CN116171780A - Control method and device for multi-smoke-oven combined sowing catalyst, storage medium and server - Google Patents

Abstract

The application provides a control method, a device, a storage medium and a server for multi-smoke-oven combined sowing catalysts, which comprise the following steps: acquiring meteorological data; the meteorological data comprises air flow information and cloud layer information; acquiring an operable cloud layer in the target influence area based on the cloud layer information; acquiring first position information of the operable cloud layer and precipitation information of the cloud layer; acquiring second position information of each smoke furnace in the target influence area and surrounding smoke furnaces; generating smoke furnace broadcasting work control information based on the first position information, cloud layer precipitation information, air flow information and the second position information; the tobacco furnace broadcasting work control information comprises a target tobacco furnace position, a catalyst broadcasting amount of the target tobacco furnace, a catalyst broadcasting frequency and a catalyst broadcasting time; and controlling the target smoke furnace to broadcast the catalyst according to the catalyst broadcast amount, the catalyst broadcast frequency and the catalyst broadcast time, so that the broadcast catalyst can increase the possibility of precipitation or snowfall of the operable cloud cover with target probability.

Description

Control method and device for multi-smoke-oven combined sowing catalyst, storage medium and server

Technical Field

The invention relates to the technical field of artificial intelligence rain enhancement, in particular to a control method, a device, a storage medium and a server for multi-smoke-oven combined sowing catalysts.

Background

The weather-influencing operation is an operation means for increasing precipitation or snowfall. In the prior art, the manual influence operation mainly comprises a ground sowing catalysis operation and an aerial sowing operation. Ground catalysis has the defects of low efficiency, poor accuracy and limited precision; in addition, in the air catalysis, the catalyst carried by the unmanned aerial vehicle and the man-machine is mainly utilized to realize the in-cloud catalysis sowing, and compared with the ground catalysis, the air catalysis has the advantages of high efficiency, high accuracy and high precision, and is limited by geographic conditions, air control and the like. Thus, the ground catalytic operation is still an operation mode of necessary weather-influencing operation.

Chinese patent publication No. CN109315196a discloses a method for artificial precipitation and snow work of a ground smoke furnace, which includes selecting a precipitation cloud system under the control of a precipitation weather system as a target cloud; placing a ground smoke furnace on the upper part of a windward slope of a mountain, placing artificial precipitation and snow smoke strips, igniting, and taking a catalyst in the artificial precipitation and snow smoke strips into a target cloud layer by utilizing ascending airflow of the windward slope; continuously burning artificial precipitation snow tobacco strips for 40 minutes to form an operation unit; judging whether the target cloud layer still meets the operation conditions, if so, entering a second operation unit at intervals of 10 minutes; if not, stopping the operation. In the patent, on one hand, a ground smoke furnace needs to be temporarily placed on the upper part of a windward slope, so that the operation method has low efficiency; on the other hand, the accuracy is affected by the selection of the windward slope, and if the selection is wrong, the operation is failed. Therefore, the technical scheme has low efficiency, poor accuracy and limited precision.

The Chinese patent with publication number CN104729365A discloses a broadcasting control method of artificial precipitation rocket projectile, which comprises the following steps: 1) Launching a rocket projectile; 2) Detecting cloud layer information related to rainfall when the rocket projectile reaches a set height; 3) And broadcasting a catalyst to artificially enhance the rain when the cloud layer information meets the set condition. Compared with the traditional rocket shell using a timer, the method can effectively control the sowing position of the catalyst in real time according to the specific condition of the cloud layer, and improves the rain-increasing hail-suppressing effect; however, it does not give a control method of how the catalyst is spread.

In summary, the prior art has the technical defects of low ground catalyst sowing operation efficiency, poor accuracy and limited precision.

Disclosure of Invention

Aiming at the technical problems of low ground catalyst sowing operation efficiency, poor accuracy and limited precision in the prior art, the invention provides a control method, a device, a storage medium and a server for multi-smoke-oven combined sowing catalyst.

In order to achieve the above purpose, the invention is realized by the following technical scheme:

a control method for multi-smoke furnace combined sowing catalyst comprises the following steps:

acquiring meteorological data in a target influence area; the meteorological data at least comprises air flow information and cloud layer information;

acquiring an operable cloud layer in the target influence area based on the cloud layer information;

acquiring first position information of the operable cloud layer and precipitation information of the cloud layer;

acquiring second position information of each smoke furnace in the target influence area and surrounding smoke furnaces;

generating smoke furnace broadcasting work control information based on the first position information, cloud layer precipitation information, air flow information and a plurality of different second position information; the tobacco furnace sowing work control information comprises a target tobacco furnace positioned at a target geographic position, a catalyst sowing amount of the target tobacco furnace, a catalyst sowing frequency of the target tobacco furnace and a catalyst sowing time of the target tobacco furnace;

and controlling the target smoke furnace positioned at the target geographic position to broadcast the catalyst according to the catalyst broadcast amount of the target smoke furnace, the catalyst broadcast frequency of the target smoke furnace and the catalyst broadcast time of the target smoke furnace, so that the broadcast catalyst can increase the possibility of precipitation or snowfall of the operable cloud layer with target probability.

Optionally, the step of generating the smoke oven sowing work control information based on the first position information, cloud layer precipitation information, air flow information and the second position information includes:

generating relative position information of the operable cloud layer and each of a plurality of smoke ovens based on the first position information and a plurality of different second position information;

acquiring a diffusion model, and simulating to obtain a diffusion result based on the diffusion model, the air flow information and the different relative position information;

determining at least one smoke furnace from the multi-smoke furnaces as a target geographic location of the target smoke furnace and the target smoke furnace based on the diffusion result;

and determining the catalyst spreading amount of the target smoke furnace, the catalyst spreading frequency of the target smoke furnace and the catalyst spreading time of the target smoke furnace based on the target geographic position, the diffusion result, the air flow information, the first position information and the cloud layer precipitation amount information.

Optionally, before the step of obtaining a diffusion result based on the diffusion model, the air flow information and the different relative position information simulation, the control method includes:

judging whether the air flow information belongs to the air flow frequently occurring in the target influence area;

if yes, acquiring a mapping relation between a set target smoke furnace and air flow, and determining the target smoke furnace based on the mapping relation, the air flow information and the different relative position information;

if not, executing the step of obtaining a diffusion result based on the diffusion model, the air flow information and the different relative position information simulation.

Optionally, the determining, based on the diffusion result, at least one smoke furnace from the multiple smoke furnaces as the target smoke furnace and the target geographic location of the target smoke furnace includes:

determining at least two smoke stoves from the multi-smoke stoves as target geographic positions of the target smoke stoves and the target smoke stoves based on the diffusion result;

and determining the catalyst broadcasting quantity of the target smoke furnace, the catalyst broadcasting frequency and the catalyst broadcasting time of the target smoke furnace and the sequence information or synchronous broadcasting information of the broadcasting catalysts of at least two target smoke furnaces based on at least two target geographic positions, the diffusion result, the air flow information, the first position information and the cloud layer precipitation amount information.

Optionally, the relative position information is relative position information in a wind direction.

Optionally, the cloud-precipitation information includes supercooled water content and ice crystal number concentration.

Optionally, the air flow information includes horizontal wind speed and direction and vertical speed.

The application also provides a control device of multi-smoke furnace combined sowing catalyst, which comprises:

the acquisition module is suitable for acquiring meteorological data in the target influence area; the meteorological data at least comprises air flow information and cloud layer information;

the acquisition module is further adapted to acquire an operable cloud layer in the target influence area based on the cloud layer information;

the acquisition module is further adapted to acquire first position information of the operable cloud layer and precipitation information of the cloud layer;

the acquisition module is further adapted to acquire second position information of each of the multiple smoke stoves in the target influence area;

the control information generation module is suitable for generating smoke furnace sowing work control information based on the first position information, cloud layer precipitation information, air flow information and a plurality of different second position information; the tobacco furnace sowing work control information comprises a target tobacco furnace positioned at a target geographic position, a catalyst sowing amount of the target tobacco furnace, a catalyst sowing frequency of the target tobacco furnace and a catalyst sowing time of the target tobacco furnace;

the control module is suitable for controlling the target smoke furnace located at the target geographic position to broadcast the catalyst according to the catalyst broadcast amount of the target smoke furnace, the catalyst broadcast frequency of the target smoke furnace and the catalyst broadcast time of the target smoke furnace, so that the broadcast catalyst can increase the possibility of precipitation or snowfall of the operable cloud layer with target probability.

The present application also proposes a computer storage medium having a computer program stored thereon, the computer being recorded by a processor to execute the steps of the method for controlling the co-seeding of catalysts in a multi-smoke oven as described above.

The application also proposes a server comprising: a memory having a computer program stored thereon; and the processor is used for executing the computer program in the memory to realize the steps of the control method for the multi-smoke furnace combined sowing catalyst.

Drawings

FIG. 1 is a schematic diagram of an implementation environment in accordance with various embodiments of the present invention;

FIG. 2 is a schematic flow chart of a method for controlling the combined sowing of catalysts in a multi-smoke furnace according to the present application;

FIG. 3 is a schematic diagram of the multi-smoke furnace combined sowing catalyst for affecting weather;

FIG. 4 is a schematic flow chart of another method for controlling the combined sowing of catalysts in a multi-smoke furnace according to the present application;

FIG. 5 is a block diagram of a control device for multi-smoke furnace combined sowing of catalyst;

fig. 6 is a block diagram of a server according to an embodiment of the present invention.

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 schematic structural diagram of an implementation environment according to various embodiments of the present invention is shown. As shown in fig. 1, the implementation environment may include an information device, a server, and a fume oven. In the application, the information equipment comprises unmanned aerial vehicle weather detection equipment, a geographic information system, radar detection equipment, satellite remote sensing detection equipment, wind direction and wind speed acquisition equipment, wind profile radar and other equipment capable of providing weather data. The server is provided with a memory and a processor, and one or more programs are arranged in the memory and are used for executing the control method for the multi-smoke-oven combined sowing catalyst in the following embodiment. The processor invokes a program in the memory to execute the control method of the multi-smoke oven combined sowing catalyst of the following embodiment. The server is used for controlling the smoke furnace to execute the operation of sowing the catalyst.

When this application is implemented, the smoke furnace refers to the equipment that is used for broadcasting the catalyst that sets up in ground. Within a given geographical area, the smoke ovens are typically arranged in multiple numbers depending on geographical conditions, and each smoke oven is arranged in a different geographical location to cover as much of the available weather effect area as possible. Without specific limitation, the catalyst generally refers to silver iodide, which is relatively mature in the art. Of course, the catalyst may be other materials used for artificial rain or snow, such as dry ice, liquid nitrogen, liquid propane, etc.

Smoke stoves are used as the main ground equipment for artificial precipitation or snow addition, and have the disadvantages of poor accuracy and low efficiency. Therefore, the defects of poor precision and low efficiency of the lifting smoke furnace become a research hot spot and a research difficulty in the field. In this regard, through investigation and research, the chinese patent CN110915511a discloses a technical method for catalytic operation of a ground smoke-burning furnace for artificial precipitation and snow; the method comprises the following steps: acquiring the concentration of fine particles near the ground in the atmosphere; acquiring horizontal wind speed or operation season; determining the artificial precipitation and snow catalyst amount of the ground smoke-burning furnace according to the concentration of the atmospheric near-ground fine particles and the horizontal wind speed or according to the concentration of the atmospheric near-ground fine particles and the working season; when the operation conditions are met, the catalytic operation is implemented by adopting the artificial precipitation and snow catalyst amount of the ground smoke burning furnace; the concentration of the fine particles near the ground in the atmosphere is PM2.5, the horizontal wind speed is a wind speed with a height of 10 meters from the ground, and the step of determining the artificial precipitation and snow catalyst amount of the ground smoke burning furnace according to the concentration of the fine particles near the ground in the atmosphere and the horizontal wind speed or according to the concentration of the fine particles near the ground in the atmosphere and the working season comprises the following steps: when PM2.5 is less than 75 mug/m 3, the horizontal wind speed is more than or equal to 2m/s and less than or equal to 5m/s, or when PM2.5 is less than 75 mug/m 3, the working season is winter, the ground smoke furnace artificial precipitation and snow catalyst amount is determined to be 90g, or 120g.

In the technical scheme provided by the patent, the success rate of artificial precipitation and snow is improved by determining the artificial precipitation and snow catalyst amount of the ground smoke-burning furnace according to different wind speed conditions and weather conditions of season types. However, even if the amount of artificial precipitation and snow catalyst of the floor fume furnace is determined according to different wind speed conditions and weather conditions of season type within a specific influence range, the efficiency is still low. The research of the inventor shows that: the wind speed condition does have an effect on the amount of artificial precipitation and snow catalyst of the fume furnace, but the geographical position, the sowing time and the sowing frequency of the fume furnace are equivalent or larger. For example, in a particular geographic location, the layout of the smoke ovens is given, and under some wind speed conditions, the success rate of smoke oven seeding closer to the cloud is less than that of smoke oven seeding farther away. Therefore, in the current technical proposal, the ground smoke furnace is used for sowing the catalyst to increase snow or rain, and the precision and the efficiency are still insufficient.

Therefore, the control method aims to improve the accuracy and efficiency of the ground smoke furnace for sowing the catalyst to increase snow or rain. Referring to fig. 2, fig. 2 is a flow chart illustrating a control method for co-seeding a catalyst in a multi-smoke furnace according to the present application. The control method is applied to the server 130 shown in fig. 1 for illustration. In order to achieve the above purpose, the invention is realized by the following technical scheme:

a control method for multi-smoke furnace combined sowing catalyst comprises the following steps:

s100, acquiring meteorological data in a target influence area; the meteorological data at least comprises air flow information and cloud layer information;

in an embodiment, the meteorological data originates from an information device. Generally, the meteorological data includes at least air flow information and cloud information. The meteorological data may also include temperature information, humidity information, concentration information of respirable particles, barometric pressure information, and the like. In an embodiment, the air flow information mainly comprises horizontal wind speed and wind direction and vertical speed, i.e. wind field.

S200, acquiring an operable cloud layer in the target influence area based on the cloud layer information;

the cloud layer information mainly comprises air pressure information, water content, ice core number and temperature information around the cloud layer. Determining an operable cloud layer capable of being used for artificially influencing weather operation according to the cloud layer information; the "operable cloud" may be a precipitation-or snowfall-capable cloud.

S300, acquiring first position information of the operable cloud layer and precipitation information of the cloud layer;

in an embodiment, the cloud-precipitation information generally includes supercooled water content and ice crystal number concentration; the first position information may be a relative position with respect to a specific reference object or an absolute position within the target influence area.

S400, acquiring second position information of each smoke furnace in the target influence area and surrounding smoke furnaces;

in general, as shown in FIG. 3, a plurality of ovens are disposed in different geographic locations within a particular range. However, the area of the rain-enhancing operation may be entirely within the specific range, may be outside the specific range, or may have an intersecting area with the specific range. To efficiently realize weather-affected work with a high success rate. In the technical solution of the embodiment of the present application, generally, the second location information of each smoke furnace of the multiple smoke furnaces in and around the target influence area is obtained through traversal, so as to provide equipment support for efficient implementation of the weather operation affected by man.

S500, generating smoke furnace sowing work control information based on the first position information, cloud layer precipitation amount information, air flow information and a plurality of different second position information; the tobacco furnace sowing work control information comprises a target tobacco furnace positioned at a target geographic position, a catalyst sowing amount of the target tobacco furnace, a catalyst sowing frequency of the target tobacco furnace and a catalyst sowing time of the target tobacco furnace;

in the technical scheme of the application, based on the first position information, cloud layer precipitation information, air flow information and a plurality of different second position information, a target smoke furnace is selected from a plurality of smoke furnaces to be used for sowing operation, and success rate is improved. The selected smoke stoves are not necessarily in the target influence area, are not necessarily nearest to the operable cloud cover, are not necessarily unique, but are obtained by integrating the first position information, the cloud cover precipitation information, the air flow information and a plurality of different second position information. For the conventional technology in the field, only a smoke furnace close to a precipitation cloud layer is selected to perform the catalyst sowing operation or all smoke furnaces in a target influence area are generally selected to perform the catalyst sowing operation, for example, the above-mentioned Chinese patent, CN110915511A provides a technical scheme for performing the catalytic operation by adopting the artificial precipitation snowing catalyst amount of the ground smoke furnace when the radar vertical integral liquid water content of the precipitation cloud system is greater than or equal to 1kg/m3 and the radar precipitation return front edge of the precipitation cloud system is at a distance of greater than or equal to 24 minutes and less than or equal to 36 minutes from the ground smoke furnace operation point. However, the success rate of the technical scheme is still low, and the effectiveness of weather-related work is obviously reduced. All the emission catalysts can cause adverse effect on the environment and waste of the catalysts, which is unfavorable for economy and environmental protection. Therefore, in the embodiment of the application, when the weather modification operation needs to be implemented in the target influence area, the second position information of each smoke furnace in the target influence area and surrounding smoke furnaces is acquired, so that at least one smoke furnace sowing catalyst can be selected from the smoke furnaces to perform the operation based on the first position information, the cloud layer precipitation amount information, the air flow information and a plurality of different second position information, and economy, environmental protection and success rate are comprehensively considered.

As shown in fig. 4, in the technical solution of the embodiment of the present application, generating the smoke oven sowing operation control information based on the first position information, the cloud layer precipitation amount information, the air flow information, and the plurality of different second position information includes:

s510, generating relative position information of the operable cloud layer and each smoke furnace in the multi-smoke furnace based on the first position information and a plurality of different second position information;

in an embodiment, the relative position information of the operable cloud layer and each of the multi-smoke stoves may be calculated by calibrating the first position information and the plurality of different second position information in the same coordinate system; the position information of the smoke stoves can be converted by taking the operable cloud layer as the origin of coordinates, so that the relative position information of each smoke stove relative to the operable cloud layer is obtained. Since the wind direction is a significant influencing factor of catalyst diffusion in general, the relative position information is the relative position information along the wind direction, that is, in the technical solution of the present application, the relative position information is described in terms of vectors, so as to be used as important information of the target smoke furnace.

S520, a diffusion model is obtained, and a diffusion result is obtained based on the diffusion model, the air flow information and the different relative position information in a simulation mode;

diffusion models generally include diffusion modes (HYSPLIT) and mesoscale numerical modes (WRF). By simulating the diffusion track of each smoke furnace after the catalyst is scattered and analyzing the diffusion range of silver iodide, whether the catalyst released by the ground smoke furnace reaches an operable cloud layer or a region high enough above the ground is simulated, so that a target smoke furnace can be determined from the multi-smoke furnace.

S530, determining at least one smoke furnace from the multi-smoke furnaces as the target smoke furnace and the target geographic position of the target smoke furnace based on the diffusion result;

in general, after each diffusion result is obtained, determining at least one smoke furnace from the multiple smoke furnaces as the target smoke furnace according to a preset determination condition; in general, the predetermined conditions include the degree of deviation of the diffusion trajectory from the straight trajectory between the target fume furnace and the operable cloud. If the deviation degree of the diffusion track of the smoke furnace is low, the smoke furnace can be determined as the target smoke furnace; if the deviation degree of the diffusion track of a smoke furnace is high, the smoke furnace is not used in the sowing process. In general, further pairs of primary and secondary target ovens are selected from the target ovens based on the degree of deviation. The main target tobacco furnace is used for high-frequency sowing and high-quantity sowing of the catalyst, and the secondary target tobacco furnace is used for low-frequency sowing and low-quantity sowing of the catalyst, so that the sowing operation success rate of the tobacco furnace is increased.

S540, determining the catalyst broadcasting quantity of the target smoke furnace, the catalyst broadcasting frequency of the target smoke furnace and the catalyst broadcasting time of the target smoke furnace based on the target geographic position, the diffusion result, the air flow information, the first position information and the cloud cover precipitation amount information.

In an embodiment, after determining the target fume, determining the catalyst broadcast amount of the target fume, the catalyst broadcast frequency of the target fume, and the catalyst broadcast time of the target fume by based on the target geographic location, the diffusion result, the air flow information, the first location information, and the cloud cover precipitation amount information. The sowing quantity is related to the water content and nucleation number of the operable cloud cover; the spreading frequency and spreading time are related to the spreading result, wind direction and wind speed. The broadcast time is also related to the target geographic location, the first location information.

And S600, controlling the target smoke furnace positioned at the target geographic position to broadcast the catalyst according to the catalyst broadcast amount of the target smoke furnace, the catalyst broadcast frequency of the target smoke furnace and the catalyst broadcast time of the target smoke furnace, so that the broadcast catalyst can increase the possibility of precipitation or snowfall of the operable cloud layer with target probability.

In the application, after the tobacco furnace sowing operation control information is obtained, the target tobacco furnace at the target geographic position is controlled to perform the tobacco furnace sowing operation according to the catalyst sowing amount of the target tobacco furnace, the catalyst sowing frequency of the target tobacco furnace and the catalyst sowing time of the target tobacco furnace.

As an optional implementation manner of the foregoing embodiment, before the step of obtaining a diffusion result based on the diffusion model, the air flow information, and the different relative position information simulation, the control method includes: judging whether the air flow information belongs to the air flow frequently occurring in the target influence area; if yes, acquiring a mapping relation between a set target smoke furnace and air flow, and determining the target smoke furnace based on the mapping relation, the air flow information and the different relative position information. For example, for having a particular wind direction and wind speed within a particular geographic range; when the air flow is performed according to or approximate to the specific wind direction and wind speed, the mapping relation between the set target smoke furnace and the air flow is acquired and acquired so as to be used for quickly determining the target smoke furnace. If not, executing the step of obtaining a diffusion result based on the diffusion model, the air flow information and the different relative position information simulation. Namely: when the air flow is not performed according to or approximate to the specific wind direction and wind speed, the target smoke furnace is determined by performing the spreading simulation. Through the technical scheme of the embodiment, the sowing operation is rapidly executed under the frequent weather condition; and diffusion simulation is performed again under infrequent weather conditions to determine the target smoke furnace.

As an optional implementation of the foregoing embodiment, the determining, based on the diffusion result, at least one smoke furnace from the multiple smoke furnaces as the target smoke furnace and the target geographic location of the target smoke furnace includes: determining at least two smoke stoves from the multi-smoke stoves as target geographic positions of the target smoke stoves and the target smoke stoves based on the diffusion result; and determining the catalyst broadcasting quantity of the target smoke furnace, the catalyst broadcasting frequency and the catalyst broadcasting time of the target smoke furnace and the sequence information or synchronous broadcasting information of the broadcasting catalysts of at least two target smoke furnaces based on at least two target geographic positions, the diffusion result, the air flow information, the first position information and the cloud layer precipitation amount information. In general, further pairs of primary and secondary target ovens are selected from the target ovens based on the degree of deviation. In the embodiment, the main target smoke furnace and the secondary target smoke furnace can synchronously broadcast the catalyst, and can broadcast the catalyst successively. In general, according to system settings, a main target smoke furnace is generally used for high-frequency sowing and high-volume sowing of catalysts, and a secondary target smoke furnace is used for low-frequency sowing and low-volume sowing of catalysts, so that the success rate of sowing operation of the smoke furnace is increased.

As shown in fig. 5, the present application provides a control device for multi-smoke furnace combined sowing catalyst, comprising:

an acquisition module 100 adapted to acquire meteorological data within a target area of influence; the meteorological data at least comprises air flow information and cloud layer information;

the obtaining module 100 is further adapted to obtain an operable cloud layer in the target influence area based on the cloud layer information;

the obtaining module 100 is further adapted to obtain first position information of the operable cloud layer and cloud layer precipitation information;

the obtaining module 100 is further adapted to obtain second location information of each of the multiple smoke stoves within the target impact area;

a control information generating module 200 adapted to generate smoke oven sowing work control information based on the first position information, cloud layer precipitation amount information, air flow information, and the second position information; the tobacco furnace sowing work control information comprises a target tobacco furnace positioned at a target geographic position, a catalyst sowing amount of the target tobacco furnace, a catalyst sowing frequency of the target tobacco furnace and a catalyst sowing time of the target tobacco furnace;

the control module 300 is adapted to control the target smoke furnace located at the target geographic position to broadcast the catalyst according to the catalyst broadcast amount of the target smoke furnace, the catalyst broadcast frequency of the target smoke furnace and the catalyst broadcast time of the target smoke furnace, so that the broadcast catalyst can increase the precipitation or snowfall possibility of the operable cloud layer with the target probability.

Referring to fig. 6, a schematic structural diagram of a server according to an embodiment of the invention is shown. The server 130 includes a Central Processing Unit (CPU) 1301, a system memory 1304 including a Random Access Memory (RAM) 1302 and a Read Only Memory (ROM) 1303, and a system bus 1305 connecting the system memory 1304 and the central processing unit 1301. The server 130 further includes a basic input/output system (I/O system) 1306 to facilitate the transfer of information between various devices within the computer, and a mass storage device 1307 for storing an operating system 1313, application programs 1314, and other program modules 1315.

The basic input/output system 1306 includes a display 1308 for displaying information, and an input device 1309, such as a mouse, keyboard, etc., for a user to input information. Wherein the display 1308 and the input device 1309 are connected to the central processing unit 1301 through an input output controller 1310 connected to the system bus 1305. The basic input/output system 1306 may also include an input/output controller 1310 for receiving and processing input from a keyboard, mouse, or electronic stylus, among a plurality of other devices. Similarly, the input output controller 1310 also provides output to a display screen, a printer, or other type of output device.

The mass storage device 1307 is connected to the central processing unit 1301 through a mass storage controller (not shown) connected to the system bus 1305. The mass storage device 1307 and its associated computer-readable media provide non-volatile storage for the server 130. That is, the mass storage device 1307 may include a computer-readable medium (not shown), such as a hard disk or CD-ROM drive.

The computer readable medium may include computer storage media and communication media without loss of generality. Computer storage media includes volatile and nonvolatile, removable and non-removable media implemented in any method or technology for storage of information such as computer readable instructions, data structures, program modules or other data. Computer storage media includes RAM, ROM, EPROM, EEPROM, flash memory or other solid state memory technology, CD-ROM, DVD or other optical storage, magnetic cassettes, magnetic tape, magnetic disk storage or other magnetic storage devices. Of course, those skilled in the art will recognize that the computer storage medium is not limited to the one described above. The system memory 1304 and mass storage device 1307 described above may be referred to collectively as memory.

The server 130 may also operate in accordance with various embodiments of the present invention, through a network, such as the internet, to remote computers connected to the network. I.e., the server 130 may be connected to the network 1312 via a network interface unit 1311 coupled to the system bus 1305, or the network interface unit 1311 may be used to connect to other types of networks or remote computer systems (not shown).

The memory further comprises one or more programs, the one or more programs are stored in the memory, and the one or more programs are used for executing the control method for the multi-smoke furnace combined sowing catalyst.

Claims (10)

1. The control method for the multi-smoke furnace combined sowing catalyst is characterized by comprising the following steps:

acquiring meteorological data in a target influence area; the meteorological data at least comprises air flow information and cloud layer information;

acquiring an operable cloud layer in the target influence area based on the cloud layer information;

acquiring first position information of the operable cloud layer and precipitation information of the cloud layer;

acquiring second position information of each smoke furnace in the multi-smoke furnace in the target influence area;

generating smoke furnace broadcasting work control information based on the first position information, cloud layer precipitation information, air flow information and a plurality of different second position information; the tobacco furnace sowing work control information comprises a target tobacco furnace positioned at a target geographic position, a catalyst sowing amount of the target tobacco furnace, a catalyst sowing frequency of the target tobacco furnace and a catalyst sowing time of the target tobacco furnace;

and controlling the target smoke furnace positioned at the target geographic position to broadcast the catalyst according to the catalyst broadcast amount of the target smoke furnace, the catalyst broadcast frequency of the target smoke furnace and the catalyst broadcast time of the target smoke furnace, so that the broadcast catalyst can increase the possibility of precipitation or snowfall of the operable cloud layer with target probability.

2. The control method of claim 1, wherein the step of generating the smoke oven broadcasting operation control information based on the first position information, cloud layer precipitation amount information, air flow information, and the second position information comprises:

generating relative position information of the operable cloud layer and each of a plurality of smoke ovens based on the first position information and a plurality of different second position information;

acquiring a diffusion model, and simulating to obtain a diffusion result based on the diffusion model, the air flow information and the different relative position information;

determining at least one smoke furnace from the multi-smoke furnaces as a target geographic location of the target smoke furnace and the target smoke furnace based on the diffusion result;

and determining the catalyst spreading amount of the target smoke furnace, the catalyst spreading frequency of the target smoke furnace and the catalyst spreading time of the target smoke furnace based on the target geographic position, the diffusion result, the air flow information, the first position information and the cloud layer precipitation amount information.

3. The control method according to claim 2, wherein before the step of simulating a diffusion result based on the diffusion model, the air flow information, and the different relative position information, the control method includes:

judging whether the air flow information belongs to the air flow frequently occurring in the target influence area;

if yes, acquiring a mapping relation between a set target smoke furnace and air flow, and determining the target smoke furnace based on the mapping relation, the air flow information and the different relative position information;

if not, executing the step of obtaining a diffusion result based on the diffusion model, the air flow information and the different relative position information simulation.

4. The control method of claim 2, wherein the determining at least one fume from the multi-fume ovens as the target fume and the target geographic location of the target fume based on the diffusion result comprises:

determining at least two smoke stoves from the multi-smoke stoves as target geographic positions of the target smoke stoves and the target smoke stoves based on the diffusion result;

and determining the catalyst broadcasting quantity of the target smoke furnace, the catalyst broadcasting frequency and the catalyst broadcasting time of the target smoke furnace and the sequence information or synchronous broadcasting information of the broadcasting catalysts of at least two target smoke furnaces based on at least two target geographic positions, the diffusion result, the air flow information, the first position information and the cloud layer precipitation amount information.

5. The control method according to any one of claims 1 to 4, characterized in that the relative position information is relative position information in a wind direction.

6. The control method of any one of claims 1 to 4, wherein the cloud-precipitation information includes supercooled water content and ice crystal number concentration.

7. The control method according to any one of claims 1 to 4, wherein the air flow information includes a horizontal wind speed and a wind direction and a vertical speed.

8. The control device for jointly sowing catalyst in a multi-smoke furnace is characterized by comprising:

the acquisition module is suitable for acquiring meteorological data in the target influence area; the meteorological data at least comprises air flow information and cloud layer information;

the acquisition module is further adapted to acquire an operable cloud layer in the target influence area based on the cloud layer information;

the acquisition module is further adapted to acquire first position information of the operable cloud layer and precipitation information of the cloud layer;

the acquisition module is further adapted to acquire second position information of each of the multiple smoke stoves in the target influence area;

the control information generation module is suitable for generating smoke furnace sowing work control information based on the first position information, cloud layer precipitation information, air flow information and a plurality of different second position information; the tobacco furnace sowing work control information comprises a target tobacco furnace positioned at a target geographic position, a catalyst sowing amount of the target tobacco furnace, a catalyst sowing frequency of the target tobacco furnace and a catalyst sowing time of the target tobacco furnace;

the control module is suitable for controlling the target smoke furnace located at the target geographic position to broadcast the catalyst according to the catalyst broadcast amount of the target smoke furnace, the catalyst broadcast frequency of the target smoke furnace and the catalyst broadcast time of the target smoke furnace, so that the broadcast catalyst can increase the possibility of precipitation or snowfall of the operable cloud layer with target probability.

9. A computer storage medium having a computer program stored thereon, the computer being recorded by a processor to execute the steps of the method for controlling the joint sowing of catalysts in a multi-smoke furnace according to any one of claims 1 to 7.

10. A server, comprising:

a memory having a computer program stored thereon;

a processor for executing the computer program in the memory to implement the steps of the method for controlling the co-seeding of catalysts in a multi-smoke furnace according to any one of claims 1 to 6.

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