Power-on control method, system and device, electronic equipment, storage medium and product

By enabling remote monitoring of the device's mechanism in advance through the device management platform and shutting it down at the appropriate time, the issues of high power consumption and long waiting time of the ONVIF mechanism are resolved, improving the user experience and optimizing the utilization of device resources.

CN122308581APending Publication Date: 2026-06-30SHANDONG SENTER ELECTRONICS

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
SHANDONG SENTER ELECTRONICS
Filing Date
2024-12-25
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

The high power consumption of ONVIF mechanisms in existing remote monitoring equipment leads to rapid battery drain, and users experience excessively long waiting times for the mechanism to power on and initialize, impacting user experience.

Method used

The device management platform responds to user operations by sending the activation command for the movement in advance and displaying the operation page, reducing user waiting time, and shutting down the movement at the appropriate time to optimize power consumption.

Benefits of technology

It achieves a balance between reducing user waiting time and device power consumption, improving user experience and optimizing resource utilization.

✦ Generated by Eureka AI based on patent content.

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Abstract

This application provides a power-on control method, system, device, electronic device, storage medium, and product. The method includes: for any device, in response to a user's first operation on the device icon and / or the device icon of any corresponding mechanism of the device, sending a mechanism activation command to the device, wherein the mechanism activation command instructs the activation of at least a portion of the mechanisms in the device, including the mechanism corresponding to the first operation; after the first operation, displaying an operation page corresponding to any of the at least a portion of the mechanisms, the operation page including a shooting button for controlling the mechanism to take a picture. By activating the mechanism in advance, the user's waiting time during operation can be reduced, improving the user experience, and balancing device power consumption, achieving a good balance between waiting time and device power consumption.
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Description

Technical Field

[0001] This application relates to the field of online monitoring of power transmission lines, and in particular to a power-on control method, system, device, electronic equipment, storage medium, and product. Background Technology

[0002] In remote monitoring equipment, lens solutions typically employ several types of modules, including MIPI (Mobile Industry Processor Interface), UVC (USB Video Class), and ONVIF (Open Network Video Interface Forum). Compared to MIPI and UVC lenses, ONVIF modules offer a universal interface compatible with various ONVIF standard vendors' equipment, meeting the needs of diverse and complex monitoring scenarios and providing a more comprehensive monitoring solution.

[0003] However, the ONVIF sensor has relatively high power consumption. If the sensor is kept powered for a long time, the power of the remote monitoring device will be consumed too quickly, and the monitoring device may shut down due to low power in rainy weather.

[0004] Currently, the main approach involves the user clicking the photo or video button on the operation page corresponding to a specific device on the device management platform. The device management platform then sends a command to the monitoring device to activate the device. Upon receiving the command, the monitoring device powers on the device. However, the device's system detection and loading process typically takes 20-30 seconds. Adding the time for operation command initialization and parameter configuration, it usually takes 20-60 seconds to complete the entire operation command. This results in excessively long waiting times and a poor user experience. Summary of the Invention

[0005] This application provides a power-on control method, system, device, electronic device, storage medium, and product to reduce user waiting time and improve user experience.

[0006] In a first aspect, embodiments of this application provide a power-on control method applied to a device management platform. The device management platform manages multiple devices, each device including at least one mechanism. The display interface of the device management platform includes device icons corresponding to each device, and / or device icons corresponding to each mechanism of any given device. The method includes:

[0007] For any device, in response to a user’s first operation on the device icon of the device and / or the device icon of any mechanism corresponding to the device, a mechanism activation command is sent to the device, wherein the mechanism activation command is used to instruct the activation of at least a portion of the mechanisms in the device, the at least a portion of the mechanisms including the mechanism corresponding to the first operation;

[0008] After the first operation, an operation page corresponding to any one of the at least some of the movement is displayed, the operation page including a shooting button for controlling the movement to take pictures.

[0009] Optionally, the method further includes:

[0010] The second operation performed by the user on the display interface is monitored, and when the second operation meets preset conditions, at least a portion of the mechanism in the device is shut down.

[0011] Optionally, when the second operation meets preset conditions, at least a portion of the mechanism in the device is shut down, including:

[0012] The time corresponding to the first operation is taken as the current timing start time. The following timing operation is repeated until the user does not perform a third operation within a first preset time after the current start time. Then, the timing operation is stopped and at least part of the movement in the device is turned off. The third operation is used to indicate the user's operation in the operation interface of the device, or the user's operation in the operation interface of any movement corresponding to the device.

[0013] The timing operation includes:

[0014] Determine whether the user has performed a third operation within the first preset time period after the current start time;

[0015] If the user performs a third operation, the time corresponding to the third operation will be updated to the current timer start time.

[0016] Optionally, when the second operation meets preset conditions, at least a portion of the mechanism in the device is shut down, including:

[0017] In response to a user's operation on the device icon of the first device, or in response to a user's operation on the device icon of any mechanism corresponding to the first device, or in response to a user's shutdown operation on the device management platform, at least some mechanisms in the device are shut down, wherein the first device is a device other than the device mentioned above among a plurality of devices.

[0018] Optionally, the device further includes multiple non-camera-based cameras, and the display interface also includes device icons corresponding to each non-camera-based camera for any given device. The method further includes:

[0019] For any of the first non-core cameras corresponding to the device, in response to the user's operation on the device icon of the first non-core camera, a core activation command is sent to the device.

[0020] For any second non-mechanical camera corresponding to the first device, in response to the user's operation on the device icon of the second non-mechanical camera, at least a portion of the mechanism in the device is turned off.

[0021] Optionally, the method further includes:

[0022] If the second operation does not meet the preset conditions, a heartbeat signal is sent to the device every second preset time interval;

[0023] Accordingly, when the second operation meets the preset conditions, at least a portion of the mechanism in the device is shut down, including:

[0024] When the second operation meets the preset conditions, the sending of heartbeat signals to the device is stopped, so that the device will power down at least part of the mechanism if it does not receive a heartbeat signal for a preset number of consecutive times.

[0025] Optionally, the method further includes:

[0026] The number of times a user interacts with the device icon of each corresponding mechanism of the device within a preset time range is counted.

[0027] The probability of each mechanism being operated is determined based on the number of operations corresponding to each mechanism of the device; the number of operations is positively correlated with the probability of being operated.

[0028] Accordingly, a mechanism activation command is sent to the device, including:

[0029] Based on the probability of operation of each mechanism in the device, at least one mechanism to be opened is selected from a plurality of first mechanisms. The first mechanism is used to indicate the mechanism other than the mechanism corresponding to the first operation in the mechanism of the device.

[0030] Send an instruction to open the mechanism to the device, wherein the at least part of the mechanism also includes each mechanism to be opened.

[0031] Secondly, embodiments of this application provide a power-on control method, applied to any device managed by a device management platform, wherein the device includes at least one mechanism, and the display interface of the device management platform includes device icons corresponding to each device, and / or device icons corresponding to each mechanism of any device, the method comprising:

[0032] The device receives a device activation command sent by the device management platform. The device activation command is used to instruct the activation of at least some of the devices in the device. The device activation command is sent by the device management platform in response to a first operation by the user on the device icon of the device and / or the device icon of any device corresponding to the device. After the first operation, the platform displays an operation page corresponding to any of the at least some devices. The operation page includes a shooting button for controlling the device to take pictures. The at least some devices include the device corresponding to the first operation.

[0033] For any of the at least some of the camera mechanisms, obtain the shooting instruction sent by the device management platform for the camera mechanism;

[0034] The camera mechanism is controlled to take a picture according to the shooting command, the shooting result is obtained, and the shooting result is sent to the device management platform.

[0035] Optionally, the method further includes:

[0036] The device receives a heartbeat signal from the device management platform every second preset time interval. The heartbeat signal is sent by the device management platform when the second operation of the user in the display interface does not meet preset conditions.

[0037] If no heartbeat signal is received for a preset number of consecutive times, power is applied to at least part of the mechanism.

[0038] Thirdly, embodiments of this application provide a power-on control system, including:

[0039] Multiple devices, any one of which is used to perform the method according to any one of claims 8-9;

[0040] An equipment management platform, wherein the equipment management platform is used to perform the method according to any one of claims 1-7.

[0041] Fourthly, embodiments of this application provide a power-on control device applied to an equipment management platform. The equipment management platform manages multiple devices, each device including at least one mechanism. The display interface of the equipment management platform includes device icons corresponding to each device, and / or device icons corresponding to each mechanism of any given device. The device includes:

[0042] A sending module is configured to send an open mechanism instruction to any device in response to a first operation by a user on the device icon of the device and / or the device icon of any mechanism corresponding to the device, wherein the open mechanism instruction is used to instruct the opening of at least a portion of the mechanisms in the device, the at least a portion of the mechanisms including the mechanism corresponding to the first operation;

[0043] The display module is used to display an operation page corresponding to any one of the at least some of the movement after the first operation. The operation page includes a shooting button for controlling the movement to take pictures.

[0044] Fifthly, embodiments of this application provide a power-on control device, applied to any device managed by a device management platform. The device includes at least one mechanism, and the display interface of the device management platform includes device icons corresponding to each device, and / or device icons corresponding to each mechanism of any given device. The device includes:

[0045] A receiving module is configured to receive a device activation command sent by the device management platform, wherein the device activation command is used to instruct the activation of at least some of the devices in the device, the device activation command is sent by the device management platform in response to a first operation by the user on the device icon of the device and / or the device icon of any device corresponding to the device, and after the first operation, an operation page corresponding to any of the at least some devices is displayed, the operation page includes a shooting button for controlling the device to take pictures, and the at least some devices include the device corresponding to the first operation;

[0046] The acquisition module is used to acquire, for any one of the at least some of the movement mechanisms, a shooting instruction sent by the device management platform for the movement mechanism;

[0047] The control module is used to control the camera mechanism to take pictures according to the shooting instructions, obtain the shooting results, and send the shooting results to the device management platform.

[0048] Sixthly, embodiments of this application provide an electronic device, including: a processor, and a memory communicatively connected to the processor;

[0049] The memory stores computer-executed instructions;

[0050] The processor executes computer execution instructions stored in the memory to implement the method described in any of the above aspects.

[0051] In a seventh aspect, embodiments of this application provide a computer-readable storage medium storing computer-executable instructions, which, when executed by a processor, are used to implement the method described in any of the above aspects.

[0052] Eighthly, embodiments of this application provide a computer program product, including a computer program that, when executed by a processor, implements the method described in any of the above aspects.

[0053] The power-on control method, system, device, electronic device, storage medium, and product provided in this application embodiment include: for any device, in response to a user's first operation on the device icon of the device and / or the device icon of any corresponding mechanism of the device, sending a mechanism activation command to the device, wherein the mechanism activation command is used to instruct the activation of at least a portion of the mechanisms in the device, the at least a portion of the mechanisms including the mechanism corresponding to the first operation; after the first operation, displaying an operation page corresponding to any of the at least a portion of the mechanisms, the operation page including a shooting button for controlling the mechanism to take pictures. By activating the mechanism in advance, the user's waiting time during operation can be reduced, the user experience can be improved, and the power consumption of the device can be taken into account, achieving a good balance between waiting time and device power consumption. Attached Figure Description

[0054] The accompanying drawings, which are incorporated in and form part of this specification, illustrate embodiments consistent with this application and, together with the description, serve to explain the principles of this application.

[0055] Figure 1 An application scenario diagram provided for an embodiment of this application;

[0056] Figure 2 A flowchart illustrating a power-on control method provided in an embodiment of this application;

[0057] Figure 3 A schematic diagram illustrating the power-on timing of a movement, provided as an embodiment of this application;

[0058] Figure 4 A schematic diagram illustrating another power-on timing of the movement as provided in an embodiment of this application;

[0059] Figure 5 A flowchart illustrating another power-on control method provided in an embodiment of this application;

[0060] Figure 6 A flowchart illustrating yet another power-on control method provided in an embodiment of this application;

[0061] Figure 7 A schematic diagram of the structure of a power-on control device provided in this application;

[0062] Figure 8 A schematic diagram of another power-on control device provided in this application;

[0063] Figure 9 A schematic diagram of the structure of the electronic device provided in this application.

[0064] The accompanying drawings illustrate specific embodiments of this application, which will be described in more detail below. These drawings and descriptions are not intended to limit the scope of the concept in any way, but rather to illustrate the concept of this application to those skilled in the art through reference to particular embodiments. Detailed Implementation

[0065] Exemplary embodiments will now be described in detail, examples of which are illustrated in the accompanying drawings. When the following description relates to the drawings, unless otherwise indicated, the same numbers in different drawings denote the same or similar elements. The embodiments described in the following exemplary embodiments do not represent all embodiments consistent with this application. Rather, they are merely examples of apparatuses and methods consistent with some aspects of this application as detailed in the appended claims.

[0066] In remote monitoring equipment, lens solutions typically include MIPI, UVC, and ONVIF modules. Compared to MIPI and UVC lenses, ONVIF modules offer a universal interface compatible with various ONVIF standard manufacturers' equipment, meeting the needs of diverse and complex monitoring scenarios and providing a more comprehensive monitoring solution.

[0067] However, the ONVIF sensor has relatively high power consumption. Remote monitoring equipment generally uses batteries for power storage and is powered by solar panels. If the sensor is kept powered for a long time, the power consumption of the remote monitoring equipment will be too fast, and it is easy for the monitoring equipment to shut down due to low power in rainy weather.

[0068] Currently, the main approach involves the user clicking the photo or video button on the operation page corresponding to a specific device on the device management platform. The device management platform then sends a command to the monitoring device to activate the device. Upon receiving the command, the monitoring device powers on the device. However, the device's system detection and loading process typically takes 20-30 seconds. Adding the time for operation command initialization and parameter configuration, it usually takes 20-60 seconds to complete the entire operation command. This results in excessively long waiting times and a poor user experience.

[0069] In view of this, this application provides a power-on control method. For any device, in response to a user's first operation on the device icon and / or the device icon of any corresponding mechanism, a mechanism activation command is sent to the device. The mechanism activation command instructs at least some mechanisms in the device to be activated. After the first operation, an operation page corresponding to any of the at least some mechanisms is displayed. The operation page includes a shooting button for controlling the mechanism to take pictures. In this way, by activating the mechanism in advance, the user's waiting time during operation can be reduced, the user experience can be improved, and the power consumption of the device can be taken into account, achieving a good balance between waiting time and device power consumption.

[0070] Figure 1 An application scenario diagram provided for an embodiment of this application, such as... Figure 1 As shown, the system includes a device management platform and multiple devices, including device 1, device 2, ..., device n. The device management platform manages the multiple devices. Each device includes at least one camera module. The display interface of the device management platform includes device icons corresponding to each device and / or device icons corresponding to each camera module of each device. The display interface includes a first area and a second area. The device icons of each device and the device icons of each camera module are located in the first area of ​​the display interface. When a user clicks on the device icon of any device, the operation page corresponding to that device is displayed in the second area of ​​the display interface. When a user clicks on the device icon of any camera module, the operation interface corresponding to that camera module is displayed in the second area of ​​the display interface. The operation interface corresponding to the camera module includes a shooting button to control the camera module to take pictures.

[0071] For example, device 1 includes mechanism 1, mechanism 2, and mechanism 3. When a user performs a first operation on the device icon of device 1 on the device management platform, the device management platform, in response to the user's first operation, sends an activation command to device 1, instructing mechanism 1 and mechanism 2 to be activated. Upon receiving the activation command, device 1 activates mechanism 1 and mechanism 2. After the user performs the first operation on the device icon of device 1, they perform a first operation on the device icon of mechanism 1. In response to this first operation, the device management platform displays the operation page corresponding to mechanism 1 in a second area. When the user clicks the shutter button on the operation page corresponding to mechanism 1, the device management platform sends a shutter command to device 1. Upon receiving the shutter command, device 1 controls mechanism 1 to take a picture, obtains the shooting result, and sends the shooting result to the device management platform, which then displays the shooting result.

[0072] The technical solution of this application and how the technical solution of this application solves the above-mentioned technical problems are described in detail below with specific embodiments. These specific embodiments can be combined with each other, and the same or similar concepts or processes may not be described again in some embodiments. The embodiments of this application will now be described with reference to the accompanying drawings.

[0073] Figure 2 This application provides a flowchart illustrating a power-on control method. The method is applied to a device management platform that manages multiple devices. Each device includes at least one mechanism. The display interface of the device management platform includes device icons corresponding to each device, and / or device icons corresponding to each mechanism of any given device, such as... Figure 2 As shown in the embodiment of this application, a power-on control method may include:

[0074] Step 201: For any device, in response to a user's first operation on the device icon of the device and / or the device icon of any mechanism corresponding to the device, send an activation mechanism instruction to the device, wherein the activation mechanism instruction is used to instruct the activation of at least a portion of the mechanisms in the device, the at least a portion of the mechanisms including the mechanism corresponding to the first operation.

[0075] The display interface includes a first area and a second area. The device icons of each device and the device icons of each mechanism are located in the first area of ​​the display interface. When the user clicks on the device icon of any device, the corresponding operation page of that device is displayed in the second area of ​​the display interface. When the user clicks on the device icon of any mechanism, the corresponding operation interface of that mechanism is displayed in the second area of ​​the display interface. The operation interface of the mechanism includes a shooting button to control the mechanism to take pictures.

[0076] The first operation can trigger the device management platform to send an instruction to the device to turn on the mechanism. This application does not limit this operation. For example, it can be a single click, double click, etc.

[0077] All the devices mentioned in this article are remote monitoring devices.

[0078] Specifically, for any device, when a user performs a first operation on the device icon of the device, or performs a first operation on the device icon of any corresponding mechanism of the device, the device management platform sends a mechanism activation command to the device. The mechanism activation command can be used to instruct the activation of all mechanisms in the device, or it can be used to instruct the activation of some mechanisms in the device. Some mechanisms can be predetermined or determined based on the current situation. This application does not limit this.

[0079] When a user performs the first operation on the device icon corresponding to a certain movement of the device, some movements will necessarily contain that movement.

[0080] Optionally, the power-on control method provided in this application also includes:

[0081] The number of times a user interacts with the device icon of each corresponding mechanism of the device within a preset time range is counted.

[0082] The probability of each mechanism being operated is determined based on the number of operations corresponding to each mechanism of the device; the number of operations is positively correlated with the probability of being operated.

[0083] Accordingly, a mechanism activation command is sent to the device, including:

[0084] Based on the probability of operation of each mechanism in the device, at least one mechanism to be opened is selected from a plurality of first mechanisms. The first mechanism is used to indicate the mechanism other than the mechanism corresponding to the first operation in the mechanism of the device.

[0085] Send an instruction to open the mechanism to the device, wherein the at least part of the mechanism also includes each mechanism to be opened.

[0086] Specifically, before sending the activation command to the device, the device management platform can count the number of times the user operates the device icon of each corresponding mechanism within a preset time range. The preset time range can be a period between a start time and an end time, and can be flexibly set according to actual needs. This application does not limit this; for example, the end time corresponding to the preset time range can be the current time, and the difference between the end time and the start time can be a preset value. The number of times the device icon of any mechanism is operated is the number of times the device icon of that mechanism is first operated by the user.

[0087] This application does not limit the process by which the device management platform determines the probability of operation of each mechanism corresponding to the device based on the number of operations corresponding to each mechanism. In one optional implementation, the device management platform can add up the number of operations corresponding to each mechanism to obtain the total number of operations. For any mechanism, the number of operations corresponding to that mechanism is divided by the total number of operations to obtain the probability of operation of that mechanism.

[0088] This application does not limit the process by which the equipment management platform selects at least one mechanism to be opened from multiple first mechanisms based on the probability of operation of each mechanism in the equipment. In one optional implementation, the mechanisms can be sorted from largest to smallest according to the probability of operation to obtain a mechanism sequence, and the first preset number of mechanisms in the mechanism sequence are determined to be mechanisms to be opened.

[0089] The device management platform sends an instruction to the device to open the mechanism, wherein at least some of the mechanisms include each mechanism to be opened.

[0090] In this way, by analyzing users' operating habits, the system can intelligently predict which movements are more likely to be used, thus activating these movements in advance and further saving energy. Furthermore, it can dynamically adjust the movement activation strategy based on actual user usage, making it more aligned with user habits.

[0091] Step 202: After the first operation, display the operation page corresponding to any one of the at least some of the movement mechanisms, the operation page including a shooting button for controlling the movement mechanism to take pictures.

[0092] The shooting button can be either a photo button or a video button.

[0093] In one optional implementation, after the user performs a first operation on the device icon of the device and then performs a first operation on the device icon of a certain mechanism of the device, the operation page corresponding to the mechanism is displayed in the second area. The operation page includes a shooting button for controlling the mechanism to take pictures. When the user clicks the shooting button on the operation page, the device management platform sends a shooting command to the device. After receiving the shooting command, the device controls the mechanism to take pictures, obtains the shooting results, and sends the shooting results to the device management platform. The device management platform then displays the shooting results.

[0094] In another alternative implementation, after the user performs a first operation on the device icon of a certain mechanism of the device, the corresponding operation page of the mechanism is displayed in the second area. When the user clicks the shooting button on the operation page, the device management platform sends a shooting command to the device. After receiving the shooting command, the device controls the mechanism to take a picture, obtains the shooting result, and sends the shooting result to the device management platform, which then displays the shooting result.

[0095] The following comparison of the time taken by existing technologies and this application is based on the first operation being a click operation.

[0096] In the existing technology, when a user wants to control the camera to take a picture, they must first click the corresponding device icon, then move the mouse to find the corresponding camera icon and click it, and then find the shooting button on the camera's operation page. They may also need to view the pictures and videos uploaded by the device. The time from when the user clicks the device icon to when they click the shooting button is called the operation interval, denoted as T1.

[0097] In existing technology, after the user clicks the shutter button, the device management platform sends a command to the device to turn on a certain mechanism and control the mechanism to take a picture. After receiving the command, the device powers on the mechanism, the mechanism turns on, and takes a picture. The time interval from when the user clicks the shutter button to when the mechanism actually takes a picture is set as T2.

[0098] Figure 3 A schematic diagram illustrating the power-on timing of a movement, as provided in an embodiment of this application, is shown below. Figure 3 As shown in the figure, in the prior art, the green block in the figure represents the power-on time of the mechanism, that is, when the user clicks the shooting button, the device management platform will control the mechanism to power on.

[0099] In this application, when a user clicks the device icon of the device or the device icon of any corresponding mechanism on the device management platform, the device management platform sends a mechanism activation command to the device. After receiving the mechanism activation command, the device activates part or all of the mechanisms in the device. After the user clicks the shooting button, the device management platform sends a shooting command to the device. After receiving the shooting command, the device takes a picture.

[0100] Figure 4 A schematic diagram illustrating another mechanism power-on timing provided in this application embodiment, as shown below. Figure 4 As shown in the figure, the green block in this application represents the power-on time of the mechanism, that is, when the user clicks the device icon of the device, or clicks the device icon of any mechanism corresponding to the device, the device management platform will control the mechanism to power on.

[0101] Assuming the user perceives the shooting time as T, in the prior art: T = T2. In this application, when T2 > T1, T = T2 - T1; when T2 ≤ T1, T = 0.

[0102] Note: The above excludes network latency and software processing time.

[0103] In this way, after the user clicks the device icon of the device, or clicks the device icon of any corresponding mechanism of the device, there is an operation interval. This application sets the power-on time of the mechanism to the moment when the user clicks the device icon of the device, or clicks the device icon of any corresponding mechanism of the device. The operation interval can be used to reduce the waiting time for the mechanism to power on when the user clicks to take a picture.

[0104] The power-on control method provided in this application embodiment can, for any device, in response to a user's first operation on the device icon of the device and / or the device icon of any corresponding mechanism of the device, send a mechanism activation command to the device. The mechanism activation command instructs the activation of at least a portion of the mechanisms in the device, including the mechanism corresponding to the first operation. After the first operation, an operation page corresponding to any of the at least a portion of the mechanisms is displayed. The operation page includes a shooting button for controlling the mechanism to take pictures. By activating the mechanism in advance, the user's waiting time during operation can be reduced, improving the user experience. This method also balances device power consumption, achieving a good balance between waiting time and device power consumption.

[0105] Optionally, the power-on control method provided in this application also includes:

[0106] The second operation performed by the user on the display interface is monitored, and when the second operation meets preset conditions, at least a portion of the mechanism in the device is shut down.

[0107] Specifically, the device management platform monitors the user's second operation on the display interface, and shuts down at least part of the device's mechanism when the first operation meets preset conditions.

[0108] In this way, by shutting down the mechanism at the appropriate time, unnecessary resource consumption can be reduced and the resource utilization of the equipment can be optimized.

[0109] Optionally, when the second operation meets preset conditions, at least a portion of the mechanism in the device is shut down, including:

[0110] The time corresponding to the first operation is taken as the current timing start time. The following timing operation is repeated until the user does not perform a third operation within a first preset time after the current start time. Then, the timing operation is stopped and at least part of the movement in the device is turned off. The third operation is used to indicate the user's operation in the operation interface of the device, or the user's operation in the operation interface of any movement corresponding to the device.

[0111] The timing operation includes:

[0112] Determine whether the user has performed a third operation within the first preset time period after the current start time;

[0113] If the user performs a third operation, the time corresponding to the third operation will be updated to the current timer start time.

[0114] Specifically, within a first preset time period after the first operation, if the user does not perform a third operation, at least a portion of the mechanism in the device is turned off. If the user performs a third operation, it is determined whether the user performs a new third operation within the first preset time period after the third operation. If no new third operation is performed, at least a portion of the mechanism in the device is turned off. If a new third operation is performed, it is determined whether the user performs a new third operation within the first preset time period after the new third operation, until no new third operation is performed, at least a portion of the mechanism in the device is turned off.

[0115] In this way, the camera module can be powered down when the user does not operate the device for a long time to reduce the device's power consumption. However, when the user operates the device, the camera module will remain powered on even if the shutter button is not pressed for a long time, ready to be used by the user to take pictures.

[0116] Optionally, when the second operation meets preset conditions, at least a portion of the mechanism in the device is shut down, including:

[0117] In response to a user's operation on the device icon of the first device, or in response to a user's operation on the device icon of any mechanism corresponding to the first device, or in response to a user's shutdown operation on the device management platform, at least some mechanisms in the device are shut down, wherein the first device is a device other than the device mentioned above among a plurality of devices.

[0118] Specifically, when a user operates on the device icon of the first device, or on the device icon of any of the corresponding mechanisms of the first device, or performs a shutdown operation on the device management platform, the device management platform responds to the user's operation by shutting down at least a portion of the mechanisms within the device. Furthermore, this application does not limit the user's operation on the device icon of the first device, or on the device icon of the mechanism; for example, the operation can be a single click, a double click, etc.

[0119] In this way, the device is powered down when the user selects another device or leaves the device management platform, further reducing device power consumption.

[0120] Optionally, the device further includes multiple non-camera-based cameras, and the display interface also includes device icons corresponding to each non-camera-based camera for any given device. The method further includes:

[0121] For any of the first non-core cameras corresponding to the device, in response to the user's operation on the device icon of the first non-core camera, a core activation command is sent to the device.

[0122] For any second non-mechanical camera corresponding to the first device, in response to the user's operation on the device icon of the second non-mechanical camera, at least a portion of the mechanism in the device is turned off.

[0123] Specifically, when a user operates the device icon of any of the first non-core cameras corresponding to the device, the device management platform sends a core activation command to the device, and when the user operates the device icon of any of the second non-core cameras corresponding to the first device, at least part of the core mechanism in the device is deactivated.

[0124] In this way, when a user interacts with the icon of a non-camera module on this device, there's a high probability they'll also interact with the camera module itself. Therefore, sending a command to activate the camera module powers it on, preparing it for user captures, thus improving the user experience. When a user interacts with the icon of a non-camera module on another device, it can be determined that the user has left the current device, allowing at least part of the camera module in the current device to be turned off, reducing power consumption.

[0125] Optionally, the method further includes:

[0126] If the second operation does not meet the preset conditions, a heartbeat signal is sent to the device every second preset time interval;

[0127] Accordingly, when the second operation meets the preset conditions, at least a portion of the mechanism in the device is shut down, including:

[0128] When the second operation meets the preset conditions, the sending of heartbeat signals to the device is stopped, so that the device will power down at least part of the mechanism if it does not receive a heartbeat signal for a preset number of consecutive times.

[0129] Specifically, when the second operation fails to meet the preset conditions, the device management platform sends a heartbeat signal to the device every second preset time interval to keep the mechanism powered on. When the second operation meets the preset conditions, the platform stops sending heartbeat signals to the device. If the device fails to receive a heartbeat signal for a preset number of consecutive times, it powers down at least part of the mechanism. For example, the preset number of times can be 3, meaning that if the device fails to receive a heartbeat signal for 3 consecutive times, it will power down at least part of the mechanism.

[0130] In this way, intelligent power-off management of the mechanism is achieved through the heartbeat signal mechanism, which reduces energy consumption, improves equipment reliability and user experience, and optimizes resource utilization and system security.

[0131] Figure 5 A flowchart illustrating another power-on control method provided in this application embodiment is shown below. Figure 5 As shown:

[0132] 1. When a user selects a device on the platform, the platform will send a command to the device to turn it on.

[0133] 2. Upon receiving the instruction, the device immediately powers on the control unit. This is because users can only actively execute business operation instructions if they turn on the device on the platform, and once the user turns on the device on the platform, there is a high probability that they will execute the operation instructions.

[0134] 3. When the user remains on the device interface, the platform sends a core-keeping power-on heartbeat message to the device every 15 seconds to inform the device that the user is still on the device interface and the device keeps the core-keeping power-on.

[0135] 4. The platform captures user mouse and keyboard operations (including but not limited to determining whether the user has left). If the user stays on the interface for more than 15 minutes, the platform sends a power-off command to the device, and the device powers off the mechanism.

[0136] 5. When the user selects another device, the platform sends a power-off command to the device's mechanism, and the device powers off the mechanism.

[0137] 6. If the device does not receive the power-on heartbeat message from the platform, the device will power off the mechanism.

[0138] Figure 6 This is a flowchart illustrating another power-on control method provided in an embodiment of this application. The method is applied to any device managed by a device management platform. The device includes at least one mechanism. The display interface of the device management platform includes device icons corresponding to each device, and / or device icons corresponding to each mechanism of any given device, such as... Figure 6 As shown in the embodiments of this application, another power-on control method may include:

[0139] Step 601: Receive an activation command from the device management platform, wherein the activation command is used to instruct the activation of at least some of the mechanisms in the device. The activation command is sent by the device management platform in response to a first operation by the user on the device icon of the device and / or the device icon of any of the mechanisms corresponding to the device. After the first operation, the platform displays an operation page corresponding to any of the at least some mechanisms. The operation page includes a shooting button for controlling the mechanism to take pictures. The at least some mechanisms include the mechanism corresponding to the first operation.

[0140] Step 602: For any of the at least some of the camera mechanisms, obtain the shooting instruction sent by the device management platform for the camera mechanism.

[0141] Step 603: Control the camera mechanism to take a picture according to the shooting command, obtain the shooting result, and send the shooting result to the device management platform.

[0142] Optionally, the power-on control method provided in this application also includes:

[0143] The device receives a heartbeat signal from the device management platform every second preset time interval. The heartbeat signal is sent by the device management platform when the second operation of the user in the display interface does not meet preset conditions.

[0144] If no heartbeat signal is received for a preset number of consecutive times, power is applied to at least part of the mechanism.

[0145] This embodiment provides another power-on control method, which has a similar implementation principle and technical effect, and will not be described in detail here.

[0146] This application also provides a power-on control system, including:

[0147] Multiple devices, any one of which is used to perform the method described in any of the above embodiments;

[0148] A device management platform, which is used to execute the methods described in any of the above embodiments.

[0149] Optionally, another power-on control system provided in this application embodiment includes an equipment management platform and multiple devices, wherein the equipment management platform includes: a selection determination module, a platform heartbeat communication module, a user operation determination module, and a user departure determination module; any one of the devices includes: a device heartbeat communication module and a mechanism power-on / off control module.

[0150] The functions of each module are as follows:

[0151] A. Platform - Select the judgment module. After the user selects the device icon corresponding to the device, the module sends a command to the device to notify the device to power on the mechanism.

[0152] B. Platform - Heartbeat Communication Module: Sends a heartbeat to the device every 15 seconds to inform the device that it is currently in the user-selected open state.

[0153] C. Platform - User Operation Judgment Module: Determines whether the user is using a mouse and keyboard, and whether the user is operating the platform or device.

[0154] D. Platform - User Departure Module: This module determines whether the user has selected another device or left this device.

[0155] E. Device side – Heartbeat communication module, where users process heartbeat messages from the device and platform.

[0156] F. Equipment side – Movement power-on / off control module, used to handle the power-on and power-off of the movement.

[0157] The other power-on control system provided in this embodiment has a similar implementation principle and technical effect, and will not be described in detail here.

[0158] Corresponding to the above power-on control method, this application embodiment also provides a power-on control device applied to an equipment management platform. The equipment management platform is used to manage multiple devices, each device including at least one mechanism. The display interface of the equipment management platform includes device icons corresponding to each device, and / or device icons corresponding to each mechanism of any device. Figure 7 A schematic diagram of a power-on control device provided in this application is shown below. Figure 7 As shown, this embodiment provides a power-on control device, including:

[0159] The sending module 701 is configured to send an open mechanism instruction to any device in response to a first operation by a user on the device icon of the device and / or the device icon of any mechanism corresponding to the device, wherein the open mechanism instruction is used to instruct the opening of at least a portion of the mechanisms in the device, and the at least a portion of the mechanisms includes the mechanism corresponding to the first operation.

[0160] The display module 702 is used to display an operation page corresponding to any one of the at least some of the movement after the first operation. The operation page includes a shooting button for controlling the movement to take pictures.

[0161] Optionally, the transmitting module 701 is also used for:

[0162] The second operation performed by the user on the display interface is monitored, and when the second operation meets preset conditions, at least a portion of the mechanism in the device is shut down.

[0163] Optionally, when the second operation satisfies a preset condition and at least a portion of the mechanism in the device is shut down, the sending module 701 is specifically used for:

[0164] The time corresponding to the first operation is taken as the current timing start time. The following timing operation is repeated until the user does not perform a third operation within a first preset time after the current start time. Then, the timing operation is stopped and at least part of the movement in the device is turned off. The third operation is used to indicate the user's operation in the operation interface of the device, or the user's operation in the operation interface of any movement corresponding to the device.

[0165] The timing operation includes:

[0166] Determine whether the user has performed a third operation within the first preset time period after the current start time;

[0167] If the user performs a third operation, the time corresponding to the third operation will be updated to the current timer start time.

[0168] Optionally, when the second operation satisfies a preset condition and at least a portion of the mechanism in the device is shut down, the sending module 701 is specifically used for:

[0169] In response to a user's operation on the device icon of the first device, or in response to a user's operation on the device icon of any mechanism corresponding to the first device, or in response to a user's shutdown operation on the device management platform, at least some mechanisms in the device are shut down, wherein the first device is a device other than the device mentioned above among a plurality of devices.

[0170] Optionally, the device further includes multiple non-mechanical cameras, and the display interface also includes device icons corresponding to each non-mechanical camera for any given device. The sending module 701 is further configured to:

[0171] For any of the first non-core cameras corresponding to the device, in response to the user's operation on the device icon of the first non-core camera, a core activation command is sent to the device.

[0172] For any second non-mechanical camera corresponding to the first device, in response to the user's operation on the device icon of the second non-mechanical camera, at least a portion of the mechanism in the device is turned off.

[0173] Optionally, the transmitting module 701 is also used for:

[0174] If the second operation does not meet the preset conditions, a heartbeat signal is sent to the device every second preset time interval;

[0175] Accordingly, when the second operation satisfies the preset conditions and at least part of the mechanism in the device is shut down, the sending module 701 is specifically used for:

[0176] When the second operation meets the preset conditions, the sending of heartbeat signals to the device is stopped, so that the device will power down at least part of the mechanism if it does not receive a heartbeat signal for a preset number of consecutive times.

[0177] Optionally, the transmitting module 701 is also used for:

[0178] The number of times a user interacts with the device icon of each corresponding mechanism of the device within a preset time range is counted.

[0179] The probability of each mechanism being operated is determined based on the number of operations corresponding to each mechanism of the device; the number of operations is positively correlated with the probability of being operated.

[0180] Accordingly, when sending the activation command to the device, the sending module 701 is specifically used for:

[0181] Based on the probability of operation of each mechanism in the device, at least one mechanism to be opened is selected from a plurality of first mechanisms. The first mechanism is used to indicate the mechanism other than the mechanism corresponding to the first operation in the mechanism of the device.

[0182] Send an instruction to open the mechanism to the device, wherein the at least part of the mechanism also includes each mechanism to be opened.

[0183] The power-on control device provided in this embodiment can execute the method provided in the above method embodiment. Its implementation principle and technical effect are similar, and will not be described in detail here.

[0184] This application embodiment also provides another power-on control device, applied to any device managed by a device management platform. The device includes at least one mechanism, and the display interface of the device management platform includes device icons corresponding to each device, and / or device icons corresponding to each mechanism of any device. Figure 8 A schematic diagram of another power-on control device provided in this application is shown below. Figure 8 As shown, the power-on control device provided in this embodiment includes:

[0185] The receiving module 801 is configured to receive a device activation command sent by the device management platform, wherein the device activation command is used to instruct the activation of at least some of the devices in the device, the device activation command is sent by the device management platform in response to a first operation by the user on the device icon of the device and / or the device icon of any device corresponding to the device, and after the first operation, displays an operation page corresponding to any of the at least some devices, the operation page including a shooting button for controlling the device to take a picture, and the at least some devices include the device corresponding to the first operation;

[0186] The acquisition module 802 is used to acquire a shooting instruction sent by the device management platform for any one of the at least some of the movement mechanisms.

[0187] The control module 803 is used to control the camera mechanism to take pictures according to the shooting command, obtain the shooting results, and send the shooting results to the device management platform.

[0188] Optionally, receiver module 801 also uses:

[0189] The device receives a heartbeat signal from the device management platform every second preset time interval. The heartbeat signal is sent by the device management platform when the second operation of the user in the display interface does not meet preset conditions.

[0190] If no heartbeat signal is received for a preset number of consecutive times, power is applied to at least part of the mechanism.

[0191] Another power-on control device provided in this embodiment can execute the method provided in the above method embodiment. Its implementation principle and technical effect are similar, and will not be described in detail here.

[0192] Figure 9 A schematic diagram of the structure of the electronic device provided in this application. Figure 9As shown, the electronic device 90 provided in this embodiment includes at least one processor 901 and a memory 902. Optionally, the device 90 further includes a communication component 903. The processor 901, memory 902, and communication component 903 are connected via a bus 904.

[0193] In a specific implementation, at least one processor 901 executes computer execution instructions stored in memory 902, causing at least one processor 901 to perform the above-described method.

[0194] The specific implementation process of processor 901 can be found in the above method embodiments, and its implementation principle and technical effect are similar. It will not be repeated here.

[0195] In the above embodiments, it should be understood that the processor can be a Central Processing Unit (CPU), or other general-purpose processors, digital signal processors (DSPs), application-specific integrated circuits (ASICs), etc. The general-purpose processor can be a microprocessor or any conventional processor. The steps of the method disclosed in this invention can be directly implemented by a hardware processor, or implemented by a combination of hardware and software modules within the processor.

[0196] The memory may include random access memory (RAM) and may also include non-volatile memory (NVM), such as at least one disk storage device.

[0197] The bus can be an Industry Standard Architecture (ISA) bus, a Peripheral Component Interconnect (PCI) bus, or an Extended Industry Standard Architecture (EISA) bus, etc. Buses can be categorized as address buses, data buses, control buses, etc. For ease of illustration, the buses shown in the accompanying drawings are not limited to a single bus or a single type of bus.

[0198] This application also provides a computer program product, including a computer program that, when executed by a processor, implements the above-described method.

[0199] This application also provides a computer-readable storage medium storing computer-executable instructions, which, when executed by a processor, implement the above-described method.

[0200] The aforementioned readable storage medium can be implemented by any type of volatile or non-volatile storage device or a combination thereof, such as static random access memory (SRAM), electrically erasable programmable read-only memory (EEPROM), erasable programmable read-only memory (EPROM), programmable read-only memory (PROM), read-only memory (ROM), magnetic storage, flash memory, magnetic disk, or optical disk. The readable storage medium can be any available medium accessible to a general-purpose or special-purpose computer.

[0201] An exemplary readable storage medium is coupled to a processor, enabling the processor to read information from and write information to the readable storage medium. Of course, the readable storage medium can also be a component of the processor. The processor and the readable storage medium can reside in an Application Specific Integrated Circuit (ASIC). Alternatively, the processor and the readable storage medium can exist as discrete components in the device.

[0202] The division of units is merely a logical functional division; in actual implementation, there may be other division methods. For example, multiple units or components may be combined or integrated into another system, or some features may be ignored or not executed. Furthermore, the coupling or direct coupling or communication connection shown or discussed may be indirect coupling or communication connection through some interfaces, devices, or units, and may be electrical, mechanical, or other forms.

[0203] The units described as separate components may or may not be physically separate. The components shown as units may or may not be physical units; that is, they may be located in one place or distributed across multiple network units. Some or all of the units can be selected to achieve the purpose of this embodiment according to actual needs.

[0204] In addition, the functional units in the various embodiments of the present invention can be integrated into one processing unit, or each unit can exist physically separately, or two or more units can be integrated into one unit.

[0205] If a function is implemented as a software functional unit and sold or used as an independent product, it can be stored in a computer-readable storage medium. Based on this understanding, the technical solution of this invention, or the part that contributes to the prior art, or a part of the technical solution, can be embodied in the form of a software product. This computer software product is stored in a storage medium and includes several instructions to cause a computer device (which may be a personal computer, server, or network device, etc.) to execute all or part of the steps of the methods of the various embodiments of this invention. The aforementioned storage medium includes various media capable of storing program code, such as USB flash drives, portable hard drives, read-only memory (ROM), random access memory (RAM), magnetic disks, or optical disks.

[0206] Those skilled in the art will understand that all or part of the steps of the above-described method embodiments can be implemented by hardware related to program instructions. The aforementioned program can be stored in a computer-readable storage medium. When executed, the program performs the steps of the above-described method embodiments; and the aforementioned storage medium includes various media capable of storing program code, such as ROM, RAM, magnetic disks, or optical disks.

[0207] Finally, it should be noted that other embodiments of the invention will readily occur to those skilled in the art upon consideration of the specification and practice of the invention disclosed herein. This invention is intended to cover any variations, uses, or adaptations of the invention that follow the general principles of the invention and include common knowledge or customary techniques in the art not disclosed herein, and is not limited to the precise structures described above and shown in the accompanying drawings, and various modifications and changes can be made without departing from its scope. The scope of the invention is limited only by the appended claims.

Claims

1. A power-on control method, characterized in that, An application is made to an equipment management platform for managing multiple devices, each device including at least one mechanism. The display interface of the equipment management platform includes device icons corresponding to each device, and / or device icons corresponding to each mechanism of any given device. The method includes: For any device, in response to a user’s first operation on the device icon of the device and / or the device icon of any mechanism corresponding to the device, a mechanism activation command is sent to the device, wherein the mechanism activation command is used to instruct the activation of at least a portion of the mechanisms in the device, the at least a portion of the mechanisms including the mechanism corresponding to the first operation; After the first operation, an operation page corresponding to any one of the at least some of the movement is displayed, the operation page including a shooting button for controlling the movement to take pictures.

2. The method according to claim 1, characterized in that, The method further includes: The second operation performed by the user on the display interface is monitored, and when the second operation meets preset conditions, at least a portion of the mechanism in the device is shut down.

3. The method according to claim 2, characterized in that, When the second operation meets preset conditions, at least a portion of the mechanism in the device is shut down, including: The time corresponding to the first operation is taken as the current timing start time. The following timing operation is repeated until the user does not perform a third operation within a first preset time after the current start time. Then, the timing operation is stopped and at least part of the movement in the device is turned off. The third operation is used to indicate the user's operation in the operation interface of the device, or the user's operation in the operation interface of any movement corresponding to the device. The timing operation includes: Determine whether the user has performed a third operation within the first preset time period after the current start time; If the user performs a third operation, the time corresponding to the third operation will be updated to the current timer start time.

4. The method according to claim 2, characterized in that, When the second operation meets preset conditions, at least a portion of the mechanism in the device is shut down, including: In response to a user's operation on the device icon of the first device, or in response to a user's operation on the device icon of any mechanism corresponding to the first device, or in response to a user's shutdown operation on the device management platform, at least some mechanisms in the device are shut down, wherein the first device is a device other than the device mentioned above among a plurality of devices.

5. The method according to claim 4, characterized in that, The device also includes multiple non-camera-based cameras, and the display interface also includes device icons corresponding to each non-camera-based camera for any given device. The method further includes: For any of the first non-core cameras corresponding to the device, in response to the user's operation on the device icon of the first non-core camera, a core activation command is sent to the device. For any second non-mechanical camera corresponding to the first device, in response to the user's operation on the device icon of the second non-mechanical camera, at least a portion of the mechanism in the device is turned off.

6. The method according to claim 2, characterized in that, The method further includes: If the second operation does not meet the preset conditions, a heartbeat signal is sent to the device every second preset time interval; Accordingly, when the second operation meets the preset conditions, at least a portion of the mechanism in the device is shut down, including: When the second operation meets the preset conditions, the sending of heartbeat signals to the device is stopped, so that the device will power down at least part of the mechanism if it does not receive a heartbeat signal for a preset number of consecutive times.

7. The method according to any one of claims 1-6, characterized in that, The method further includes: The number of times a user interacts with the device icon of each corresponding mechanism of the device within a preset time range is counted. The probability of each mechanism being operated is determined based on the number of operations corresponding to each mechanism of the device; the number of operations is positively correlated with the probability of being operated. Accordingly, a mechanism activation command is sent to the device, including: Based on the probability of operation of each mechanism in the device, at least one mechanism to be opened is selected from a plurality of first mechanisms. The first mechanism is used to indicate the mechanism other than the mechanism corresponding to the first operation in the mechanism of the device. Send an instruction to open the mechanism to the device, wherein the at least part of the mechanism also includes each mechanism to be opened.

8. A power-on control method, characterized in that, The method is applicable to any device managed by a device management platform, wherein the device includes at least one mechanism, the display interface of the device management platform includes device icons corresponding to each device, and / or device icons corresponding to each mechanism of any device, the method comprising: The device receives a device activation command sent by the device management platform. The device activation command is used to instruct the activation of at least some of the devices in the device. The device activation command is sent by the device management platform in response to a first operation by the user on the device icon of the device and / or the device icon of any device corresponding to the device. After the first operation, the platform displays an operation page corresponding to any of the at least some devices. The operation page includes a shooting button for controlling the device to take pictures. The at least some devices include the device corresponding to the first operation. For any of the at least some of the camera mechanisms, obtain the shooting instruction sent by the device management platform for the camera mechanism; The camera mechanism is controlled to take a picture according to the shooting command, the shooting result is obtained, and the shooting result is sent to the device management platform.

9. The method according to claim 8, characterized in that, The method further includes: The device receives a heartbeat signal from the device management platform every second preset time interval. The heartbeat signal is sent by the device management platform when the second operation of the user in the display interface does not meet preset conditions. If no heartbeat signal is received for a preset number of consecutive times, power is applied to at least part of the mechanism.

10. A power-on control system, characterized in that, include: Multiple devices, any one of which is used to perform the method according to any one of claims 8-9; An equipment management platform, wherein the equipment management platform is used to perform the method according to any one of claims 1-7.

11. A power-on control device, characterized in that, An application is made to an equipment management platform for managing multiple devices, each device including at least one mechanism. The display interface of the equipment management platform includes device icons corresponding to each device, and / or device icons corresponding to each mechanism of any given device. The device includes: A sending module is configured to send an open mechanism instruction to any device in response to a first operation by a user on the device icon of the device and / or the device icon of any mechanism corresponding to the device, wherein the open mechanism instruction is used to instruct the opening of at least a portion of the mechanisms in the device, the at least a portion of the mechanisms including the mechanism corresponding to the first operation; The display module is used to display an operation page corresponding to any one of the at least some of the movement after the first operation. The operation page includes a shooting button for controlling the movement to take pictures.

12. A power-on control device, characterized in that, Applied to any device managed by a device management platform, the device includes at least one mechanism, the display interface of the device management platform includes device icons corresponding to each device, and / or device icons corresponding to each mechanism of any device, the device includes: A receiving module is configured to receive a device activation command sent by the device management platform, wherein the device activation command is used to instruct the activation of at least some of the devices in the device, the device activation command is sent by the device management platform in response to a first operation by the user on the device icon of the device and / or the device icon of any device corresponding to the device, and after the first operation, an operation page corresponding to any of the at least some devices is displayed, the operation page includes a shooting button for controlling the device to take pictures, and the at least some devices include the device corresponding to the first operation; The acquisition module is used to acquire, for any one of the at least some of the movement mechanisms, a shooting instruction sent by the device management platform for the movement mechanism; The control module is used to control the camera mechanism to take pictures according to the shooting instructions, obtain the shooting results, and send the shooting results to the device management platform.

13. An electronic device, characterized in that, include: Memory, processor; The memory stores computer-executed instructions; The processor executes computer execution instructions stored in the memory, causing the processor to perform the method as described in any one of claims 1-9.

14. A computer-readable storage medium, characterized in that, The computer-readable storage medium stores computer-executable instructions, which, when executed by a processor, are used to implement the method as described in any one of claims 1-9.

15. A computer program product, characterized in that, Includes a computer program that, when executed by a processor, implements the method described in any one of claims 1-9.