that is, the internal structure of the device can be divided into different functional units or modules to complete all or part of the functions described above.

The above-described embodiments are only used to illustrate the technical solutions of the present invention, but not to limit them; although the present invention has been described in detail with reference to the foregoing embodiments, those of ordinary skill in the art should understand that they can still implement the above-mentioned implementations. The technical solutions described in the examples are modified, or some of the technical features are equivalently replaced; and these modifications or substitutions do not cause the essence of the corresponding technical solutions to deviate from the spirit and scope of the technical solutions of each embodiment of the present invention, and should be included in within the protection scope of the present invention.

Claims (8)

1. A microwave pulse generating system, comprising a laser, a modulator, a saturable absorber, a photodetector, an electrical amplifier, an electrical bandpass filter, an electrical coupler, and a radio frequency signal source, wherein the laser, the modulator, the saturable absorber, the photodetector, the electrical amplifier, the electrical bandpass filter, and the electrical coupler are sequentially connected, and the electrical coupler is connected with the modulator to form a closed photoelectric oscillation loop, and the modulator is further connected with the radio frequency signal source; wherein,

the laser is used for generating an optical carrier wave;

the radio frequency signal source is used for generating a modulated microwave signal to modulate an optical carrier;

the modulator is used for modulating the modulated microwave signal transmitted by the radio frequency signal source to the optical carrier wave to form a modulated optical signal;

the saturable absorber is used for carrying out nonlinear absorption on the modulated optical signal and outputting an optical signal after absorption treatment;

the photoelectric detector is used for performing photoelectric conversion on the optical signal after the absorption treatment to form photocurrent and outputting a microwave signal;

the electric amplifier is used for amplifying the microwave signals output by the photoelectric detector and outputting amplified microwave signals;

the electric band-pass filter is used for carrying out filtering treatment on the amplified microwave signals and outputting the filtered microwave signals;

the electric coupler is used for feeding back one part of the microwave signals after filtering to the modulator and outputting the other part of the microwave signals after filtering;

the modulator is further configured to modulate the modulated microwave signal transmitted by the radio frequency signal source and the microwave signal fed back by the electric coupler to the optical carrier after receiving the microwave signal fed back by the electric coupler, so as to form a modulated optical signal.

2. The microwave pulse generating system of claim 1, further comprising a transmission module connecting the saturable absorber and the photodetector, the transmission module configured to transmit the absorbed processed optical signal to the photodetector.

3. The microwave pulse generating system of claim 2, wherein the transmission module comprises a single mode fiber.

4. A microwave pulse generating system according to any one of claims 1-3, wherein the saturable absorber is configured to perform nonlinear absorption processing on the modulated optical signal, and output an optical signal after the absorption processing, and the output power of the optical signal after the absorption processing is:

wherein alpha is ₀ Modulation depth of saturable absorber, P _sat Saturated power of the saturable absorber, V _π And V _B Respectively the half-wave voltage and the bias voltage of the modulator, P (t) is the output optical power of the modulated optical signal output by the modulator, V' _in Sigma is the insertion loss of the modulator, P, for the signal input to the modulator ₀ Optical power is input for the optical signal received by the modulator.

5. A microwave pulse generating system according to claim 3, wherein the output port of the laser is connected to an optical input port of the modulator, the optical output port of the modulator is connected to an input port of the saturable absorber, a first microwave input port of the modulator is connected to an output port of the radio frequency signal source, and a second microwave input port of the modulator is connected to an output port of the electrical coupler; the input port of the transmission module is connected with the output port of the saturable absorber, and the output port of the transmission module is connected with the optical input port of the photoelectric detector; the input port of the electric amplifier is connected with the electric output port of the photoelectric detector, and the output port of the electric amplifier is connected with the input port of the electric band-pass filter; the input port of the electric coupler is connected with the output port of the electric band-pass filter.

6. A microwave pulse generating method, characterized by being applied to a microwave pulse generating system, the system comprising a laser, a modulator, a saturable absorber, a photodetector, an electric amplifier, an electric bandpass filter, an electric coupler and a radio frequency signal source, the laser, the modulator, the saturable absorber, the photodetector, the electric amplifier, the electric bandpass filter and the electric coupler being connected in sequence, and the electric coupler being connected with the modulator to form a closed photoelectric oscillation circuit, the modulator being further connected with the radio frequency signal source; the method comprises the following steps:

generating an optical carrier wave by the laser;

modulating an optical carrier wave by generating a modulated microwave signal through the radio frequency signal source;

modulating the modulated microwave signal transmitted by the radio frequency signal source to the optical carrier wave through the modulator to form a modulated optical signal;

nonlinear absorption is carried out on the modulated optical signal through the saturable absorber, and the optical signal after absorption treatment is output;

photoelectric conversion is carried out on the optical signals after the absorption treatment through the photoelectric detector to form photocurrent, and microwave signals are output;

amplifying the microwave signal output by the photoelectric detector through the electric amplifier, and outputting the amplified microwave signal;

filtering the amplified microwave signal through the electric band-pass filter, and outputting a filtered microwave signal;

feeding back a part of the filtered microwave signals to the modulator through the electric coupler, and outputting another part of the filtered microwave signals;

after receiving the microwave signal fed back by the electric coupler, modulating the modulated microwave signal transmitted by the radio frequency signal source and the microwave signal fed back by the electric coupler to the optical carrier through the modulator to form a modulated optical signal.

7. The method of any of claims 6, wherein the microwave pulse generation system further comprises a transmission module connecting the saturable absorber and the photodetector, the method further comprising:

and transmitting the light signal after the absorption treatment to the photoelectric detector through the transmission module.

8. A computer-readable storage medium storing a computer program, characterized in that the computer program when executed by a processor implements the steps of the microwave pulse generation method according to claim 6 or 7.