CN115168754A

CN115168754A - Electronic equipment monitoring method

Info

Publication number: CN115168754A
Application number: CN202210685296.XA
Authority: CN
Inventors: 王永傑; 胡国柱; 葉思辛; 洪啟文
Original assignee: Chroma ATE Suzhou Co Ltd
Current assignee: Chroma ATE Suzhou Co Ltd
Priority date: 2022-06-17
Filing date: 2022-06-17
Publication date: 2022-10-11

Abstract

The application provides an electronic device monitoring method, which is used for monitoring a plurality of electronic devices in a cabinet, wherein the plurality of electronic devices are defined with a master electronic device and at least one slave electronic device, and the electronic device monitoring method comprises the following steps. First, the main electronic device acquires coordinate information and additional information of each electronic device. And generating a display position corresponding table by the main electronic equipment according to the coordinate information and the additional information of each piece of electronic equipment. Then, the main electronic device generates a bar code pattern in real time according to the display position corresponding table, wherein the bar code pattern is used for indicating the monitoring website and a plurality of display parameters. Then, the bar code pattern is read by the mobile device to connect to the browsing interface of the monitoring website. And displaying the device pattern corresponding to each electronic device by the browsing interface according to the plurality of display parameters.

Description

Electronic equipment monitoring method

Technical Field

The present disclosure relates to an electronic device monitoring method, and more particularly, to an electronic device monitoring method for remote operation.

Background

Conventionally, when the number of electronic devices is large, one monitoring computer is often used to control and manage all the electronic devices, and a plurality of electronic devices and monitoring computers are often installed in the same place. The advantage is that the engineer can directly see the individual electronic devices in the field, making it easier to determine the correct electronic device to control. And when the engineer carries out each operation, the engineer can check the working state of each electronic device in real time. In other words, the conventional method for monitoring electronic devices is to leave engineers on the site to use the monitoring computer, which is not only intuitive but also capable of avoiding misoperation. However, leaving the engineer on site is clearly inefficient if the electronic equipment needs to be worked for a longer period of time.

Some electronic devices currently support remote connection functions, thereby enabling engineers to perform remote operations. In practice, to ensure that the correct electronic device has been connected, the engineer is still required to be on the site where the electronic device is located when connecting to the electronic device. The engineer can leave the field to perform remote work after determining that the correct electronic device is connected. However, when the engineer wants to switch the connection to a different electronic device, the engineer needs to return to the field to reconnect to another electronic device, which also results in inconvenient ways of connecting to the electronic device. Accordingly, there is a need for a new method for monitoring electronic devices, which can not only remotely control the electronic devices, but also enable engineers to operate and use the electronic devices more intuitively.

Disclosure of Invention

The technical problem to be solved by the present application is to provide an electronic device monitoring method, which allows an engineer to obtain information related to all connectable electronic devices at a time by providing a set of barcode patterns. And the related information of all the connectable electronic devices is displayed in a browsing interface, so that an engineer can operate and use the device more intuitively.

The application provides an electronic device monitoring method, which is used for monitoring a plurality of electronic devices in a cabinet, wherein the plurality of electronic devices are defined with a master electronic device and at least one slave electronic device, and the electronic device monitoring method comprises the following steps. First, coordinate information and additional information of each electronic device are acquired by the main electronic device. And generating a display position corresponding table by the main electronic equipment according to the coordinate information and the additional information of each piece of electronic equipment. Then, the main electronic device generates a bar code pattern in real time according to the display position corresponding table, wherein the bar code pattern is used for indicating the monitoring website and a plurality of display parameters. Then, the bar code pattern is read by the mobile device to connect to the browsing interface of the monitoring website. And displaying the equipment pattern corresponding to each piece of electronic equipment by the browsing interface according to the plurality of display parameters.

In some embodiments, the coordinate information of each electronic device may record a physical location sequence of each electronic device in the cabinet, or record a wiring sequence of each electronic device in the cabinet. Here, the additional information of each electronic device may record a connection address of each electronic device. In addition, the browsing interface may be connected to each electronic device according to the connection address of each electronic device, so as to obtain a plurality of device patterns corresponding to the plurality of electronic devices. In addition, the arrangement order of the device patterns of each electronic device displayed in the browsing interface can be the same as the physical position order or the wiring order.

In some embodiments, the step of obtaining the coordinate information and the additional information of each electronic device from the main electronic device may include the following steps: broadcasting, by the master electronic device, the positioning requirements; and each slave electronic device feeds back coordinate information and additional information to the master electronic device according to the positioning requirement.

In some embodiments, each device pattern displayed in the browsing interface may link to a connection address of the electronic device corresponding to the device pattern. When one device pattern is selected from the browsing interface, the electronic device corresponding to the device pattern can be remotely connected. In addition, the step of remotely connecting the electronic device corresponding to the device pattern may include the steps of: acquiring working state information of electronic equipment corresponding to the equipment pattern; and displaying the working state information in a browsing interface. In addition, the browsing interface can be further used for receiving an operation instruction, and the operation instruction can be used for controlling the electronic equipment corresponding to the selected equipment pattern.

In summary, according to the electronic device monitoring method provided by the application, the main electronic device establishes the display position mapping table and converts the display position mapping table into the barcode pattern, so that an engineer can acquire relevant information of all connectable electronic devices at one time by scanning the barcode pattern. In addition, the electronic device monitoring method provided by the application can also display a plurality of device patterns related to a plurality of electronic devices in one browsing interface at the same time. Because each device pattern simulates the appearance shape of the electronic device, and the relative position of the device pattern in the browsing interface and the position relation of the electronic device in reality correspond to each other, an engineer can intuitively operate and use the device pattern in the browsing interface.

Other features and embodiments of the present application will be described in detail below with reference to the drawings.

Drawings

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

FIG. 1 is a block diagram of a testing system to which the monitoring method of the electronic device according to an embodiment of the present application can be applied;

FIG. 2 is a schematic view of a browsing interface of an electronic device monitoring method according to an embodiment of the present application;

FIG. 3 is a schematic view of a monitoring method of an electronic device in a browsing interface according to another embodiment of the present application;

fig. 4 is a flowchart illustrating steps of a method for monitoring an electronic device according to an embodiment of the present application.

Description of the symbols

1. Test system 10 cabinet 12 a-12 e electronic equipment

14. Bar code pattern 2 web platform 20 browsing interface

22 a-22 e device patterns 24 a-24 e display location 3 network platform

30. Navigation interface 32 a-32 e device pattern 34 control panel pattern

340. Operating status information block

342. Input block 36 inputs row 38 key pattern

S40-S48 step flow

Detailed Description

The positional relationship described in the following embodiments includes: top, bottom, left and right, unless otherwise indicated, are based on the direction in which elements in the drawings are depicted.

Referring to fig. 1 and fig. 2 together, fig. 1 is a block diagram of a testing system to which the electronic device monitoring method according to an embodiment of the present disclosure can be applied, and fig. 2 is a schematic view of the electronic device monitoring method according to an embodiment of the present disclosure in a browsing interface. As shown in the figure, the electronic device monitoring method of the present application can be applied to a test system 1, and the test system 1 may include a cabinet 10 and a plurality of electronic devices 12a to 12e. The cabinet 10 may be a box or a rack for storing the electronic devices 12a to 12e, and the electronic devices 12a to 12e may be various machines for performing electrical tests, such as a voltage supply, a current supply, or an instrument for detecting voltage or current, which is not limited in this embodiment. Furthermore, although fig. 1 shows 1

cabinet

10 and 5 electronic devices 12a to 12e placed in the cabinet 10, the embodiment does not actually limit the number of cabinets 10 that can be included in the test system 1 and the number of electronic devices that can be included in each cabinet 10. In addition, the cabinet 10 in fig. 1 exemplifies the stacking of the electronic devices 12a to 12e, which is for convenience of description and is not limited in this embodiment, for example, the electronic devices 12a to 12e may be disposed in the cabinet 10 in a horizontally adjacent manner.

In one embodiment, the electronic devices 12 a-12 e in the cabinet 10 have fixed sequence numbers, and the sequence numbers can be regarded as the first to fifth electronic devices from top to bottom according to the sequence of the physical positions of the electronic devices 12 a-12 e in the cabinet 10. In another embodiment, the order of the wiring of the electronic equipment 12 a-12 e in the cabinet 10 may be different from the order of physical locations in the cabinet 10. For example, assume that electronic device 12a is wired to electronic device 12e, and then, electronic device 12e is wired to electronic device 12c. At this time, the sequence number of electronic device 12e is immediately after electronic device 12a, and the sequence number of electronic device 12c is immediately after electronic device 12e. For convenience of description, it is assumed that the physical location sequence and the wiring sequence of the electronic devices 12a to 12e in the cabinet 10 are the same.

In addition to the functions of the electronic devices 12 a-12 e for performing electrical tests, each electronic device should also have networking communication functions. For example, each of the electronic devices 12 a-12 e may be wired or wirelessly connected to a network and each may be assigned an identifiable connection address (IP address). Here, any one of the electronic devices 12a to 12e may be set as a master electronic device, and the other four electronic devices may be slave electronic devices. In this embodiment, it is assumed that the electronic device 12c is a master electronic device, and the

electronic devices

12a, 12b, 12d, and 12e are slave electronic devices. In one example, the electronic devices 12a to 12e should know the sequence numbers of their own physical locations or wiring sequences in advance, and the embodiment does not limit how the electronic devices 12a to 12e obtain the sequence numbers. For example, an engineer may give a sequential number for each electronic device, or the electronic devices 12 a-12 e may each execute a localization program to determine their own sequential number in a physical location sequence or wiring sequence. In the present embodiment, the sequence numbers of the electronic devices 12a to 12e in the physical position sequence or the wiring sequence are defined as coordinate information. It should be noted that the present embodiment does not limit the format of the sequence numbers of the physical location sequence or the wiring sequence, and the sequence numbers only need to indicate the sequence of the electronic devices 12a to 12e.

In addition, the electronic devices 12a to 12e may also store additional information other than coordinate information. In practice, the additional information may be a model number, a connection address, or a function menu, and this embodiment is not limited. In actual operation, the electronic device 12c (the master electronic device) obtains the coordinate information and the additional information of each electronic device. In detail, the electronic device 12c actively broadcasts a positioning request to other connected electronic devices (

electronic devices

12a, 12b, 12d, 12 e) in addition to its own coordinate information and additional information, which should be known. Since the electronic devices 12a to 12e in the cabinet 10 are assumed to be connected together by wires in the present embodiment, the other connected electronic devices are slave electronic devices (

electronic devices

12a, 12b, 12d, and 12 e) other than the master electronic device. When the slave electronic device receives the positioning request, the coordinate information and the additional information of the slave electronic device are fed back to the master electronic device (the electronic device 12 c). As can be seen from the above, the main electronic device can record the coordinate information and the additional information of all the electronic devices 12a to 12e. In one example, the master electronic device may periodically broadcast a location request to proactively determine whether there has been an increase or decrease in connected electronic devices. Alternatively, the master electronic device may be automatically notified whenever there is a change in the connected electronic device to trigger its broadcast location request. Alternatively, the engineer may connect to the main electronic device to manually trigger the broadcast positioning request, and the embodiment is not limited.

Then, the main electronic device generates a display position corresponding table according to the recorded coordinate information and the additional information. Here, the display position correspondence table may include other information besides the recording coordinate information and the additional information, and the embodiment is not limited thereto. For example, the display position mapping table of the embodiment may record the physical position sequence or the wiring sequence of each electronic device in the cabinet 10, and the connection address of each electronic device. In one example, the host electronic device generates a barcode pattern 14 in real time according to the content of the display location mapping table. It is worth mentioning that the main electronic device may update the barcode pattern 14 in real time whenever there is a change in the display position correspondence table content maintained by the main electronic device. For example, an electronic device is added to the cabinet 10, and as long as the added electronic device is connected to the main electronic device, the main electronic device modifies the display position correspondence table and generates a new barcode pattern 14.

To remotely control the electronic devices 12 a-12 e in the cabinet 10, an engineer may design a network platform 2, which network platform 2 may be constructed, for example, in the form of web pages or applications. In practice, the barcode pattern 14 is used to indicate a monitoring website and a plurality of display parameters, the monitoring website described in this embodiment indicates a network address of the network platform 2, and the plurality of display parameters described in this embodiment may include part or all of the information in the display location correspondence table. In other words, the plurality of display parameters may indicate at least the physical location sequence or wiring sequence of each electronic device in the cabinet 10, the model number of each electronic device, or the connection address of each electronic device. The present embodiment does not limit the number of display parameters, and the content of each display parameter may be different, for example, part of the display parameters may be used to indicate the physical location order or the wiring order of the electronic device, part of the display parameters may be used to indicate the model of the electronic device, and part of the display parameters may be used to indicate the connection address of the electronic device.

To facilitate engineer control, the network platform 2 may include a graphical navigation interface 20, and the navigation interface 20 may be configured to display a plurality of device designs 22 a-22 e. In practice, the browsing interface may obtain the connection address of each electronic device from the display parameters to connect each electronic device. In one example, each electronic device may store a device pattern of its own device, for example, the electronic device 12a stores a corresponding device pattern 22a. Then, the browsing interface can be connected to the electronic devices 12 a-12 e respectively to obtain the device patterns 22 a-22 e corresponding to all the electronic devices 12 a-12 e. Since the display parameters may indicate the physical location sequence or the connection sequence of the electronic devices 12a to 12e, the browsing interface 20 may determine the arrangement sequence and the relative location of the device patterns 22a to 22e in the display by the display parameters. In detail, some display parameters may record the connection address IP1 corresponding to the electronic device 12a, and under the field of the connection address IP1, the display position 24a in the browsing interface 20 may be marked. Similarly, some display parameters may sequentially record that the electronic devices 12b to 12e correspond to the connection addresses IP2 to IP5, and the connection addresses IP2 to IP5 correspond to the display positions 24b to 24e in the browsing interface 20, respectively, which is not described herein again. In addition, the display parameters may also indicate the model of each electronic device and the corresponding device pattern, and after the browsing interface 20 obtains the device patterns 22a to 22e, it can check whether each device pattern is correct through the display parameters. In one example, the device patterns 22 a-22 e may be two-dimensional maps or three-dimensional models representing physical electronic devices 12 a-12 e. It should be noted that the device patterns 22 a-22 e are not necessarily pre-stored in the electronic devices 12 a-12 e, and may also be stored in the network platform 2. For example, the network platform 2 stores a plurality of device patterns in advance, and determines which device patterns to use and the location of the browsing interface 20 according to the received display parameters.

The embodiment demonstrates that the electronic devices 12a to 12e can store their own device patterns 22a to 22e, and one of the advantages is that since the electronic devices are numerous in models in practice, the storage space of the network platform 2 can be saved by storing their own device patterns, rather than storing too many device patterns corresponding to models in advance in the network platform 2. For example, the electronic device 12a may store its own device pattern 22a when it leaves the factory, which may ensure that the device pattern 22a conforms to the external shape of the electronic device 12a, and because the electronic device 12a only needs to store a single (own) device pattern 22a, the storage space is not required much, and other functions of the electronic device 12a are not affected. In one example, the device design 22a may be an appearance facsimile design of the electronic device 12a that may fully simulate the appearance shape of the electronic device 12a. That is, when the network platform 2 connects to the electronic device 12a, the device pattern 22a is obtained from the electronic device 12a and displayed on the browsing interface 20. In this case, the device pattern 22a displayed on the browsing interface 20 can completely correspond to the actual appearance of the electronic device 12a, thereby greatly reducing confusion and erroneous judgment during control.

In a practical example, when the engineer needs to perform the remote operation, the engineer only needs to go to the location of the cabinet 10 once, and the mobile device (e.g., a mobile phone) can acquire the related information of all the connectable electronic devices 12a to 12e at one time by scanning the barcode pattern 14 on the electronic device 12c (main electronic device). In addition, when the barcode pattern 14 is scanned by the mobile device, the instruction in the barcode pattern 14 may drive the mobile device to automatically open a default browser or a corresponding application program, so as to connect to the network platform 2 from the monitoring website provided by the barcode pattern 14. In one example, after the engineer successfully scans the barcode pattern 14, the browsing interface 20 of the network platform 2 automatically brings in a plurality of device patterns 22 a-22 e, and the engineer only needs to click one of the device patterns to connect to the electronic device corresponding to the device pattern. That is, when the engineer wants to replace the electronic device for operation, the engineer does not need to go to the location of the cabinet 10, and directly clicks the device pattern corresponding to the electronic device to be operated on the browsing interface 20.

In addition, the browsing interface 20 may display not only the device patterns 22a to 22e but also the respective operation state information of the device patterns 22a to 22e. In one example, the network platform 2 may obtain the operating status information of the electronic device 12a from the electronic device 12a in real time. For example, the network platform 2 may know the voltage, current, and power being outputted by the electronic device 12a or the voltage, current, and power being set to be outputted by the electronic device 12a, and link the obtained operation status information to the device pattern 22a. Of course, there are many ways for the network platform 2 to link the operating status information to the corresponding device pattern 22a, and the embodiment is not limited thereto. In a practical example, if an engineer wants to view the operating status information of the electronic device 12a in the browsing interface 20, the network platform 2 may directly display the operating status information of the electronic device 12a around the device pattern 22a, so that the engineer can see that the operating status information is associated with the device pattern 22a, and thus can understand that the operating status information is obtained from the electronic device 12a. In addition, the network platform 2 may also directly display the operating status information of the electronic device 12a on the browsing interface 20 in a pop-up dialog box or window manner after the engineer clicks the device drawing 22a to indicate that the engineer wants to view the operating status information of the electronic device 12a, instead of directly displaying the operating status information on the browsing interface 20. In addition, assuming that the network platform 2 is a web page structure (e.g., a web browser), when the engineer clicks the device drawing 22a to indicate that the engineer wants to view the working status information of the electronic device 12a, the network platform 2 may open a new page again, and directly display the working status information of the electronic device 12a in the new page.

Referring to fig. 1 to 3, fig. 3 is a schematic view of a browsing interface of an electronic device monitoring method according to another embodiment of the present application. As shown, the network platform 3 may also have a browsing interface 30, the browsing interface 30 may also display device patterns 32 a-32 e, and the device patterns 32 a-32 e may also correspond to the electronic devices 12 a-12 e, as in the previous embodiment. Unlike the previous embodiment, the navigation interface 30 may also include other information, for example, the navigation interface 30 may include a control panel pattern 34, an input column 36, and a key pattern 38 corresponding to each device pattern. In one example, if the models of the device patterns 32 a-32 e are the same, then the respective device patterns 32 a-32 e corresponding to the control panel pattern 34 should also be the same. For the control panel pattern 34 corresponding to the device pattern 32a, the control panel pattern 34 may include an operation status information block 340 and an input block 342. Here, the operation status information block 340 may be used to display the operation status information of the electronic device 12a, and the input block 342 may provide the engineer with intuitive input of various operation instructions. For example, when the electronic device 12a is a power supply, the operation status information block 340 may display the current and voltage supplied by the electronic device 12a, and the engineer may provide an operation command from the input block 342, where the operation command may be used to set the current and voltage to be outputted by the electronic device 12a corresponding to the device pattern 32 a.

Of course, although the input block 342 shown in fig. 3 includes numeric keys, the present embodiment is not limited thereto, as long as the engineer can give an operation instruction to control the corresponding electronic device 12a through the input block 342, which is within the scope of the present embodiment. In addition, the input column 36 of the navigation interface 30 can input other commands, such as an engineer can set the voltage or current to be output by the electronic device 12a in the input block 342 and input logic commands such as "cycle" and "delay" in the input column 36 to control the electronic device 12a remotely and precisely. In addition, it is also possible for an engineer to set the voltage or current to be output by the electronic device 12a directly in the input column 36 and add a logic command, and the embodiment does not limit the use of the input column 36.

In one example, the key pattern 38 may be a fully selected key, such as may be selected to mark all of the device patterns 32 a-32 e, or may not mark any of the device patterns 32 a-32 e. For the above example, assuming that the engineer wants the electronic devices 12 a-12 e to perform the same operation, the engineer can input the operation command into the input area 342 corresponding to the input column 36 or the device pattern 32a and click the key pattern 38 to select all the device patterns 32 a-32 e, so that the operation command received by the input column 36 or the input area 342 can be applied to all the device patterns 32 a-32 e. That is, the engineer can synchronously control all the electronic devices 12a to 12e by clicking the key pattern 38, thereby eliminating the trouble of inputting operation commands one by one. It is noted that the control panel design 34 may also be part of the device design 32 a. For example, as long as the electronic device 12a itself includes a control panel, since the device pattern 32a is a simulated pattern of the appearance of the electronic device 12a, the device pattern 32a may be more complex and may include the control panel pattern 34.

In an example, the operating state information of the electronic device 12a may further include warning information, which may be used to, for example, remind the electronic device 12a of overheating, abnormal output, or other various faults, and the embodiment is not limited thereto. In practice, when the electronic device 12a fails, the network platform 3 may play an alarm sound effect corresponding to the alarm information in the browsing interface 30, for example, when the electronic device 12a is overheated, the browsing interface 30 may play a voice such as "the electronic device 12a is overheated" or may play a special audio to indicate the type of the failure. Of course, the embodiment does not limit that an alarm signal only utters voice in one language. In one example, the network platform 3 can selectively play the voices corresponding to various language systems in the browsing interface 30 based on the country or the custom language system (e.g., chinese, english, japanese, etc.) set in the browsing interface 30.

It should be noted that the device pattern 32a of the present embodiment may also be updated at a certain time, for example, after the electronic device 12a is repaired or the hardware is upgraded, the device pattern 32a may be updated to the latest appearance shape of the electronic device 12a. Alternatively, the device pattern 32a may reflect the most real-time appearance of the electronic device 12a, for example, when the electronic device 12a fails, the physical electronic device 12a may light a certain light indicating the failure. At this time, since the network platform 3 may receive the alarm message, it is possible to actively update the device pattern 32a in the browsing interface 30 in practice, and make the device pattern 32a display the corresponding failed light. That is, the network platform 3 may enable the device design 32a to simulate the real-time appearance of the electronic device 32a, thereby enabling the engineer to view the field condition of the electronic device 12a in the browsing interface 20 approximately directly.

For convenience of describing the electronic device monitoring method of the present application, please refer to fig. 1, fig. 2 and fig. 4 together, and fig. 4 is a flowchart illustrating steps of the electronic device monitoring method according to an embodiment of the present application. As shown in the drawings, the electronic device monitoring method of the present application is used for monitoring a plurality of electronic devices 12a to 12e in a cabinet 10, where the electronic devices 12a to 12e define a master electronic device (e.g., the electronic device 12c in the foregoing example) and at least one slave electronic device (e.g., the electronic devices 12a to 12b in the foregoing example, and the electronic devices 12d to 12 e). In step S40, the host electronic device obtains the coordinate information and the additional information of each electronic device. In step S42, a display position mapping table is generated by the main electronic device according to the coordinate information and the additional information of each electronic device. Next, in step S44, the main electronic device generates the barcode pattern 14 in real time according to the display location mapping table, wherein the barcode pattern 14 is used to indicate the monitoring website and a plurality of display parameters. Next, in step S46, the barcode pattern 14 is read by the mobile device to connect to the browsing interface 20 for monitoring the website. In step S48, the browsing interface 20 displays the device patterns 22a to 22e corresponding to each of the electronic devices (the electronic devices 12a to 12 e) according to the display parameters. The steps of the method for monitoring an electronic device of this embodiment can be found in the foregoing embodiments, and are not described herein again.

The above-described embodiments and/or implementations are only for illustrating the preferred embodiments and/or implementations of the technology of the present application, and are not intended to limit the implementations of the technology of the present application in any way, and those skilled in the art can make modifications or changes to other equivalent embodiments without departing from the scope of the technology disclosed in the present application, but should be construed as technology or implementations substantially the same as the present application.

Claims

1. An electronic device monitoring method for monitoring a plurality of electronic devices in a cabinet, the electronic devices defining a master electronic device and at least one slave electronic device, the electronic device monitoring method comprising:

obtaining coordinate information and additional information of each electronic device by the main electronic device;

generating a display position corresponding table by the main electronic equipment according to the coordinate information and the additional information of each electronic equipment;

the main electronic equipment generates a bar code pattern in real time according to the display position corresponding table, and the bar code pattern is used for indicating a monitoring website and a plurality of display parameters;

reading the bar code pattern by a mobile device so as to connect to a browsing interface of the monitoring website; and

and displaying an equipment pattern corresponding to each piece of electronic equipment by the browsing interface according to the display parameters.

2. The method of claim 1, wherein the coordinate information of each electronic device is recorded in a physical location sequence of each electronic device in the cabinet or a wiring sequence of each electronic device in the cabinet.

3. The method of claim 2, wherein the additional information of each electronic device is recorded with a connection address of each electronic device.

4. The method of claim 3, wherein the browsing interface is connected to each of the electronic devices according to the connection address of each of the electronic devices to obtain a plurality of device patterns corresponding to the electronic devices.

5. The method of claim 4, wherein the device patterns of each of the electronic devices are displayed in the browsing interface in a same sequence as the physical location sequence or the connection sequence.

6. The method of claim 1, wherein the step of obtaining the coordinate information and the additional information of each of the electronic devices from the host electronic device comprises:

broadcasting a positioning requirement by the main electronic device; and

each slave electronic device feeds the coordinate information and the additional information back to the master electronic device according to the positioning requirement.

7. The method of claim 1, wherein each device pattern displayed in the browsing interface is connected to a connection address of the electronic device corresponding to the device pattern.

8. The method of claim 7, further comprising:

when one of the device patterns is selected in the browsing interface, the electronic device corresponding to the device pattern is remotely connected.

9. The method of claim 8, wherein the step of remotely connecting the electronic device corresponding to the device pattern comprises:

obtaining working state information of the electronic equipment corresponding to the equipment pattern; and

and displaying the working state information in the browsing interface.

10. The method of claim 8, wherein the browser interface is further configured to receive an operation command for controlling the electronic device corresponding to the selected device pattern.