CN115079304B - Microwave radiometer and method for simulating cloud water distribution - Google Patents

Abstract

The invention discloses a microwave radiometer and a method for simulating cloud water distribution, and belongs to the technical field of liquid water detection in clouds. In order to solve the problems that cloud water resource distribution display is not visual and manual operation is difficult to simulate, the cloud water resource data visualization system is set to visually simulate the cloud water resource distribution through a three-dimensional model, the traditional detection defect is overcome, the cloud water resource distribution condition, the moving running track and the like in the corresponding atmosphere environment can be more clearly and intuitively understood, the cloud water resource can be mastered by workers and the follow-up manual intervention operation can be conveniently implemented by workers, the detection result display is more visual and effective, the setting of the simulation auxiliary system enables that after the simulation operation is carried out, the cloud water resource distribution simulation MR holographic image and the image can generate corresponding effects according to the corresponding operation, the effect prediction and simulation on the behavior of other manual intervention cloud water resources such as artificial rainfall are improved, and the accuracy and the practicability of decision are improved.

Description

Microwave radiometer and method for simulating cloud water distribution

Technical Field

The invention relates to the technical field of liquid water detection in clouds, in particular to a microwave radiometer and a method for simulating cloud water distribution.

Background

Cloud water resources mean water resources that are available through natural precipitation. The cloud water resources in different regions and different precipitation clouds are greatly different, and the cloud water resources are required to be evaluated through observation and comprehensive analysis of various instruments.

When the cloud water resource distribution is detected in the prior art, the following defects often exist: when the cloud water resource distribution situation obtained by detection is displayed, more visual and three-dimensional display is difficult to achieve; before the relative cloud water resources are subjected to manual intervention operations such as artificial rainfall, a certain simulation system is lacked, so that the later effect generated by the manual intervention of the cloud water resources is not easy to expect and infer.

Disclosure of Invention

The invention aims to provide a microwave radiometer and a method for simulating cloud water distribution, which have the advantages of more visual cloud water resource distribution display and capability of simulating manual operation so as to solve the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions: a microwave radiometer for simulating cloud water distribution comprises a cloud water resource data processing system, a cloud water resource data visualization system, a simulation auxiliary system, a cloud platform, a lower processor, acquisition equipment, a microwave radiometer body and a simulation platform;

the cloud water resource data processing system is used for constructing a virtual cloud water resource distribution environment, including a cloud water resource distribution and a virtualized space of an atmospheric environment;

the cloud water resource data visualization system is used for matching artificial data after receiving virtual environment data of the cloud water resource data processing system and presenting MR holographic images or images;

the simulation auxiliary system is used for interacting the virtual space with the actual operation, and dynamically presenting the manual cloud water resource distribution operation process;

the cloud platform respectively transmits the classified information to the simulation platform after storing and editing through the cloud, and returns feedback information, wherein the classified stored data are grouped according to stream attribute information and data content and classified and marked;

the lower processor is used for processing and treating cloud water resource data, the cloud water resource data processing system, the cloud water resource data visualization system and the simulation auxiliary system are arranged in the lower processor, the lower processor is in communication connection with the acquisition equipment and the microwave radiometer body, and the lower processor is in network connection with the cloud platform through the Internet or a local area network;

the acquisition equipment is used for detecting atmospheric environment information required by cloud water resource distribution simulation, and comprises a Raman laser radar, a millimeter wave cloud radar, a wind profile radar and a Doppler wind-measuring laser radar;

the microwave radiometer body utilizes the passive microwave signals for receiving the temperature radiation transmitted by each height to judge the temperature and humidity curves, quantitatively measures the low-level microwave radiation of the atmospheric environment, and receives microwaves with high sensitivity and high resolution;

the simulation platform receives operation data feedback of the simulation auxiliary system and the lower processor, sends feedback information to the cloud platform, and is used for displaying cloud water resource distribution simulation MR holographic images or images generated by the cloud water resource data visualization system.

Further, the cloud water resource data processing system comprises a data acquisition management unit and a data calculation unit;

the data acquisition management unit is used for carrying out signal connection with the acquisition equipment and the microwave radiometer body, and sending a control command to the equipment control circuit to quantitatively acquire data;

the data calculation unit is used for calculating the atmospheric environment data acquired by the data acquisition management unit to obtain cloud water resource distribution data and atmospheric environment simulation data.

Further, after each part in the acquisition equipment detects atmospheric environment information, the detection data are uploaded to a lower processor;

the Raman laser radar is combined with the microwave radiometer body to detect cloud system temperature and humidity data;

the millimeter wave cloud radar is combined with the microwave radiometer body to detect a cloud water content profile;

the cloud system horizontal wind speed is detected by the wind profile radar;

the Doppler wind lidar detects the vertical movement speed of the cloud base.

Further, after the microwave radiometer body receives the microwave signals of the temperature radiation, the temperature and humidity curves are judged, the low-level microwave radiation of the atmospheric environment is quantitatively measured, and corresponding data obtained through measurement are uploaded to a lower processor.

Further, the cloud water resource data visualization system comprises a holographic image playing module, an angle acquisition module and a visualization recording module;

the holographic image playing module is used for acquiring the cloud water resource data processing system, constructing cloud water resource distribution simulation model data and then rendering three dimensions to obtain an MR holographic image and an image;

the angle acquisition module is used for processing the shielding relation between the MR hologram and a real object and between objects in the MR hologram through the reflection of the projection entity of the hologram playing module;

the visual recording module is used for recording the holographic image and the real operation played by the holographic image playing module in real time and uploading the holographic image and the real operation to the cloud platform.

Furthermore, the holographic image playing module converts a plurality of paths of video data streams into a format and resolution required by the adaptive playing according to the adaptive information.

Further, the holographic image playing module projects and generates a light source to irradiate an object in a real environment, the object is positioned on other bright and dark surfaces outside a bright and dark boundary line, the object is slightly influenced by reflection of other substances to form a reflecting surface, and the intensity of reflection is determined by the depth of the inherent color of the object, the capability of receiving the influence of the texture of the object and the intensity of the influence of the environment in opposite directions;

the angle acquisition module is more clear and deeper when the object is closer to the body under the influence of the distance between the light source and the body, and has stronger contrast with the brightness of the bright part; the farther the distance is, the more blurred and shallower the light and shade contrast with the bright part is, and the processing of the shielding relation between the MR hologram and the real object and between the objects in the MR hologram is realized.

Further, the simulation auxiliary system comprises an interaction module, a behavior decision module and a behavior model database;

the interaction module is based on the angle acquisition module and is used for accurately positioning the acquired operation position;

the behavior decision module is used for acquiring the simulated operation behavior of an operator, the behavior model database provides a data base for the behavior decision module, the behavior in the operation of the cloud water resource data visualization system is matched according to the operation, and the determined operation instruction is fed back to the behavior decision module;

the behavior decision module applies the determined running instruction to the running cloud water resource data visualization system.

Furthermore, the projection function of the holographic image playing module is MR holographic images.

The invention provides a method for simulating a cloud water distribution microwave radiometer, which comprises the following steps:

step one: the acquisition equipment and the microwave radiometer body detect cloud system temperature and humidity data, cloud water content profile, cloud system horizontal wind speed and vertical movement speed of a cloud bottom, and upload atmospheric environment data obtained by detection to a cloud platform and a lower processor;

step two: the cloud platform edits and stores the data at the cloud, the cloud water resource data processing system processes and calculates the detected atmospheric environment data, and the processing result information is transmitted back to the cloud water resource data visualization system;

step three: the simulation platform performs simulation display on the cloud water resource distribution simulation MR holographic image and the image constructed by the cloud water resource data visualization system, and performs manual operation simulation on the displayed cloud water resource distribution simulation MR holographic image and image through the simulation auxiliary system

Compared with the prior art, the invention has the beneficial effects that:

1. according to the microwave radiometer and the method for simulating cloud water distribution, which are provided by the invention, the cloud water resource data visualization system comprises the holographic image playing module, the angle acquisition module and the visual recording module, the cloud water resource data visualization system is arranged through the three-dimensional model cloud water resource distribution visual simulation, the traditional detection defect is broken through, the cloud water resource distribution situation, the moving track and the like in the corresponding atmospheric environment can be more clearly and intuitively known, the cloud water resource can be mastered by workers and the subsequent implementation of manual intervention operation of the workers is facilitated, and the detection result display is more intuitive and effective.

2. According to the microwave radiometer and the method for simulating cloud water distribution, provided by the invention, the simulation auxiliary system comprises the interaction module, the behavior decision module and the behavior model database, the simulation auxiliary system is arranged to enable manual intervention operation, such as artificial rainfall, to be performed on cloud water resources at a simulated position in the system, after the simulation auxiliary system performs simulation operation, the system can perform related intervention operation on MR holographic images and images simulated on cloud water resource distribution, and then the holographic images and images can generate corresponding effects according to corresponding operation, so that simulation on manual operation by workers is facilitated, effect prediction and simulation on the behavior of other artificial intervention cloud water resources such as artificial rainfall are improved, and accuracy and feasibility of decision are improved.

Drawings

FIG. 1 is a schematic diagram of the overall module of the present invention;

FIG. 2 is a schematic diagram of a cloud water resource data processing system module according to the present invention;

FIG. 3 is a schematic diagram of an acquisition device and microwave radiometer module according to the present invention;

FIG. 4 is a schematic diagram of a cloud water resource data visualization system module according to the present invention;

FIG. 5 is a schematic diagram of a simulation assistance system according to the present invention.

In the figure: 1. cloud water resource data processing system; 11. a data acquisition management unit; 12. a data calculation unit; 2. the cloud water resource data visualization system; 21. a holographic image playing module; 22. an angle acquisition module; 23. a visual recording module; 3. a simulation auxiliary system; 31. an interaction module; 32. a behavior decision module; 33. a behavior model database; 4. a cloud platform; 5. a lower processor; 6. a collection device; 7. a microwave radiometer body; 8. and simulating a platform.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1, a microwave radiometer for simulating cloud water distribution comprises a cloud water resource data processing system 1, a cloud water resource data visualization system 2, a simulation auxiliary system 3, a cloud platform 4, a lower processor 5, acquisition equipment 6, a microwave radiometer body 7 and a simulation platform 8; the cloud water resource data processing system 1 is used for constructing a virtual cloud water resource distribution environment, including a virtual space of cloud water resource distribution and atmospheric environment; the cloud water resource data visualization system 2 is used for matching artificial data after receiving virtual environment data of the cloud water resource data processing system 1 and presenting MR holographic images or images; the simulation auxiliary system 3 is used for interacting the virtual space with the actual operation, and dynamically presenting the manual cloud water resource distribution operation process; after cloud platform 4 stores and edits through the cloud, the classified information is respectively transmitted to simulation platform 8, feedback information is returned, and the classified stored data are grouped according to stream attribute information and data content, and classified marks are formed; the lower processor 5 is used for processing and treating cloud water resource data, the cloud water resource data processing system 1, the cloud water resource data visualization system 2 and the simulation auxiliary system 3 are arranged in the lower processor 5, the lower processor 5 is in communication connection with the acquisition equipment 6 and the microwave radiometer body 7, and the lower processor 5 is in network connection with the cloud platform 4 through the Internet or a local area network; the acquisition equipment 6 is used for detecting atmospheric environment information required by cloud water resource distribution simulation, and comprises a Raman laser radar, a millimeter wave cloud radar, a wind profile radar and a Doppler wind-measuring laser radar; the microwave radiometer body 7 utilizes the passive microwave signals for receiving the temperature radiation transmitted by each height to judge the temperature and humidity curves, quantitatively measures the low-level microwave radiation of the atmosphere environment, and receives microwaves with high sensitivity and high resolution; the simulation platform 8 receives feedback of operation data of the simulation auxiliary system 3 and the lower processor 5, sends feedback information to the cloud platform 4, and is used for displaying cloud water resource distribution simulation MR holographic images or images generated by the cloud water resource data visualization system 2, and when the simulation platform works, the acquisition equipment 6 and the microwave radiometer body 7 detect cloud system temperature and humidity data, cloud water content profile, cloud system horizontal wind speed and vertical movement speed of the cloud bottom, and upload atmospheric environment data obtained by detection to the cloud platform 4 and the lower processor 5; the cloud platform 4 edits and stores the data at the cloud, the cloud water resource data processing system 1 processes and calculates the detected atmospheric environment data, and the processing result information is transmitted back and sent to the cloud water resource data visualization system 2; the simulation platform 8 performs simulation display on the cloud water resource distribution simulation MR holographic image and the image constructed by the cloud water resource data visualization system 2, and the simulation auxiliary system 3 performs manual operation simulation on the displayed cloud water resource distribution simulation MR holographic image and the displayed cloud water resource distribution simulation MR holographic image.

Referring to fig. 2, the cloud water resource data processing system 1 includes a data acquisition management unit 11 and a data calculation unit 12; the data acquisition management unit 11 is used for carrying out signal connection with the acquisition equipment 6 and the microwave radiometer body 7, and sending a control command to the equipment control circuit to quantitatively acquire data; the data calculation unit 12 is configured to calculate the atmospheric environment data collected by the data collection management unit 11, obtain cloud water resource distribution data and atmospheric environment simulation data, and the data collection management unit 11 and the data calculation unit 12 can collect, integrate and calculate the atmospheric environment data detected by the various collection devices 6 and the microwave radiometer body 7, and then analyze the distribution of the cloud water resources in the atmosphere, so as to obtain the resource distribution data, and the cloud water resource data visualization system 2 performs cloud water distribution simulation.

Referring to fig. 3, after each component in the collecting device 6 detects atmospheric environment information, the detected data is uploaded to the lower processor 5; the Raman laser radar is combined with the microwave radiometer body 7 to detect cloud system temperature and humidity data; the millimeter wave cloud radar is combined with the microwave radiometer body 7 to detect the cloud water content profile; the cloud system horizontal wind speed is detected by the wind profile radar; the Doppler wind lidar detects the vertical movement speed of the cloud base. After the microwave radiometer body 7 receives the microwave signals of the temperature radiation, the temperature and humidity curves are judged, the low-level microwave radiation of the atmospheric environment is quantitatively measured, corresponding data obtained by measurement are uploaded to the lower processor 5, various acquisition devices 6 and the microwave radiometer body 7 can detect atmospheric environment data required by simulating cloud water resource distribution, and therefore the cloud water resource distribution condition is calculated and simulated by using the detected various data for the cloud water resource data processing system 1.

Referring to fig. 4, the cloud water resource data visualization system 2 includes a hologram playing module 21, an angle obtaining module 22 and a visualization recording module 23; the holographic image playing module 21 is used for obtaining MR holographic images and images after the cloud water resource data processing system 1 constructs cloud water resource distribution simulation model data; the angle acquisition module 22 is used for processing the shielding relation between the MR hologram and the real object and between the objects in the MR hologram through the reflection of the projection entity of the hologram playing module 21; the visual recording module 23 is used for recording the holographic image and the actual operation played by the holographic image playing module 21 in real time and uploading the recorded holographic image and the actual operation to the cloud platform 4, the cloud water resource data visual system 2 is set through the visual simulation of the cloud water resource distribution of the three-dimensional model, the traditional detection defect is broken through, the cloud water resource distribution condition, the moving track and the like in the corresponding atmosphere environment can be more clearly and intuitively understood, the staff can master the cloud water resource and subsequently implement the manual intervention operation of the staff, and the detection result display is more visual and effective.

The hologram playing module 21 converts a plurality of paths of video data streams into a format and resolution required by the adaptive playing according to the adaptive information, and the projection function of the hologram playing module 21 is MR hologram. The holographic image playing module 21 projects a light source to irradiate an object in a real environment, and other bright and dark surfaces outside a bright and dark boundary line are affected by the reflection of other substances to form a reflecting surface, wherein the intensity of the reflection is determined by the intensity of the inherent color of the object, the capability of receiving the influence of the texture of the object and the intensity of the opposite influence of the environment; the angle acquisition module 22 is more clear and deeper as the object is closer to the body by being influenced by the distance between the light source and the body, and has stronger brightness contrast with the bright part; the farther the distance is, the more blurred and shallower the light and shade contrast with the bright part is, the processing of the shielding relation between the MR holographic image and the real object and between the objects in the MR holographic image is realized, the simulation of the cloud water resource distribution is more real and effective by the multi-module cooperation work, and the follow-up related work operation of the staff on the detection result is facilitated.

Referring to fig. 5, the simulation assistance system 3 includes an interaction module 31, a behavior decision module 32, and a behavior model database 33; the interaction module 31 is based on the angle acquisition module 22 and is used for accurately positioning the acquired operation position; the behavior decision module 32 is used for acquiring the simulated operation behavior of an operator, the behavior model database 33 provides a data base for the behavior decision module 32, matches the behavior in the operation of the cloud water resource data visualization system 2 according to the operation, and feeds back the determined operation instruction to the behavior decision module 32; the behavior decision module 32 applies the determined running instruction to the running cloud water resource data visualization system 2, and the simulation auxiliary system 3 is arranged to enable manual intervention operation, such as artificial rainfall, to be performed on the cloud water resource at the simulated position in the system, after the simulation auxiliary system 3 performs simulation operation, the system performs related intervention operation on the cloud water resource distribution simulation MR holographic image and image, and then the holographic image and image generate corresponding effects according to the corresponding operation, so that simulation of manual operation by workers is facilitated, effect prediction and simulation on the behavior of other manual intervention cloud water resources such as artificial rainfall are improved, and accuracy and feasibility of decision are improved.

In order to better show the microwave radiometer simulating the cloud water distribution, the embodiment now provides a method for simulating the microwave radiometer simulating the cloud water distribution, which comprises the following steps:

step one: the acquisition equipment 6 and the microwave radiometer body 7 detect cloud system temperature and humidity data, cloud water content profile, cloud system horizontal wind speed and vertical movement speed of the cloud bottom, and upload atmospheric environment data obtained by detection to the cloud platform 4 and the lower processor 5;

step two: the cloud platform 4 edits and stores the data at the cloud, the cloud water resource data processing system 1 processes and calculates the detected atmospheric environment data, and the processing result information is transmitted back and sent to the cloud water resource data visualization system 2;

step three: the simulation platform 8 performs simulation display on the cloud water resource distribution simulation MR holographic image and the image constructed by the cloud water resource data visualization system 2, and the simulation auxiliary system 3 performs manual operation simulation on the displayed cloud water resource distribution simulation MR holographic image and the displayed cloud water resource distribution simulation MR holographic image.

In summary, the setting of the cloud water resource data visualization system 2 breaks through the traditional detection defect through the visual simulation of the cloud water resource distribution of the three-dimensional model, so that the cloud water resource distribution condition, the moving track and the like in the corresponding atmosphere environment can be more clearly and intuitively understood, the mastering of the cloud water resource by workers and the subsequent implementation of the manual intervention operation of the cloud water resource are facilitated, the detection result display is more intuitively and effectively shown, the setting of the simulation auxiliary system 3 enables the artificial intervention operation, such as artificial rainfall, to be performed on the cloud water resource at the simulated position in the system, after the simulation auxiliary system 3 performs the simulation operation, the system can perform related intervention operation on the cloud water resource distribution simulation MR holographic image and the image, and then the holographic image and the image can generate corresponding effects according to the corresponding operation, so that the simulation of the manual operation by workers is facilitated, the effect prediction and simulation on the behavior of other manual intervention cloud water resource such as artificial rainfall are improved, and the accuracy and the feasibility of decision are improved.

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should be covered by the protection scope of the present invention by making equivalents and modifications to the technical solution and the inventive concept thereof.

Claims (9)

1. The microwave radiometer simulating cloud water distribution is characterized by comprising a cloud water resource data processing system (1), a cloud water resource data visualization system (2), a simulation auxiliary system (3), a cloud platform (4), a lower processor (5), acquisition equipment (6), a microwave radiometer body (7) and a simulation platform (8),

the cloud water resource data processing system (1) is used for constructing a virtual cloud water resource distribution environment, and comprises a cloud water resource distribution and a virtualized space of an atmospheric environment;

the cloud water resource data visualization system (2) is used for receiving virtual environment data of the cloud water resource data processing system (1), matching with artificial data and presenting MR holographic images or images;

the simulation auxiliary system (3) is used for interacting the virtual space with the actual operation, and dynamically presenting the manual cloud water resource distribution operation process;

the cloud platform (4) respectively transmits the classified information to the simulation platform (8) after cloud storage and editing, and returns feedback information, and the cloud platform is used for grouping the classified stored data according to stream attribute information and data content and classifying and marking;

the lower processor (5) is used for processing and treating cloud water resource data, the cloud water resource data processing system (1), the cloud water resource data visualization system (2) and the simulation auxiliary system (3) are arranged in the lower processor (5), the lower processor (5) is in communication connection with the acquisition equipment (6) and the microwave radiometer body (7), and the lower processor (5) is in network connection with the cloud platform (4) through the Internet or a local area network;

the acquisition equipment (6) is used for detecting atmospheric environment information required by cloud water resource distribution simulation, and comprises a Raman laser radar, a millimeter wave cloud radar, a wind profile radar and a Doppler wind lidar;

the microwave radiometer body (7) utilizes the passive microwave signals for receiving the temperature radiation transmitted by each height to judge the temperature and humidity curves, quantitatively measures the low-level microwave radiation of the atmosphere environment, and receives microwaves with high sensitivity and high resolution;

the simulation platform (8) receives operation data feedback of the simulation auxiliary system (3) and the lower processor (5), sends feedback information to the cloud platform (4), and is used for displaying cloud water resource distribution simulation MR holographic images or images generated by the cloud water resource data visualization system (2).

2. A microwave radiometer simulating cloud water distribution as claimed in claim 1, wherein: the cloud water resource data processing system (1) comprises a data acquisition management unit (11) and a data calculation unit (12);

the data acquisition management unit (11) is used for carrying out signal connection with the acquisition equipment (6) and the microwave radiometer body (7), and sending a control command to the equipment control circuit to quantitatively acquire data;

the data calculation unit (12) is used for calculating the atmospheric environment data acquired by the data acquisition management unit (11) to obtain cloud water resource distribution data and atmospheric environment simulation data.

3. A microwave radiometer simulating cloud water distribution as claimed in claim 1, wherein: after each part in the acquisition equipment (6) detects atmospheric environment information, uploading detection data to the lower processor (5);

the Raman laser radar is combined with the microwave radiometer body (7) to detect cloud system temperature and humidity data;

the millimeter wave cloud radar is combined with the microwave radiometer body (7) to detect the cloud water content profile;

the cloud system horizontal wind speed is detected by the wind profile radar;

the Doppler wind lidar detects the vertical movement speed of the cloud base.

4. A microwave radiometer simulating cloud water distribution as claimed in claim 3, wherein: after receiving the microwave signals of the temperature radiation, the microwave radiometer body (7) judges the temperature and humidity curves, quantitatively measures the low-level microwave radiation of the atmospheric environment and uploads corresponding data obtained by measurement to the lower processor (5).

5. A microwave radiometer simulating cloud water distribution as claimed in claim 1, wherein: the cloud water resource data visualization system (2) comprises a holographic image playing module (21), an angle acquisition module (22) and a visualization recording module (23);

the holographic image playing module (21) is used for acquiring the cloud water resource data processing system (1) to construct cloud water resource distribution simulation model data and then performing three-dimensional rendering to obtain an MR holographic image and an image;

the angle acquisition module (22) is used for processing the shielding relation between the MR hologram and a real object and between objects in the MR hologram through the reflection of a projection entity of the hologram playing module (21);

the visual recording module (23) is used for recording the holographic images and the actual operation played by the holographic image playing module (21) in real time and uploading the holographic images and the actual operation to the cloud platform (4).

6. A microwave radiometer simulating cloud water distribution as claimed in claim 5, wherein: the holographic image playing module (21) converts a plurality of paths of video data streams into a format and resolution required by the adaptive playing according to the adaptive information.

7. A microwave radiometer simulating cloud water distribution as claimed in claim 1, wherein: the simulation assistance system (3) comprises an interaction module (31), a behavior decision module (32) and a behavior model database (33), wherein,

the interaction module (31) is based on the angle acquisition module (22) and is used for accurately positioning the acquired operation position;

the behavior decision module (32) is used for acquiring the simulated operation behavior of an operator, the behavior model database (33) provides a data base for the behavior decision module (32), matches the behavior of the cloud water resource data visualization system (2) in operation according to the operation, and feeds back the determined operation instruction to the behavior decision module (32);

the behavior decision module (32) applies the determined running instruction to the running cloud water resource data visualization system (2).

8. A microwave radiometer simulating cloud water distribution as claimed in claim 5, wherein: the holographic image playing module (21) has a projection function of MR holographic images.

9. A method of using a microwave radiometer simulating cloud water distribution according to any of claims 1-8, wherein: the method comprises the following steps:

step one: the acquisition equipment (6) and the microwave radiometer body (7) detect cloud system temperature and humidity data, cloud water content profile, cloud system horizontal wind speed and vertical movement speed of a cloud bottom, and upload atmospheric environment data obtained by detection to the cloud platform (4) and the lower processor (5);

step two: the cloud platform (4) edits and stores the data at the cloud, the cloud water resource data processing system (1) processes and calculates the detected atmospheric environment data, and the processing result information is transmitted back to the cloud water resource data visualization system (2);

step three: the simulation platform (8) performs simulation display on the cloud water resource distribution simulation MR holographic image and the image constructed by the cloud water resource data visualization system (2), and the simulation auxiliary system (3) performs manual operation simulation on the displayed cloud water resource distribution simulation MR holographic image and the displayed cloud water resource distribution simulation MR holographic image.