CN109120441B - Remote regulation and control method and device and electronic equipment - Google Patents

Abstract

The invention provides a remote control method, a remote control device and electronic equipment, wherein a virtual model for simulating the running state of each system in different regions is pre-constructed, and the virtual model for simulating the running state of each system in different regions is obtained; collecting operation data of each virtual role model in the virtual models; and remotely regulating and controlling at least one piece of equipment based on the acquired running data of each virtual role model in the virtual models. In the invention, the equipment can be adjusted based on the operation data in the whole virtual model, and each equipment group is not managed independently, so that the whole management can be realized.

Description

Remote regulation and control method and device and electronic equipment

Technical Field

The invention relates to the field of communication, in particular to a remote regulation and control method, a remote regulation and control device and electronic equipment.

Background

For better service of users, more and more systems are being created, such as operator systems, online shopping systems, etc. Each system includes a plurality of device groups, such as a host group including a plurality of hosts and a network device group including a plurality of network devices. The various groups of devices in the system work in concert.

Each equipment group in each system is managed independently, and the management among the equipment groups is not linked, so that the system level management cannot be realized.

Disclosure of Invention

In view of the above, the present invention provides a remote control method, a remote control device and an electronic device, so as to solve the problems that each device group in a system is managed independently, the management among the device groups is not linked, and the system level management cannot be realized.

In order to solve the technical problems, the invention adopts the following technical scheme:

a remote regulation method comprising:

acquiring a virtual model for simulating the running state of each device in each system in different areas; the virtual model comprises virtual role models corresponding to each device in each system in different areas and communication connection relations among the different virtual role models;

collecting operation data of each virtual role model in the virtual models; the running data of each virtual role model is the same as the running data of the corresponding equipment of the corresponding virtual role model;

and remotely regulating and controlling at least one piece of equipment based on the acquired running data of each virtual role model in the virtual models.

Preferably, before obtaining the virtual model for simulating the operating state of each device in the systems in different areas, the method further includes:

acquiring role information of each device in each system in each area; the role information comprises equipment identity information and a communication connection relation;

generating a virtual role model of each device based on the acquired role information of each device, and determining a coordinate point of the virtual role model corresponding to each device in the virtual model and a communication connection relation between the virtual role models;

acquiring a virtual model generation rule;

and generating the virtual model based on the virtual model generation rule, the virtual role model of each device, the coordinate point of the virtual role model corresponding to each device in the virtual model and the communication connection relation among the virtual role models.

Preferably, the remote control of at least one device based on the collected operation data of each virtual character model in the virtual models includes:

determining a virtual role model with a fault in the virtual models based on the acquired operation data of each virtual role model in the virtual models;

issuing an isolation instruction to the equipment corresponding to the virtual role model with the fault so as to stop the equipment corresponding to the virtual role model with the fault;

and controlling the equipment receiving the isolation instruction to perform self-checking and fault repairing operations.

Preferably, the remote control of at least one device based on the collected operation data of each virtual character model in the virtual models includes:

determining an area to be expanded which needs to be subjected to equipment expansion operation and an area to be contracted which needs to be subjected to equipment contraction operation based on the acquired running data of each virtual character model in the virtual models;

and controlling the standby equipment of the area to be expanded to be added into the equipment group of the area to be expanded, and removing at least one piece of equipment in the equipment group of the area to be reduced out of the equipment group of the area to be reduced.

Preferably, the remote control of at least one device based on the collected operation data of each virtual character model in the virtual models includes:

and generating and sending an operation instruction to equipment corresponding to a target virtual role model based on the acquired running data of each virtual role model in the virtual models so as to enable the equipment to execute the operation instruction.

A remote regulating device comprising:

the model acquisition module is used for acquiring a virtual model for simulating the running state of each device in each system in different areas; the virtual model comprises virtual role models corresponding to each device in each system in different areas and communication connection relations among the different virtual role models;

the data acquisition module is used for acquiring the operation data of each virtual role model in the virtual models; the running data of each virtual role model is the same as the running data of the corresponding equipment of the corresponding virtual role model;

and the regulation and control module is used for remotely regulating and controlling at least one piece of equipment based on the acquired running data of each virtual role model in the virtual models.

Preferably, the method further comprises the following steps:

the information acquisition module is used for acquiring role information of each device in each system in each area before the model acquisition module acquires a virtual model for simulating the running state of each device in each system in different areas; the role information comprises equipment identity information and a communication connection relation;

the information processing module is used for generating a virtual role model of each device based on the acquired role information of each device, and determining a coordinate point of the virtual role model corresponding to each device in the virtual model and a communication connection relation between the virtual role models;

the rule obtaining module is used for obtaining a virtual model generation rule;

and the model generation module is used for generating the virtual model based on the virtual model generation rule, the virtual role model of each device, the coordinate point of the virtual role model corresponding to each device in the virtual model and the communication connection relation among the virtual role models.

Preferably, the regulatory module comprises:

the fault determining submodule is used for determining a virtual role model with a fault in the virtual model based on the acquired running data of each virtual role model in the virtual model;

the instruction issuing sub-module is used for issuing an isolation instruction to the equipment corresponding to the virtual role model with the fault so as to stop the equipment corresponding to the virtual role model with the fault;

and the first control submodule is used for controlling the equipment receiving the isolation instruction to carry out self-checking and fault repairing operation.

Preferably, the regulatory module comprises:

the area determination submodule is used for determining an area to be expanded, which needs to be subjected to equipment expansion operation, and an area to be contracted, which needs to be subjected to equipment contraction operation, based on the acquired running data of each virtual character model in the virtual models;

and the second control submodule is used for controlling the standby equipment of the area to be expanded to be added into the equipment group of the area to be expanded and removing at least one piece of equipment in the equipment group of the area to be reduced out of the equipment group of the area to be reduced.

Preferably, the regulatory module comprises:

and the instruction processing submodule is used for generating and sending an operation instruction to the equipment corresponding to the target virtual role model based on the acquired running data of each virtual role model in the virtual models so as to enable the equipment to execute the operation instruction.

An electronic device, comprising: a memory and a processor;

wherein the memory is used for storing programs;

the processor calls a program and is used to:

acquiring a virtual model for simulating the running state of each device in each system in different areas; the virtual model comprises virtual role models corresponding to each device in each system in different areas and communication connection relations among the different virtual role models;

collecting operation data of each virtual role model in the virtual models; the running data of each virtual role model is the same as the running data of the corresponding equipment of the corresponding virtual role model;

and remotely regulating and controlling at least one piece of equipment based on the acquired running data of each virtual role model in the virtual models.

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

the invention provides a remote control method, a remote control device and electronic equipment, wherein a virtual model for simulating the running state of each system in different regions is pre-constructed, and the virtual model for simulating the running state of each system in different regions is obtained; collecting operation data of each virtual role model in the virtual models; and remotely regulating and controlling at least one piece of equipment based on the acquired running data of each virtual role model in the virtual models. In the invention, the equipment can be adjusted based on the operation data in the whole virtual model, and each equipment group is not managed independently, so that the whole management can be realized.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

Fig. 1 is a flowchart of a method of a remote control method according to an embodiment of the present invention;

FIG. 2 is a flow chart of another method for remote control according to an embodiment of the present invention;

FIG. 3 is a flowchart of a method of a remote control method according to an embodiment of the present invention;

FIG. 4 is a flowchart of a method of a remote control method according to an embodiment of the present invention;

fig. 5 is a schematic structural diagram of a remote control device according to an embodiment of the present invention.

Detailed Description

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. 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.

An embodiment of the present invention provides a remote control method, and with reference to fig. 1, the method may include:

s11, acquiring a virtual model for simulating the running state of each device in each system in different areas;

the virtual model comprises virtual role models corresponding to each device in each system in different areas and communication connection relations among the different virtual role models. The virtual model is also partitioned by the partitioned area subsystem. All areas are isolated from each other, only through gateway communication, and other operations need permission application, so that faults of other areas caused by faults of one area are avoided, and safety is improved.

Specifically, the regions are divided into regions, and the regions may be boundaries having actual region boundaries as regions. Each area comprises a plurality of systems, such as an operator system, a network management system, an online shopping system and the like,

the systems within the area may work in concert or independently. Each system comprises various devices, such as a router with a communication protocol, a communication device, a server for installing an application, a machine room controller and the like, each device corresponds to a virtual role model, the virtual role model can execute a working role corresponding to the device, and the operation data of the virtual role model is the same as the operation data of the device.

The simulation model is divided into regions, the whole simulation model is similar to a map, and the devices are participants on the map, namely the virtual model displays the devices in all the regions in the form of the map.

The virtual model can simulate the operation state of each device in each system in different areas, such as the data processing and transmission process of each system device.

It should be noted that the operation state of each device in the virtual model is updated in real time according to the operation state of the device. The virtual model is equivalent to a white box, and provides a visual monitoring scene, and the operation state of each device can be seen through the virtual model. In addition, the virtual model can be displayed in a 2d and 3d map mode, and is convenient for a user to watch.

S12, collecting the operation data of each virtual role model in the virtual models;

and the running data of each virtual role model is the same as the running data of the corresponding equipment of the corresponding virtual role model.

Specifically, the running data of the device can be used as the running data of the corresponding virtual character model by collecting the running data of the device in the running data collection process.

When the device is a server, the running data can be the memory size, the CPU occupation amount and the like, and when the device is a router, the running data can be the device connection number, the routing table and the like.

And S13, remotely controlling at least one piece of equipment based on the collected operation data of each virtual character model in the virtual models.

Specifically, the instruction may be directly issued to the corresponding device, or the instruction may be first sent to the control end of the system, and the control end of the system forwards the instruction to the corresponding device.

In this embodiment, a virtual model for simulating the operating states of the systems in different areas is pre-constructed, and a virtual model for simulating the operating states of the systems in different areas is obtained; collecting operation data of each virtual role model in the virtual models; and remotely regulating and controlling at least one piece of equipment based on the acquired running data of each virtual role model in the virtual models. In the invention, the equipment can be adjusted based on the operation data in the whole virtual model, and each equipment group is not managed independently, so that the whole management can be realized.

Optionally, on the basis of the above embodiment of the remote control method, before the step S11, the method further includes:

s21, acquiring role information of each device in each system in each area;

the role information comprises equipment identity information and a communication connection relation.

The equipment identity information can be an equipment identification number, an equipment name, a system where the equipment is located, equipment working content and the like. The communication connection relationship includes a connection relationship of each device with the remaining devices. The communication connection relation may include a communication protocol, a communication object, a communication method, and the like.

S22, generating a virtual character model of each device based on the acquired character information of each device, and determining a coordinate point of each device in the virtual model;

specifically, the process of generating the virtual character model of each device may include:

according to the contents of the equipment identification number, the equipment name, the system where the equipment is located, the equipment working content and the like in the role information of the virtual role model of the equipment, a virtual role model with the equipment identification number and the equipment name is generated, and the virtual role model executes the working content executed by the corresponding equipment.

Based on the information of the system where the device is located in the role information of the virtual character model of the device, the position, i.e., the coordinate point, of the virtual character model corresponding to the device in the virtual model can be determined. The virtual model is also divided by the sub-area subsystem.

S23, acquiring a virtual model generation rule;

the virtual model generation rule includes a drawing scale, parameters (such as size, orientation, etc.) of the virtual model, and the like.

And S24, generating the virtual model based on the virtual model generation rule, the virtual character model of each device, the coordinate point of the virtual character model corresponding to each device in the virtual model and the communication connection relationship among the virtual character models.

Specifically, the corresponding virtual character models are placed on the corresponding coordinate points according to the coordinate points of the virtual character models corresponding to each device in the virtual models, and communication connection between the virtual character models is established according to the communication connection relationship between the virtual character models, so that the virtual models are obtained.

The constructed virtual model can be viewed from the local part and the global part, the part needing to be viewed is amplified when the virtual model is viewed from the local part so as to clearly display the local part, and the global part is displayed when the virtual model is viewed from the global part, so that the mutual conversion between the local part and the global part can be realized. In addition, the constructed virtual model is not fixed, and when a new system or area is added, only the devices in the newly added system or area need to be extended into the virtual model according to the method corresponding to the map.

In this embodiment, a method for generating a virtual model is provided, and further, a model may be generated by the method in this embodiment, so as to visually view the operation conditions of each device in all the areas.

Alternatively, on the basis of any of the above embodiments, step S13 may include the following three implementation manners, which are now separately described.

1. The first implementation mode comprises the following steps:

referring to fig. 3, step S13 may include:

s31, determining the virtual role model with faults in the virtual model based on the collected operation data of each virtual role model in the virtual model;

specifically, based on the operational data, a machine learning algorithm may be used in the process of determining the virtual character model in which the fault exists.

And inputting the operation data into a model comprising a machine learning algorithm, and determining the virtual character model with the fault by analyzing abnormal operation data.

Such as by analyzing network traffic throughout the virtual model and network flows for each virtual character model to determine virtual character models with abnormal traffic.

S32, issuing an isolation instruction to the equipment corresponding to the virtual role model with the fault so as to stop the equipment corresponding to the virtual role model with the fault;

specifically, the isolation instruction may be directly sent to the device corresponding to the virtual role model with the fault, or the isolation instruction may be forwarded to the device corresponding to the virtual role model with the fault through the control terminal of the system.

After the device receives the isolation instruction, the device automatically stops working and cuts off the communication connection with other devices.

And S33, controlling the equipment receiving the isolation instruction to perform self-checking and fault repairing operation.

Specifically, the device has a self-checking function, and whether the device has a fault or not can be determined through the self-checking function, and if the device has the fault, the device is controlled to perform fault repairing, for example, the repairing device can be used to repair the faulty device, or the self-repairing function of the faulty device is started.

And if the fault does not exist, the equipment is enabled to communicate with the equipment needing to communicate with the equipment again.

2. The second implementation mode comprises the following steps:

referring to fig. 4, step S13 may include:

s41, determining an area to be expanded which needs to be subjected to equipment expansion operation and an area to be contracted which needs to be subjected to equipment contraction operation based on the collected operation data of each virtual character model in the virtual models;

specifically, it may be determined whether the load borne by one region has reached the upper limit according to the operation data, and if the load borne by one region has reached the upper limit, the region is considered as the region to be expanded.

Whether the load borne by one region is too small or not can be determined according to the operation data, if the load borne by the region is smaller than a preset value, the region is considered to be a region to be shrunk.

S42, controlling the standby equipment of the area to be expanded to be added into the equipment group of the area to be expanded, and removing at least one piece of equipment in the equipment group of the area to be reduced out of the equipment group of the area to be reduced.

And executing capacity expansion operation on the area to be expanded, and adding the standby equipment into the equipment group of the area to be expanded, wherein the standby equipment can be newly added equipment or equipment with smaller workload in other areas.

And executing capacity reduction operation on the area to be subjected to capacity reduction, and removing at least one device in the device group of the area to be subjected to capacity reduction out of the device group of the area to be subjected to capacity reduction, thereby avoiding resource waste.

3. The third implementation mode comprises the following steps:

step S13 may include:

and generating and sending an operation instruction to equipment corresponding to a target virtual role model based on the acquired running data of each virtual role model in the virtual models so as to enable the equipment to execute the operation instruction.

Specifically, a target virtual character model whose operation state needs to be changed is determined based on operation data of the virtual character model, and then an operation instruction, such as an adjustment parameter, a start-stop control command, and the like, is sent to a device corresponding to the target virtual character model, and the device executes the operation instruction.

In this embodiment, the fault can be quickly located and repaired, and capacity expansion and capacity reduction operations and adjustment of the working state of the device can also be performed according to the workload.

Optionally, on the basis of the above embodiment of the remote control method, another embodiment of the present invention provides a remote control device, and with reference to fig. 5, the remote control device may include:

a model obtaining module 101, configured to obtain a virtual model for simulating an operating state of each device in each system in different areas; the virtual model comprises virtual role models corresponding to each device in each system in different areas and communication connection relations among the different virtual role models;

a data acquisition module 102, configured to acquire operation data of each virtual character model in the virtual models; the running data of each virtual role model is the same as the running data of the corresponding equipment of the corresponding virtual role model;

and the regulation and control module 103 is configured to remotely regulate and control at least one device based on the acquired operation data of each virtual character model in the virtual model.

In this embodiment, a virtual model for simulating the operating states of the systems in different areas is pre-constructed, and a virtual model for simulating the operating states of the systems in different areas is obtained; collecting operation data of each virtual role model in the virtual models; and remotely regulating and controlling at least one piece of equipment based on the acquired running data of each virtual role model in the virtual models. In the invention, the equipment can be adjusted based on the operation data in the whole virtual model, and each equipment group is not managed independently, so that the whole management can be realized.

It should be noted that, for the working process of each module in this embodiment, please refer to the corresponding description in the above embodiments, which is not described herein again.

Optionally, on the basis of the above embodiment of the remote control device, the remote control device further includes:

the information acquisition module is used for acquiring role information of each device in each system in each area before the model acquisition module acquires a virtual model for simulating the running state of each device in each system in different areas; the role information comprises equipment identity information and a communication connection relation;

the information processing module is used for generating a virtual role model of each device based on the acquired role information of each device, and determining a coordinate point of the virtual role model corresponding to each device in the virtual model and a communication connection relation between the virtual role models;

the rule obtaining module is used for obtaining a virtual model generation rule;

and the model generation module is used for generating the virtual model based on the virtual model generation rule, the virtual role model of each device, the coordinate point of the virtual role model corresponding to each device in the virtual model and the communication connection relation among the virtual role models.

In this embodiment, a method for generating a virtual model is provided, and further, a model may be generated by the method in this embodiment, so as to visually view the operation conditions of each device in all the areas.

It should be noted that, for the working process of each module in this embodiment, please refer to the corresponding description in the above embodiments, which is not described herein again.

Optionally, on the basis of any one of the above embodiments of the remote regulation device, the regulation module includes:

the fault determining submodule is used for determining a virtual role model with a fault in the virtual model based on the acquired running data of each virtual role model in the virtual model;

the instruction issuing sub-module is used for issuing an isolation instruction to the equipment corresponding to the virtual role model with the fault so as to stop the equipment corresponding to the virtual role model with the fault;

and the first control submodule is used for controlling the equipment receiving the isolation instruction to carry out self-checking and fault repairing operation.

Further, the regulatory module comprises:

the area determination submodule is used for determining an area to be expanded, which needs to be subjected to equipment expansion operation, and an area to be contracted, which needs to be subjected to equipment contraction operation, based on the acquired running data of each virtual character model in the virtual models;

and the second control submodule is used for controlling the standby equipment of the area to be expanded to be added into the equipment group of the area to be expanded and removing at least one piece of equipment in the equipment group of the area to be reduced out of the equipment group of the area to be reduced.

Further, the regulatory module comprises:

and the instruction processing submodule is used for generating and sending an operation instruction to the equipment corresponding to the target virtual role model based on the acquired running data of each virtual role model in the virtual models so as to enable the equipment to execute the operation instruction.

In this embodiment, the fault can be quickly located and repaired, and capacity expansion and capacity reduction operations and adjustment of the working state of the device can also be performed according to the workload.

It should be noted that, for the working processes of each module and sub-module in this embodiment, please refer to the corresponding description in the above embodiments, which is not described herein again.

Optionally, on the basis of the embodiments of the remote control method and apparatus, another embodiment of the present invention provides an electronic device, which may include: a memory and a processor;

wherein the memory is used for storing programs;

the processor calls a program and is used to:

acquiring a virtual model for simulating the running state of each device in each system in different areas; the virtual model comprises virtual role models corresponding to each device in each system in different areas and communication connection relations among the different virtual role models;

collecting operation data of each virtual role model in the virtual models; the running data of each virtual role model is the same as the running data of the corresponding equipment of the corresponding virtual role model;

and remotely regulating and controlling at least one piece of equipment based on the acquired running data of each virtual role model in the virtual models.

In this embodiment, a virtual model for simulating the operating states of the systems in different areas is pre-constructed, and a virtual model for simulating the operating states of the systems in different areas is obtained; collecting operation data of each virtual role model in the virtual models; and remotely regulating and controlling at least one piece of equipment based on the acquired running data of each virtual role model in the virtual models. In the invention, the equipment can be adjusted based on the operation data in the whole virtual model, and each equipment group is not managed independently, so that the whole management can be realized.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (9)

1. A remote control method, comprising:

acquiring a virtual model for simulating the running state of each device in each system in different areas; the virtual model comprises virtual role models corresponding to each device in each system in different areas and communication connection relations among the different virtual role models; different areas in the virtual model are isolated from each other, and the different areas only communicate through a gateway;

collecting operation data of each virtual role model in the virtual models; the running data of each virtual role model is the same as the running data of the corresponding equipment of the corresponding virtual role model;

remotely regulating and controlling at least one piece of equipment based on the acquired running data of each virtual role model in the virtual models; the remote control of at least one of the devices based on the collected operating data of each of the virtual character models includes: and generating and sending an operation instruction to equipment corresponding to a target virtual role model based on the acquired running data of each virtual role model in the virtual models so as to enable the equipment to execute the operation instruction.

2. The remote control method according to claim 1, wherein before obtaining the virtual model for simulating the operating state of each device in the systems in different regions, the method further comprises:

acquiring role information of each device in each system in each area; the role information comprises equipment identity information and a communication connection relation;

generating a virtual role model of each device based on the acquired role information of each device, and determining a coordinate point of the virtual role model corresponding to each device in the virtual model and a communication connection relation between the virtual role models;

acquiring a virtual model generation rule;

and generating the virtual model based on the virtual model generation rule, the virtual role model of each device, the coordinate point of the virtual role model corresponding to each device in the virtual model and the communication connection relation among the virtual role models.

3. The remote control method according to claim 1, wherein the remote control of at least one of the devices based on the collected operation data of each of the virtual character models comprises:

determining a virtual role model with a fault in the virtual models based on the acquired operation data of each virtual role model in the virtual models;

issuing an isolation instruction to the equipment corresponding to the virtual role model with the fault so as to stop the equipment corresponding to the virtual role model with the fault;

and controlling the equipment receiving the isolation instruction to perform self-checking and fault repairing operations.

4. The remote control method according to claim 1, wherein the remote control of at least one of the devices based on the collected operation data of each of the virtual character models comprises:

determining an area to be expanded which needs to be subjected to equipment expansion operation and an area to be contracted which needs to be subjected to equipment contraction operation based on the acquired running data of each virtual character model in the virtual models;

and controlling the standby equipment of the area to be expanded to be added into the equipment group of the area to be expanded, and removing at least one piece of equipment in the equipment group of the area to be reduced out of the equipment group of the area to be reduced.

5. A remote regulating device, comprising:

the model acquisition module is used for acquiring a virtual model for simulating the running state of each device in each system in different areas; the virtual model comprises virtual role models corresponding to each device in each system in different areas and communication connection relations among the different virtual role models; different areas in the virtual model are isolated from each other, and the different areas only communicate through a gateway;

the data acquisition module is used for acquiring the operation data of each virtual role model in the virtual models; the running data of each virtual role model is the same as the running data of the corresponding equipment of the corresponding virtual role model;

the control module is used for remotely controlling at least one piece of equipment based on the acquired running data of each virtual role model in the virtual models; wherein the regulatory module comprises: and the instruction processing submodule is used for generating and sending an operation instruction to the equipment corresponding to the target virtual role model based on the acquired running data of each virtual role model in the virtual models so as to enable the equipment to execute the operation instruction.

6. The remote regulating device according to claim 5, further comprising:

the information acquisition module is used for acquiring role information of each device in each system in each area before the model acquisition module acquires a virtual model for simulating the running state of each device in each system in different areas; the role information comprises equipment identity information and a communication connection relation;

the information processing module is used for generating a virtual role model of each device based on the acquired role information of each device, and determining a coordinate point of the virtual role model corresponding to each device in the virtual model and a communication connection relation between the virtual role models;

the rule obtaining module is used for obtaining a virtual model generation rule;

and the model generation module is used for generating the virtual model based on the virtual model generation rule, the virtual role model of each device, the coordinate point of the virtual role model corresponding to each device in the virtual model and the communication connection relation among the virtual role models.

7. The remote regulating device according to claim 5, wherein the regulating module comprises:

the fault determining submodule is used for determining a virtual role model with a fault in the virtual model based on the acquired running data of each virtual role model in the virtual model;

the instruction issuing sub-module is used for issuing an isolation instruction to the equipment corresponding to the virtual role model with the fault so as to stop the equipment corresponding to the virtual role model with the fault;

and the first control submodule is used for controlling the equipment receiving the isolation instruction to carry out self-checking and fault repairing operation.

8. The remote regulating device according to claim 5, wherein the regulating module comprises:

the area determination submodule is used for determining an area to be expanded, which needs to be subjected to equipment expansion operation, and an area to be contracted, which needs to be subjected to equipment contraction operation, based on the acquired running data of each virtual character model in the virtual models;

and the second control submodule is used for controlling the standby equipment of the area to be expanded to be added into the equipment group of the area to be expanded and removing at least one piece of equipment in the equipment group of the area to be reduced out of the equipment group of the area to be reduced.

9. An electronic device, comprising: a memory and a processor;

wherein the memory is used for storing programs;

the processor calls a program and is used to:

acquiring a virtual model for simulating the running state of each device in each system in different areas; the virtual model comprises virtual role models corresponding to each device in each system in different areas and communication connection relations among the different virtual role models;

collecting operation data of each virtual role model in the virtual models; the running data of each virtual role model is the same as the running data of the corresponding equipment of the corresponding virtual role model;

remotely regulating and controlling at least one piece of equipment based on the acquired running data of each virtual role model in the virtual models; the remote control of at least one of the devices based on the collected operating data of each of the virtual character models includes: and generating and sending an operation instruction to equipment corresponding to a target virtual role model based on the acquired running data of each virtual role model in the virtual models so as to enable the equipment to execute the operation instruction.

Images