CN117408287B - Intelligent label generation method based on secondary loop - Google Patents

Abstract

The invention discloses an intelligent label generation method based on a secondary loop, which comprises the following steps: acquiring an optical fiber connection relation table and an equipment hierarchy relation diagram; inquiring the device hierarchy relation graph to obtain a plurality of pieces of device information; determining a corresponding target equipment three-dimensional model from a pre-established equipment three-dimensional model library according to the equipment name to obtain a target equipment three-dimensional model set; configuring a target equipment three-dimensional model to obtain a candidate three-dimensional model; adding the target optical fiber three-dimensional model to the candidate three-dimensional model to obtain a standard three-dimensional model corresponding to the target substation; and for each piece of optical fiber information, the corresponding target optical fiber three-dimensional model in the standard three-dimensional model is differentially displayed, the differential three-dimensional model corresponding to the optical fiber information is obtained and stored in a target storage space, label information is generated based on the storage address and the optical fiber information, and coding information is further generated and written into the electronic label. Thus, the electronic tag capable of automatically generating the coded information is realized.

Description

Intelligent label generation method based on secondary loop

Technical Field

The invention relates to the field of label generation, in particular to an intelligent label generation method based on a secondary circuit.

Background

The optical fiber tag of the intelligent substation still adopts a cable representation method of a conventional substation, namely information such as a starting point, a terminal point, a number and the like of the optical fiber is displayed by hanging a hangtag.

However, the information of the optical fiber is displayed by hanging the hangtag, which often has the following technical problems:

with the increasing complexity of secondary systems of intelligent substations, the conventional hanging tag manner is difficult to meet the operation and maintenance requirements.

Disclosure of Invention

This summary is provided to introduce a selection of concepts in a simplified form that are further described below in the detailed description. This summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used to limit the scope of the claimed subject matter.

The invention provides a secondary loop-based intelligent label generation method which solves one or more of the technical problems mentioned in the background section.

The invention provides a secondary circuit-based intelligent label generation method, which comprises the following steps: acquiring an optical fiber connection relation table and an equipment hierarchy relation diagram of a target transformer substation, wherein the optical fiber connection relation table comprises a plurality of pieces of optical fiber information, and each piece of optical fiber information in the plurality of pieces of optical fiber information comprises an optical fiber number, an optical fiber model, an optical fiber starting point, an optical fiber ending point and an optical fiber terminal number; performing image recognition on the equipment hierarchy relation graph to obtain a plurality of pieces of equipment information included in the equipment hierarchy relation graph, wherein each piece of equipment information in the plurality of pieces of equipment information comprises an equipment name, an equipment number, equipment attributes and equipment hierarchy relation information; for each piece of equipment information in the pieces of equipment information, determining a corresponding target equipment three-dimensional model from a pre-created equipment three-dimensional model library according to the equipment name of the equipment information, and obtaining a target equipment three-dimensional model set corresponding to the pieces of equipment information; configuring each target equipment three-dimensional model in the target equipment three-dimensional model set according to equipment numbers, equipment attributes and equipment hierarchy relation information included in each piece of equipment information, wherein each configured target equipment three-dimensional model forms a candidate three-dimensional model corresponding to the target transformer substation; for each piece of optical fiber information in the optical fiber connection relation table, determining a corresponding target optical fiber three-dimensional model from a pre-established optical fiber three-dimensional model library according to the optical fiber model of the optical fiber information, adding the target optical fiber three-dimensional model corresponding to each piece of optical fiber information to the candidate three-dimensional model according to the optical fiber starting point, the optical fiber ending point and the optical fiber terminal number included in each piece of optical fiber information, obtaining a standard three-dimensional model corresponding to a target transformer substation, and storing the standard three-dimensional model in a target storage space; for each piece of optical fiber information, the optical fiber number included in the optical fiber information and the storage address corresponding to the target storage space are combined into label information corresponding to the optical fiber information, the label information is coded to generate coded information corresponding to the optical fiber information, and the coded information is written into an electronic label of the optical fiber information.

Optionally, the optical fiber information further includes a category of transmission signals; and determining a corresponding target optical fiber three-dimensional model from a pre-created optical fiber three-dimensional model library according to the optical fiber model of the optical fiber information, wherein the method comprises the following steps of: and determining a corresponding target optical fiber three-dimensional model from a pre-established optical fiber three-dimensional model library according to the optical fiber model of the optical fiber information and the type of the transmission signal.

Optionally, for each piece of optical fiber information, displaying a corresponding target optical fiber three-dimensional model in the standard three-dimensional model in a first preset format, and displaying the rest three-dimensional models in the standard three-dimensional model in a second preset format to obtain a differential three-dimensional model corresponding to the optical fiber information, including: and for each piece of optical fiber information, displaying a corresponding target optical fiber three-dimensional model in the standard three-dimensional model in a first preset format, displaying at least one three-dimensional model with an association relation with the target optical fiber three-dimensional model in a third preset format, and displaying the rest three-dimensional models in the standard three-dimensional model in a second preset format to obtain a differential three-dimensional model corresponding to the optical fiber information.

Optionally, before displaying, for each piece of optical fiber information, a corresponding target optical fiber three-dimensional model in the standard three-dimensional model in a first preset format, displaying the other three-dimensional models in the standard three-dimensional model in a second preset format to obtain a differential three-dimensional model corresponding to the optical fiber information, storing the differential three-dimensional model in a target storage space, generating tag information corresponding to the optical fiber information based on a storage address corresponding to the target storage space and the optical fiber information, encoding the tag information to generate encoded information corresponding to the optical fiber information, and writing the encoded information into an electronic tag of the optical fiber information, the method further includes: for each piece of optical fiber information, generating broadcasting voice corresponding to the optical fiber information according to the optical fiber number, the optical fiber model, the optical fiber starting point and end point and the optical fiber terminal number contained in the optical fiber information; and storing the differentiated three-dimensional model to a target storage space, comprising: and storing the differentiated three-dimensional model and the broadcasting voice into a target storage space.

Optionally, before displaying, for each piece of optical fiber information, a corresponding target optical fiber three-dimensional model in the standard three-dimensional model in a first preset format, displaying the other three-dimensional models in the standard three-dimensional model in a second preset format to obtain a differential three-dimensional model corresponding to the optical fiber information, storing the differential three-dimensional model in a target storage space, generating tag information corresponding to the optical fiber information based on a storage address corresponding to the target storage space and the optical fiber information, encoding the tag information to generate encoded information corresponding to the optical fiber information, and writing the encoded information into an electronic tag of the optical fiber information, the method further includes: for each piece of optical fiber information, determining the voice broadcast tone according to the optical fiber model included in the optical fiber information; and generating broadcasting voice corresponding to the optical fiber information according to the optical fiber number, the optical fiber model, the optical fiber starting point, the optical fiber ending point and the optical fiber terminal number contained in the optical fiber information for each piece of optical fiber information, wherein the voice comprises the following components: and for each piece of optical fiber information, generating broadcasting voice corresponding to the optical fiber information according to the optical fiber number, the optical fiber model, the optical fiber starting point and ending point, the optical fiber terminal number and the corresponding voice broadcasting tone contained in the optical fiber information.

Optionally, before displaying, for each piece of optical fiber information, a corresponding target optical fiber three-dimensional model in the standard three-dimensional model in a first preset format, displaying the other three-dimensional models in the standard three-dimensional model in a second preset format to obtain a differential three-dimensional model corresponding to the optical fiber information, storing the differential three-dimensional model in a target storage space, generating tag information corresponding to the optical fiber information based on a storage address corresponding to the target storage space and the optical fiber information, encoding the tag information to generate encoded information corresponding to the optical fiber information, and writing the encoded information into an electronic tag of the optical fiber information, the method further includes: for each piece of optical fiber information, determining a voice broadcasting virtual image according to the optical fiber model included in the optical fiber information; and storing the differentiated three-dimensional model and the broadcast voice to a target storage space, comprising: and storing the differentiated three-dimensional model, the broadcasting voice and the voice broadcasting virtual image into a target storage space.

The invention has the following beneficial effects:

automatically generating the electronic tag with the coded information of the optical fiber. Therefore, an operation and maintenance person can check the label information of the corresponding optical fiber by reading the information in the electronic label. Therefore, the problem of poor visibility of the optical fiber virtual circuit is solved, and the optical fiber virtual circuit is convenient to detect and maintain.

Drawings

The above and other features, advantages and aspects of embodiments of the present invention will become more apparent by reference to the following detailed description when taken in conjunction with the accompanying drawings. The same or similar reference numbers will be used throughout the drawings to refer to the same or like elements. It should be understood that the figures are schematic and that elements and components are not necessarily drawn to scale.

Fig. 1 is an exemplary flow chart of a secondary loop-based smart tag generation method of the present invention.

Detailed Description

The invention will be described in more detail below with reference to the accompanying drawings. While certain embodiments of the invention have been illustrated in the accompanying drawings, it is to be understood that the invention may be embodied in various forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete. It should be understood that the drawings and embodiments of the invention are for illustration purposes only and are not intended to limit the scope of the present invention.

It should be noted that, for convenience of description, only the portions related to the present invention are shown in the drawings. Embodiments of the invention and features of the embodiments may be combined with each other without conflict.

It should be noted that the terms "first," "second," and the like herein are merely used for distinguishing between different devices, modules, or units and not for limiting the order or interdependence of the functions performed by such devices, modules, or units.

It should be noted that references to "one", "a plurality" and "a plurality" in this disclosure are intended to be illustrative rather than limiting, and those skilled in the art will appreciate that "one or more" is intended to be construed as "one or more" unless the context clearly indicates otherwise.

The names of messages or information interacted between the devices of the present invention are for illustrative purposes only and are not intended to limit the scope of such messages or information.

The invention will be described in detail below with reference to the drawings in connection with embodiments.

As shown in fig. 1, there is an exemplary flowchart of the secondary loop-based smart tag generation method of the present invention, which includes the steps of:

step 101, obtaining an optical fiber connection relation table and an equipment hierarchy relation diagram of a target transformer substation, wherein the optical fiber connection relation table comprises a plurality of pieces of optical fiber information, and each piece of optical fiber information in the plurality of pieces of optical fiber information comprises an optical fiber number, an optical fiber model, an optical fiber starting point and an optical fiber terminal number.

In some embodiments, the execution subject of the secondary loop-based smart tag generation method may be a background server. On this basis, the execution subject may first acquire the optical fiber connection relationship table and the device hierarchy relationship diagram of the target substation. The target substation may be any substation in the area. The optical fiber connection relation table and the equipment hierarchy relation diagram corresponding to each transformer substation in a certain area can be generated in advance. The optical fiber connection relation table comprises a plurality of pieces of optical fiber information, wherein each piece of optical fiber information comprises an optical fiber number, an optical fiber model, an optical fiber starting point, an optical fiber ending point and an optical fiber terminal number. The device hierarchy graph may include images that characterize the hierarchy between different devices. The device hierarchy relation graph is graph structure data, and the internal storage structure of the device hierarchy relation graph adopts a mode of an adjacency matrix or an adjacency table.

Step 102, querying the device hierarchy relation diagram to obtain a plurality of pieces of device information included in the device hierarchy relation diagram, wherein each piece of device information in the plurality of pieces of device information comprises a device name, a device number, a device attribute and device hierarchy relation information.

In some embodiments, the executing entity may query the plurality of device information included in the device hierarchical relationship graph using a graph database query language, and the devices characterized by the device information may include various devices in the substation, including but not limited to: a cell, a board card, a screen cabinet, a terminal block, etc. Each device information includes a device name, a device number, a device attribute, device hierarchy relationship information. The device hierarchy relationship information may be represented by a number or a code, and specifically, the device hierarchy relationship information includes relationship information and hierarchy information, for example, the relationship information may be letters, devices with the same letters have an association relationship, devices with different letters have no association relationship before, and the hierarchy information is a number. For example, the device hierarchy relation information of the cell is "A1", and the device hierarchy relation information of the cabinet is "A2".

Step 103, for each piece of equipment information in the pieces of equipment information, determining a corresponding target equipment three-dimensional model from a pre-created equipment three-dimensional model library according to the equipment name of the piece of equipment information, and obtaining a target equipment three-dimensional model set corresponding to the pieces of equipment information.

In some embodiments, a device three-dimensional model corresponding to each device may be created in advance, where the device three-dimensional models corresponding to the respective devices form a device three-dimensional model library, and each device name corresponds to one device three-dimensional model. On this basis, for each device information, a corresponding device three-dimensional model, i.e., a target device three-dimensional model, may be determined from a device three-dimensional model library.

And 104, configuring each target equipment three-dimensional model in the target equipment three-dimensional model set according to equipment numbers, equipment attributes and equipment hierarchy relation information included in each piece of equipment information, wherein each configured target equipment three-dimensional model forms a candidate three-dimensional model corresponding to the target transformer substation.

In some embodiments, the device three-dimensional model library, the candidate three-dimensional model, the fiber-optic three-dimensional model library and the standard three-dimensional model can be built by using some open-source three-dimensional model building tools or applications. The three-dimensional model building application provides a model self-defining function, so that a technician can self-define a model corresponding to each piece of optical fiber information or equipment information. In addition, after the models are created, the user is supported to configure the three-dimensional model for each target device. Thus, each configured target device three-dimensional model in the candidate three-dimensional models displays the corresponding device name, device number and device attribute, and is connected or matched with other target device three-dimensional models according to the device hierarchy relation information.

Step 105, for each piece of optical fiber information in the optical fiber connection relation table, determining a corresponding target optical fiber three-dimensional model from a pre-created optical fiber three-dimensional model library according to the optical fiber model of the optical fiber information, and adding the target optical fiber three-dimensional model corresponding to each piece of optical fiber information to the candidate three-dimensional model according to each piece of optical fiber information including the optical fiber number, the optical fiber model, the optical fiber starting point and ending point and the optical fiber terminal number.

In some embodiments, a library of fiber optic three-dimensional models may be created in advance, one fiber optic three-dimensional model for each fiber optic model. On the basis of this, for each piece of optical fiber information, the above-described execution body may determine a three-dimensional model corresponding to the optical fiber, that is, a target three-dimensional optical fiber model, based on the optical fiber model contained in the optical fiber information. And then, configuring the target three-dimensional optical fiber model according to the optical fiber information. Specifically, the fiber number and the fiber model may be configured into the model, so that the fiber number and the fiber model may be displayed in association with the three-dimensional fiber model, for example, above the three-dimensional fiber model. In addition, the starting point and the ending point of the three-dimensional optical fiber model are configured according to the information of the starting point and the ending point of the optical fiber and the terminal number of the optical fiber, so that the two-dimensional optical fiber model and the secondary circuit of the actual optical fiber are mutually mapped.

And 106, for each piece of optical fiber information, displaying the corresponding target optical fiber three-dimensional model in the standard three-dimensional model in a first preset format, displaying the other three-dimensional models in the standard three-dimensional model in a second preset format to obtain a differentiated three-dimensional model corresponding to the optical fiber information, storing the differentiated three-dimensional model in a target storage space, generating tag information corresponding to the optical fiber information based on a storage address corresponding to the target storage space and the optical fiber information, encoding the tag information to generate encoded information corresponding to the optical fiber information, and writing the encoded information into an electronic tag of the optical fiber information.

In some embodiments, the first preset format and the second preset format are different, and in general, the first preset format is a highlighted format and the second preset format is a normal format. Therefore, the target optical fiber three-dimensional model corresponding to each piece of optical fiber information can be highlighted, so that maintenance personnel can more intuitively see the optical fiber three-dimensional model, and the rest three-dimensional models in the area are distinguished.

Optionally, the optical fiber information further includes a category of transmission signal. At this time, determining a corresponding target optical fiber three-dimensional model from a pre-created optical fiber three-dimensional model library according to the optical fiber model of the optical fiber information, including: and determining a corresponding target optical fiber three-dimensional model from a pre-established optical fiber three-dimensional model library according to the optical fiber model of the optical fiber information and the type of the transmission signal.

Optionally, for each piece of optical fiber information, displaying a corresponding target optical fiber three-dimensional model in the standard three-dimensional model in a first preset format, displaying at least one three-dimensional model with an association relationship with the target optical fiber three-dimensional model in a third preset format, and displaying the rest three-dimensional models in the standard three-dimensional model in a second preset format to obtain a differential three-dimensional model corresponding to the optical fiber information.

Optionally, before displaying, for each piece of optical fiber information, a corresponding target optical fiber three-dimensional model in the standard three-dimensional model in a first preset format, displaying the other three-dimensional models in the standard three-dimensional model in a second preset format to obtain a differential three-dimensional model corresponding to the optical fiber information, storing the differential three-dimensional model in a target storage space, generating tag information corresponding to the optical fiber information based on a storage address corresponding to the target storage space and the optical fiber information, encoding the tag information to generate encoded information corresponding to the optical fiber information, and writing the encoded information into an electronic tag of the optical fiber information, the method further includes: for each piece of optical fiber information, generating broadcasting voice corresponding to the optical fiber information according to the optical fiber number, the optical fiber model, the optical fiber starting point and end point and the optical fiber terminal number contained in the optical fiber information; and storing the differentiated three-dimensional model to a target storage space, comprising: and storing the differentiated three-dimensional model and the broadcasting voice into a target storage space.

Optionally, before displaying, for each piece of optical fiber information, a corresponding target optical fiber three-dimensional model in the standard three-dimensional model in a first preset format, displaying the other three-dimensional models in the standard three-dimensional model in a second preset format to obtain a differential three-dimensional model corresponding to the optical fiber information, storing the differential three-dimensional model in a target storage space, generating tag information corresponding to the optical fiber information based on a storage address corresponding to the target storage space and the optical fiber information, encoding the tag information to generate encoded information corresponding to the optical fiber information, and writing the encoded information into an electronic tag of the optical fiber information, the method further includes: for each piece of optical fiber information, determining the voice broadcast tone according to the optical fiber model included in the optical fiber information; and generating broadcasting voice corresponding to the optical fiber information according to the optical fiber number, the optical fiber model, the optical fiber starting point, the optical fiber ending point and the optical fiber terminal number contained in the optical fiber information for each piece of optical fiber information, wherein the voice comprises the following components: and for each piece of optical fiber information, generating broadcasting voice corresponding to the optical fiber information according to the optical fiber number, the optical fiber model, the optical fiber starting point and ending point, the optical fiber terminal number and the corresponding voice broadcasting tone contained in the optical fiber information.

Optionally, before displaying, for each piece of optical fiber information, a corresponding target optical fiber three-dimensional model in the standard three-dimensional model in a first preset format, displaying the other three-dimensional models in the standard three-dimensional model in a second preset format to obtain a differential three-dimensional model corresponding to the optical fiber information, storing the differential three-dimensional model in a target storage space, generating tag information corresponding to the optical fiber information based on a storage address corresponding to the target storage space and the optical fiber information, encoding the tag information to generate encoded information corresponding to the optical fiber information, and writing the encoded information into an electronic tag of the optical fiber information, the method further includes: for each piece of optical fiber information, determining a voice broadcasting virtual image according to the optical fiber model included in the optical fiber information; and storing the differentiated three-dimensional model and the broadcast voice to a target storage space, comprising: and storing the differentiated three-dimensional model, the broadcasting voice and the voice broadcasting virtual image into a target storage space.

In these embodiments, an electronic tag with encoded information of the optical fiber is automatically generated. Therefore, an operation and maintenance person can check the label information of the corresponding optical fiber by reading the information in the electronic label. Therefore, the problem of poor visibility of the optical fiber virtual circuit is solved, and the optical fiber virtual circuit is convenient to detect and maintain.

The above description is only illustrative of the few preferred embodiments of the present invention and of the principles of the technology employed. It will be appreciated by persons skilled in the art that the scope of the invention referred to in the present invention is not limited to the specific combinations of the technical features described above, but also covers other technical features formed by any combination of the technical features described above or their equivalents without departing from the inventive concept described above. Such as the above-mentioned features and the technical features disclosed in the present invention (but not limited to) having similar functions are replaced with each other.

Claims (6)

1. A secondary loop-based smart tag generation method, comprising:

acquiring an optical fiber connection relation table and an equipment hierarchy relation chart of a secondary circuit of a target transformer substation, wherein the optical fiber connection relation table comprises a plurality of pieces of optical fiber information, and each piece of optical fiber information in the plurality of pieces of optical fiber information comprises an optical fiber number, an optical fiber model, an optical fiber starting point and an optical fiber ending point and an optical fiber terminal number;

querying the equipment hierarchy relation diagram to obtain a plurality of pieces of equipment information contained in the equipment hierarchy relation diagram, wherein each piece of equipment information in the plurality of pieces of equipment information comprises an equipment name, an equipment number, equipment attributes and equipment hierarchy relation information;

for each piece of equipment information in the plurality of pieces of equipment information, determining a corresponding target equipment three-dimensional model from a pre-created equipment three-dimensional model library according to the equipment name of the piece of equipment information, and obtaining a target equipment three-dimensional model set corresponding to the plurality of pieces of equipment information;

configuring each target equipment three-dimensional model in the target equipment three-dimensional model set according to equipment numbers, equipment attributes and equipment hierarchy relation information included in each piece of equipment information, wherein each configured target equipment three-dimensional model forms a candidate three-dimensional model corresponding to the target transformer substation;

for each piece of optical fiber information in the optical fiber connection relation table, determining a corresponding target optical fiber three-dimensional model from a pre-created optical fiber three-dimensional model library according to the optical fiber model of the optical fiber information, and adding the target optical fiber three-dimensional model corresponding to each piece of optical fiber information to the candidate three-dimensional model according to the optical fiber starting point, the optical fiber ending point and the optical fiber terminal number included in each piece of optical fiber information to obtain a standard three-dimensional model corresponding to the target transformer substation;

and for each piece of optical fiber information, displaying a corresponding target optical fiber three-dimensional model in the standard three-dimensional model in a first preset format, displaying other three-dimensional models in the standard three-dimensional model in a second preset format to obtain a differentiated three-dimensional model corresponding to the optical fiber information, storing the differentiated three-dimensional model in a target storage space, generating tag information corresponding to the optical fiber information based on a storage address corresponding to the target storage space and the optical fiber information, encoding the tag information to generate encoded information corresponding to the optical fiber information, and writing the encoded information into an electronic tag of the optical fiber information.

2. The secondary loop-based smart tag generation method of claim 1, wherein the fiber optic information further includes a category of transmission signal; and

the determining a corresponding target optical fiber three-dimensional model from a pre-created optical fiber three-dimensional model library according to the optical fiber model of the optical fiber information comprises the following steps:

and determining a corresponding target optical fiber three-dimensional model from a pre-established optical fiber three-dimensional model library according to the optical fiber model of the optical fiber information and the type of the transmission signal.

3. The secondary circuit-based intelligent label generation method according to claim 2, wherein for each piece of optical fiber information, displaying a corresponding target optical fiber three-dimensional model in the standard three-dimensional model in a first preset format, and displaying the rest three-dimensional models in the standard three-dimensional model in a second preset format, to obtain a differential three-dimensional model corresponding to the optical fiber information, including:

and for each piece of optical fiber information, displaying a corresponding target optical fiber three-dimensional model in the standard three-dimensional model in a first preset format, displaying at least one three-dimensional model with an association relation with the target optical fiber three-dimensional model in a third preset format, and displaying the rest three-dimensional models in the standard three-dimensional model in a second preset format to obtain a differential three-dimensional model corresponding to the optical fiber information.

4. The secondary circuit-based intelligent tag generation method according to claim 3, wherein, before the displaying, for each piece of optical fiber information, a corresponding target optical fiber three-dimensional model in the standard three-dimensional model in a first preset format, displaying the remaining three-dimensional models in the standard three-dimensional model in a second preset format, obtaining a differential three-dimensional model corresponding to the optical fiber information, storing the differential three-dimensional model in a target storage space, generating tag information corresponding to the optical fiber information based on a storage address corresponding to the target storage space and the optical fiber information, and encoding the tag information to generate encoded information corresponding to the optical fiber information, and writing the encoded information into an electronic tag of the optical fiber information, the method further comprises:

for each piece of optical fiber information, generating broadcasting voice corresponding to the optical fiber information according to the optical fiber number, the optical fiber model, the optical fiber starting point, the optical fiber ending point and the optical fiber terminal number contained in the optical fiber information; and

the storing the differential three-dimensional model in a target storage space comprises:

and storing the differentiated three-dimensional model and the broadcasting voice into the target storage space.

5. The secondary circuit-based intelligent label generation method according to claim 4, wherein before the displaying, for each piece of optical fiber information, a corresponding target optical fiber three-dimensional model in the standard three-dimensional model in a first preset format, displaying the remaining three-dimensional models in the standard three-dimensional model in a second preset format, obtaining a differential three-dimensional model corresponding to the optical fiber information, storing the differential three-dimensional model in a target storage space, generating label information corresponding to the optical fiber information based on a storage address corresponding to the target storage space and the optical fiber information, and encoding the label information to generate encoded information corresponding to the optical fiber information, and writing the encoded information into an electronic label of the optical fiber information, the method further comprises:

for each piece of optical fiber information, determining voice broadcast tone according to the type of the optical fiber included in the optical fiber information; and

for each piece of optical fiber information, generating broadcasting voice corresponding to the optical fiber information according to the optical fiber number, the optical fiber model, the optical fiber starting point, the optical fiber ending point and the optical fiber terminal number contained in the optical fiber information, including:

and for each piece of optical fiber information, generating broadcasting voice corresponding to the optical fiber information according to the optical fiber number, the optical fiber model, the optical fiber starting point and ending point, the optical fiber terminal number and the corresponding voice broadcasting tone contained in the optical fiber information.

6. The secondary circuit-based intelligent tag generation method according to claim 5, wherein before the displaying, for each piece of optical fiber information, a corresponding target optical fiber three-dimensional model in the standard three-dimensional model in a first preset format, displaying the remaining three-dimensional models in the standard three-dimensional model in a second preset format, obtaining a differential three-dimensional model corresponding to the optical fiber information, storing the differential three-dimensional model in a target storage space, generating tag information corresponding to the optical fiber information based on a storage address corresponding to the target storage space and the optical fiber information, and encoding the tag information to generate encoded information corresponding to the optical fiber information, and writing the encoded information into an electronic tag of the optical fiber information, the method further comprises:

for each piece of optical fiber information, determining a voice broadcasting virtual image according to the optical fiber model included in the optical fiber information; and

the storing the differential three-dimensional model and the broadcast voice in the target storage space includes:

and storing the differential three-dimensional model, the broadcasting voice and the voice broadcasting virtual image into the target storage space.