CN116821060A - Optical cable wiring information processing method and device - Google Patents

Abstract

The disclosure relates to a method and a device for processing optical cable wiring information, and relates to the field of rail transit optical cable wiring operation and maintenance. The method comprises the following steps: acquiring wiring source data; analyzing the wiring source data to determine metadata of the optical cable wiring; determining position information corresponding to the optical cable wiring; and storing the wiring source data, the metadata and the position information to a preset platform. By the aid of the method and the device, maintenance and processing of the optical cable wiring data can be achieved through the preset platform, and accordingly accuracy and maintainability of optical cable wiring information are improved.

Description

Optical cable wiring information processing method and device

Technical Field

The application relates to the field of rail transit, in particular to the field of optical cable wiring, and particularly relates to an optical cable wiring information processing method and device.

Background

The optical cable wiring of the track traffic signal system mainly comprises indoor side terminal wiring, indoor combined cabinet internal terminal wiring, indoor power supply cables, outdoor optical cables, wiring, outdoor box wiring, and the optical cable wiring plays roles of supplying power to indoor and outdoor equipment of the signal system, transmitting signals, controlling logic conditions and the like, and the accuracy of information directly influences railway transportation efficiency and safety, and plays a vital role in the whole signal system.

In the design, construction and operation and maintenance stages of a rail transit signal system, the information delivery and management medium of the optical cable wiring is mainly paper graphic data after examination and signing, and a unified informatization management and maintenance platform is not available, so that the method cannot adapt to the development needs of the informatization level of the rail transit in the new era, and the high-quality development of the rail transit is seriously hindered.

Disclosure of Invention

The embodiment of the disclosure provides an optical cable wiring information processing method and device.

In a first aspect, an embodiment of the present disclosure provides an optical cable wiring information processing method, including: acquiring wiring source data; analyzing the wiring source data to determine metadata of the optical cable wiring; determining position information corresponding to the optical cable wiring; and storing the wiring source data, the metadata and the position information to a preset platform.

In a second aspect, embodiments of the present disclosure provide an optical cable wiring information processing apparatus including: a source data acquisition unit configured to acquire wiring source data; a metadata generation unit configured to parse the wiring source data and determine metadata of the optical cable wiring; a position determining unit configured to determine position information corresponding to the optical cable wiring; and an information processing unit configured to store the wiring source data, the metadata, and the positional information to a preset platform.

It should be understood that the description in this section is not intended to identify key or critical features of the embodiments of the disclosure, nor is it intended to be used to limit the scope of the disclosure. Other features of the present disclosure will become apparent from the following specification.

Drawings

The drawings are for a better understanding of the present solution and are not to be construed as limiting the present disclosure. Wherein:

FIG. 1 is an exemplary system architecture diagram to which one embodiment of the optical cable wiring information processing method of the present disclosure may be applied;

FIG. 2 is a flow diagram of one embodiment of an optical fiber distribution information processing method of the present disclosure;

FIG. 3 is a flow chart of another embodiment of an optical cable wiring information processing method of the present disclosure;

FIG. 4 is a metadata generation diagram;

FIG. 5 is a schematic diagram of a life cycle maintenance flow of optical cable wiring information;

FIG. 6 is a schematic diagram of a default platform architecture;

fig. 7 is a schematic structural view of one embodiment of an optical cable distribution information processing apparatus of the present disclosure.

Detailed Description

It should be noted that the following detailed description is exemplary and is intended to provide further explanation of the present disclosure. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this disclosure belongs.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of exemplary embodiments in accordance with the present disclosure. As used herein, the singular is also intended to include the plural unless the context clearly indicates otherwise, and furthermore, it is to be understood that the terms "comprises" and/or "comprising" when used in this specification are taken to specify the presence of stated features, steps, operations, devices, components, and/or combinations thereof.

Embodiments of the present disclosure and features of embodiments may be combined with each other without conflict.

In order to make the technical scheme and advantages of the present disclosure more apparent, the present disclosure will be further described in detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 illustrates an exemplary system architecture 100 to which embodiments of the optical cable wiring information processing method or optical cable wiring information processing apparatus of the present disclosure may be applied.

As shown in fig. 1, the system architecture 100 may include terminal devices 101, 102, 103, a server 104, and a database 105. The terminal devices 101, 102, 103 and the server 104 and the database 105 interact with each other through a network. The network may include various connection types, such as wired, wireless communication links, or fiber optic cables, among others.

A user can interact with the database 105 via the network 104 using the terminal devices 101, 102, 103 to obtain various data from the server. Various communication client applications, such as a drawing processing class application, an image recognition class application, and the like, may be installed on the terminal devices 101, 102, 103.

The terminal devices 101, 102, 103 may be hardware or software. When the terminal devices 101, 102, 103 are hardware, they may be various electronic devices including, but not limited to, smartphones, tablets, car-mounted computers, laptop and desktop computers, and the like. When the terminal devices 101, 102, 103 are software, they can be installed in the above-listed electronic devices. Which may be implemented as multiple software or software modules (e.g., to provide distributed services), or as a single software or software module. The present application is not particularly limited herein.

The server 104 may acquire information such as drawings and images from the terminal devices 101, 102, and 103, process the information, and store the acquired wiring information in the database 105. The server 104 may provide various services, such as a query service, an identification service, etc., to the terminal devices 101, 102, 103. The query service can query the connection information of the wiring with specific identification. The recognition service may be for recognizing drawings or images, etc.

The server 104 may be hardware or software. When the server 104 is hardware, it may be implemented as a distributed server cluster formed by a plurality of servers, or as a single server. When server 104 is software, it may be implemented as multiple software or software modules (e.g., to provide distributed services), or as a single software or software module. The present application is not particularly limited herein.

The database 105 may be a database for storing various data, such as a database for wiring information. The database 105 may be hardware or software. When the database 105 is hardware, it may be implemented as a distributed database cluster composed of a plurality of databases, or as a single database. When database 105 is software, it may be implemented as a plurality of software or software modules (e.g., to provide distributed services), or as a single software or software module. The present application is not particularly limited herein.

It should be noted that, the method for processing optical cable wiring information provided in the embodiment of the present disclosure is generally performed by the server 104. Accordingly, the optical cable wiring information processing apparatus is generally provided in the server 104.

It should be understood that the number of terminal devices, servers and databases in fig. 1 is merely illustrative. There may be any number of terminal devices, servers, and databases, as desired for implementation.

Fig. 2 illustrates a flow 200 of one embodiment of an optical cabling information processing method of the present disclosure. As shown in fig. 2, the optical cable wiring information processing method of the present embodiment may include the steps of:

in step 201, wiring source data is acquired.

In the present embodiment, the execution subject of the optical cable wiring information processing method may acquire wiring source data in various ways. Here, the wiring source data may include drawing files, photo cable wiring BIM model data, photo cable wiring construction overhaul operation training videos, photo cable wiring construction overhaul specification documents, field pictures, and the like.

Step 202, analyzing the wiring source data to determine metadata of the optical cable wiring.

After the execution body obtains the wiring source data, the execution body can analyze the wiring source data to obtain metadata of the optical cable wiring. Specifically, if the wiring source data is a CAD drawing, since the CAD drawing defines related information in a "block" element and extension data manner, metadata about the optical cable wiring in the CAD drawing can be directly read in an analytic manner. If the wiring source data is an image, text recognition or object recognition can be performed on the image, and metadata of the optical cable wiring can be determined. If the wiring source data is a building information model, parsing can be directly implemented by a building information model processing application to determine metadata for the optical cable wiring.

Here, the metadata of the optical cable wiring may include information of an identification, a position, a length, an access port, and the like of the optical cable wiring. In this embodiment, metadata corresponding to different types of optical cable wirings may be different. Metadata obtained by analyzing different types of wiring source data is also different. For example, outdoor optical cable wiring CAD drawings define the end wiring and outdoor cable lengths and models within the directional box; the outdoor box wiring CAD defines information such as terminal wiring, model and the like in the XB box; the indoor combined list and the cabinet layout CAD diagram define indoor cabinet information and indoor cabinet layer information; the indoor combined internal wiring CAD defines the connection relation of the indoor cabinet combined internal wiring; the indoor side wiring CAD defines the connection relation information of the indoor cabinet terminal side wiring; the indoor power cable wiring CAD defines the type of the indoor power cable, the head and tail access ports of the power cable and other information.

In step 203, position information corresponding to the optical cable wire is determined.

The execution body may further determine the position information corresponding to the optical cable wiring obtained in step 202. Specifically, the execution body may map the wiring source data, and determine position information corresponding to the optical cable wiring according to the position of the area in the map. Or the execution body can acquire the position information acquired by the technician according to the wiring source data in the field, so that the position information corresponding to the optical cable wiring can also be obtained.

And 204, storing the wiring source data, the metadata and the position information to a preset platform.

After obtaining the source data and the corresponding position information of the optical cable wiring, the execution body can store the wiring source data and the information together to a preset platform. Here, the preset platform may be a service platform that provides support for the optical cable wiring information. The platform may allow different users to register and may assign different rights to different users. Different authority users can operate different wiring information, such as consulting, adding, searching and the like, on the wiring information. The database can provide data support for the preset platform, and can store structural data such as metadata and position information and unstructured data such as wiring source data.

According to the optical cable wiring information processing method provided by the embodiment of the disclosure, wiring source data can be automatically analyzed to obtain metadata and position information of the optical cable, and the metadata and the position information are correspondingly stored on the preset platform together with the wiring source data, so that unified informatization management and maintenance of the optical cable wiring information are realized, and the high-quality development requirement of rail transit can be met.

With continued reference to fig. 3, a flow 300 of another embodiment of a method of optical cabling information processing according to the present disclosure is shown. As shown in fig. 3, the method of the present embodiment may include the steps of:

in step 301, wiring source data is acquired.

In this embodiment, the wiring source data may include different types of source data. For example, unstructured data may be drawing files, photo cable wiring BIM model data, photo cable wiring construction overhaul operation training videos, photo cable wiring construction overhaul specification documents, field pictures and the like. Wherein, the drawing file may include a CAD drawing file, and the CAD drawing file may further include: an outdoor optical cable wiring CAD drawing, an outdoor box wiring CAD drawing, an indoor combined list and cabinet arrangement CAD drawing, an indoor combined internal wiring CAD drawing, an indoor side wiring CAD drawing and an indoor power cable wiring CAD drawing.

Step 302, determining metadata corresponding to each wiring drawing according to analysis rules of the wiring drawings.

The execution body can analyze the different types of wiring source data so as to determine the metadata corresponding to each wiring drawing. Specifically, the lengths and the types of the inner terminal wiring and the outdoor cable in the direction box can be determined by analyzing the outdoor optical cable wiring CAD graph; the information such as terminal wiring and model in the XB box can be determined by analyzing the outdoor box wiring CAD graph; indoor cabinet information and indoor cabinet layer information can be determined by analyzing the indoor combination list and the cabinet arrangement CAD graph; the connection relation of the internal wiring of the indoor cabinet combination can be determined by analyzing the CAD graph of the internal wiring of the indoor combination; the connection relation information of the indoor cabinet terminal side wiring can be determined by analyzing the indoor side wiring CAD graph; the type of the indoor power cable, the head-tail access port of the power cable and other information can be determined by analyzing the indoor power cable wiring CAD graph.

Or, the execution body may analyze the BIM to determine information such as the length and the connection relationship of the optical cable therein.

In this embodiment, the metadata may include outdoor box wiring data, outdoor optical cable data, indoor combined internal wiring data, indoor terminal side wiring data, indoor power cable data.

Step 303, map mapping is performed on the wiring source data to determine the position information corresponding to the optical cable.

The executing body may also acquire the positional information of the optical cable in various ways. Specifically, the position of each optical cable may be detected by a position detecting instrument. For example, the measurement can be obtained by moving a high-precision positioning measuring instrument through Real-time kinematic (RTK). Alternatively, the execution body may perform map mapping according to the wiring drawing, thereby determining the relative position of the optical cable.

Step 304, determining structured data according to the metadata and the position information; determining unstructured data according to the wiring source data; and storing the structured data and the unstructured data to a preset platform.

The execution body may determine the structured data according to the metadata and the location information, and specifically, the execution body may fill each metadata and the location information into a preset template, thereby obtaining the structured data. The structured data may include an outdoor portion and an indoor portion. The outdoor part may include an outdoor optical cable information table, an outdoor optical cable geographical information table, an outdoor box wiring information table, and an outdoor box geographical information table. The indoor portion may include an indoor cabinet information table, an indoor cabinet layer information table, an indoor cabinet combination internal wiring information table, an indoor cabinet terminal side wiring information table, and an indoor power cable information table.

Action and definition fields of each information table:

1) Outdoor optical cable information table

The outdoor optical cable information table is used for storing optical cable basic information.

The fields in the outdoor optical cable information table include: optical cable ID, home site ID, cable model, cable maximum core number, cable length, engineering stage (primary transition, secondary transition, …, formal), design unit related information, construction unit related information, optical cable manufacturer related information, laying time, and the like.

2) Outdoor optical cable geographic information table

The outdoor optical cable geographic information table is used for storing geographic positions of outdoor optical cables, one optical cable is described by a plurality of key points (including a starting point, a bending point 1, bending points 2, … and an end point), and the three-dimensional visual service can generate a three-dimensional visual model of the optical cable according to the data.

The key point geographic information can be obtained by measuring RTK moving high-precision positioning measuring instruments during cable laying, and can also be obtained by mapping the key point geographic information to a three-dimensional map according to a design CAD drawing and then marking according to the laying relative position.

The fields in the outdoor optical cable geographic information table include: outdoor optical cable keypoint ID, home site ID, corresponding optical cable ID, optical cable keypoint longitude, optical cable keypoint latitude, optical cable keypoint burial depth, and the like.

3) Outdoor box information table

The outdoor optical cable information table is used for storing basic information of the outdoor box.

The fields in the outdoor box information table include: outdoor box ID, home site ID, box model path design unit related information, construction unit related information, box manufacturer related information, erection time and the like.

4) Outdoor box wiring information table

The outdoor box wiring information table is used for storing connection relation information of the internal terminals of the outdoor box and the connecting optical cables and process management.

The fields in the outdoor box wiring information table include: outdoor box wiring ID, home site ID, corresponding outdoor box ID, connection box terminal number, connection outdoor cable ID, connection outdoor cable core number, engineering stage (including primary transition, secondary transition, …, formal), outdoor box wiring checking state (including unchecked, checked, abnormal), outdoor box wiring confirmation state (including unchecked, confirmed, abnormal), design unit related information, construction unit related information, maintenance responsible person information.

5) Outdoor box geographical information table

The outdoor box geographic information table is used for storing the geographic position of the outdoor box, the box is described by unique point coordinates, the point coordinates can be obtained by measuring an RTK mobile high-precision positioning measuring instrument when the box is erected, and can be obtained by measuring the RTK mobile high-precision positioning measuring instrument, and can also be obtained by mapping the RTK mobile high-precision positioning measuring instrument to a three-dimensional map according to a design CAD drawing and then marking according to the relative position.

The fields in the outdoor box geographic information table include: outdoor box point location ID, home site ID, corresponding outdoor box ID, outdoor box point location longitude, outdoor box point location latitude.

6) Indoor cabinet information table

The indoor cabinet information table is used for storing information of the indoor cabinet of the machine.

The table field includes: enclosure ID, home site ID, enclosure type (including: interlocking, section, coded, interface, branching, comprehensive), enclosure number (e.g., 11, QZ5, M2, JDK3, F1, QZH 2), etc.

7) Indoor cabinet layer information table

The indoor cabinet layer information table is used for storing information of each layer of the indoor cabinet.

The table field includes: layer ID, home site ID, home enclosure ID, layer number (e.g., 11-2, QZ5-1, M2-6, JDK3-4, F1-5, QZH 2-8), etc.

8) Indoor cabinet combined internal wiring information table

The indoor cabinet combined internal wiring information table is used for storing connection relation information between each combined relay contact and the side terminal of the indoor combined cabinet and managing flow.

The table field includes: the method comprises the steps of combining an internal wiring ID, a home station ID, a corresponding layer ID, a combined internal name (such as L, LU, 1LQ and the like), relay contact terminal numbers (such as 108-1, 209-61), combined side terminal numbers (such as 07-1, 06-13, 10-2), engineering stages (including primary transition, secondary transition, … and formal), combining an internal wiring checking state (including unchecked, checked and abnormal), design unit related information, construction unit related information, manufacturer related information and maintenance responsible person information.

9) Indoor cabinet terminal side wiring information table

The indoor cabinet terminal side wiring information table is used for storing connection relation information between the indoor cabinet side terminals and the side terminals and managing flow.

The table field includes: side wiring ID, home site ID, head terminal number full scale (e.g. 07-1, 06-13, 10-2), terminal number full scale (e.g. 02-11, 08-6, 10-12), engineering stage (including primary construction completion, primary transition, secondary transition, …, formal), side wiring checking state (including unchecked, checked, abnormal), combined internal wiring confirmation state (including unchecked, checked, abnormal), design unit related information, construction unit related information, manufacturer related information, maintenance responsible person information.

10 Indoor power cable information table

The indoor power cable information table is used for storing information from an indoor distribution board to a power supply screen and from the power supply screen to each piece of equipment or subsystem power cables.

The table field includes: the power cable ID, the power cable type (1: indoor distribution board to power screen, 2: power screen to each piece of equipment or subsystem), the power type (e.g., KZ, KF, DJZ, GGJF 220), the head port number, the tail port number, the cable type (e.g., 10XV-3X95, ZB-VVR-2X 16 mm), design unit related information, construction unit related information, manufacturer related information, maintenance responsible person information.

In some specific practices, the execution subject can update the information into the database table through the import service in the preset platform, so that metadata generation is realized. A schematic diagram of a metadata generation method may be seen in fig. 4.

In some optional implementations of this embodiment, each of the information tables may further include a field for characterizing a status of the optical cable, which is referred to herein as a status field. The execution body may determine the operation progress of the optical cable wiring according to the above-described status field. Specifically, the above-mentioned states may include a collation, validation state field. This field is used for the flow management of the wiring verification, and the verification and confirmation progress can be calculated by counting the ratio of the number of the verified and confirmed wirings to the number of all wirings in the yard.

In some optional implementations of this embodiment, each of the information tables may further include a field for characterizing a construction stage, which is referred to herein as a construction stage field. The execution body can confirm the current construction stage of the optical cable according to the construction stage field. It will be appreciated that the flow of processing of the optical cable distribution information may be different during different construction stages. For example, at the construction stage, if an optical cable wiring request is received, the actual wiring at the construction site may be compared with the wiring information stored in the preset platform. If so, a status field of the optical cable may be set. In the operation and maintenance stage, if the maintenance request of the optical cable is received, the maintenance operation can be started only after the optical cable is approved by a responsible person. And judging whether the wiring information stored in the preset platform is consistent or not again after overhauling, and setting a state field of the optical cable under the condition of consistency.

In this implementation, if the execution body detects a change in the engineering phase field, the status field is reset. Thus, after entering a new engineering stage, the wiring information needs to be checked again, so that the safety and the correctness of the wiring are ensured.

In some optional implementations of the present embodiment, if the execution body receives a collation request for the optical cable wiring, it is first necessary to determine the optical cable identification for which the collation request is intended. And then acquiring actual wiring information according to the identification. And comparing the actual wiring information with the corresponding standard wiring information stored in the preset platform. If the two are identical, the status field may be modified to a preset value. Here, the preset value indicates that the wiring information is checked. Here, in order to further secure the correctness of the wiring information, at least two status fields, that is, a collation status field and a verification status field, respectively, may be provided. The collation status field may be set to collated if the actual wiring information coincides with the corresponding standard wiring information stored in the preset platform. And prompts the user for further confirmation, and if a confirmation instruction sent by the user is received, the confirmation status field may be set to confirmed.

In this implementation, if the engineering stage field indicates that the current construction stage and construction transition stage are present, the execution subject may determine standard wiring information according to the metadata. If the engineering stage field indicates that the operation and maintenance stage is currently performed, overhaul of the optical cable wiring may be involved. If an optical cable wiring overhaul job application is received, the optical cable wiring overhaul job application may be sent to a designated user. The specified user can examine and approve the optical cable distribution maintenance operation application according to actual conditions. The execution body determines if the wiring maintenance work application has been approved. Here, the maintenance technician should initiate the above-mentioned optical cable wiring maintenance work application, and the manager should examine and approve the above-mentioned optical cable wiring maintenance work application. If the wiring maintenance operation application is approved, the standard wiring information can be determined according to the wiring information obtained by modifying the original wiring information according to the faults by the management personnel. After the construction is completed and at the transition stage, wiring data referred to by the "wiring verification" and the "wiring confirmation" are acquired from CAD drawings. In the operation and maintenance stage, the wiring data referred to by the wiring check and the wiring confirmation are wiring data modified by a business approver in the platform. See fig. 5 for a specific flow.

In this embodiment, the foregoing preset platform adopts a front-end and rear-end separation architecture, and is mainly composed of a data resource layer, a data service layer, an application service layer, and a presentation interaction layer 4, which can be flexibly deployed in the same or different servers, and the transmission of information in the platform can be through a public network or a track traffic dedicated secure data network, as shown in fig. 6. The platform is referred to herein as a rail transit optical cable distribution information management platform.

The data resource layer is used for storing structured data and unstructured data in the platform.

The structured data includes outdoor box wiring data, outdoor optical cable data, indoor cabinet wiring data, indoor power cable data, customized flow form data, user data, station data, role data, menu authority data, log data and the like, and can be stored in a Sql Server, mysql, oracle mainstream database and a part of domestic databases.

The user data, the station data, the role data and the menu authority data belong to basic information data, are used for platform user management and data authority allocation, can define different station access ranges and menu authorities for different roles, and allocate different roles for different level users, so that the data authority management based on RBAC (role-based access control) model is realized. In some specific practices, the above-described preset platform supports users of roles in 4, which may be referred to as "service initiation", "service approval", "wire verification", and "wire confirmation", respectively. After the service initiator sends the service form to the service approver for service approval or directly to the wiring check person according to the engineering stage.

Outdoor box wiring data, outdoor optical cable data, indoor cabinet wiring data and indoor power cable data are core data of the optical cable wiring information management platform and are collectively called as metadata.

The flow form data is used for recording the electronic form data in the flow management, and the flow form data structure can be customized according to the number of workflow nodes and the form flow sequence.

The log data records all operations of each user in the platform, and is convenient for backtracking the problems.

The unstructured data comprise drawing files, optical cable wiring BIM model data, optical cable wiring construction overhaul operation training videos, optical cable wiring construction overhaul specification documents, field pictures and the like. Unstructured data is stored in the server disk in the form of files.

The data service layer and the application service layer in the platform are developed based on Spring boot, and can be deployed with Windows Server and Linux Server environments in a cross-platform mode.

The data service layer provides structured data management services, unstructured data management services, wiring data consistency detection services, and data external interface services around all types of data of the platform.

The structured data management service adopts JDBC (Java database connection) technology to realize the butt joint of platform service and database, and realize the functions of adding, deleting, modifying, checking and batch importing and exporting structured data.

The unstructured data management service adopts binary data stream or WebSocket technology to realize 'access', 'uploading', 'downloading', 'compression' and the like to unstructured data according to unstructured data types.

The wiring data consistency detection service is used for consistency comparison analysis of the actual connection relation of the cabinet terminals and the drawing wiring connection relation.

The data external interface service is used for providing data access interfaces for other operation and maintenance systems or platforms, and only allows the other systems or platforms to read the data resources of the platform. For example: the wiring drawing generation system can access the metadata of the platform so as to generate a wiring CAD drawing.

The application service layer provides core operation applications required by the platform, and the core operation applications comprise: system management, basic information management, optical cable distribution information retrieval and check, flow control, three-dimensional visualization, CAD-web, timing tasks, form management, log management and other services.

The system management service is used for platform login and authorization operation and data authority distribution. After the user logs in, different menus and function buttons can be displayed according to the role data authority control platform of the user, data access ranges are allocated, and the like, so that data authority management based on RBAC (role-based access control) model is realized.

The basic information management service provides front-end display and management operation of basic information data in the structured data, and cooperates with the structured data management service to realize management of the basic information data of the platform.

The optical cable distribution information retrieval service provides for the rapid retrieval of outdoor optical cables, outdoor box wiring, indoor cabinet wiring data, and indoor power cable data. The user inputs the key information index in the front-end interface of the display interaction layer, and the target data can be retrieved. Particularly, for an area with good positioning signals, a user can acquire current geographic position data by virtue of positioning services of the front-end equipment of the display interaction layer, and wiring data of N (N > 0) optical cables or boxes closest to the current geographic position can be quickly searched.

The optical cable wiring information checking service provides logic implementation of wiring checking and confirming service, and is matched with the front-end display interaction layer to realize wiring checking and confirming operation service.

CAD-web service provides on-line browsing and annotating of CAD drawings. The open source WEB plug-in is adopted for development, after the DWG drawing is converted into a fixed format file, the online browsing and annotating of the drawing can be realized in a WebSocket mode according to the URL address of the converted file.

The three-dimensional visualization service is developed by adopting a Cesium open source three-dimensional map JavaScript engine, and provides front-end three-dimensional visualization of an optical cable wiring three-dimensional model, and assists in construction and maintenance of optical cable wiring.

The timed task may time the execution of a service. For example: and the method is combined with a WeChat or short message API, so that the daily fixed time can be used for sending prompt information such as wiring checking progress and the like to a user.

The flow control provides flow management of the optical cable wiring information, integrates an open source WEB flow engine, and controls the flow of the information management flow at different nodes. For example: the form management provides a front end online dragging design of the form, and the job form can be customized according to the user requirement.

The log management provides log record and log data management services, and can store detailed data (including service type, calling method name, front-end and back-end request mode, operation terminal category, operator information, request parameters, return parameters and the like) of each operation of the user in a database.

The display interaction layer in the platform can be deployed at the mobile phone, the tablet and the computer end in a cross-platform manner and is used for platform login, deletion, modification, check, import, download of optical cable wiring data, wiring information flow management, and interaction of core functions such as browsing and management of resources such as CAD drawing, BIM model, documents and videos.

According to the optical cable wiring information processing method provided by the embodiment of the disclosure, maintenance and processing of optical cable wiring data can be realized through the preset platform, so that the accuracy and maintainability of the optical cable wiring information are improved.

With further reference to fig. 7, as an implementation of the method shown in the foregoing figures, the present disclosure provides an embodiment of an optical cable wiring information processing apparatus, which corresponds to the method embodiment shown in fig. 2, and which is particularly applicable to various electronic devices.

As shown in fig. 7, the optical cable wiring information processing apparatus 700 of the present embodiment includes: a source data acquisition unit 701, a metadata generation unit 702, a position determination unit 703, and an information processing unit 704.

The source data acquisition unit 701 is configured to acquire wiring source data.

The metadata generation unit 702 is configured to parse the wiring source data and determine metadata of the optical cable wiring.

The position determining unit 703 is configured to determine position information corresponding to the optical cable wiring.

An information processing unit 704 configured to store the wiring source data, the metadata, and the positional information to a preset platform.

In summary, in the technical scheme of the disclosure, maintenance and processing of the optical cable wiring data are realized through the preset platform, so that the accuracy and safety of the optical cable wiring are improved.

The foregoing description of the preferred embodiments of the present disclosure is not intended to limit the disclosure, but rather to cover all modifications, equivalents, improvements and alternatives falling within the spirit and principles of the present disclosure.

Claims (10)

1. An optical cable wiring information processing method, comprising:

acquiring wiring source data;

analyzing the wiring source data to determine metadata of the optical cable wiring;

determining position information corresponding to the optical cable wiring;

and storing the wiring source data, the metadata and the position information to a preset platform.

2. The method of claim 1, wherein the wiring source data comprises different types of wiring drawings; and

the analyzing the wiring source data to determine metadata of the optical cable wiring includes:

and determining metadata corresponding to each wiring drawing according to the analysis rule of the wiring drawing.

3. The method of claim 1, wherein the determining the location information corresponding to the optical cable wiring comprises:

and mapping the wiring source data to determine the position information corresponding to the optical cable.

4. The method of claim 3, wherein the storing the wiring source data, the metadata, and the location information to a preset platform comprises:

determining structured data according to the metadata and the position information;

determining unstructured data according to the wiring source data;

and storing the structured data and the unstructured data to the preset platform.

5. The method of claim 4, wherein the structured data comprises a status field; and

the method further comprises the steps of:

and determining the operation progress of the optical cable wiring according to the status field.

6. The method of claim 5, wherein the structured data comprises an engineering stage field; and

the method further comprises the steps of:

the status field is reset in response to detecting a change in the engineering stage field.

7. The method of claim 5, wherein the method further comprises:

acquiring actual wiring information in response to receiving a verification request for optical cable wiring;

and in response to determining that the actual wiring information is consistent with the corresponding standard wiring information stored in the preset platform, modifying the status field to a preset value.

8. The method of claim 7, wherein the method further comprises:

and determining the standard wiring information according to the metadata in response to the engineering stage field indicating that the construction stage and the construction transition stage are currently performed.

9. The method of claim 7, wherein the method further comprises:

determining whether the wiring maintenance operation application passes the trial batch or not in response to the engineering stage field indicating the current operation and maintenance stage and receiving the optical cable wiring maintenance operation application;

and in response to determining that the wiring maintenance operation application is approved, determining the standard wiring information according to the wiring information obtained after the user approving the wiring maintenance operation application modifies the original wiring information according to the fault.

10. An optical cable wiring information processing apparatus comprising:

a source data acquisition unit configured to acquire wiring source data;

a metadata generation unit configured to parse the wiring source data and determine metadata of the optical cable wiring;

a position determining unit configured to determine position information corresponding to the optical cable wiring;

an information processing unit configured to store the wiring source data, the metadata, and the positional information to a preset platform.