CN114519929B - Startup control method, equipment control system, terminal equipment and storage medium - Google Patents

Abstract

The embodiment of the invention discloses a startup control method, a device control system, a terminal device and a storage medium, wherein the method comprises the following steps: the power-on control equipment receives a wake-up signal sent by the background controller, and communicates with the background controller through the cellular communication module to receive a starting-up password sent by the background controller; the power-on control equipment sends the power-on password through the special communication module, so that the corresponding controlled equipment is started based on the power-on password after receiving the power-on password. The embodiment of the invention realizes the startup of the controlled equipment by sending the startup password to the controlled equipment through the special communication module, the 4G communication module on the controlled equipment can be in a closed state when the controlled equipment is shut down, the power consumption of the controlled equipment is reduced, the cost required by the special communication module is low, the real-time control of the controlled equipment can be realized under the condition of low cost, and the problem that the prior art needs high cost for simultaneously ensuring the endurance of the equipment and the real-time performance of the equipment control is solved.

Description

Startup control method, equipment control system, terminal equipment and storage medium

Technical Field

The embodiment of the application relates to the field of equipment control, in particular to a starting-up control method, an equipment control system, terminal equipment and a storage medium.

Background

With the development of hardware devices and communication technologies, the control of devices to perform corresponding functions by means of remote automatic control is widely applied to various fields.

In the existing equipment control mode, when a large number of controlled equipment exist, a background control system generally uses a 4G wireless communication module to communicate with each controlled equipment in order to ensure the communication distance, and meanwhile, the solar power supply mode is adopted for outdoor equipment to provide electric energy for the equipment. However, the 4G wireless communication module has a large current during sleep and operation, and in order to increase the cruising ability of the device, the solar panel area and the battery capacity of the device need to be increased when solar power is used for power supply, which significantly increases the cost. The 4G wireless communication module can be shut down when the equipment does not work, and the main controller of the equipment wakes up regularly, but the background control system cannot control the equipment in real time and can control the equipment after the equipment is woken up.

Disclosure of Invention

The embodiment of the invention provides a starting-up control method, an equipment control system, terminal equipment and a storage medium, and solves the problem that the prior art needs higher cost for simultaneously ensuring equipment endurance and equipment control real-time performance.

In a first aspect, an embodiment of the present invention provides a boot control method, including:

the power-on control equipment receives a wake-up signal sent by the background controller, and a cellular communication module of the power-on control equipment is in a wake-up state;

the power-on control equipment is communicated with the background controller through the cellular communication module to receive the power-on password sent by the background controller;

the power-on control equipment sends the power-on password through the special communication module so that the corresponding controlled equipment can be started based on the power-on password after receiving the power-on password, wherein the special communication module is specially used for transmitting the power-on password.

Preferably, the power-on control device is at least one of a plurality of controlled devices.

Preferably, the controlled device to be used as the power-on control device is determined by:

the controlled devices upload the device information of the controlled devices to the background controller;

and the background controller determines the controlled equipment used as the power-on control equipment according to the equipment information of the controlled equipment.

Preferably, the device information includes one or more of: the power of the controlled device, the position of the controlled device, and the working time of the controlled device.

Preferably, the determining, by the background controller, the controlled device to be used as the power-on control device according to the device information of the controlled device includes:

and the background controller selects at least one controlled device with the electric quantity larger than the preset electric quantity value and the position in a preset area as the power-on control device according to the electric quantity of the controlled device and the position of the controlled device.

Preferably, the method further comprises the following steps:

the switching request information is sent to a background controller when controlled equipment serving as power-on control equipment meets a preset condition;

and the background controller redetermines the first controlled equipment serving as the power-on control equipment according to the switching request information, and controls the controlled equipment serving as the power-on control equipment to be powered off and the cellular communication module of the first controlled equipment to be in an awakenable state.

Preferably, after receiving the boot password, the method for booting based on the boot password includes:

and after receiving the starting-up password, the corresponding controlled equipment compares the starting-up password with a preset starting-up password, and if the comparison result is consistent, starting up is carried out.

Preferably, if the comparison result is consistent, the booting is performed, including:

if the comparison result is consistent, the corresponding controlled equipment stops comparing the power-on password with the preset power-on password and starts up.

Preferably, after the booting, the method further includes:

and the corresponding controlled equipment receives a shutdown signal sent by the background controller, analyzes the currently received first startup password, compares the first startup password with a preset startup password, keeps starting up if the comparison result is consistent, and shuts down if the comparison result is inconsistent.

Preferably, before the power on control device receives the wake-up signal sent by the background controller, the method further includes:

the controlled equipment is started, and the password setting step is executed, wherein the password setting step specifically comprises the following steps:

receiving a second power-on password sent by the background controller, and setting the preset power-on password as the second power-on password;

the controlled equipment receives a shutdown signal sent by the background controller and shuts down the controlled equipment according to the shutdown signal.

Preferably, after the controlled device is powered on, before the password setting step is performed, the method further includes:

the controlled equipment judges whether a preset starting-up password is set by the controlled equipment;

if the preset startup password is set, the controlled equipment uploads the preset startup password to the background controller and judges whether a password modification instruction sent by the background controller is received;

if yes, executing the password setting step.

In a second aspect, an embodiment of the present invention provides an apparatus control system, where the apparatus control system includes a power-on control apparatus, a background controller, and a controlled apparatus, where the power-on control apparatus includes a cellular communication module and a dedicated communication module;

the power-on control equipment is used for receiving the wake-up signal sent by the background controller, communicating with the background controller through the cellular communication module to receive the power-on password sent by the background controller and sending the power-on password through the special communication module; the power-on control equipment comprises a power-on control equipment, a power-on password transmission module and a power-on password transmission module, wherein a cellular communication module of the power-on control equipment is in a wakenable state, and a special communication module is specially used for transmitting the power-on password;

the background controller is used for sending a wake-up signal and a power-on password to the power-on control equipment;

the controlled equipment is used for receiving the starting-up password and starting up the controlled equipment based on the starting-up password.

Preferably, the power-on control device further comprises a first controller module;

the cellular communication module is connected with the first controller module, and is used for receiving the wake-up signal and the power-on password, sending the controller wake-up signal to the first controller module according to the wake-up signal, and sending the power-on password to the first controller module;

the first controller module is connected with the special communication module and is used for establishing communication with the background controller through the cellular communication module when receiving the awakening signal; and is used for controlling the special communication module to send the starting-up password;

the special communication module is used for sending the starting-up password.

Preferably, the power-on control device is configured as a power-on controller, and the power-on controller is used for controlling the power-on of the controlled device.

Preferably, the power-on control device is at least one of a plurality of controlled devices.

In a third aspect, an embodiment of the present invention provides a terminal device, where the terminal device includes a processor and a memory;

the memory is used for storing the computer program and transmitting the computer program to the processor;

the processor is configured to execute a power-on control method according to the first aspect according to instructions in a computer program.

In a fourth aspect, embodiments of the present invention provide a storage medium storing computer-executable instructions for performing a power-on control method as in the first aspect when executed by a computer processor.

In the foregoing, an embodiment of the present invention provides a startup control method, an apparatus control system, a terminal apparatus, and a storage medium, where the method includes: the power-on control equipment receives a wake-up signal sent by the background controller, and a cellular communication module of the power-on control equipment is in a wake-up state; the power-on control equipment communicates with the background controller through the cellular communication module to receive the power-on password sent by the background controller; the power-on control equipment sends the power-on password through the special communication module so that the corresponding controlled equipment can be started based on the power-on password after receiving the power-on password, wherein the special communication module is specially used for transmitting the power-on password.

In the foregoing, in the embodiment of the present invention, the power-on control device is arranged as an intermediary between the background controller and the controlled device, and the power-on control device is provided with the special communication module, and when the background controller wakes up the power-on control device, the power-on control device can send the power-on password to the controlled device through the special communication module to start the controlled device. Because the power-on control equipment sends the power-on password through the special communication module, the 4G communication module on the controlled equipment can be in a closed state when the controlled equipment is powered off, and does not need to be in a high-power-consumption awakenable state, so that the power consumption of the controlled equipment is reduced, and the endurance time of the controlled equipment is ensured; secondly, because the special communication module is only used for sending or broadcasting the starting-up password, the cost required by the special communication module is lower, the real-time control of the controlled equipment can be realized under the condition of lower cost, and the problem that the prior art needs higher cost for simultaneously ensuring the endurance of the equipment and the real-time property of the equipment control is solved.

Drawings

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

Fig. 2 is a schematic structural diagram of an apparatus control system according to an embodiment of the present invention.

Fig. 3 is a schematic structural diagram of a power-on control device according to an embodiment of the present invention.

Fig. 4 is a schematic structural diagram of another device control system according to an embodiment of the present invention.

Fig. 5 is a schematic structural diagram of another device control system according to an embodiment of the present invention.

Fig. 6 is a flowchart illustrating another boot control method according to an embodiment of the present invention.

Fig. 7 is a flowchart illustrating another boot control method according to an embodiment of the present invention.

Fig. 8 is a schematic structural diagram of an irrigation device according to an embodiment of the present invention.

Fig. 9 is a schematic diagram of an irrigation device according to an embodiment of the present invention.

Fig. 10 is a schematic structural diagram of another irrigation device provided by the embodiment of the invention.

Fig. 11 is a schematic flow chart illustrating a preset power-on password set by irrigation equipment according to an embodiment of the present invention.

Fig. 12 is a schematic structural diagram of a terminal device according to an embodiment of the present invention.

Detailed Description

The following description and the annexed drawings set forth in detail certain illustrative embodiments of the application so as to enable those skilled in the art to practice them. The examples merely typify possible variations. Individual components and functions are optional unless explicitly required, and the sequence of operations may vary. Portions and features of some embodiments may be included in or substituted for those of others. The scope of the embodiments of the present application includes the full ambit of the claims, as well as all available equivalents of the claims. Embodiments may be referred to herein, individually or collectively, by the term "invention" merely for convenience and without intending to voluntarily limit the scope of this application to any single invention or inventive concept if more than one is in fact disclosed. Herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, or terminal apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed. The embodiments are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other. For the structures, products and the like disclosed by the embodiments, the description is relatively simple because the structures, the products and the like correspond to the parts disclosed by the embodiments, and the relevant parts can be just described by referring to the method part.

Example one

As shown in fig. 1, fig. 1 is a flowchart of a boot control method according to an embodiment of the present invention. The power-on control method provided by the embodiment of the invention can be executed by a power-on control device, the power-on control device can be realized in a software and/or hardware mode, and the power-on control device can be composed of two or more physical entities or one physical entity. For example, the power-on control device can be a computer, an upper computer, a tablet and other devices. In this embodiment, taking irrigation equipment as an example of controlled equipment, the method includes the following steps:

step 101, the power-on control device receives a wake-up signal sent by the background controller, and a cellular communication module of the power-on control device is in a wakenable state.

In this embodiment, in order to reduce the consumption of power, the cellular communication module of the power-on control device is set to enter the awakenable state when not operating. When the background controller needs to wake up a certain controlled device, a wake-up signal is sent to the power-on control device to wake up the cellular communication module of the power-on control device, so that the power-on control device can communicate with the background controller through the woken-up cellular communication module.

And 102, the power-on control equipment communicates with the background controller through the cellular communication module to receive the power-on password sent by the background controller.

When the power-on control equipment receives the wake-up signal, the power-on control equipment is switched to be in a working state, the power-on control equipment is communicated with the background controller through the cellular communication module after entering the working state, and a power-on password sent by the background controller is received and is used for controlling the corresponding controlled equipment to be powered on.

And 103, the power-on control equipment sends the power-on password through the special communication module so as to start the corresponding controlled equipment based on the power-on password after receiving the power-on password, wherein the special communication module is specially used for transmitting the power-on password.

The power-on control equipment sends the power-on password through the special communication module after receiving the power-on password, and after receiving the power-on password, the controlled equipment is started according to the power-on password to complete the starting process of the controlled equipment. After the startup is completed, the corresponding controlled device can also communicate with the background controller to receive the task instruction sent by the background controller and complete the corresponding task according to the task instruction.

It should be noted that, in this embodiment, the power-on control device may be configured with a dedicated communication module, and the controlled device may be configured with a corresponding dedicated receiving circuit. When the controlled device does not need to work, the cellular communication module of the controlled device can be in a non-awakenable power-off state, so that the power consumption of the controlled device can be greatly reduced, and the special receiving circuit of the controlled device can be kept in an awakenable state to receive the power-on password at any time. Here, since the dedicated receiving circuit is used exclusively or mainly for receiving the power-on password, the dedicated receiving circuit is not added at much cost, and the power consumption of the dedicated receiving circuit for keeping the wake-up state is low, and the duration of the controlled device is little affected.

By arranging the special communication module on the power-on control device, and the special communication module is only used for sending or broadcasting the power-on password, the cost required by the special communication module is low. And when the controlled equipment is awakened through the power-on control equipment, the 4G communication module on the controlled equipment does not need to work at this time because the power-on control equipment sends the power-on password through the special communication module, the 4G communication module of the controlled equipment can be in a closed state when being powered off, and does not need to be in a high-power-consumption awakenable state, and the real-time control of the controlled equipment is realized at lower cost while the endurance of the controlled equipment is ensured.

In this embodiment, taking irrigation equipment as controlled equipment as an example, in an existing remote automatic control irrigation system, when the number of irrigation equipment is large, in order to ensure that all irrigation equipment can be controlled, a 4G communication module with a long communication distance needs to be used for communication, however, the 4G communication module has a large current in sleep and work, which results in poor cruising ability of the irrigation equipment. When adopting solar energy power supply in the open air, for increasing irrigation equipment duration, increase solar panel's area and battery capacity on irrigation equipment usually, but when irrigation equipment is many, the cost is higher, secondly, if close 4G communication module, then can't realize irrigation equipment's real time control.

In this embodiment, when the background controller needs to wake up an irrigation device, a wake-up signal is sent to the power-on control device, and after the power-on control device receives the wake-up signal, the power-on control device communicates with the background controller through the cellular communication module to receive the power-on password sent by the background controller, and after receiving the power-on password, the power-on control device sends the power-on password through the dedicated communication module. The special receiving circuit of the irrigation equipment can receive the starting password in real time because the special receiving circuit is always in the awakenable state, the irrigation equipment can be started according to the starting password after receiving the starting password, the irrigation equipment can be communicated with the background controller after being started, the irrigation instruction sent by the background controller is received, and an irrigation task is completed according to the irrigation instruction, in the process, the 4G communication module of the irrigation equipment can be in the closed state when being shut down, so that the endurance time of the controlled equipment is ensured, and secondly, the special communication module is low in cost, and the real-time control of the irrigation equipment can be realized at low cost.

As shown in fig. 2, fig. 2 is a schematic structural diagram of an apparatus control system according to an embodiment of the present invention, where the apparatus control system includes a power-on control apparatus 201, a background controller 202, and a controlled apparatus 203, and the power-on control apparatus includes a cellular communication module 2011 and a dedicated communication module 2013.

The power-on control device 201 is configured to receive a wake-up signal sent by the background controller 202, communicate with the background controller 202 through the cellular communication module 2011 to receive a power-on password sent by the background controller 202, and send the power-on password through the dedicated communication module 2013; the cellular communication module 2011 of the power-on control device 201 is in the awake state, and the dedicated communication module 2013 is dedicated for transmitting the power-on password.

The background controller 202 is configured to send a wake-up signal and a power-on password to the power-on control device.

The controlled device 203 is configured to receive a power-on password and perform power-on based on the power-on password.

In this embodiment, the power-on control device 201, the background controller 202, and the controlled device 203 are connected wirelessly, and the cellular communication module 2011 and the dedicated communication module 2013 are included in the power-on control device 201. The controlled device 203 may be an irrigation device (or other devices), when the background controller 202 needs to start up an irrigation device, it first needs to send a wake-up signal to the upper electric control device 201, the upper electric control device 201 communicates with the background controller 202 through the cellular communication module 2011 after receiving the wake-up signal, the background controller 202 sends a start-up password to the upper electric control device 201 through the cellular communication module 2011, the upper electric control device 201 sends the start-up password through the dedicated communication module 2013 after receiving the start-up password, and the corresponding irrigation device starts up according to the start-up password after receiving the start-up password sent by the dedicated communication module 2013 of the upper electric control device 201.

In an embodiment, as shown in fig. 3, fig. 3 is a schematic structural diagram of a power-on control device 201 according to an embodiment of the present invention, and the power-on control device 201 further includes a first controller module 2012.

The cellular communication module 2011 is connected to the first controller module 2012, and configured to receive the wake-up signal and the power-on password, send the controller wake-up signal to the first controller module 2012 according to the wake-up signal, and send the power-on password to the first controller module 2012.

The cellular communication module 2011 is connected to the first controller module 2012, it should be noted that the cellular communication module 2011 needs to be kept awake all the time, so that when the cellular communication module 2011 receives the wake-up signal sent by the background controller 202, the cellular communication module 2011 can send the controller wake-up signal to the first controller module 2012 in time. Meanwhile, the cellular communication module 2011 is further configured to receive the power-on password sent by the background controller 202, and send the power-on password to the first controller module 2012. In one embodiment, the cellular communication module 2011 is a 4G communication module.

The first controller module 2012 is connected to the dedicated communication module 2013, it can be understood that the first controller module 2012 also needs to be always awake, and the first controller module 2012 is configured to establish communication with the background controller 202 through the cellular communication module 2011 when receiving the wakeup signal; and is used for controlling the special communication module 2013 to send the power-on password.

The first controller module 2012 is respectively connected to the cellular communication module 2011 and the dedicated communication module 2013, and the first controller module 2012 is in an awake state when not in use, and wakes up when the first controller module 2012 receives a wake-up signal sent by the cellular communication module 2011, and then sends a communication establishment instruction to the cellular communication module 2011, establishes communication with the background controller 202 through the cellular communication module 2011 to receive a power-on password sent by the background controller 202, and controls the dedicated communication module 2013 to send the power-on password after receiving the power-on password.

The special communication module 2013 is used for sending a power-on password.

The special communication module 2013 is used for sending the power-on password at a certain frequency in a wireless transmission mode. The special communication module 2013 is only used for sending or broadcasting the power-on password, and has single function and simpler function, so the special communication module 2013 needs lower cost. Secondly, when the special communication module 2013 is used for sending the power-on password, the 4G communication module on the controlled device does not need to work, and when the controlled device 203 is in the power-off state, the 4G communication module does not need to be in the dormant state or the working state, so that the power consumption of the controlled device 203 can be reduced, and the endurance time of the controlled device 203 is ensured.

In this embodiment, the cellular communication module 2011 needs to be kept in an awake state all the time, or the cellular communication module 2011 and the first controller module 2012 need to be kept in the awake state all the time, when the background controller 202 needs to power on an irrigation device, first, an awake signal needs to be sent to the power-on control device 201 to awake the power-on control device 201, after receiving the awake signal sent by the background controller 202, the cellular communication module 2011 sends a controller awake signal to the first controller module 2012, after receiving the controller awake signal, the first controller module 2012 wakes up, and establishes communication with the background controller 202 through the cellular communication module 2011 to inform the background controller 202 that the first controller module 2012 is already powered on, then, the background controller 202 sends a power-on password to the cellular communication module 2011, and after receiving the power-on password, the first controller module 2012 controls the dedicated communication module 2013 to send the power-on password at a certain frequency.

The embodiment of the invention is provided with the power-on control equipment as an intermediary between the background controller and the controlled equipment, and the power-on control equipment is provided with the special communication module. After the background controller wakes up the power-on control equipment, the controlled equipment can be started up by sending a power-on password to the controlled equipment through the special communication module, redundant power supply facilities do not need to be added on the controlled equipment in the process, the cost required by the special communication module is low, the controlled equipment can be controlled in real time in a low-cost mode, the 4G communication module on the controlled equipment can be in a closed state when the controlled equipment is shut down, and does not need to be in a high-power-consumption wakenable state, so that the electric quantity used by the controlled equipment is reduced, the electric energy consumption is reduced, and the cruising ability of the controlled equipment is improved.

In one embodiment, the power-on control device 201 is configured as a power-on controller, and the power-on controller is used to control the power-on of the controlled devices 203, and at this time, in order for the power-on controller to control the power-on of all the controlled devices 203 in real time, the cellular communication module 2011 and the first controller module 2012 in the power-on controller need to be kept in the wakeable state. It should be further noted that, in order to improve the endurance time of the power-on controller, a battery with a larger capacity may be separately configured for the power-on controller. Illustratively, in one embodiment, the power-on control device is configured as a power-on controller, as shown in FIG. 4, such that the power-on controller is capable of controlling the powering-on of the irrigation device.

On the basis of the above embodiment, the power-on control device is at least one of a plurality of controlled devices.

In another embodiment, the power-on control device 201 is at least one of a plurality of controlled devices 203. Illustratively, as shown in fig. 5, one controlled device 203 is selected as the power-on control device 201, and at this time, the irrigation device can control other irrigation devices. It is understood that the number of the controlled devices 203 selected as the power-on control device 201 may be set according to actual needs, and the number of the controlled devices 203 selected as the power-on control device 201 is not particularly limited in this embodiment.

On the basis of the above embodiment, the controlled device to be used as the power-on control device is determined by:

and step 1001, uploading own device information to a background controller by a plurality of controlled devices.

In this embodiment, when the power-on control apparatus 201 is at least one of the plurality of controlled apparatuses 203, it is necessary to select a controlled apparatus as the power-on control apparatus 201. Therefore, after the controlled device 203 is turned on for the first time, the device information of the controlled device 203 needs to be uploaded to the background controller 202, where the device information includes the state information of the controlled device 203. The controlled device 203 may communicate with the background controller 202 through the cellular communication module 2011 to upload device information. For example, in one embodiment, after all irrigation devices are powered on, the irrigation device serving as the powered-on control device 201 needs to be selected from all irrigation devices, so that the device can control other irrigation devices, and therefore, multiple irrigation devices need to upload their own device information to the background controller 202. It should be noted that, by providing a sensor on the irrigation equipment, the sensor can be used to obtain the status information of the irrigation equipment. It is understood that, in this embodiment, the manner of acquiring the device information may be set according to actual needs, and is not specifically limited in this embodiment.

Step 1002, the background controller determines a controlled device to be used as a power-on control device according to the device information of the controlled device.

After receiving the device information of all the controlled devices 203, the background controller 202 summarizes the device information of all the controlled devices 203, performs summary analysis on the device information of all the controlled devices 203, and determines the controlled device serving as the power-on control device 201 in all the controlled devices 203 according to the analysis result.

In one embodiment, after selecting the irrigation device as the powered control device 201, the background controller 202 sends a sleep command to the irrigation device as the powered control device 201, and after receiving the sleep command, the irrigation device as the powered control device 201 controls the cellular communication module 2011 and the first controller module 2012 to enter the wakenable state, and other circuits or modules are powered off. Meanwhile, the background controller 202 also sends a shutdown signal to other irrigation equipment, so that the other irrigation equipment is shut down.

On the basis of the above embodiment, the device information includes one or more of the following: the power of the controlled device, the location of the controlled device, and the operating time of the controlled device.

For the electric quantity, the controlled device 203 may directly read the state information on the self power supply module to obtain the electric quantity, for the position, a GPS sensor may be set on the controlled device 203, the controlled device 203 obtains the position of the controlled device by reading the GPS sensor, for the working time, a timer may be set on the controlled device 203, when the controlled device 203 is in the wakenable state, counting is performed, and the controlled device 203 determines the working time of the controlled device by reading the timer.

For example, in an embodiment, after receiving the device information, the background controller 202 may select, as the powered control device 201, an irrigation device with the largest power among all irrigation devices 203, select, as the powered control device 201, an irrigation device located at the center of all irrigation devices 203, or select, as the powered control device 201, an irrigation device with the shortest operating time among all irrigation devices 202.

On the basis of the foregoing embodiment, in step 1002, the background controller determines, according to the device information of the controlled device, that the controlled device to be used as the power-on control device is specifically executed in step 10021, where the step includes:

step 100221, the background controller selects, according to the electric quantity of the controlled device and the position of the controlled device, at least one controlled device whose electric quantity is greater than the preset electric quantity value and whose position is within the preset area as the power-on control device.

In one embodiment, the device information includes the power amount of the controlled device 203 and the location of the controlled device 203, and after receiving the device information of the controlled device 203, the background controller 202 selects the controlled device 203 with the power amount greater than the preset power amount value and the location within the preset area from all the controlled devices 203 as the power-on control device. For example, the background controller 202 sets the preset area as a central area of all irrigation devices, and uses at least one irrigation device with a power greater than the preset power value and a location in the central area as the power-on control device 201. It will be appreciated that since the irrigation equipment is located in the central area, it can be controlled to other irrigation equipment as much as possible, and secondly, since the irrigation equipment has a higher power level, it can last for a longer period of time, and thus, it acts as a power-on control device 201. It is understood that the number of irrigation devices as the power-on control device 201 can be set according to actual needs, and the number of irrigation devices as the power-on control device is not specifically limited in this embodiment.

On the basis of the above embodiment, the method further includes steps 1003 to 1004, and specifically includes:

step 1003, configured to send switching request information to the background controller when the controlled device serving as the power-on control device meets a preset condition.

In this embodiment, when the controlled device serving as the power-on control device 201 meets the preset condition, the controlled device sends switching request information to the background controller 202, where the switching request information is used to request to switch the power-on control device 201. For example, in one embodiment, the preset condition is that the electric quantity is lower than the electric quantity threshold or the working time is longer than the time threshold, and when the electric quantity of the irrigation device serving as the power-on control device 201 is lower than the electric quantity threshold or the working time is longer than the time threshold, a switching request message is sent to the background controller 202 to request to switch the power-on control device 201, so as to avoid that the irrigation device serving as the power-on control device 201 is shut down due to too low electric quantity or damaged due to too long working time.

Step 1004, the background controller re-determines the first controlled device as the power-on control device according to the switching request information, and controls the controlled device as the power-on control device to be powered off and controls the cellular communication module of the first controlled device to be in a wakenable state.

After receiving the switching request information, the background controller 202 reselects the first controlled device serving as the power-on control device 201 from all the controlled devices 203, and controls the controlled device originally used as the power-on control device 201 to be powered off, and controls the cellular communication module of the first controlled device serving as the new power-on control device 201 to be in an awakenable state, so that the first controlled device can subsequently receive an awakening signal sent by the background controller 202 in time to be awakened, and send a power-on password to the other controlled devices 203.

Specifically, in an embodiment, after reselecting the first irrigation device serving as the powered-on control device 201, the background controller 202 sends a power-on password of the first irrigation device to the irrigation device serving as the powered-on control device 201, so that the irrigation device serving as the powered-on control device 201 broadcasts the power-on password, so that the first irrigation device is powered on, the first irrigation device communicates with the background controller 202 after being powered on, the background controller 202 sends the powered-on control device setting information to the first irrigation device, so that the first irrigation device knows that the first irrigation device is set as a new powered-on control device, the first irrigation device controls its own cellular communication module to be in a wakenable state, and then the background controller 202 sends a power-off signal to the irrigation device serving as the powered-on control device 201 to control the irrigation device serving as the powered-on control device 201 to be powered off. If the position of the reselected first irrigation equipment is deviated and the other irrigation equipment with the farthest distance cannot be controlled to start, a plurality of first irrigation equipment can be selected to control all other irrigation equipment.

It is understood that, if conditions permit, if the controlled device as the power-on control device 201 can be charged for a long period of time or the capacity of the battery is sufficiently large, one controlled device may be fixed as the power-on control device without switching.

As shown in fig. 6, fig. 6 is a flowchart of another boot control method according to an embodiment of the present invention, which includes the following steps:

step 301, the power-on control device receives a wake-up signal sent by the background controller, and the cellular communication module of the power-on control device is in a wakenable state.

Step 302, the power-on control device communicates with the background controller through the cellular communication module to receive the power-on password sent by the background controller.

Step 303, the power-on control device sends the boot password through the dedicated communication module, so that after the corresponding controlled device receives the boot password, the power-on password is compared with a preset boot password, and if the comparison result is consistent, the power-on is performed, wherein the dedicated communication module is specially used for transmitting the boot password.

In this embodiment, after receiving the power-on password sent by the power-on control device 201, the controlled device 203 compares the power-on password with a preset power-on password, if the power-on password is the same as the preset power-on password, the comparison result is consistent, the controlled device 203 starts up, and if the comparison result is inconsistent, the controlled device 203 does not start up, so that the monomer control of the controlled device 203 can be realized through the power-on password.

On the basis of the above embodiment, if the comparison result in step 303 is consistent, the step 3031 specifically performs the boot process, including:

step 3031, if the comparison result is consistent, the corresponding controlled device stops comparing the boot password with the preset boot password and boots up.

If the comparison result is consistent, the corresponding controlled device 203 stops comparing the received power-on password with the preset power-on password in the process of starting up. It should be further noted that the purpose of stopping comparing the received boot password with the preset boot password in this step is to keep the corresponding controlled device in a boot state, it can be understood that if the power-on control device 201 may stop sending the boot password or send another boot password during the boot process, at this time, if the corresponding controlled device 203 continues to receive the boot password, the currently received boot password is inconsistent with the preset boot password (if the boot password is not received, the received boot password is set to 0 by default), at this time, the boot cannot be continued, and the boot failure is caused. Therefore, in the process of booting the corresponding controlled device 203, the comparison between the boot password and the preset boot password needs to be stopped.

As shown in fig. 7, fig. 7 is a flowchart of another boot control method according to the embodiment of the present invention, and after step 303 is executed, the method further includes the following steps:

step 304, the corresponding controlled device receives the shutdown signal sent by the background controller, analyzes the currently received first startup password, compares the first startup password with a preset startup password, if the comparison result is consistent, the controlled device is kept to be started, and if the comparison result is inconsistent, the controlled device is shut down.

In this embodiment, after the corresponding controlled device 203 is powered on, communication is established with the background controller 202, after the related task is executed according to the task instruction sent by the background controller 202, the background controller 202 sends a power-off signal to the corresponding controlled device 203, at this time, the corresponding controlled device 203 parses the currently received first power-on password, and re-executes the step of comparing the power-on password with the preset power-on password, that is, comparing the first power-on password with the preset power-on password, if the first power-on password is consistent with the preset power-on password, the power-on state is continuously maintained, and if the first power-on password is inconsistent with the preset power-on password, the power-off is performed. It can be understood that, since the power-on password of the power-on control device 201 is sent only once, when the corresponding controlled device 203 receives the power-off signal, the first power-on password at this time cannot correspond to the preset power-on password, and the corresponding controlled device 203 is powered off. However, the situation that the first power-on password corresponds to the preset power-on password is not excluded, and if the first power-on password corresponds to the preset power-on password, the corresponding controlled device 203 continues to maintain the power-on state until a new power-off signal arrives.

For example, in an embodiment, after the corresponding irrigation device is powered on, communication is established with the background controller 202, an irrigation task is performed according to a task instruction sent by the background controller 202, after the irrigation task is executed, the background controller 202 sends a power-off signal to the corresponding irrigation device, the corresponding irrigation device analyzes the currently received first power-on password, compares the first power-on password with the preset power-on password, and is powered off because the first power-on password is not consistent with the preset power-on password.

In one embodiment, when the power-on control device is configured as a power-on controller, the irrigation device is configured as shown in fig. 8, and includes a password receiving module 2031, a password processing module 2032, a decoder module 2033, a latch module 2034, a second controller module 2035, a 4G communication module 2036, a power supply module 2037, and a task execution module 2038;

the password receiving module 2031 is connected to the password processing module 2032, and is configured to receive the boot password and send the boot password to the password processing module 2032;

the password processing module 2032 is connected to the decoder module 2033, and is configured to pre-process the boot password and send the pre-processed boot password to the decoder module 2033;

the decoder module 2033 is connected to the latch module 2034, the second controller module 2035, and the power supply module 2037, and is configured to obtain a preset boot password from the latch module 2034, compare the boot password with the preset boot password, and continuously send a power-on signal to the power supply module 2037 if the comparison result is consistent; if the comparison result is not consistent, a power-off signal is sent to the power supply module 2037; and a power-on signal receiving module 2037 configured to receive the first enable signal and the second enable signal sent by the second controller module 2035, stop comparing the power-on password with the preset power-on password according to the first enable signal, and continuously send the power-on signal to the power supply module 2035; continuously comparing the power-on password with the preset power-on password according to the second enabling signal;

the latch module 2034 is connected to the second controller module 2035 and configured to store and lock a preset boot password;

the second controller module 2035 is connected to the 4G communication module 2036 and the power supply module 2037, and is configured to control the 4G communication module 2036 to communicate with the background controller 202, and to control the task execution module to execute a corresponding task according to the task instruction; and for sending a first enable signal to the decoder module 2033 upon receiving power supplied by the power supply module 2037; upon receiving the shutdown signal transmitted by the 4G communication module 2036, transmit a second enable signal to the decoder module 2033;

the 4G communication module 2036 is configured to receive a shutdown signal sent by the background controller 202, send the shutdown signal to the second controller module 2035, and receive a task instruction sent by the background controller 202, and send the task instruction to the second controller module 2035;

the power supply module 2037 is configured to supply power to the second controller module 2035 when receiving a power-on signal, and to stop supplying power to the second controller module 2035 when receiving a power-off signal;

the task execution module 2038 is configured to execute corresponding tasks under the control of the second controller module 2035.

It should be further noted that in this embodiment, the dedicated receiving circuit (the password receiving module 2031, the password processing module 2032, the decoder module 2033, and the latch module 2034) of the irrigation device needs to be kept in a constant power supply state. The password receiving module 2031 receives the power-on password sent by the power-on control device 201, sends the power-on password to the password processing module 2032, and the password processing module 2032 sends the power-on password to the decoder module 2033 after preprocessing the power-on password. Illustratively, in one embodiment, the cryptographic processing module 2032 comprises a filter, a power amplifier, and a voltage comparator, the filter is connected to the cryptographic receiving module 2031 and the power amplifier, respectively, and the voltage comparator is connected to the power amplifier and the decoder, respectively. The password receiving module 2031 sends the boot password to the password processing module 2032 after receiving the boot password, the filter filters the boot password to remove noise, then sends the filtered boot password to the power amplifier for amplification, and finally inputs the amplified boot password to the voltage comparator, and finally the voltage comparator sends the boot password to the decoder module 2033.

The decoder module 2033 obtains a preset boot password from the latch module 2034, compares the boot password with the preset boot password, and locks the comparison result if the comparison result is consistent, and continuously sends a power-on signal to the power supply module 2037. For example, if the preset boot password is Y and the boot password is X, if X-Y =0 is true, the comparison result is consistent, the decoder module locks the comparison result at this time, and continuously sends the power-on signal to the power supply module 2037. After receiving the power-on signal, the power supply module 2037 provides electrical energy to the second controller module 2035, the second controller module 2035 executes the boot process, meanwhile, the second controller module 2035 sends a first enable signal to the decoder module 2033, the decoder module 2033 is disabled after receiving the first enable signal, stops comparing the boot password with the preset boot password and continuously sends the power-on signal to the power supply module 2037, and the power supply module 2037 continuously outputs electrical energy to the second controller module 2035.

After the machine is started, the second controller module 2035 communicates with the background controller 202 through the 4G communication module 2036, the background controller 202 sends a task instruction to the 4G communication module 2036, the 4G communication module 2036 sends the task instruction to the second controller module 2035 after receiving the task instruction, and the second controller module 2035 controls the task execution module 2038 to execute the irrigation task according to the task instruction.

After the task execution module 2038 completes an irrigation task, the background controller 202 sends a shutdown signal to the 4G communication module 2036, the 4G communication module 2036 sends the shutdown signal to the second controller module 2035, the second controller module 2035 sends a second enable signal to the decoder module 2033 after receiving the shutdown signal, the decoder module 2033 is disabled, the decoder module 2033 continues to compare the currently analyzed first startup password with the preset startup password, at this time, if the comparison result is not consistent, the decoder module 2033 sends a power-off signal to the power supply module 2037, after receiving the power-off signal, the power supply module 2037 stops supplying power to the second controller module 2035, and waits for the arrival of the next startup password, which process is shown in fig. 9.

In another embodiment, when the power-on control device 201 is at least one of the plurality of controlled devices 203, the controlled device 203 as the power-on control device 201 further includes a cellular communication module 2011, a first controller module 2012, and a dedicated communication module 2013. The special communication module 2013 of the power-on control device 201 comprises a wireless transmitting unit 20131 and a first antenna, wherein the wireless transmitting unit 20131 is respectively connected with the first controller module 2012 and the first antenna; the wireless transmitting unit 20131 is configured to receive the power-on password sent by the first controller module 2012, and send the power-on password to the first antenna, where the first antenna is configured to send the power-on password. The password receiving module 2031 of the irrigation apparatus comprises a second antenna 20311.

In one embodiment, when the power-on control device 201 is at least one of the controlled devices 203, the cellular communication module 2011 is multiplexed into the 4G communication module 2036, the first controller module 2012 is multiplexed into the second controller module 2035, the first antenna is multiplexed into the second antenna 20311, the irrigation device is further provided with a radio frequency switch unit 2039, and the radio frequency switch unit 2039 is respectively connected with the second antenna 20311, the wireless transmission unit 20131, the cryptographic processing module 2032 and the decoder module 2033, and the structure of the irrigation device is shown in fig. 10.

The wireless transmitting unit 20131 is configured to receive the power-on password sent by the second controller module 2035, and send the power-on password to the radio frequency switch unit 2039;

the radio frequency switch unit 2039 is configured to receive the mode switching information sent by the decoder module 2033, switch the operating mode to a signal transmission mode or a signal reception mode according to the mode switching information, send the boot password sent by the wireless sending unit to the second antenna 20311 when the operating mode is in the signal transmission mode, receive the boot password sent by the second antenna 20311 when the operating mode is in the signal reception mode, and send the boot password to the password processing module 2032;

the second antenna 20311 is configured to send or receive a boot password;

the decoder module 2033 is further configured to send mode switching information to the radio frequency switch unit 2039 according to the mode control instruction sent by the second controller module 2035.

The second controller module 2035 is also used to send mode control instructions to the decoder module 2033.

For the irrigation device shown in fig. 10, this irrigation device is selected as the power-on control device 201 for waking up other irrigation devices. When the 4G communication module 2036 in the wakenable state receives the wake-up signal sent by the background controller 202, the 4G communication module 2036 wakes up the second controller module 2035, the second controller module 2035 communicates with the background controller 202, receives the power-on password sent by the background controller 202, and sends the power-on password to the wireless transmitting unit 20131, the wireless transmitting unit 20131 sends the power-on password to the radio frequency switch unit 2039, the radio frequency switch unit 2039 sends the power-on password through the second antenna 20311, and then the 4G communication module 2036 and the second controller module 2035 reenter the wakenable state, and other modules or components are powered off to wait for the arrival of the next wake-up signal.

Other irrigation devices (i.e. controlled devices) not selected as the power-on control device 201, after receiving the power-on password, the second antenna 20311 sends the power-on password to the radio frequency switch unit 2039, the radio frequency switch unit 2039 sends the power-on password to the password processing module 2032, the password processing module 2032 preprocesses the power-on password and sends the power-on password to the decoder module 2033, the decoder module 2033 obtains the preset power-on password from the latch module 2034, compares the power-on password with the preset power-on password, and sends a power-on signal to the power supply module 2037 if the comparison result is consistent. After receiving the power-on signal, the power supply module 2037 provides electrical energy to the second controller module 2035, the second controller module 2035 executes the boot process, meanwhile, the second controller module 2035 sends a first enable signal to the decoder module 2033, the decoder module 2033 is disabled after receiving the first enable signal, stops comparing the boot password with the preset boot password and continuously sends the power-on signal to the power supply module 2037, and the power supply module 2037 continuously outputs electrical energy to the second controller module 2035.

After the machine is started, the second controller module 2035 communicates with the background controller 202 through the 4G communication module 2036, the background controller 202 sends a task instruction to the 4G communication module 2036, the 4G communication module 2036 sends the task instruction to the second controller module 2035 after receiving the task instruction, and the second controller module 2035 controls the task execution module 2038 to execute the irrigation task according to the task instruction.

This is the internal structure and the operation principle of the irrigation device when the power-on control device 201 is at least one of the irrigation devices.

In an embodiment, before the power-on control device in the wakeable state executing step 301 receives the wake-up signal sent by the background controller, the method further includes steps 3001 to 3003, specifically:

step 3001, the controlled device is powered on, and the password setting step is executed, wherein the password setting step specifically includes steps 3002 to 3003.

Before executing step 301, a preset power-on password needs to be set in each controlled device 203, and the setting step of the preset power-on password is specifically executed in steps 3002 to 3003.

Step 3002, receiving a second boot password sent by the background controller, and setting the preset boot password as the second boot password.

After the controlled device 203 is powered on, it receives the second power-on password sent by the background controller 202, and sets the preset power-on password as the second power-on password. Specifically, after the controlled device 203 is powered on, the second controller module 2035 communicates with the background controller 202 through the 4G communication module 2036, the background controller 202 sends a second power-on password to be set to the 4G communication module 2036, the 4G communication module 2036 sends the second power-on password to the second controller module 2035, and the second controller module 2035 sets the preset power-on password to the second power-on password. It can be understood that the second power-on password may be set according to actual needs, and specific contents of the second power-on password are not limited in this embodiment.

Specifically, the irrigation device shown in fig. 8 is taken as an example for explanation. When the irrigation device is powered on, the latch module 2034 is powered on, and the default power-on password is used as the power-on password, for example, 0, since the irrigation device does not receive the power-on password at this time, the power-on password received by the decoder module 2033 is also 0 at this time, the power-on password is consistent with the default power-on password, the decoder module 2033 locks the comparison result at this time, the decoder module 2033 continuously sends a power-on signal to the power supply module 2037, and the power supply module 2037 continuously supplies power to the second controller module 2035.

When the power supply module 2037 starts to supply power to the second controller module 2035, the second controller module 2035 sends a first enable signal to the decoder module 2033, the decoder module 2033 is disabled, the comparison between the power-on password and the preset power-on password is stopped, and a power-on signal is continuously output to the power supply module 2037. The second controller module 2035 communicates with the background controller 202 through the 4G communication module 2036 to notify that the irrigation device 203 is powered on, the background controller 202 sends a second power-on password to the 4G communication module 2036, and the 4G communication module 2036 forwards the second power-on password to the second controller module 2035. After receiving the second boot password, the second controller module 2035 controls the latch module 2034 to set the preset boot password as the second boot password and lock the preset boot password.

Step 3003, the controlled device receives a shutdown signal sent by the background controller, and shuts down the controlled device according to the shutdown signal.

After the controlled device 203 sets the second power-on password, the controlled device communicates with the background controller 202 to notify the background controller 202 that the second power-on password is set, the background controller 202 sends a power-off signal to the controlled device 203, and the controlled device 203 shuts down after receiving the power-off signal. Specifically, after the latch module 2034 of the irrigation device locks the second power-on password, the second controller module 2035 informs the background controller 202 through the 4G communication module 2036 that the second power-on password is successfully set, the background controller 202 sends a power-off signal to the second controller module 2035 through the 4G communication module 2036, the second controller module 2035 outputs a second enable signal to the decoder module 2033 after receiving the power-off signal, the decoder module 2033 compares the power-on password with the preset power-on password again, at this time, the power-on password received by the decoder module 2033 is inconsistent with the preset power-on password, and the decoder module 2033 outputs a power-off signal to the power supply module 2033 so that the power supply module stops supplying power to the second controller module 2035.

It should be further noted that, for example, in the case of multiplexing modules or components as shown in fig. 10, after the password setting step is performed, the controlled device serving as the power-on control device 201 controls the 4G communication module 2036 and the second controller 2035 to enter the wakeable state, the second controller module 2035 sends a mode control instruction to the decoder module 2033, the decoder module 2033 sends mode switching information to the radio frequency switch unit 2039, controls the operating mode of the radio frequency switch unit 2039 to be the signal transmission mode, then shuts down the modules or components except for the 4G communication module 2036 and the second controller 2035, for other controlled devices 203, the second controller module 2035 controls the operating mode of the radio frequency switch unit 2039 to be the signal reception mode, and after the password setting step is performed, shuts down the modules or components except for the dedicated reception circuit (the radio frequency switch unit 2039, the password processing module 2032, the decoder module 2033, and the latch module 2034).

If there is no module or component multiplexing, the cellular communication module 2011 and the first controller module 2012, which are controlled by the power-on control device 201, enter the wakenable state, and the other components, modules, or modules are powered off. For other controlled devices 203, after the subsequent step of setting the secret code, the modules or components except the dedicated receiving circuit (the rf switch unit 2039, the cryptographic processing module 2032, the decoder module 2033, and the latch module 2034) are shut down.

On the basis of the above embodiment, after the controlled device is powered on in step 3001 and before the password setting step is performed, the method further includes steps 30011 to 30013, which specifically include:

step 30011, the controlled device determines whether a preset boot password is set.

After the controlled device 203 is powered on, it first determines whether a preset power-on password is set. Illustratively, the second controller module 2035 on the irrigation device reads the data stored in the latch module 2034 and determines whether a preset boot password has been set in the latch module 2034 according to the data.

Step 30012, if a preset boot password is set, the controlled device uploads the preset boot password to the background controller, and determines whether a password modification instruction sent by the background controller is received;

if the preset power-on password is set for the irrigation equipment, it is determined that the irrigation equipment is not started for the first time, at this time, the set preset power-on password is uploaded to the background controller 202 by the irrigation equipment, the user determines whether to modify the preset power-on password according to the preset power-on password, if so, the user sends a password modification instruction to the background controller 202, and the background controller 202 sends the password modification instruction to the irrigation equipment. In one embodiment, the controlled device 203 uploads the power-on resume information at the same time when the preset power-on password is uploaded to the background controller 202, so that the user can clearly know that the controlled device 203 is not powered on for the first time.

Step 30013, if yes, execute the password setup step.

If the irrigation device receives the password modification instruction sent by the background controller 202, the preset power-on password needs to be modified, and at this time, the password setting step is executed, that is, step 3002 to step 3003, and the specific process may refer to the above description of step 3002 and step 3003, which is not described herein again. If the password modification instruction sent by the background controller 202 is not received at this time, it indicates that the preset boot password does not need to be modified at this time. The background controller 202 may send a task instruction to the irrigation device according to actual needs, so that the irrigation device executes a corresponding irrigation task, and then is shut down, where a specific process is as shown in fig. 11.

As mentioned above, in the embodiment of the present invention, the power-on control device is arranged as an intermediary between the background controller and the controlled device, and the power-on control device is provided with the dedicated communication module, and after the background controller wakes up the power-on control device, the power-on control device can start the controlled device by sending the power-on password to the controlled device through the dedicated communication module, because the power-on control device sends the power-on password through the dedicated communication module, the 4G communication module on the controlled device can be in a closed state when being powered off, and does not need to be in a high-power consumption wakenable state, thereby reducing the power consumption of the controlled device and ensuring the endurance time of the controlled device; secondly, because the special communication module is only used for sending or broadcasting the starting-up password, the cost required by the special communication module is lower, the real-time control of the controlled equipment can be realized under the condition of lower cost, and the problem that the prior art needs higher cost for simultaneously ensuring the endurance of the equipment and the real-time property of the equipment control is solved.

Example two

The present embodiment also provides a terminal device, as shown in fig. 12, a terminal device 40, which includes a processor 400 and a memory 401;

the memory 401 is used to store the computer program 402 and to transfer the computer program 402 to the processor;

the processor 400 is configured to execute the steps of one of the embodiments of the power-on control method described above according to instructions in the computer program 402.

Illustratively, the computer program 402 may be divided into one or more modules/units, which are stored in the memory 401 and executed by the processor 400 to accomplish the present application. One or more modules/units may be a series of computer program instruction segments capable of performing specific functions, which are used to describe the execution of the computer program 402 in the terminal device 40.

The terminal device 40 may be a desktop computer, a notebook, a palm computer, a cloud server, or other computing devices. Terminal device 40 may include, but is not limited to, a processor 400, a memory 401. Those skilled in the art will appreciate that fig. 12 is merely an example of a terminal device 40 and does not constitute a limitation of terminal device 40 and may include more or fewer components than shown, or some components may be combined, or different components, e.g., terminal device 40 may also include input-output devices, network access devices, buses, etc.

The Processor 400 may be a Central Processing Unit (CPU), other general purpose Processor, a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), an off-the-shelf Programmable Gate Array (FPGA) or other Programmable logic device, discrete Gate or transistor logic, discrete hardware components, etc. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like.

The storage 401 may be an internal storage unit of the terminal device 40, such as a hard disk or a memory of the terminal device 40. The memory 401 may also be an external storage terminal device of the terminal device 40, such as a plug-in hard disk provided on the terminal device 40, a Smart Media Card (SMC), a Secure Digital (SD) Card, a Flash memory Card (Flash Card), and the like. Further, the memory 401 may also include both an internal storage unit of the terminal device 40 and an external storage device. The memory 401 is used to store computer programs and other programs and data required by the terminal device 40. The memory 401 may also be used to temporarily store data that has been output or is to be output.

It is clear to those skilled in the art that, for convenience and brevity of description, the specific working processes of the above-described systems, apparatuses and units may refer to the corresponding processes in the foregoing method embodiments, and are not described herein again.

In the several embodiments provided in the present application, it should be understood that the disclosed system, apparatus and method may be implemented in other ways. For example, the above-described apparatus embodiments are merely illustrative, and for example, a division of a unit is merely a logical division, and an actual implementation may have another division, for example, a plurality of units or components may be combined or integrated into another system, or some features may be omitted, or not executed. In addition, the shown or discussed mutual coupling or direct coupling or communication connection may be an indirect coupling or communication connection through some interfaces, devices or units, and may be in an electrical, mechanical or other form.

The units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, may be located in one position, or may be distributed on a plurality of network units. Some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment.

In addition, functional units in the embodiments of the present invention may be integrated into one processing unit, or each unit may exist alone physically, or two or more units are integrated into one unit. The integrated unit may be implemented in the form of hardware, or may also be implemented in the form of a software functional unit.

The integrated unit, if implemented in the form of a software functional unit and sold or used as a separate product, may be stored in a computer readable storage medium. Based on such understanding, the technical solution of the present invention may be embodied in the form of a software product, which is stored in a storage medium and includes instructions for causing a computer device (which may be a personal computer, a server, or a network device) to execute all or part of the steps of the method according to the embodiments of the present invention. And the aforementioned storage medium includes: a U disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk or an optical disk, and other various media capable of storing computer programs.

EXAMPLE III

Embodiments of the present invention further provide a storage medium containing computer-executable instructions, which when executed by a computer processor, are configured to perform a boot control method, the method including the steps of:

the power-on control equipment receives the wake-up signal sent by the background controller, and the cellular communication module of the power-on control equipment is in a wakenable state.

The power-on control equipment communicates with the background controller through the cellular communication module to receive the power-on password sent by the background controller.

The power-on control equipment sends the power-on password through the special communication module so that the corresponding controlled equipment can be started based on the power-on password after receiving the power-on password, wherein the special communication module is specially used for transmitting the power-on password.

It should be noted that the foregoing is only a preferred embodiment of the present invention and the technical principles applied. Those skilled in the art will appreciate that the embodiments of the present invention are not limited to the specific embodiments described herein, and that various obvious changes, adaptations, and substitutions are possible, without departing from the scope of the embodiments of the present invention. Therefore, although the embodiments of the present invention have been described in more detail through the above embodiments, the embodiments of the present invention are not limited to the above embodiments, and many other equivalent embodiments may be included without departing from the concept of the embodiments of the present invention, and the scope of the embodiments of the present invention is determined by the scope of the appended claims.

Claims (17)

1. A startup control method is characterized by comprising the following steps:

the method comprises the steps that a power-on control device receives a wake-up signal sent by a background controller, and a cellular communication module of the power-on control device is in a wake-up state;

the power-on control equipment is communicated with the background controller through the cellular communication module so as to receive the power-on password sent by the background controller;

the power-on control equipment sends the power-on password through a special communication module so that the corresponding controlled equipment can be started based on the power-on password after receiving the power-on password, wherein the special communication module is specially used for transmitting the power-on password, the controlled equipment receives the power-on password through a special receiving circuit, and the special receiving circuit is in a wakenable state.

2. The power-on control method according to claim 1, wherein the power-on control device is at least one of a plurality of controlled devices.

3. The power-on control method according to claim 2, wherein the controlled device to be the power-on control device is determined by:

the controlled devices upload own device information to the background controller;

and the background controller determines the controlled equipment used as the power-on control equipment according to the equipment information of the controlled equipment.

4. The power-on control method according to claim 3, wherein the device information includes one or more of the following: the power of the controlled device, the location of the controlled device, and the operating time of the controlled device.

5. The power-on control method according to claim 4, wherein the determining, by the background controller, the controlled device to be the power-on control device according to the device information of the controlled device includes:

and the background controller selects at least one controlled device with the electric quantity larger than a preset electric quantity value and the position in a preset area as the power-on control device according to the electric quantity of the controlled device and the position of the controlled device.

6. The power-on control method according to claim 2, further comprising:

when the controlled equipment serving as the power-on control equipment meets a preset condition, sending switching request information to the background controller;

and the background controller redetermines the first controlled equipment serving as the power-on control equipment according to the switching request information, and controls the controlled equipment serving as the power-on control equipment to be powered off and the cellular communication module of the first controlled equipment to be in a wakenable state.

7. A power-on control method according to any one of claims 1 to 6, wherein said enabling the corresponding controlled device to perform power-on based on the power-on password after receiving the power-on password comprises:

and after receiving the starting-up password, the corresponding controlled equipment compares the starting-up password with a preset starting-up password, and if the comparison result is consistent, starting up is carried out.

8. The method according to claim 7, wherein if the comparison result is consistent, performing boot-up includes:

and if the comparison result is consistent, the corresponding controlled equipment stops comparing the starting-up password with the preset starting-up password and starts up.

9. The power-on control method according to claim 8, further comprising, after the power-on, the steps of:

and the corresponding controlled equipment receives a shutdown signal sent by the background controller, analyzes a currently received first power-on password, compares the first power-on password with the preset power-on password, keeps the startup if the comparison result is consistent, and shuts down if the comparison result is inconsistent.

10. The power-on control method according to claim 7, before the power-on control device receives the wake-up signal sent by the background controller, further comprising:

the controlled equipment is started, and password setting steps are executed, wherein the password setting steps specifically comprise:

receiving a second power-on password sent by the background controller, and setting the preset power-on password as the second power-on password;

and the controlled equipment receives a shutdown signal sent by the background controller and shuts down the equipment according to the shutdown signal.

11. The power-on control method according to claim 10, wherein after the controlled device is powered on, before the password setting step is performed, the method further comprises:

the controlled equipment judges whether the preset starting-up password is set by the controlled equipment;

if the preset power-on password is set, the controlled equipment uploads the preset power-on password to the background controller and judges whether a password modification instruction sent by the background controller is received;

if yes, the password setting step is executed.

12. The equipment control system is characterized by comprising a power-on control device, a background controller and controlled equipment, wherein the power-on control device comprises a cellular communication module and a special communication module;

the power-on control equipment is used for receiving a wake-up signal sent by a background controller, communicating with the background controller through a cellular communication module to receive a power-on password sent by the background controller, and sending the power-on password through a special communication module; wherein, the cellular communication module of the power-on control device is in a wakenable state, and the special communication module is specially used for transmitting the power-on password;

the background controller is used for sending the wake-up signal and the power-on password to the power-on control equipment;

the controlled equipment is used for receiving the starting-up password and starting up the controlled equipment based on the starting-up password; and the controlled equipment receives the power-on password through a special receiving circuit, and the special receiving circuit is in a wakenable state.

13. The device control system of claim 12, wherein the power-on control device further comprises a first controller module;

the cellular communication module is connected with the first controller module, and is configured to receive the wake-up signal and the power-on password, send a controller wake-up signal to the first controller module according to the wake-up signal, and send the power-on password to the first controller module;

the first controller module is connected with the special communication module and used for establishing communication with the background controller through the cellular communication module when the wake-up signal is received; and is used for controlling the special communication module to send the starting password;

the special communication module is used for sending the starting password.

14. The device control system according to claim 13, wherein the power-on control device is configured as a power-on controller, and the power-on controller is configured to control power-on of the controlled device.

15. The device control system according to claim 13, wherein the power-on control device is at least one of a plurality of the controlled devices.

16. A terminal device, characterized in that the terminal device comprises a processor and a memory;

the memory is used for storing a computer program and transmitting the computer program to the processor;

the processor is configured to execute a power-on control method according to any one of claims 1-11 according to instructions in the computer program.

17. A storage medium storing computer-executable instructions for performing a power-on control method as claimed in any one of claims 1-11 when executed by a computer processor.

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