Phase synchronization method, satellite-borne radar and ground receiving station

文档序号:6623 发布日期:2021-09-17 浏览:41次 中文

1. A signal synchronization method applied to a first satellite-borne radar, the method comprising:

under the driving of a disciplined crystal oscillator, obtaining a first reference frequency signal through a first reference frequency source;

sending the first reference frequency signal to a second satellite-borne radar, and receiving a second reference frequency signal transmitted by the second satellite-borne radar; processing the first reference frequency signal by the second satellite-borne radar by using a second local oscillation frequency corresponding to the second satellite-borne radar to obtain first reference frequency data;

processing the second reference frequency signal by using a first local oscillator frequency to obtain second reference frequency data; the first local oscillator frequency is the frequency generated by the first reference frequency source;

receiving a first ground echo signal reflected by the ground, and acquiring first ground echo data corresponding to the first ground echo signal; the first ground echo signal is a signal which is reflected to the first satellite-borne radar after the second satellite-borne radar transmits a radar signal to the ground;

and sending the first ground echo data and the second reference frequency data to a ground receiving station so that the ground receiving station can perform phase compensation on the first ground echo data by using the second reference frequency data and the first reference frequency data sent by the second satellite-borne radar.

2. The method of claim 1, wherein before obtaining the first reference frequency signal from the first reference frequency source under the disciplined crystal oscillator driving, the method further comprises:

adopting an atomic clock signal and a global navigation satellite system signal to discipline the initial crystal oscillator drive to obtain the disciplined crystal oscillator drive;

or adopting an atomic clock signal to discipline the initial crystal oscillator drive to obtain the disciplined crystal oscillator drive.

3. The method of claim 2, wherein the disciplining an initial crystal oscillator drive using an atomic clock signal and a global navigation satellite system signal, resulting in the disciplined crystal oscillator drive, comprises:

frequency doubling is carried out on the frequency of the atomic clock signal to obtain a first frequency doubling signal;

obtaining a first reference signal by frequency synthesis by using the global navigation satellite system signal and the first frequency multiplication signal;

frequency multiplication is carried out on the frequency of the first reference signal to obtain a second frequency multiplication signal, and the frequency of the second frequency multiplication signal is equal to the frequency of the first crystal oscillator; the first crystal oscillator frequency is the crystal oscillator frequency of the first satellite-borne radar;

and phase-locking the frequency driven by the initial crystal oscillator to the second frequency doubling signal to obtain the tame crystal oscillator drive.

4. The method of claim 2, wherein the disciplining the initial crystal oscillator drive with the atomic clock signal, resulting in the disciplined crystal oscillator drive, comprises:

frequency doubling is carried out on the frequency of the atomic clock signal to obtain a third frequency doubling signal, and the frequency of the third frequency doubling signal is equal to the frequency of the first crystal oscillator; the first crystal oscillator frequency is the crystal oscillator frequency of the first satellite-borne radar;

and phase-locking the frequency driven by the initial crystal oscillator to the third frequency multiplication signal to obtain the taming crystal oscillator drive.

5. The method of claim 1, wherein said transmitting said first ground echo data and said second reference frequency data to a ground receiving station comprises:

and when a pulse period arrives, at least the first ground echo data and the second reference frequency data are sent to the ground receiving station.

6. The method of claim 5, wherein the one pulse cycle comprises a first time period and a second time period, the first time period precedes the second time period, and the sending the first reference frequency signal to a second satellite radar and receiving a second reference frequency signal transmitted by the second satellite radar comprises:

in the first time period, the first reference frequency signal is sent to the second satellite-borne radar, and the second reference frequency signal transmitted by the second satellite-borne radar is received;

correspondingly, the receiving the first ground echo signal reflected by the ground comprises:

receiving the first ground echo signal reflected by the ground during the second time period.

7. The method of claim 5, wherein the one pulse cycle comprises a first time period and a second time period, the first time period precedes the second time period, and the sending the first reference frequency signal to a second satellite radar and receiving a second reference frequency signal transmitted by the second satellite radar comprises:

in the second time period, the first reference frequency signal is sent to the second satellite-borne radar, and the second reference frequency signal transmitted by the second satellite-borne radar is received;

correspondingly, the receiving the first ground echo signal reflected by the ground comprises:

receiving the first ground echo signal of the ground reflection in the first time period.

8. The method of claim 1, wherein sending the first reference frequency signal to a second satellite radar and receiving a second reference frequency signal transmitted by the second satellite radar comprises:

and sending the first reference frequency signal to the second satellite-borne radar by adopting an omnidirectional antenna, and receiving the second reference frequency signal transmitted by the second satellite-borne radar.

9. The method of claim 1,

the frequency of the first reference frequency signal is selected from frequencies in a preset frequency range; the preset frequency range is a frequency range with the intermediate frequency of the first satellite-borne radar receiving channel as the center;

the frequency of the second reference frequency signal is selected from frequencies in a preset frequency range; the preset frequency range is a frequency range with the intermediate frequency of the second satellite-borne radar receiving channel as the center;

the difference between the frequency of the first reference frequency signal and the intermediate frequency is an integral multiple of the first crystal oscillator frequency, and the difference between the frequency of the second reference frequency signal and the intermediate frequency is an integral multiple of the first crystal oscillator frequency; the first crystal oscillator frequency is the crystal oscillator frequency of the first satellite-borne radar;

the difference between the frequency of the first reference frequency signal and the frequency of the second reference frequency signal is an integral multiple of the frequency of the first crystal oscillator, and the frequency of the first reference frequency signal is not equal to the frequency of the second reference frequency signal.

10. A signal synchronization method applied to a second satellite-borne radar, the method comprising:

under the driving of the taming crystal oscillator, a second reference frequency signal is obtained through a second reference frequency source;

sending the second reference frequency signal to a first satellite-borne radar, and receiving a first reference frequency signal transmitted by the first satellite-borne radar;

processing the first reference frequency signal by using a second local oscillation frequency to obtain first reference frequency data, wherein the second local oscillation frequency is the frequency generated by the second reference frequency source;

and sending the first reference frequency data to a ground receiving station so that the ground receiving station can perform phase compensation on the first ground echo data by using the first reference frequency data, the second reference frequency data sent by the first satellite-borne radar and the first ground echo data.

11. The method of claim 10, wherein prior to sending the second reference frequency signal to a first satellite based radar and receiving a first reference frequency signal transmitted by the first satellite based radar, the method further comprises:

and transmitting radar signals to the ground so that a first satellite-borne radar can receive first ground echo signals reflected by the ground after the radar signals are transmitted and acquire first ground echo data corresponding to the first ground echo signals.

12. The method of claim 10, wherein said transmitting said first reference frequency data to a ground receiving station comprises:

and when one pulse period arrives, at least the first reference frequency data is sent to the ground receiving station.

13. A signal synchronization method applied to a ground receiving station, the method comprising:

under the condition of receiving second reference frequency data sent by a second satellite-borne radar, first ground echo data and first reference frequency data sent by a first satellite-borne radar, calculating the first reference frequency data and the second reference frequency data to obtain a phase difference;

and performing phase compensation on the first ground echo data by using the phase difference to obtain phase-compensated first ground echo data.

14. The method of claim 13, wherein the calculating the phase difference from the first reference frequency data and the second reference frequency data comprises:

and performing fast Fourier transform on the first reference frequency data and the second reference frequency data to obtain the phase difference.

15. A first satellite radar, comprising:

the transmitting module is used for obtaining a first reference frequency signal through a first reference frequency source under the driving of a taming crystal oscillator, and transmitting the first reference frequency signal to a second satellite-borne radar so that the second satellite-borne radar can process the first reference frequency signal by using a second local oscillator frequency corresponding to the second satellite-borne radar to obtain first reference frequency data;

the receiving module is used for receiving a second reference frequency signal transmitted by the second satellite-borne radar;

the data processing module is used for processing the second reference frequency signal by using a first local oscillator frequency to obtain second reference frequency data; the first local oscillator frequency is the frequency generated by the first reference frequency source;

the receiving module is further used for receiving a first ground echo signal reflected by the ground and acquiring first ground echo data corresponding to the first ground echo signal; the first ground echo signal is a signal which is reflected to the first satellite-borne radar after the second satellite-borne radar transmits a radar signal to the ground;

the sending module is further configured to send the first ground echo data and the second reference frequency data to a ground receiving station, so that the ground receiving station performs phase compensation on the first ground echo data by using the second reference frequency data and the first reference frequency data sent by the second satellite-borne radar.

16. A second satellite-borne radar, comprising:

the transmitting module is used for obtaining a second reference frequency signal through a second reference frequency source under the driving of the taming crystal oscillator and transmitting the second reference frequency signal to the first satellite-borne radar;

the receiving module is used for receiving a first reference frequency signal transmitted by the first satellite-borne radar;

the data processing module is used for processing the first reference frequency signal by using a second local oscillator frequency to obtain first reference frequency data, wherein the second local oscillator frequency is a frequency generated by a second reference frequency source;

the sending module is further configured to send the first reference frequency data to a ground receiving station, so that the ground receiving station performs phase compensation on the first ground echo data by using the first reference frequency data, the second reference frequency data sent by the first satellite-borne radar, and the first ground echo data.

17. A ground receiving station, comprising:

the data processing module is used for calculating the first reference frequency data and the second reference frequency data to obtain a phase difference under the condition of receiving the second reference frequency data sent by a second satellite-borne radar, the first ground echo data and the first reference frequency data sent by a first satellite-borne radar;

the data processing module is further configured to perform phase compensation on the first ground echo data by using the phase difference to obtain the first ground echo data after the phase compensation.

18. A first satellite radar, comprising: the system comprises a first processor, a first transmitter, a first receiver, a first memory and a first communication bus; the first processor, when executing the running program stored in the first memory, implements the method of any of claims 1-9.

19. A second satellite-borne radar, comprising: the second processor, the second transmitter, the second receiver, the second memory and the second communication bus; the second processor, when executing the operating program stored in the second memory, implements the method of any of claims 10-12.

20. A ground receiving station, comprising: a third processor, a third receiver, a third memory, and a third communication bus; the third processor, when executing the operating program stored in the third memory, implements the method of any of claims 13-14.

21. A distributed satellite-borne radar system consisting of a first satellite-borne radar according to claim 18, a second satellite-borne radar according to claim 19 and a ground receiving station according to claim 20.

Background

In a distributed satellite radar system, because radars on different satellites adopt different frequency sources, fixed frequency differences and time-varying frequency differences caused by phase noise necessarily exist between radar carriers, and therefore, when the interference altimetry function or the ground moving target detection function of the distributed satellite radar system is used, the measurement accuracy of the functions is reduced due to the existence of the fixed frequency differences and the time-varying frequency differences.

Disclosure of Invention

The embodiment of the application provides a phase synchronization method, a satellite-borne radar and a ground receiving station, which can eliminate fixed frequency difference and time-varying frequency difference between different satellite radar carriers, and further improve the measurement precision of a distributed satellite radar system.

The technical scheme of the application is realized as follows:

in a first aspect, an embodiment of the present application provides a phase synchronization method, which is applied to a first satellite-borne radar, and the method includes:

under the driving of a disciplined crystal oscillator, obtaining a first reference frequency signal through a first reference frequency source;

sending the first reference frequency signal to a second satellite-borne radar, and receiving a second reference frequency signal transmitted by the second satellite-borne radar; processing the first reference frequency signal by the second satellite-borne radar by using a second local oscillation frequency corresponding to the second satellite-borne radar to obtain first reference frequency data;

processing the second reference frequency signal by using a first local oscillator frequency to obtain second reference frequency data; the first local oscillator frequency is the frequency generated by the first reference frequency source;

receiving a first ground echo signal reflected by the ground, and acquiring first ground echo data corresponding to the first ground echo signal; the first ground echo signal is a signal which is reflected to the first satellite-borne radar after the second satellite-borne radar transmits a radar signal to the ground;

and sending the first ground echo data and the second reference frequency data to a ground receiving station so that the ground receiving station can perform phase compensation on the first ground echo data by using the second reference frequency data and the first reference frequency data sent by the second satellite-borne radar.

In the above phase synchronization method, before the obtaining of the first reference frequency signal by the first reference frequency source under the driving of the disciplined crystal oscillator, the method further includes:

adopting an atomic clock signal and a global navigation satellite system signal to discipline the initial crystal oscillator drive to obtain the disciplined crystal oscillator drive;

or adopting an atomic clock signal to discipline the initial crystal oscillator drive to obtain the disciplined crystal oscillator drive.

In the above phase synchronization method, the disciplining the initial crystal oscillator drive by using an atomic clock signal and a global navigation satellite system signal to obtain the disciplined crystal oscillator drive includes:

frequency doubling is carried out on the frequency of the atomic clock signal to obtain a first frequency doubling signal;

obtaining a first reference signal by frequency synthesis by using the global navigation satellite system signal and the first frequency multiplication signal;

frequency multiplication is carried out on the frequency of the first reference signal to obtain a second frequency multiplication signal, and the frequency of the second frequency multiplication signal is equal to the frequency of the first crystal oscillator; the first crystal oscillator frequency is the frequency of a first satellite-borne radar;

and phase-locking the frequency driven by the initial crystal oscillator to the second frequency doubling signal to obtain the tame crystal oscillator drive.

In the above phase synchronization method, the disciplining the initial crystal oscillator drive by using the atomic clock signal to obtain the disciplined crystal oscillator drive includes:

frequency doubling is carried out on the frequency of the atomic clock signal to obtain a third frequency doubling signal, and the frequency of the third frequency doubling signal is equal to the frequency of the first crystal oscillator; the first crystal oscillator frequency is the crystal oscillator frequency of the first satellite-borne radar;

and phase-locking the frequency driven by the initial crystal oscillator to the third frequency multiplication signal to obtain the taming crystal oscillator drive.

In the above phase synchronization method, the transmitting the first ground echo data and the second reference frequency data to a ground receiving station includes:

and when a pulse period arrives, at least the first ground echo data and the second reference frequency data are sent to the ground receiving station.

In the above phase synchronization method, the one pulse cycle includes a first time period and a second time period, the first time period precedes the second time period, and the sending the first reference frequency signal to a second satellite radar and receiving a second reference frequency signal transmitted by the second satellite radar includes:

in the first time period, the first reference frequency signal is sent to the second satellite-borne radar, and the second reference frequency signal transmitted by the second satellite-borne radar is received;

correspondingly, the receiving the first ground echo signal reflected by the ground comprises:

receiving the first ground echo signal reflected by the ground during the second time period.

In the above phase synchronization method, the one pulse cycle includes a first time period and a second time period, the first time period precedes the second time period, and the sending the first reference frequency signal to a second satellite radar and receiving a second reference frequency signal transmitted by the second satellite radar includes:

in the second time period, the first reference frequency signal is sent to the second satellite-borne radar, and the second reference frequency signal transmitted by the second satellite-borne radar is received;

correspondingly, the receiving the first ground echo signal reflected by the ground comprises:

receiving the first ground echo signal of the ground reflection in the first time period.

In the above phase synchronization method, the sending the first reference frequency signal to a second satellite-borne radar and receiving a second reference frequency signal transmitted by the second satellite-borne radar includes:

and sending the first reference frequency signal to the second satellite-borne radar by adopting an omnidirectional antenna, and receiving the second reference frequency signal transmitted by the second satellite-borne radar.

In the phase synchronization method, the frequency of the first reference frequency signal is selected from frequencies within a preset frequency range; the preset frequency range is a frequency range with the intermediate frequency of the first satellite-borne radar receiving channel as the center;

the frequency of the second reference frequency signal is selected from frequencies in a preset frequency range; the preset frequency range is a frequency range with the intermediate frequency of the second satellite-borne radar receiving channel as the center;

the difference between the frequency of the first reference frequency signal and the intermediate frequency is an integral multiple of the first crystal oscillator frequency, and the difference between the frequency of the second reference frequency signal and the intermediate frequency is an integral multiple of the first crystal oscillator frequency; the first crystal oscillator frequency is the crystal oscillator frequency of the first satellite-borne radar;

the difference between the frequency of the first reference frequency signal and the frequency of the second reference frequency signal is an integral multiple of the first crystal oscillator frequency.

In a second aspect, an embodiment of the present application provides a phase synchronization method, which is applied to a second satellite-borne radar, and the method includes:

under the driving of the taming crystal oscillator, a second reference frequency signal is obtained through a second reference frequency source;

sending the second reference frequency signal to a first satellite-borne radar, and receiving a first reference frequency signal transmitted by the first satellite-borne radar;

processing the first reference frequency signal by using a second local oscillation frequency to obtain first reference frequency data, wherein the second local oscillation frequency is the frequency generated by the second reference frequency source;

and sending the first reference frequency data to a ground receiving station so that the receiving station can perform phase compensation on the first ground echo data by using the first reference frequency data, the second reference frequency data sent by the first satellite-borne radar and the first ground echo data.

In the above phase synchronization method, before the sending the second reference frequency signal to a first satellite radar and receiving a first reference frequency signal transmitted by the first satellite radar, the method further includes:

and transmitting radar signals to the ground so that a first satellite-borne radar can receive first ground echo signals reflected by the ground after the radar signals are transmitted and acquire first ground echo data corresponding to the first ground echo signals.

In the above phase synchronization method, the transmitting the first reference frequency data to a ground receiving station includes:

and when one pulse period arrives, at least the first reference frequency data is sent to the ground receiving station.

In a third aspect, an embodiment of the present application provides a phase synchronization method, which is applied to a ground receiving station, and the method includes:

under the condition of receiving second reference frequency data sent by a second satellite-borne radar, first ground echo data and first reference frequency data sent by a first satellite-borne radar, calculating the first reference frequency data and the second reference frequency data to obtain a phase difference;

and performing phase compensation on the first ground echo data by using the phase difference to obtain phase-compensated first ground echo data.

In the above phase synchronization method, the obtaining a phase difference by calculating the first reference frequency data and the second reference frequency data includes:

and performing fast Fourier transform on the first reference frequency data and the second reference frequency data to obtain a phase difference.

In a fourth aspect, an embodiment of the present application provides a first satellite-borne radar, where the first satellite-borne radar includes:

the transmitting module is used for obtaining a first reference frequency signal through a first reference frequency source under the driving of a taming crystal oscillator, and transmitting the first reference frequency signal to a second satellite-borne radar so that the second satellite-borne radar can process the first reference frequency signal by using a second local oscillator frequency corresponding to the second satellite-borne radar to obtain first reference frequency data;

the receiving module is used for receiving a second reference frequency signal transmitted by the second satellite-borne radar;

the data processing module is used for processing the second reference frequency signal by using a first local oscillator frequency to obtain second reference frequency data; the first local oscillator frequency is the frequency generated by the first reference frequency source;

the receiving module is further used for receiving a first ground echo signal reflected by the ground and acquiring first ground echo data corresponding to the first ground echo signal; the first ground echo signal is a signal which is reflected to the first satellite-borne radar after the second satellite-borne radar transmits a radar signal to the ground;

the sending module is further configured to send the first ground echo data and the second reference frequency data to a ground receiving station, so that the ground receiving station performs phase compensation on the first ground echo data by using the second reference frequency data and the first reference frequency data sent by the second satellite-borne radar.

In a fifth aspect, an embodiment of the present application provides a second satellite-borne radar, where the second satellite-borne radar includes:

the transmitting module is used for obtaining a second reference frequency signal through a second reference frequency source under the driving of the taming crystal oscillator and transmitting the second reference frequency signal to the first satellite-borne radar;

the receiving module is used for receiving a first reference frequency signal transmitted by the first satellite-borne radar;

the data processing module is used for processing the first reference frequency signal by using a second local oscillator frequency to obtain first reference frequency data, wherein the second local oscillator frequency is a frequency generated by a second reference frequency source;

the sending module is further configured to send the first reference frequency data to a ground receiving station, so that the ground receiving station performs phase compensation on the first ground echo data by using the first reference frequency data, the second reference frequency data sent by the first satellite-borne radar, and the first ground echo data.

In a sixth aspect, an embodiment of the present application provides a ground receiving station, where the ground receiving station includes:

the data processing module is used for calculating the first reference frequency data and the second reference frequency data to obtain a phase difference under the condition of receiving the second reference frequency data sent by a second satellite-borne radar, the first ground echo data and the first reference frequency data sent by a first satellite-borne radar;

the data processing module is further configured to perform phase compensation on the first ground echo data by using the phase difference to obtain the first ground echo data after the phase compensation.

In a seventh aspect, an embodiment of the present application provides a first satellite-borne radar, where the first satellite-borne radar includes: the system comprises a first processor, a first transmitter, a first receiver, a first memory and a first communication bus; the first processor, when executing the operating program stored in the first memory, implements the method of any of the first aspects.

In an eighth aspect, an embodiment of the present application provides a second satellite-borne radar, where the second satellite-borne radar includes: the second processor, the second transmitter, the second receiver, the second memory and the second communication bus; the second processor, when executing the operating program stored in the second memory, implements the method of any of the second aspects.

In a ninth aspect, an embodiment of the present application provides a ground receiving station, where the ground receiving station includes: a third processor, a third receiver, a third memory, and a third communication bus; the third processor, when executing the operating program stored in the third memory, implements the method of any of the third aspects.

In a tenth aspect, embodiments of the present application provide a distributed satellite-borne radar system, which is composed of the first satellite-borne radar according to claim 18, the second satellite-borne radar according to claim 19, and the ground receiving station according to claim 20.

The embodiment of the application provides a phase synchronization method, a satellite-borne radar and a ground receiving station, which are applied to a first satellite-borne radar, and the method comprises the following steps: under the driving of a disciplined crystal oscillator, obtaining a first reference frequency signal through a first reference frequency source; sending the first reference frequency signal to a second satellite-borne radar, and receiving a second reference frequency signal transmitted by the second satellite-borne radar; processing the second reference frequency signal by using the first local oscillation frequency to obtain second reference frequency data; receiving a first ground echo signal reflected by the ground, and acquiring first ground echo data corresponding to the first ground echo signal; the first ground echo signal is a signal which is reflected to the first satellite-borne radar after the second satellite-borne radar transmits a radar signal to the ground; and sending the first ground echo data and the second reference frequency data to a ground receiving station. By adopting the implementation scheme, the reference frequency source is generated by the domestication crystal oscillator after domestication, so that the frequency deviation between the first satellite-borne radar and the second satellite-borne radar is reduced, and then the phase compensation is carried out on the first ground echo data through the received first reference frequency data and the second reference frequency data, so that the phase difference between the first satellite-borne radar and the second satellite-borne radar is eliminated, the phase synchronization between the first satellite-borne radar and the second satellite-borne radar is realized, and the purpose of improving the measurement precision of the distributed satellite radar system is achieved.

Drawings

Fig. 1 is a first flowchart of a phase synchronization method according to an embodiment of the present disclosure;

FIG. 2 is a schematic diagram illustrating an exemplary disciplined crystal oscillator drive using an atomic clock signal and a global navigation satellite system signal provided by an embodiment of the present application;

FIG. 3 is a schematic diagram of an exemplary disciplined crystal oscillator driving using an atomic clock signal provided by an embodiment of the present application;

FIG. 4 is a diagram illustrating an exemplary pulse period according to an embodiment of the present disclosure;

FIG. 5 is a schematic diagram of an exemplary pulse period provided by an embodiment of the present application;

FIG. 6 is a schematic diagram illustrating operation of an exemplary first and second satellite-borne radar according to an embodiment of the present disclosure;

fig. 7 is a flowchart of a phase synchronization method according to an embodiment of the present application;

fig. 8 is a third flowchart of a phase synchronization method according to an embodiment of the present application;

fig. 9 is a first schematic structural diagram of a first satellite-borne radar according to an embodiment of the present disclosure;

fig. 10 is a schematic structural diagram of a first satellite-borne radar according to an embodiment of the present application;

FIG. 11 is a first schematic diagram of exemplary hardware for a first satellite-borne radar provided in an embodiment of the present application;

FIG. 12 is a second schematic diagram of an exemplary first satellite-borne radar hardware according to an embodiment of the present disclosure;

fig. 13 is a schematic structural diagram of a second satellite-borne radar according to an embodiment of the present disclosure;

fig. 14 is a schematic structural diagram of a second satellite-borne radar according to an embodiment of the present application;

fig. 15 is a first schematic structural diagram of a ground receiving station according to an embodiment of the present disclosure;

fig. 16 is a schematic structural diagram of a ground receiving station according to an embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application. It is to be understood that the specific embodiments described herein are merely illustrative of the relevant application and are not limiting of the application. It should be noted that, for the convenience of description, only the parts related to the related applications are shown in the drawings.

Example one

An embodiment of the present application provides a phase synchronization method, which is applied to a first satellite-borne radar, and fig. 1 is a first flowchart of the phase synchronization method provided in the embodiment of the present application, and as shown in fig. 1, the phase synchronization method may include:

and S101, under the driving of the disciplined crystal oscillator, obtaining a first reference frequency signal through a first reference frequency source.

In the embodiment of the application, the first satellite-borne radar obtains a first reference frequency signal through a first reference frequency source under the driving of the taming crystal oscillator.

It should be noted that the first reference frequency source is one of the components of the first satellite-borne radar, and is responsible for generating various reference frequencies required by the first satellite-borne radar.

After the first reference frequency source generates the required first reference frequency, the first reference frequency source generates a first reference frequency signal corresponding to the first reference frequency as the first phase synchronization signal.

In the embodiment of the present application, the frequency of the first reference frequency signal is selected from frequencies within a preset frequency range; the preset frequency range is a frequency range taking the intermediate frequency of the first satellite-borne radar receiving channel as the center; the difference between the frequency of the first reference frequency signal and the intermediate frequency is an integral multiple of the first crystal oscillator frequency.

It should be noted that the first crystal oscillator frequency is a crystal oscillator frequency of the first satellite-borne radar.

It should be noted that the intermediate frequency of the first satellite-borne radar receiving channel is a fixed frequency that is set in advance according to needs.

For example, assuming that the intermediate frequency of the first satellite-borne radar receiving channel is 1000 mhz, the predetermined frequency range centered at 1000 mhz may be set to be 800 mhz to 1200 mhz, at this time, the frequency of the first reference frequency signal may only be selected from 800 mhz to 1200 mhz, and assuming that the frequency of the first crystal oscillator is 100 mhz, since the difference between the frequency of the first reference frequency signal and the 1000 mhz is an integral multiple of 100 mhz and only can be selected from 800 mhz to 1200 mhz, at this time, the frequency of the first reference frequency signal may be selected from 800 mhz, 900 mhz, 1100 mhz and 1200 mhz. The specific intermediate frequency and the first crystal frequency of the first satellite-borne radar receiving channel can be determined according to actual conditions, and the embodiment of the application is not limited thereto.

In an embodiment of the present application, before obtaining the first reference frequency signal through the first reference frequency source under the driving of the disciplined crystal oscillator, the method further includes: adopting an atomic clock signal and a global navigation satellite system signal to discipline the initial crystal oscillator drive to obtain a disciplined crystal oscillator drive; or adopting an atomic clock signal to discipline the initial crystal oscillator drive to obtain the disciplined crystal oscillator drive.

In this embodiment of the present application, using an atomic clock signal and a global navigation satellite system signal to discipline an initial crystal oscillator drive, to obtain a disciplined crystal oscillator drive, includes: carrying out frequency doubling on the frequency of the atomic clock signal to obtain a first frequency doubling signal; obtaining a first reference signal by frequency synthesis by using a global navigation satellite system signal and a first frequency doubling signal; frequency multiplication is carried out on the frequency of the first reference signal to obtain a second frequency multiplication signal, and the frequency of the second frequency multiplication signal is equal to the frequency of the first crystal oscillator; and phase-locking the frequency driven by the initial crystal oscillator to the second frequency doubling signal to obtain the taming crystal oscillator drive.

It should be noted that the global navigation satellite system signal is also generated from the atomic clock signal.

It should be noted that the atomic clock signal may be a rubidium atomic clock signal or a cesium atomic clock signal, and a specific atomic clock signal may be determined according to an actual situation, which is not limited in this embodiment of the present application.

In the embodiment of the present application, fig. 2 is a schematic diagram illustrating a crystal oscillator driving training method using an atomic clock signal and a global navigation satellite system signal, as shown in fig. 2, including the following components: frequency multiplier, direct digital frequency synthesizer, global navigation satellite system receiver, phase discriminator, filter and initial crystal oscillator drive. The specific implementation mode is as follows: for example, rubidium atomic clock signals are used, 5 mhz or 10 mhz signals output by a rubidium atomic clock are subjected to frequency doubling through a frequency multiplier and then serve as reference clocks of a direct digital frequency synthesizer, the output frequency of the direct digital frequency synthesizer is controlled through output frequency control words of a global navigation satellite system receiver, the output frequency signals of the direct digital frequency synthesizer are subjected to frequency doubling through the frequency multiplier and are converted to crystal oscillator frequency required by the satellite-borne radar during working, the crystal oscillator frequency is output to a phase discriminator, then frequency signals driven by an initial crystal oscillator are also input to the phase discriminator, the phase discriminator phase-locks the frequency signals driven by the initial crystal oscillator to the crystal oscillator frequency required by the satellite-borne radar during working, and then the filter is used for filtering out the unnecessary frequencies to obtain the domesticated crystal oscillator drive.

It should be noted that, when the gnss receiver needs to calibrate the frequency according to the actual situation, the adjustment of the frequency of the tamed crystal oscillator is realized by changing the frequency control word.

In this embodiment of the present application, disciplining the initial crystal oscillator drive by using an atomic clock signal to obtain a disciplined crystal oscillator drive includes: carrying out frequency doubling on the frequency of the atomic clock signal to obtain a third frequency doubling signal, wherein the frequency of the third frequency doubling signal is equal to the frequency of the first crystal oscillator; and locking the frequency of the initial crystal oscillator drive to the third frequency multiplication signal to obtain the taming crystal oscillator drive.

In the embodiment of the present application, fig. 3 is a schematic diagram illustrating an exemplary disciplined crystal oscillator driving by using an atomic clock signal, and as shown in fig. 3, the following components are included: frequency multiplier, phase discriminator, filter and initial crystal oscillator drive. The specific implementation mode is as follows: for example, rubidium atomic clock signals are used, 5 MHz or 10 MHz signals output by the rubidium atomic clock are subjected to frequency doubling conversion through a frequency multiplier to crystal oscillator frequency required by the satellite-borne radar during working, the signals are output to a phase discriminator, then frequency signals driven by an initial crystal oscillator are input to the phase discriminator, the phase discriminator is used for phase-locking the frequency signals driven by the initial crystal oscillator to the crystal oscillator frequency required by the satellite-borne radar during working, and then a filter is used for filtering out the unnecessary frequency to obtain the domesticated crystal oscillator drive.

It can be understood thatAfter the over-disciplined crystal oscillator is driven, the consistency of the first reference frequency source and the second reference frequency source is high, and the relative frequency difference is better than 1 multiplied by 10-10

S102, sending the first reference frequency signal to a second satellite-borne radar, and receiving a second reference frequency signal transmitted by the second satellite-borne radar; and processing the first reference frequency signal by the second satellite-borne radar by using a second local oscillator frequency corresponding to the second satellite-borne radar to obtain first reference frequency data.

In the embodiment of the application, after a first reference frequency signal is obtained by a first satellite-borne radar through a first reference frequency source, the first reference frequency signal is sent to a second satellite-borne radar, and a second reference frequency signal transmitted by the second satellite-borne radar is received; and processing the first reference frequency signal by the second satellite-borne radar by using a second local oscillator frequency corresponding to the second satellite-borne radar to obtain first reference frequency data.

In the embodiment of the present application, the frequency of the second reference frequency signal is selected from frequencies within a preset frequency range; the preset frequency range is a frequency range taking the intermediate frequency of the second satellite-borne radar receiving channel as the center; the difference between the frequency of the second reference frequency signal and the intermediate frequency is an integral multiple of the frequency of the first crystal oscillator.

It should be noted that the second reference frequency signal is a second reference frequency signal received by the first satellite-borne radar and sent by the second satellite-borne radar.

The second reference frequency signal is also obtained by the second satellite-borne radar through the second reference frequency source under the driving of the taming crystal oscillator.

It should be noted that the second reference frequency source is one of the components of the second satellite-borne radar, and is responsible for generating various reference frequency signals required by the second satellite-borne radar.

It should be noted that the second crystal frequency is a crystal frequency of the second satellite-borne radar.

It should be noted that the intermediate frequency of the second satellite-borne radar receiving channel is a fixed frequency that is set in advance according to needs.

For example, assuming that the intermediate frequency of the second satellite-borne radar receiving channel is 1000 mhz, the predetermined frequency range centered at 1000 mhz may be set to be 800 mhz to 1200 mhz, at this time, the frequency of the second reference frequency signal may only be selected from 800 mhz to 1200 mhz, and assuming that the second oscillation frequency is 100 mhz, since the difference between the frequency of the second reference frequency signal and 1000 mhz is an integral multiple of 100 mhz and only can be selected from 800 mhz to 1200 mhz, at this time, the frequency of the second reference frequency signal may be selected from 800 mhz, 900 mhz, 1100 mhz and 1200 mhz. The specific intermediate frequency and the second crystal frequency of the second satellite-borne radar receiving channel can be determined according to actual conditions, and the embodiment of the application is not limited to this.

In the embodiment of the present application, the difference between the frequency of the first reference frequency signal and the frequency of the second reference frequency signal is an integral multiple of the first crystal oscillator frequency, and the frequency of the first reference frequency signal is not equal to the frequency of the second reference frequency signal.

For example, it is assumed that the frequency of the first reference frequency signal and the frequency of the second reference frequency signal can be selected from 800 mhz, 900 mhz, 1100 mhz and 1200 mhz, but the frequency of the first reference frequency signal and the frequency of the second reference frequency signal cannot be the same and must be an integral multiple of the frequency of the first crystal oscillator, at this time, when the frequency of the first reference frequency signal is selected to be 800 mhz, the frequency of the second reference frequency signal can only be selected to be one of 900 mhz, 1100 mhz and 1200 mhz, and the specific selection condition is specified according to the actual situation, and the present application is not limited herein.

In this embodiment, when the first satellite-borne radar transmits the first reference frequency signal to the second satellite-borne radar and receives the second reference frequency signal transmitted by the second satellite-borne radar, an omnidirectional antenna may be used.

It should be noted that, the first satellite-borne radar may employ an omnidirectional antenna to transmit the first reference frequency signal to the second satellite-borne radar, and the first satellite-borne radar may employ the omnidirectional antenna to receive the second reference frequency signal transmitted by the second satellite-borne radar.

Similarly, the second satellite-borne radar may transmit the second reference frequency signal to the first satellite-borne radar using the omnidirectional antenna, and the second satellite-borne radar may receive the first reference frequency signal transmitted by the first satellite-borne radar using the omnidirectional antenna.

It should be noted that the omnidirectional antenna, i.e. the antenna shows 360 ° uniform radiation in the horizontal directional diagram, and shows a beam with a certain width in the vertical directional diagram, can receive signals transmitted in any direction, and can transmit signals to any direction.

S103, processing the second reference frequency signal by using the first local oscillation frequency to obtain second reference frequency data; the first local oscillator frequency is a frequency generated by the first reference frequency source.

In the embodiment of the application, after receiving a second reference frequency signal transmitted by a second satellite-borne radar, a first satellite-borne radar processes the second reference frequency signal by using a first local oscillator frequency to obtain second reference frequency data; the first local oscillator frequency is a frequency generated by the first reference frequency source.

In the embodiment of the present application, it is assumed that the frequency of the second reference frequency signal is the crystal frequency Ksyn1The frequency of the first reference frequency signal is the crystal oscillator frequency Ksyn2Multiple, i.e. the frequency of the second reference frequency signal transmitted by the second satellite-borne radar to the first satellite-borne radar is fM=Ksyn1(f0+Δf1) The frequency of a first reference frequency signal transmitted by the first satellite-borne radar to the second satellite-borne radar is fS=Ksyn2(f0+Δf2)。

Wherein the crystal oscillation frequency f0For the nominal crystal frequency of the distributed satellite system, the second crystal frequency is expressed as f because the crystal frequency of the first satellite-borne radar and the second satellite-borne radar are deviated when in work0+Δf1The first crystal frequency is represented as f0+Δf2

After receiving a second reference frequency signal transmitted by a second satellite-borne radar, a first local oscillator frequency is utilized to demodulate the second reference frequency signal, and the phase obtained after demodulation is as follows:

similarly, after receiving a first reference frequency signal transmitted by the first satellite-borne radar, the second satellite-borne radar demodulates the first reference frequency signal by using a second local oscillator frequency, and the phase obtained after demodulation is as follows:

in the above formula, τ is the time delay of the transmission of the first reference frequency signal and the second reference frequency signal between the first satellite-borne radar and the second satellite-borne radar,andthe phase noise of the crystal oscillator of the second satellite-borne radar and the first satellite-borne radar,andphase errors introduced by thermal noise during the process of receiving the first reference frequency signal and the second reference frequency signal for the second satellite-borne radar and the first satellite-borne radar,andthe initial phase of the second reference frequency signal and the first reference frequency signal is shown, d is the distance between the second satellite-borne radar and the first satellite-borne radar, and c is the speed of light.

In the embodiment of the application, the second satellite-borne radar and the first satellite-borne radar respectively acquire a first reference frequency signal and a second reference frequency signal which are respectively received in each pulse period, then the local oscillation frequency of the second satellite-borne radar and the local oscillation frequency of the first satellite-borne radar are utilized for demodulation, the demodulation is transmitted to a ground receiving station along with ground echo data, and during ground processing, phase information in the first reference frequency data and the second reference frequency data is extracted and converted to the radar radio frequency carrier frequency. Suppose that the center frequency of the radio frequency signal transmitted by the radar is fcK being the frequency of the crystal oscillatorNMultiplying, the phase difference finally extracted for phase compensation is:

in the formula, the first line on the right of the equal sign represents the phase difference caused by the frequency deviation and the phase noise of the first reference frequency source and the second reference frequency source, and is a component required for compensating the phase error of the first ground echo signal of the first satellite-borne radar; the second action is that phase errors caused by thermal noise in the process that the second satellite-borne radar and the first satellite-borne radar receive the first reference frequency signals and the second reference frequency signals are main factors influencing the phase synchronization performance; the third row and the second item represent phase items of the first reference frequency signal and the second reference frequency signal caused by distance change of the first satellite-borne radar and the second satellite-borne radar in the transmission process, and the relative frequency difference is better than 1 multiplied by 10 because the consistency of the first reference frequency source and the second reference frequency source is higher-10And the transmission time of the first reference frequency signal and the second reference frequency signal is short, so that the phase of the term can be ignored. The other two terms of the second term of the third row are constant phases, and the phase synchronization performance is not influenced.

It should be noted that one pulse cycle is started when the first satellite-borne radar transmits a radar signal to the ground.

In an alternative embodiment, a pulse cycle includes a first time period and a second time period, the first time period precedes the second time period, the first reference frequency signal is transmitted to a second satellite radar, and the second reference frequency signal transmitted by the second satellite radar is received, including: in a first time period, sending the first reference frequency signal to a second satellite-borne radar, and receiving a second reference frequency signal transmitted by the second satellite-borne radar; correspondingly, receiving a first ground echo signal reflected by the ground, comprises: in a second time period, a first ground echo signal of a ground reflection is received.

In the embodiment of the present application, fig. 4 is a schematic diagram of an exemplary pulse period, as shown in fig. 4, the receiving and transmitting of the reference frequency signal are performed before the receiving of the ground echo signal.

In another alternative embodiment, a pulse cycle includes a first time period and a second time period, the first time period precedes the second time period, the first reference frequency signal is sent to the second satellite-borne radar, and the second reference frequency signal transmitted by the second satellite-borne radar is received, including: in a second time period, the first reference frequency signal is sent to a second satellite-borne radar, and a second reference frequency signal transmitted by the second satellite-borne radar is received; correspondingly, receiving a first ground echo signal reflected by the ground, comprises: in a first time period, a first ground echo signal of a ground reflection is received.

In the embodiment of the present application, fig. 5 is a schematic diagram of an exemplary pulse period, as shown in fig. 5, the received ground echo signal is before the reception and transmission of the reference frequency signal.

S104, receiving a first ground echo signal reflected by the ground, and acquiring first ground echo data corresponding to the first ground echo signal; the first ground echo signal is a signal which is reflected to the first satellite-borne radar after the second satellite-borne radar transmits a radar signal to the ground.

In the embodiment of the application, a first satellite-borne radar receives a first ground echo signal reflected by the ground; the first ground echo signal is a signal which is reflected to the first satellite-borne radar after the second satellite-borne radar transmits a radar signal to the ground.

It should be noted that, the time when the first satellite-borne radar receives the first ground echo signal may be after the first reference frequency signal is sent to the second satellite-borne radar and the second reference frequency signal sent by the second satellite-borne radar is received, or before the first reference frequency signal is sent to the second satellite-borne radar and the second reference frequency signal sent by the second satellite-borne radar is received.

It should be noted that the time when the first satellite-borne radar receives the first ground echo signal and the time when the first reference frequency signal is sent to the second satellite-borne radar, and the time when the second reference frequency signal is received from the second satellite-borne radar are both after the time when the second satellite-borne radar sends the radar signal to the ground.

It should be noted that the first satellite-borne radar does not transmit radar signals but only receives ground echo signals, and the second satellite-borne radar not only transmits radar signals but also receives ground echo signals.

In the embodiment of the present application, fig. 6 is an exemplary working schematic diagram of a first satellite-borne radar and a second satellite-borne radar, as shown in fig. 6, where S1 is the second satellite-borne radar, S2 is the first satellite-borne radar, S3 is the ground, R1Is the distance, R, of the second space-borne radar from the ground2The distance between the first satellite-borne radar and the ground is taken as the distance between the second satellite-borne radar and the ground, and the radar signal transmitted to the ground by the second satellite-borne radar is a Linear Frequency Modulated (LFM) signal, which can be expressed as:

wherein T ispFor transmitting the pulse width, fcIs the carrier frequency, krTo transmit the chirp rate of the chirp signal,is the second crystal frequency phase noise of the second satellite-borne radar,for the second crystal oscillation frequency initial phase, K, of the second satellite-borne radarNIs the carrier frequency fcWith crystal frequency f0Multiples thereof.

Therefore, the phase of the second satellite-borne radar after receiving the ground echo signal reflected by the radar signal and demodulating the ground echo signal can be represented as follows:

the phase of the first satellite-borne radar after receiving the first ground echo signal reflected by the radar signal and demodulating the first ground echo signal can be represented as follows:

wherein the content of the first and second substances,is the phase noise of the first crystal oscillator frequency of the first satellite-borne radar,is the initial phase of the first crystal oscillator frequency of the first satellite-borne radar.

If the phase compensation is not performed on the first satellite-borne radar, after the interference processing is performed on the ground echo signals of the first satellite-borne radar and the second satellite-borne radar, the interference phase can be expressed as:

in the formula, a first row behind an equal sign is represented as a phase caused by a position geometric relationship between a first satellite-borne radar and a second satellite-borne radar and is a phase item required by ground elevation measurement, a first item of a second row is represented as a phase error item caused by frequency deviation between the first satellite-borne radar and the second satellite-borne radar, a second item is represented as a phase error item caused by phase noise of the first satellite-borne radar and the second satellite-borne radar, and a third item is a constant phase and has no influence on the performance of the distributed satellite radar system.

Based on the analysis, the first satellite-borne radar needs to be subjected to phase compensation, and the compensated first ground echo data can be used for realizing functions of a double-station imaging function, an interference height measurement function or a ground moving target detection function and the like of the distributed satellite radar system.

And S105, sending the first ground echo data and the second reference frequency data to a ground receiving station so that the ground receiving station can perform phase compensation on the first ground echo data by using the second reference frequency data and the first reference frequency data sent by the second satellite-borne radar.

In the embodiment of the application, after the first ground echo signal is received, first ground echo data corresponding to the first ground echo signal is acquired, and the first ground echo data and second reference frequency data are sent to a ground receiving station, so that the ground receiving station performs phase compensation on the first ground echo data by using the second reference frequency data and the first reference frequency data sent by the second satellite-borne radar.

It should be noted that, acquiring the first ground echo data corresponding to the first ground echo signal is to demodulate the first ground echo signal.

In this embodiment of the present application, the sending the first ground echo data and the second reference frequency data to the ground receiving station includes: and when one pulse period arrives, at least the first ground echo data and the second reference frequency data are sent to a ground receiving station.

It should be noted that, in each pulse period, at least the first ground echo data and the second reference frequency data need to be transmitted to the ground receiving station.

It should be noted that, in order to reduce the output data rate in the distributed satellite system, the first ground echo data is usually output after being subjected to a block adaptive quantization data compression process. In addition, since the reference frequency signal is a deterministic signal, and the distribution characteristics thereof are significantly different from those of the ground echo data, the reference frequency signal is not subjected to the block adaptive quantization data compression processing after data acquisition, but is directly subjected to data output.

It can be understood that the first satellite-borne radar obtains a first reference frequency signal through a first reference frequency source under the driving of the taming crystal oscillator; sending the first reference frequency signal to a second satellite-borne radar, and receiving a second reference frequency signal transmitted by the second satellite-borne radar; processing the second reference frequency signal by using the first local oscillation frequency to obtain second reference frequency data; receiving a first ground echo signal reflected by the ground, and acquiring first ground echo data corresponding to the first ground echo signal; the first ground echo signal is a signal which is reflected to the first satellite-borne radar after the second satellite-borne radar transmits a radar signal to the ground; and sending the first ground echo data and the second reference frequency data to a ground receiving station. By adopting the implementation scheme, the reference frequency source is generated by the domestication crystal oscillator after domestication, so that the frequency deviation between the first satellite-borne radar and the second satellite-borne radar is reduced, and then the phase compensation is carried out on the first ground echo data through the received first reference frequency data and the second reference frequency data, so that the phase difference between the first satellite-borne radar and the second satellite-borne radar is eliminated, the phase synchronization between the first satellite-borne radar and the second satellite-borne radar is realized, and the purpose of improving the measurement precision of the distributed satellite radar system is achieved.

An embodiment of the present application provides a phase synchronization method, which is applied to a second satellite-borne radar, and fig. 7 is a flow chart of the phase synchronization method provided in the embodiment of the present application, and as shown in fig. 7, the phase synchronization method may include:

and S201, under the driving of the taming crystal oscillator, obtaining a second reference frequency signal through a second reference frequency source.

In the embodiment of the application, the second satellite-borne radar obtains a second reference frequency signal through a second reference frequency source under the driving of the taming crystal oscillator.

It should be noted that the second reference frequency source is one of the components of the second satellite-borne radar, and is responsible for generating various reference frequencies required by the second satellite-borne radar.

After the second reference frequency source generates the required second reference frequency, the second reference frequency source generates a second reference frequency signal corresponding to the second reference frequency.

In the embodiment of the present application, the frequency of the second reference frequency signal is selected from frequencies within a preset frequency range; the preset frequency range is a frequency range taking the intermediate frequency of the second satellite-borne radar receiving channel as the center; the difference between the frequency of the second reference frequency signal and the intermediate frequency is an integral multiple of the frequency of the first crystal oscillator.

It should be noted that, the specific rule for selecting the frequency of the second reference frequency signal is described in detail in the first embodiment of the present application, and is not described herein again.

S202, sending the second reference frequency signal to the first satellite-borne radar, and receiving the first reference frequency signal transmitted by the first satellite-borne radar.

In the embodiment of the application, the second satellite-borne radar sends the second reference frequency signal to the first satellite-borne radar and receives the first reference frequency signal transmitted by the first satellite-borne radar; and the first satellite-borne radar processes the second reference frequency signal by using the first local oscillation frequency corresponding to the first satellite-borne radar to obtain second reference frequency data.

It should be noted that, the second satellite-borne radar may employ an omnidirectional antenna to transmit the second reference frequency signal to the first satellite-borne radar, and the second satellite-borne radar may employ the omnidirectional antenna to receive the first reference frequency signal transmitted by the first satellite-borne radar.

In this embodiment of the application, before sending the second reference frequency signal to the first satellite-borne radar and receiving the first reference frequency signal transmitted by the first satellite-borne radar, the method further includes: and transmitting radar signals to the ground so that the first satellite-borne radar can receive first ground echo signals reflected by the ground after the radar signals are transmitted and acquire first ground echo data corresponding to the first ground echo signals.

In the embodiment of the application, the second satellite-borne radar transmits radar signals to the ground, and the first satellite-borne radar receives the first ground echo signals.

It should be noted that the first satellite-borne radar does not transmit radar signals but only receives ground echo signals, and the second satellite-borne radar not only transmits radar signals but also receives ground echo signals.

And S203, processing the first reference frequency signal by using a second local oscillation frequency to obtain first reference frequency data, wherein the second local oscillation frequency is the frequency generated by the second reference frequency source.

In the embodiment of the application, after receiving a first reference frequency signal transmitted by a first satellite-borne radar, a second satellite-borne radar processes the first reference frequency signal by using a second local oscillator frequency to obtain first reference frequency data; the second local oscillator frequency is a frequency generated by the second reference frequency source.

It should be noted that, the process of demodulating the first reference frequency signal by the second satellite-borne radar using the second local oscillation frequency is described in detail in the first embodiment of the present application, and is not described herein again.

In the embodiment of the application, the second satellite-borne radar and the first satellite-borne radar respectively acquire a first reference frequency signal and a second reference frequency signal which are respectively received in each pulse period, then the local oscillation frequencies of the second satellite-borne radar and the first satellite-borne radar are used for demodulation, the demodulation is carried out, and the demodulation is transmitted to the ground receiving station along with ground echo data.

It should be noted that the calculation formula and the process of the specific phase difference are described in detail in the first embodiment of the present application, and are not described herein again.

It should be noted that one pulse cycle is started when the first satellite-borne radar transmits a radar signal to the ground.

And S204, sending the first reference frequency data to a ground receiving station so that the ground receiving station can perform phase compensation on the first ground echo data by using the first reference frequency data, the second reference frequency data sent by the first satellite-borne radar and the first ground echo data.

In the embodiment of the application, after the second satellite-borne radar obtains the first reference frequency data, the first reference frequency data is sent to the ground receiving station, so that the ground receiving station performs phase compensation on the first ground echo data by using the first reference frequency data, the second reference frequency data sent by the first satellite-borne radar and the first ground echo data.

It should be noted that the first ground echo data is data obtained by demodulating the first ground echo signal by the first satellite-borne radar.

It should be noted that, the process of specifically demodulating the first ground echo signal is described in detail in the first embodiment of the present application, and is not described herein again.

In an embodiment of the present application, transmitting the first reference frequency data to the ground receiving station includes: at least the first reference frequency data is transmitted to the ground receiving station upon arrival of a pulse period.

It should be noted that at least the first reference frequency data needs to be transmitted to the ground receiving station in each pulse period.

It can be understood that the second satellite-borne radar obtains a second reference frequency signal through a second reference frequency source under the driving of the taming crystal oscillator; sending the second reference frequency signal to a first satellite-borne radar, and receiving a first reference frequency signal transmitted by the first satellite-borne radar; and processing the first reference frequency signal by using the second local oscillation frequency to obtain first reference frequency data, and sending the first reference frequency data to the ground receiving station. By adopting the implementation scheme, the reference frequency source is generated by the domestication crystal oscillator after domestication, so that the frequency deviation between the first satellite-borne radar and the second satellite-borne radar is reduced, and then the phase compensation is carried out on the first ground echo data through the received first reference frequency data and the second reference frequency data, so that the phase difference between the first satellite-borne radar and the second satellite-borne radar is eliminated, the phase synchronization between the first satellite-borne radar and the second satellite-borne radar is realized, and the purpose of improving the measurement precision of the distributed satellite radar system is achieved.

An embodiment of the present application provides a phase synchronization method, which is applied to a ground receiving station, and fig. 8 is a flow chart of the phase synchronization method provided in the embodiment of the present application, and as shown in fig. 8, the phase synchronization method may include:

s301, under the condition that second reference frequency data sent by a second satellite-borne radar, first ground echo data and first reference frequency data sent by a first satellite-borne radar are received, calculating the first reference frequency data and the second reference frequency data to obtain a phase difference.

In the embodiment of the application, the ground receiving station calculates the first reference frequency data and the second reference frequency data to obtain the phase difference when receiving the second reference frequency data, the first ground echo data and the first reference frequency data sent by the second satellite-borne radar.

It should be noted that, at the beginning of the first time period and the second time period, a frame of radar data is output, which includes auxiliary data and sampling data, where the auxiliary data includes a data type flag indicating whether the frame of data is reference frequency data or ground echo data. And the reference frequency data of the first satellite-borne radar and the second satellite-borne radar can be separated according to the data type mark.

In the embodiment of the application, after obtaining the first reference frequency data and the second reference frequency data, the ground receiving station performs fast fourier transform on the first reference frequency data and the second reference frequency data to obtain the phase difference.

In the embodiment of the present application, a peak point after the fast fourier transform is found by performing the fast fourier transform on the first reference frequency data and the second reference frequency data, and then a phase of the peak point is calculated frame by frame as a phase history of the reference frequency data, where the phase history of the first reference frequency data corresponds to a phase history in formula (2) in the first embodiment of the present applicationThe phase history of the second reference frequency data corresponds to the phase history of equation (1) in the first embodiment of the present application

To obtainAndand then, calculating the phase difference according to a formula (3) in the first embodiment of the application, and obtaining the phase difference corresponding to the first ground echo data.

S302, phase compensation is carried out on the first ground echo data by utilizing the phase difference, and the first ground echo data after the phase compensation is obtained.

In the embodiment of the application, after the ground receiving station obtains the phase difference, the phase difference is used for performing phase compensation on the first ground echo data, so as to obtain the first ground echo data after the phase compensation.

In the embodiment of the application, after the ground receiving station obtains the phase difference, the phase difference is used for performing phase compensation on the first ground echo data of the first satellite-borne radar in the same pulse period, so that phase synchronization is realized.

It can be understood that after the phase synchronization compensation, the phase synchronization processing procedure is completed, and then the echo data of the first satellite-borne radar and the second satellite-borne radar can be subjected to subsequent imaging and interference processing.

It can be understood that, when the ground receiving station receives the second reference frequency data sent by the second satellite-borne radar, the first ground echo data and the first reference frequency data sent by the first satellite-borne radar, the phase difference is obtained by calculating the first reference frequency data and the second reference frequency data; and performing phase compensation on the first ground echo data by using the phase difference to obtain the first ground echo data after the phase compensation. By adopting the implementation scheme, the reference frequency source is generated by the domestication crystal oscillator after domestication, so that the frequency deviation between the first satellite-borne radar and the second satellite-borne radar is reduced, and then the phase compensation is carried out on the first ground echo data through the received first reference frequency data and the second reference frequency data, so that the phase difference between the first satellite-borne radar and the second satellite-borne radar is eliminated, the phase synchronization between the first satellite-borne radar and the second satellite-borne radar is realized, and the purpose of improving the measurement precision of the distributed satellite radar system is achieved.

Example two

Based on the same inventive concept of the embodiments, the embodiments of the present application provide a first satellite-borne radar 1, which corresponds to a phase synchronization method applied to the first satellite-borne radar; fig. 9 is a schematic structural diagram of a first satellite-borne radar according to an embodiment of the present disclosure, and as shown in fig. 9, the first satellite-borne radar 1 may include:

the transmitting module 11 is configured to obtain a first reference frequency signal through a first reference frequency source under the driving of a taming crystal oscillator, and transmit the first reference frequency signal to a second satellite-borne radar, so that the second satellite-borne radar processes the first reference frequency signal by using a second crystal oscillator frequency corresponding to the second satellite-borne radar to obtain first reference frequency data;

the receiving module 12 is configured to receive a second reference frequency signal transmitted by the second satellite-borne radar;

the data processing module 13 is configured to process the second reference frequency signal by using a first local oscillator frequency to obtain second reference frequency data; the first local oscillator frequency is the frequency generated by the first reference frequency source;

the receiving module 12 is further configured to receive a first ground echo signal reflected by the ground, and acquire first ground echo data corresponding to the first ground echo signal; the first ground echo signal is a signal which is reflected to the first satellite-borne radar after the second satellite-borne radar transmits a radar signal to the ground;

the sending module 11 is further configured to send the first ground echo data and the second reference frequency data to a ground receiving station, so that the ground receiving station performs phase compensation on the first ground echo data by using the second reference frequency data and the first reference frequency data sent by the second satellite-borne radar.

Accordingly, the method can be used for solving the problems that,

the data processing module 13 is further configured to discipline the initial crystal oscillator drive by using an atomic clock signal and a global navigation satellite system signal, so as to obtain the disciplined crystal oscillator drive; or adopting an atomic clock signal to discipline the initial crystal oscillator drive to obtain the disciplined crystal oscillator drive.

Accordingly, the method can be used for solving the problems that,

the data processing module 13 is further configured to perform frequency doubling on the frequency of the atomic clock signal to obtain a first frequency-doubled signal;

the data processing module 13 is further configured to obtain a first reference signal by frequency synthesis using the global navigation satellite system signal and the first frequency multiplication signal;

the data processing module 13 is further configured to perform frequency doubling on the frequency of the first reference signal to obtain a second frequency-doubled signal, where the frequency of the second frequency-doubled signal is equal to the frequency of the first crystal oscillator; the first crystal oscillator frequency is the crystal oscillator frequency of the first satellite-borne radar;

the data processing module 13 is further configured to phase-lock the frequency driven by the initial crystal oscillator to the second frequency-multiplied signal, so as to obtain the tame crystal oscillator drive.

Accordingly, the method can be used for solving the problems that,

the data processing module 13 is further configured to perform frequency doubling on the frequency of the atomic clock signal to obtain a third frequency-doubled signal, where the frequency of the third frequency-doubled signal is equal to the frequency of the first crystal oscillator; the first crystal oscillator frequency is the crystal oscillator frequency of the first satellite-borne radar;

the data processing module 13 is further configured to phase-lock the frequency driven by the initial crystal oscillator to the third frequency multiplication signal, so as to obtain the taming crystal oscillator drive.

Accordingly, the method can be used for solving the problems that,

the sending module 11 is further configured to send at least the first ground echo data and the second reference frequency data to the ground receiving station when a pulse period arrives.

Accordingly, the method can be used for solving the problems that,

the sending module 11 is further configured to send the first reference frequency signal to the second satellite-borne radar in the first time period, and receive the second reference frequency signal sent by the second satellite-borne radar;

the receiving module 12 is further configured to receive the first ground echo signal reflected by the ground in the second time period.

Accordingly, the method can be used for solving the problems that,

the sending module 11 is further configured to send the first reference frequency signal to the second satellite-borne radar in the second time period, and receive the second reference frequency signal sent by the second satellite-borne radar;

the receiving module 12 is further configured to receive the first ground echo signal reflected by the ground in the first time period.

Accordingly, the method can be used for solving the problems that,

the receiving module 12 is further configured to send the first reference frequency signal to the second satellite-borne radar by using an omnidirectional antenna, and receive the second reference frequency signal transmitted by the second satellite-borne radar.

It can be understood that the first satellite-borne radar obtains a first reference frequency signal through a first reference frequency source under the driving of the taming crystal oscillator; sending the first reference frequency signal to a second satellite-borne radar, and receiving a second reference frequency signal transmitted by the second satellite-borne radar; processing the second reference frequency signal by using the first local oscillation frequency to obtain second reference frequency data; receiving a first ground echo signal reflected by the ground, and acquiring first ground echo data corresponding to the first ground echo signal; the first ground echo signal is a signal which is reflected to the first satellite-borne radar after the second satellite-borne radar transmits a radar signal to the ground; and sending the first ground echo data and the second reference frequency data to a ground receiving station. By adopting the implementation scheme, the reference frequency source is generated by the domestication crystal oscillator after domestication, so that the frequency deviation between the first satellite-borne radar and the second satellite-borne radar is reduced, and then the phase compensation is carried out on the first ground echo data through the received first reference frequency data and the second reference frequency data, so that the phase difference between the first satellite-borne radar and the second satellite-borne radar is eliminated, the phase synchronization between the first satellite-borne radar and the second satellite-borne radar is realized, and the purpose of improving the measurement precision of the distributed satellite radar system is achieved.

Fig. 10 is a schematic structural diagram of a second composition structure of the first satellite-borne radar 1 according to an embodiment of the present application, and in practical applications, based on the same disclosure concept of the foregoing embodiment, as shown in fig. 10, the first satellite-borne radar 1 according to the present embodiment includes: a first transmitter 14, a first receiver 15, a first processor 16, a first memory 17 and a first communication bus 18.

In a Specific embodiment, the data Processing module 13 may be implemented by a first Processor 16 located on the first satellite radar 1, the transmitting module 11 may be implemented by a first transmitter 14 located on the first satellite radar 1, the receiving module 12 may be implemented by a first receiver 15 located on the first satellite radar 1, and the first Processor 16 may be at least one of an Application Specific Integrated Circuit (ASIC), a Digital Signal Processor (DSP), a Digital Signal Processing Device (DSPD), a Programmable Logic Device (PLD), a Field Programmable Gate Array (FPGA), a CPU, a controller, a microcontroller, and a Gate Array. It is understood that the electronic device for implementing the above-mentioned processor function may be other devices, and the embodiment is not limited in particular.

In the embodiment of the present application, the first communication bus 18 is used for the first processor 16, the first transmitter 14, the first receiver 15, and the first memory 17; in the first transmitter 14, the first processor 16 executes an operating program stored in the first memory 17.

In the embodiment of the present application, a first schematic diagram of an exemplary hardware of a first satellite-borne radar is provided, as shown in fig. 11, where the following components are included: the system comprises a frequency modulation signal source, a power amplifier, an antenna, a monitoring timer, a reference frequency source, a synchronous signal amplifier, a global navigation satellite system receiver, a taming crystal oscillator, a data former and a radar receiver. The specific implementation mode is as follows: the satellite navigation system receiver and the tame crystal oscillator drive a reference frequency source to generate various reference frequency signals required by a satellite-borne radar, the reference frequency source generates the reference frequency signals, the reference frequency signals pass through an amplifier and a circulator in a synchronous signal amplifier and then are transmitted to another satellite-borne radar through a synchronous antenna, and the satellite-borne radar has two schemes when receiving the reference frequency signals transmitted by the other satellite-borne radar, wherein one scheme is that the satellite-borne radar adopts an intermediate frequency sampling scheme when receiving the signals, and the other scheme is that the satellite-borne radar adopts a video sampling scheme when receiving the signals. While the scheme one is adopted in fig. 11, the scheme two is adopted in the following fig. 12, when the satellite-borne radar adopts an intermediate frequency sampling scheme in receiving signals, the radar receiver outputs intermediate frequency signals, after receiving reference frequency signals transmitted by another satellite-borne radar through the synchronous antenna, the signals are output to the data former for sampling and quantization under the control of channel switching timing signals after being amplified by the circulator and the low noise in the signal amplifier, and the channel switching timing signals are output through the monitoring timer and are sent to the data transmission equipment of the satellite after being packed by the data former to be transmitted to the ground receiving station.

In the embodiment of the present application, another exemplary first hardware schematic diagram of a satellite-borne radar is provided, as shown in fig. 12, which includes the following components: the system comprises a frequency modulation signal source, a power amplifier, an antenna, a monitoring timer, a reference frequency source, a synchronous signal amplifier, a global navigation satellite system receiver, a taming crystal oscillator, a data former and a radar receiver. The specific implementation mode is as follows: the global navigation satellite system and the tame crystal oscillator drive a reference frequency source to generate various reference frequency signals required by a satellite-borne radar, the reference frequency source generates the reference frequency signals, the reference frequency signals pass through an amplifier and a circulator in a synchronous signal amplifier and are transmitted to another satellite-borne radar through a synchronous antenna, when the satellite-borne radar adopts a video sample scheme when receiving the reference frequency signals, the other path of a gating switch inputs the received reference frequency signals, a channel switching timing signal controls the gating switch to be switched to a phase synchronous signal end in a transmission time period of the reference frequency signals, a radar receiver down-converts radio frequency received signals to intermediate frequency and outputs the intermediate frequency received signals to a gating switch, then subsequent orthogonal demodulation is carried out, the intermediate frequency received signals are output to a data former to be sampled and quantized under the control of the channel switching timing signal, and the channel switching timing signal is output through a monitoring timer, and the data is packed by the data former and then sent to the data transmission equipment of the satellite to be transmitted to the ground receiving station.

Based on the same inventive concept of the embodiments, the embodiments of the present application provide a second satellite-borne radar 2, which corresponds to a phase synchronization method applied to the second satellite-borne radar; fig. 13 is a schematic structural diagram of a second satellite-borne radar according to an embodiment of the present invention, as shown in fig. 13, the second satellite-borne radar 2 may include:

the sending module 21 is configured to obtain a second reference frequency signal through a second reference frequency source under the driving of the taming crystal oscillator, and send the second reference frequency signal to the first satellite-borne radar;

a receiving module 22, configured to receive a first reference frequency signal transmitted by the first satellite-borne radar;

the data processing module 23 is configured to process the first reference frequency signal by using a second local oscillation frequency to obtain first reference frequency data, where the second local oscillation frequency is a frequency generated by the second reference frequency source;

the sending module 21 is further configured to send the first reference frequency data to a ground receiving station, so that the ground receiving station performs phase compensation on the first ground echo data by using the first reference frequency data, the second reference frequency data sent by the first satellite-borne radar, and the first ground echo data.

In some embodiments of the present application, the second satellite borne radar further comprises a transmitting module 24;

the transmitting module 24 is configured to transmit a radar signal to the ground, so that a first satellite-borne radar receives a first ground echo signal reflected by the ground after the radar signal is transmitted, and acquires first ground echo data corresponding to the first ground echo signal.

Accordingly, the method can be used for solving the problems that,

the sending module 21 is further configured to send at least the first reference frequency data to the ground receiving station when a pulse period arrives.

It can be understood that the second satellite-borne radar obtains a second reference frequency signal through a second reference frequency source under the driving of the taming crystal oscillator; sending the second reference frequency signal to a first satellite-borne radar, and receiving a first reference frequency signal transmitted by the first satellite-borne radar; and processing the first reference frequency signal by using the second local oscillation frequency to obtain first reference frequency data, and sending the first reference frequency data to the ground receiving station. By adopting the implementation scheme, the reference frequency source is generated by the domestication crystal oscillator after domestication, so that the frequency deviation between the first satellite-borne radar and the second satellite-borne radar is reduced, and then the phase compensation is carried out on the first ground echo data through the received first reference frequency data and the second reference frequency data, so that the phase difference between the first satellite-borne radar and the second satellite-borne radar is eliminated, the phase synchronization between the first satellite-borne radar and the second satellite-borne radar is realized, and the purpose of improving the measurement precision of the distributed satellite radar system is achieved.

Fig. 14 is a schematic structural diagram of a second constituent structure of the second satellite-borne radar 2 according to an embodiment of the present application, and in practical application, based on the same disclosure concept of the foregoing embodiment, as shown in fig. 14, the second satellite-borne radar 2 according to the present embodiment includes: a second transmitter 24, a second receiver 25, a second processor 26, a second memory 27 and a second communication bus 28.

In a Specific embodiment, the data Processing module 23 may be implemented by a second Processor 26 located on the second satellite radar 2, the transmitting module 21 may be implemented by a second transmitter 24 located on the second satellite radar 2, the receiving module 22 may be implemented by a second receiver 25 located on the second satellite radar 2, and the second Processor 26 may be at least one of an Application Specific Integrated Circuit (ASIC), a Digital Signal Processor (DSP), a Digital Signal Processing Device (DSPD), a Programmable Logic Device (PLD), a Field Programmable Gate Array (FPGA), a CPU, a controller, a microcontroller, and a Gate Array. It is understood that the electronic device for implementing the above-mentioned processor function may be other devices, and the embodiment is not limited in particular.

In the embodiment of the present application, the second communication bus 28 is used for the second processor 26, the second transmitter 24, the second receiver 25, and the second memory 27; the second transmitter 24 and the second processor 26 execute an operating program stored in the second memory 27.

Based on the same inventive concept of the embodiments, the embodiments of the present application provide a ground receiving station 3, which corresponds to a phase synchronization method applied in the ground receiving station; fig. 15 is a schematic structural diagram of a ground receiving station according to an embodiment of the present invention, as shown in fig. 15, the ground receiving station 3 may include:

the data processing module 31 is configured to calculate the first reference frequency data and the second reference frequency data to obtain a phase difference when receiving second reference frequency data, first ground echo data, and first reference frequency data sent by a second satellite-borne radar;

the data processing module 31 is further configured to perform phase compensation on the first ground echo data by using the phase difference, so as to obtain the first ground echo data after phase compensation.

In some embodiments of the present application, the ground receiving station further comprises a receiving module 32;

the receiving module 32 is configured to receive second reference frequency data sent by a second satellite-borne radar, first ground echo data, and first reference frequency data sent by a first satellite-borne radar.

Accordingly, the method can be used for solving the problems that,

the data processing module 31 is further configured to perform fast fourier transform on the first reference frequency data and the second reference frequency data to obtain the phase difference.

It can be understood that, when the ground receiving station receives the second reference frequency data sent by the second satellite-borne radar, the first ground echo data and the first reference frequency data sent by the first satellite-borne radar, the phase difference is obtained by calculating the first reference frequency data and the second reference frequency data; and performing phase compensation on the first ground echo data by using the phase difference to obtain the first ground echo data after the phase compensation. By adopting the implementation scheme, the reference frequency source is generated by the domestication crystal oscillator after domestication, so that the frequency deviation between the first satellite-borne radar and the second satellite-borne radar is reduced, and then the phase compensation is carried out on the first ground echo data through the received first reference frequency data and the second reference frequency data, so that the phase difference between the first satellite-borne radar and the second satellite-borne radar is eliminated, the phase synchronization between the first satellite-borne radar and the second satellite-borne radar is realized, and the purpose of improving the measurement precision of the distributed satellite radar system is achieved.

Fig. 16 is a schematic structural diagram of a second composition structure of the ground receiving station 3 provided in the embodiment of the present application, and in practical application, based on the same disclosure concept of the foregoing embodiment, as shown in fig. 16, the ground receiving station 3 of the present embodiment includes: a third receiver 33, a third processor 34, a third memory 35 and a third communication bus 36.

In a Specific embodiment, the data Processing module 31 may be implemented by a third Processor 34 located on the ground receiving station 3, the receiving module 32 may be implemented by a third receiver 33 located on the ground receiving station 3, and the third Processor 34 may be at least one of an Application Specific Integrated Circuit (ASIC), a Digital Signal Processor (DSP), a Digital Signal Processing Device (DSPD), a Programmable Logic Device (PLD), a Field Programmable Gate Array (FPGA), a CPU, a controller, a microcontroller, and a microprocessor. It is understood that the electronic device for implementing the above-mentioned processor function may be other devices, and the embodiment is not limited in particular.

In the embodiment of the present application, the third communication bus 36 is used for the third processor 34, the third receiver 33, and the third memory 35; the third processor 34 executes the operation program stored in the third memory 35.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

Through the above description of the embodiments, those skilled in the art will clearly understand that the method of the above embodiments can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware, but in many cases, the former is a better implementation manner. Based on such understanding, the technical solutions of the present disclosure may be embodied in the form of a software product, which is stored in a storage medium (e.g., ROM/RAM, magnetic disk, optical disk) and includes instructions for enabling an image display device (which may be a computer, a server, or a network device) to execute the method according to the embodiments of the present disclosure.

The above description is only a preferred embodiment of the present application, and is not intended to limit the scope of the present application.

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