CN112526936B - Parameter control method, parameter control equipment and system - Google Patents

Abstract

The invention discloses a parameter control method, parameter control equipment and a system, wherein a target model is obtained according to scene parameters of equipment to be controlled, and a parameter control instruction for enabling the equipment to be controlled to adjust environmental parameters of different areas in a space where the equipment is located is generated; aiming at the parameter control instruction corresponding to each area, taking the parameter control instruction corresponding to the area as a simulation condition of a target model, and simulating the target model according to the simulation condition to obtain simulation data of different areas; the simulation data of all the areas are sent to the controller of the equipment to be controlled, so that the controller determines the simulation data of the target areas in all the areas and controls the equipment to be controlled based on the simulation data of the target areas, and the problem that the parameters in different functional areas in the same space where the same electronic equipment is located cannot be controlled in a partitioned mode is solved.

Description

Parameter control method, parameter control equipment and system

Technical Field

The invention relates to the technical field of control, in particular to a parameter control method, parameter control equipment and a parameter control system.

Background

Along with the development of economy and the improvement of the living standard of people, electronic equipment with various functions is produced, and great convenience is brought to the life of people. In actual life, a user usually divides the same space into different functional areas, the user has different control requirements for parameters in the different functional areas where the same electronic device is located, and the current parameter control technology can only carry out overall control on the parameters in all the functional areas in the same space where the same electronic device is located, cannot carry out regional control on the parameters in the different functional areas in the same space where the same electronic device is located, and is difficult to meet the individual needs of a large number of users. Therefore, it is an urgent technical problem to provide a method capable of performing regional control on parameters in different functional regions of the same space where the same electronic device is located.

Disclosure of Invention

The invention provides a parameter control method, parameter control equipment and a parameter control system, which can perform regional control on parameters in different functional regions of the same space where the same electronic equipment is located, and effectively meet the individual requirements of a large number of users.

In order to achieve the above purpose, the embodiment of the invention adopts the following technical scheme:

a method of parameter control, comprising:

obtaining scene parameters of equipment to be controlled, wherein the scene parameters comprise position parameters of the equipment to be controlled, equipment parameters of the equipment to be controlled and geometric parameters of a space where the equipment to be controlled is located;

obtaining a target model according to the scene parameters, and generating a parameter control instruction for enabling the equipment to be controlled to adjust the environmental parameters of different areas in the space in which the equipment is located according to the scene parameters;

aiming at the parameter control instruction corresponding to each region, taking the parameter control instruction corresponding to the region as the simulation condition of the target model, and simulating the target model according to the simulation condition to obtain the simulation data of different regions;

and sending the simulation data of all the areas to a controller of the equipment to be controlled, so that the controller determines the simulation data of a target area in all the areas and controls the equipment to be controlled based on the simulation data of the target area.

In a preferred option of the embodiment of the present invention, in the parameter control method, the step of obtaining a target model according to the scene parameter includes:

and searching a target model from a pre-stored model library according to the scene parameters.

In a preferred option of the embodiment of the present invention, in the parameter control method, the step of searching a target model from a pre-stored model library according to the scene parameter includes:

calculating the matching degree of the scene parameters and the parameter information of each model in the model base;

and taking the model with the highest matching degree and larger than a preset matching degree threshold value as a target model.

In a preferred option of the embodiment of the present invention, in the parameter control method, the step of obtaining a target model according to the scene parameter includes:

and constructing a parameter model according to the scene parameters, taking the parameter model as a target model, and adding the parameter model into a pre-stored model library.

In a preferred option of the embodiment of the present invention, in the parameter control method, after the step of obtaining the simulation data of different areas, the method further includes:

and testing the simulation data to obtain simulation test data, judging whether the simulation test data is consistent with the simulation data, if the simulation test data is inconsistent with the simulation data, modifying simulation conditions and simulating again to obtain new simulation data, and testing the new simulation data again until the simulation test data obtained by testing the new simulation data is consistent with the new simulation data.

In a preferred selection of the embodiment of the present invention, in the above-mentioned parameter control method,

the step of determining simulation data of a target area among all the areas and controlling the device to be controlled based on the simulation data of the target area includes:

and searching the analog data of the target area from the analog data of all the areas, converting the analog data of the target area into an electric signal, and controlling the equipment to be controlled based on the electric signal.

In a preferred selection of the embodiment of the present invention, in the above-mentioned parameter control method,

after the step of determining simulation data of a target area among all areas and controlling the device to be controlled based on the simulation data of the target area, the method further includes:

obtaining execution data for executing corresponding operation feedback by a controller of the equipment to be controlled based on the electric signal;

and judging whether the execution data is consistent with the simulation data, if the execution data is inconsistent with the simulation data, modifying the simulation condition and simulating again to obtain new simulation data, and sending the new simulation data to a controller of the equipment to be controlled, so that the controller executes corresponding operation based on the electric signal after converting the new simulation data into the electric signal and obtains the execution data until the execution data is consistent with the new simulation data.

In a preferred selection of the embodiment of the present invention, in the above-mentioned parameter control method,

the step of sending the simulation data of all the areas to the controller of the device to be controlled so that the controller determines the simulation data of the target area in all the areas comprises the following steps:

and constructing the simulation data of all the areas and the scene parameters as parameter sets corresponding to the scene parameters, and sending the parameter sets to a controller of the equipment to be controlled, so that the controller searches the simulation data of the target area from the parameter sets.

In a preferred choice of the embodiment of the present invention, in the parameter control method, the geometric parameter of the space where the device to be controlled is located includes:

the length, width and height of the space where the equipment to be controlled is located, and the length, width and height of each static object in the space where the equipment to be controlled is located.

Meanwhile, the invention provides a parameter control device, which comprises a memory and a processor, wherein the memory is stored with a storage medium capable of being executed by the processor, and the storage medium realizes the parameter control method in any one of the parameter control methods when being executed by the processor.

Also, the present invention provides a system comprising:

the parameter control equipment and the equipment to be controlled are in communication connection with the parameter control equipment;

the controller of the device to be controlled stores a parameter control instruction of a target area and analog data corresponding to the parameter control instruction of the target area, so that when the device to be controlled is started, the controller of the device to be controlled controls the device to be controlled based on the analog data corresponding to the parameter control instruction.

According to the parameter control method, the parameter control equipment and the parameter control system, a target model is obtained according to scene parameters of equipment to be controlled, and a parameter control instruction for enabling the equipment to be controlled to adjust environmental parameters of different areas in a space where the equipment to be controlled is located is generated; aiming at the parameter control instruction corresponding to each area, taking the parameter control instruction corresponding to the area as a simulation condition of a target model, and simulating the target model according to the simulation condition to obtain simulation data of different areas; the simulation data of all the areas are sent to the controller of the equipment to be controlled, so that the controller determines the simulation data of the target areas in all the areas, and controls the equipment to be controlled based on the simulation data of the target areas, the problem that the parameters in different functional areas of the same space where the same electronic equipment is located cannot be controlled in a partitioned mode is solved, the purpose of controlling the parameters in different functional areas of the same space where the same electronic equipment is located in a partitioned mode is achieved, and the individual needs of a large number of users are effectively met.

Drawings

The scope of the present disclosure will be better understood from the following detailed description of exemplary embodiments, which is to be read in connection with the accompanying drawings. Wherein the included drawings are:

FIG. 1 is a flow chart of a parameter control method according to an embodiment of the present invention;

fig. 2 is a flowchart of searching for a target model in the parameter control method according to the embodiment of the present invention;

fig. 3 is a test flow chart of a parameter control method according to an embodiment of the present invention;

fig. 4 is an application block diagram of a parameter control device according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures. In the description of the present invention, the terms "first", "second", and the like are used only for distinguishing the description, and are not intended to be construed as only or implying relative importance.

Referring to fig. 1 and 4, an embodiment of the invention provides a parameter control method, which includes steps S110 to S140.

In step S110, the scene parameters of the device to be controlled 140 are obtained.

The scene parameters include position parameters of the device to be controlled 140, device parameters of the device to be controlled 140, and geometric parameters of a space in which the device to be controlled 140 is located.

Specifically, the device to be controlled 140 includes but is not limited to: air conditioner, fan, air purifier, dehumidifier, humidifier; the scene parameters may further include: weather information of a city where the device to be controlled 140 is located, floor information of a space where the device to be controlled 140 is located, and the like.

The manner of obtaining the scene parameters of the device to be controlled 140 includes, but is not limited to: receiving video information including scene parameters sent by the device to be controlled 140, receiving picture information including scene parameters sent by the device to be controlled 140, and receiving text information including scene parameters sent by the device to be controlled 140.

In this embodiment, the geometric parameters of the space where the device 140 to be controlled is located include: the length, width, and height of the space in which the device to be controlled 140 is located, and the length, width, and height of each static object in the space in which the device to be controlled 140 is located; wherein the static objects include, but are not limited to: beds, sofas, tables, tea tables, and wardrobes.

Step S120, obtaining a target model according to the scene parameters, and generating parameter control instructions for controlling the environmental parameters of different areas in the space where the device to be controlled 140 is located according to the scene parameters.

The method for obtaining a target model according to the scene parameters may be to search a target model from a pre-stored model library according to the scene parameters; or a parameter model is constructed according to the scene parameters, the parameter model is taken as a target model, and the parameter model is added into a pre-stored model library.

It is understood that the models stored in the model library include, but are not limited to, models constructed by manufacturers according to commonly used scene parameters, and models constructed according to scene parameters previously uploaded by other users.

With reference to fig. 2, in the present embodiment, the step of obtaining an object model according to the scene parameters includes steps S122 to S124.

And step S122, calculating the matching degree of the scene parameters and the parameter information of each model in the model library.

And step S124, taking the model with the highest matching degree and larger than a preset matching degree threshold value as a target model.

It can be understood that when the matching degree greater than the preset matching degree threshold exists, the scene parameter representing the model in the model library is slightly different from the scene parameter, so that the model corresponding to the parameter information with the highest matching degree of the scene parameter is taken as the target model, the process of modeling according to the scene parameter can be omitted, and time is saved for a user.

In this embodiment, when there is no matching degree greater than a preset matching degree threshold, a parameter model is constructed according to the scene parameters, the parameter model is used as a target model, and the parameter model is added to a pre-stored model library.

It can be understood that, when there is no matching degree greater than the preset matching degree threshold, the scene parameters representing the models in the model base are greatly different from the scene parameters, and therefore, at this time, the model corresponding to the parameter information with the highest matching degree of the scene parameters cannot be used as the target model, and a corresponding parameter model needs to be constructed according to the scene parameters, and the parameter model is added to the pre-stored model base, so as to complete the model base.

It is understood that the parameter control instructions generated according to the scene parameters for controlling the environmental parameters of different areas of the space where the device to be controlled 140 is located include:

when the device to be controlled 140 is installed in a house, the parameter control instructions include, but are not limited to: setting the temperature of the sofa area to be 26 ℃, and setting the wind power of the dining table area to be minimum;

when the device to be controlled 140 is set in a hospital, the parameter control instructions include, but are not limited to: setting the temperature of an area where a sickbed of a special nursing patient in a ward is located at 28 ℃, and setting the wind power of a waiting area to be maximum;

when the device to be controlled 140 is installed in a factory, the parameter control instructions include, but are not limited to: the wind direction of an area which discharges harmful gas in a special production line of a factory is set to be a designated direction.

Step S130, regarding the parameter control instruction corresponding to each region, taking the parameter control instruction of the region as a simulation condition of the target model, and simulating the target model according to the simulation condition to obtain simulation data of different regions.

Specifically, the simulation software used for simulating the target model includes but is not limited to: ansys, Fluent, Comsol, and ABQUS.

It is understood that the process of simulating the target model according to the simulation condition includes: and importing the target model into the simulation software through a data interface, calling a mesh division module of the simulation software, carrying out mesh division on the target model, setting a simulation boundary condition of the target model according to the parameter control instruction, and then simulating the target model to obtain simulation data.

Referring to fig. 3, in the present embodiment, when the first simulation is finished, step S132 to step S138 are executed.

Step S132, testing the simulation data to obtain simulation test data.

It can be understood that after the target model is simulated and simulated data is obtained, the obtained simulated data needs to be tested in a test scene to obtain simulated test data, the simulated test data is compared with the simulated data, parameters such as boundary conditions for simulating the target model are modified according to the simulated test data, simulation and test are performed again, and complete simulated data is finally determined through continuous simulation and test mutual verification.

It can be understood that the test scenario refers to an entity scenario of a scenario parameter corresponding to the target model.

Specifically, the test tool for testing the obtained simulation data includes but is not limited to: the system comprises a thermometer, a flowmeter and a device for testing the flow direction of a wind field; methods for testing the simulation data using the test tool include, but are not limited to: uniformly placing temperature-sensitive sensors or thermometers with high sensitivity in a test scene, and constructing the distribution condition of a temperature field of the test scene according to temperature data acquired by the temperature-sensitive sensors or the thermometers; in a test scene, testing the wind speed and the wind direction of a target area in the test scene by adopting a flowmeter to obtain the wind speed and the wind direction of the target area in the test scene and recording the wind speed and the wind direction of the target area in the test scene; and testing the flow direction of the wind field in the test scene by adopting a device for testing the flow direction of the wind field to obtain the flow direction of the wind field in the test scene and recording the flow direction of the wind field in the test scene.

Step S134, determining whether the simulation test data is consistent with the simulation data.

When the execution result of the step S134 is no, step S136 is executed, step S136 is to modify the simulation condition and simulate again to obtain new simulation data, the new simulation data is taken as the simulation data, and the execution returns to step S132.

It is understood that the simulation conditions for simulating the target model are set based on the simulation software, and are virtual ideal conditions; the test condition for testing the target model is set based on the test scenario, and is a condition of a real scenario, and because various interferences usually exist in the real scenario, some errors necessarily exist between the simulated test data obtained according to the test condition of the test scenario and the simulated data obtained according to the simulation condition, and in view of this, when the simulated test data is inconsistent with the simulated data, the simulation condition needs to be modified so that the simulation condition is closer to the test condition of the test scenario.

When the result of the step S134 is yes, step S138 is executed, and the step S138 is to end the test on the simulation data.

It can be understood that, in this embodiment, when the simulation test data is consistent with the simulation data, an effect of executing the parameter control instruction according to the simulation data under the test condition of the test scenario is the same as an effect of executing the parameter control instruction according to the simulation data under the simulation condition, that is, the parameter control instruction can be executed in an entity scenario corresponding to the test scenario according to the simulation data and a desired effect can be achieved.

Step S140, sending the simulation data of all the areas to the controller 142 of the device to be controlled 140, so that the controller 142 determines the simulation data of the target area in all the areas, and controls the device to be controlled 140 based on the simulation data of the target area.

In this embodiment, the simulation data of all the regions and the scene parameters may be constructed as parameter sets corresponding to the scene parameters, and the parameter sets are sent to the controller 142 of the device to be controlled 140, so that the controller 142 finds the simulation data of the target region from the parameter sets.

In this embodiment, the step of finding out the simulation data corresponding to the parameter control instruction of the target area from the simulation data of the different areas, and controlling the device to be controlled 140 based on the simulation data includes: the analog data of the target area is found out from the analog data of all areas, and the analog data of the target area is converted into an electric signal, and the device to be controlled 140 is controlled based on the electric signal.

It is understood that the electrical signals include, but are not limited to: current signals for controlling the refrigeration power, electric pulses for controlling the fan speed and current signals for controlling the position of the air outlet motor.

In the present embodiment, after controlling the device to be controlled 140 based on the electric signal, execution data for the controller 142 of the device to be controlled 140 to execute corresponding operation feedback based on the electric signal needs to be obtained; and determining whether the execution data is consistent with the simulation data, if the execution data is inconsistent with the simulation data, modifying the simulation condition and simulating again to obtain new simulation data, and sending the new simulation data to the controller 142 of the device to be controlled 140, so that the controller 142 performs corresponding operations based on the electrical signal after converting the new simulation data into the electrical signal and obtains the execution data until the execution data is consistent with the new simulation data.

It is understood that, in practical application, due to the influence of factors such as personnel mobility, the practical application condition may have some errors compared with the test condition of the test scenario, and therefore, when the execution data is inconsistent with the simulation data, the simulation condition needs to be modified, so that the simulation data obtained based on the modified simulation condition is more suitable for the practical application condition.

It is understood that when the execution data is consistent with the simulation data, the effect of executing the parameter control instruction according to the simulation data under the actual application condition is the same as the effect of executing the parameter control instruction according to the simulation data under the simulation condition, that is, the parameter control instruction can be executed under the actual application condition and achieve the expected effect according to the simulation data.

In this embodiment, the parameter control device 120 includes a memory 122 and a processor 124, where the memory 122 stores a storage medium capable of being executed by the processor 124, and the storage medium implements the parameter control method when executed by the processor 124.

It is understood that the parameter control device 120 includes, but is not limited to, a server.

The embodiment of the present invention further provides a system, where the system includes the parameter control device 120 and a device to be controlled 140 in communication connection with the parameter control device 120; the controller 142 of the device to be controlled 140 stores a parameter control instruction of a target area and simulation data corresponding to the parameter control instruction of the target area, so that when the device to be controlled 140 is started again, the controller 142 controls the device to be controlled 140 based on the simulation data corresponding to the parameter control instruction.

It can be understood that the parameter control device 120 is connected to the device to be controlled 140 in a communication manner; the controller 142 of the device to be controlled 140 includes, but is not limited to, a remote controller, a cell phone, a PAD; in this embodiment, the controller 142 of the device to be controlled 140 counts the stored parameter control instruction of the target area and the number of times of the called simulation data corresponding to the parameter control instruction of the target area, and deduces the habit of the user using the device to be controlled 140 according to the descending order of the number of times of the called parameter control instruction of the target area and the number of times of the called simulation data corresponding to the parameter control instruction of the target area, so as to use the parameter control instruction of the target area with the largest number of times of the called simulation data corresponding to the parameter control instruction of the target area as the default parameter control instruction of the target area and the simulation data corresponding to the default parameter control instruction of the target area, when the user starts the device to be controlled 140 and does not issue any parameter control instruction, the controller 142 of the device to be controlled 140 controls the device to be controlled 140 based on the default parameter control instruction of the target area and the simulation data corresponding to the default parameter control instruction of the target area, which are stored therein.

In summary, the present invention provides a parameter control method, a parameter control device and a system, in which a target model is obtained according to a scene parameter of a device 140 to be controlled, and a parameter control instruction for adjusting environmental parameters of different areas in a space where the device 140 to be controlled is located in the space is generated; aiming at the parameter control instruction corresponding to each area, taking the parameter control instruction corresponding to the area as a simulation condition of a target model, and simulating the target model according to the simulation condition to obtain simulation data of different areas; the simulation data of all the areas are sent to the controller 142 of the device to be controlled 140, so that the controller 142 determines the simulation data of the target area in all the areas, and the device to be controlled 140 is controlled based on the simulation data of the target area, which can solve the problem that the parameters in different functional areas of the same space where the same electronic device is located cannot be controlled in a partitioned manner in the prior art, achieve the purpose of controlling the parameters in different functional areas of the same space where the same electronic device is located in a partitioned manner, and effectively meet the individual needs of the majority of users.

Further, the controller 142 of the device to be controlled 140 stores the parameter control instruction of the target area and the simulation data corresponding to the parameter control instruction of the target area, so that when the device to be controlled 140 is started, the controller 142 can call the simulation data corresponding to the parameter control instruction according to the habit of the user to control the device to be controlled 140, and the user experience is improved.

It should be understood that the method and apparatus disclosed herein may be implemented in other ways. The apparatus embodiments described above are merely illustrative and, for example, the flowchart and block diagrams in the figures illustrate the architecture, functionality, and operation of possible implementations of apparatus, methods and computer program products according to embodiments of the present invention. In this regard, each block in the flowchart or block diagrams may represent a module, segment, or portion of code, which comprises one or more executable instructions for implementing the specified logical function(s). It should also be noted that, in some alternative implementations, the functions noted in the block may occur out of the order noted in the figures. For example, two blocks shown in succession may, in fact, be executed substantially concurrently, or the blocks may sometimes be executed in the reverse order, depending upon the functionality involved. It will also be noted that each block of the block diagrams and/or flowchart illustration, and combinations of blocks in the block diagrams and/or flowchart illustration, can be implemented by special purpose hardware-based systems which perform the specified functions or acts, or combinations of special purpose hardware and computer instructions.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Although the embodiments of the present invention have been described above, the above description is only for the convenience of understanding the present invention, and is not intended to limit the present invention. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (10)

1. A parameter control method is characterized in that,

obtaining scene parameters of equipment to be controlled, wherein the scene parameters comprise position parameters of the equipment to be controlled, equipment parameters of the equipment to be controlled and geometric parameters of a space where the equipment to be controlled is located;

obtaining a target model according to the scene parameters, and generating a parameter control instruction for enabling the equipment to be controlled to adjust the environmental parameters of different areas in the space in which the equipment is located according to the scene parameters;

aiming at the parameter control instruction corresponding to each region, taking the parameter control instruction corresponding to the region as the simulation condition of the target model, and simulating the target model according to the simulation condition to obtain the simulation data of different regions;

testing the simulation data in a test scene to obtain simulation test data, judging whether the simulation test data is consistent with the simulation data, if the simulation test data is inconsistent with the simulation data, modifying simulation conditions and simulating again to obtain new simulation data, and testing the new simulation data again until the simulation test data obtained by testing the new simulation data is consistent with the new simulation data; the test scene is an entity scene of a scene parameter corresponding to the target model;

and sending the simulation data of all the areas to a controller of the equipment to be controlled, so that the controller determines the simulation data of a target area in all the areas and controls the equipment to be controlled based on the simulation data of the target area.

2. The method of claim 1, wherein the step of obtaining a target model based on the scene parameters comprises:

and searching a target model from a pre-stored model library according to the scene parameters.

3. The parameter control method according to claim 2, wherein the step of finding a target model from a pre-stored model library according to the scene parameter comprises:

calculating the matching degree of the scene parameters and the parameter information of each model in the model base;

and taking the model with the highest matching degree and larger than a preset matching degree threshold value as a target model.

4. The method of claim 1, wherein the step of obtaining a target model based on the scene parameters comprises:

and constructing a parameter model according to the scene parameters, taking the parameter model as a target model, and adding the parameter model into a pre-stored model library.

5. The parameter control method according to claim 1, wherein the step of determining simulation data of a target area among all the areas and controlling the device to be controlled based on the simulation data of the target area comprises:

and searching the analog data of the target area from the analog data of all the areas, converting the analog data of the target area into an electric signal, and controlling the equipment to be controlled based on the electric signal.

6. The parameter control method according to claim 5, wherein after the step of determining simulation data of a target area among all the areas and controlling the device to be controlled based on the simulation data of the target area, the method further comprises:

obtaining execution data for executing corresponding operation feedback by a controller of the equipment to be controlled based on the electric signal;

and judging whether the execution data is consistent with the simulation data, if the execution data is inconsistent with the simulation data, modifying the simulation condition and simulating again to obtain new simulation data, and sending the new simulation data to a controller of the equipment to be controlled, so that the controller executes corresponding operation based on the electric signal after converting the new simulation data into the electric signal and obtains the execution data until the execution data is consistent with the new simulation data.

7. The parameter control method according to claim 1, wherein the step of sending the simulation data of all the areas to a controller of the device to be controlled so that the controller determines the simulation data of the target area in all the areas comprises:

and constructing the simulation data of all the areas and the scene parameters as parameter sets corresponding to the scene parameters, and sending the parameter sets to a controller of the equipment to be controlled, so that the controller searches the simulation data of the target area from the parameter sets.

8. The parameter control method according to claim 1, wherein the geometric parameters of the space where the device to be controlled is located include:

the length, width and height of the space where the equipment to be controlled is located, and the length, width and height of each static object in the space where the equipment to be controlled is located.

9. A parameter control device comprising a memory and a processor, the memory having stored thereon a storage medium executable by the processor, the storage medium when executed by the processor implementing a parameter control method according to any one of claims 1 to 8.

10. A parameter control system, comprising:

the parameter control device according to claim 9 and a device to be controlled communicatively connected to the parameter control device;

the controller of the device to be controlled stores a parameter control instruction of a target area and analog data corresponding to the parameter control instruction of the target area, so that when the device to be controlled is started, the controller of the device to be controlled controls the device to be controlled based on the analog data corresponding to the parameter control instruction.

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