CN116881670A - Communication optical cable attachment checking method based on GIS map - Google Patents

Abstract

The invention discloses a communication optical cable attachment checking method based on a GIS map, and belongs to the technical field of optical cable attachment checking; carrying out calculation and integration of data with different dimensionalities on aspects of all individual communication optical cables with the same optical cable model to obtain individual checking influence coefficients, and analyzing and classifying the individual checking influence coefficients; the analysis data of the checking states of the individual communication optical cables in the earlier stage are calculated and integrated to analyze and classify the overall checking states of the communication optical cables with the same optical cable model, and dynamic alarm prompt can be carried out for the individual and overall checking and maintenance of the communication optical cables with the subsequent corresponding optical cable models. According to the invention, the data statistics is implemented on the processing behaviors attached to all the communication optical cables in the target area from different aspects, and the data preprocessing is implemented on all the counted data, so that all the data of the monitoring statistics are standardized and normalized, and the efficiency of the subsequent data calculation and analysis can be effectively improved.

Description

Communication optical cable attachment checking method based on GIS map

Technical Field

The invention relates to the technical field of optical cable attachment checking, in particular to a communication optical cable attachment checking method based on a GIS map.

Background

Communication optical cable attachment verification is a method for managing and monitoring the attachment condition of a communication optical cable by using a Geographic Information System (GIS) technology; the attachment of the communication optical cable refers to the process of fixing and installing the optical cable on equipment such as a pole tower, a cable well, a joint box and the like. In communication network construction and operation, the attachment of the optical cable has an important influence on communication quality and network performance.

Most of the existing communication optical cable attachment checking schemes stay on data statistics and data display when being implemented, only the communication optical cable attachment checking data of each time are recorded and the data display of the GIS map is updated; autonomous integrated analysis cannot be implemented on historical communication cable attachment verification data, so that dynamic prompt and management are implemented on the communication cable attachment verification of the same subsequent cable model, and flexibility and comprehensiveness of the communication cable attachment verification are poor.

Disclosure of Invention

The present invention aims to solve at least one of the technical problems existing in the prior art.

The aim of the invention can be achieved by the following technical scheme:

a communication optical cable attachment checking method based on a GIS map comprises the following steps:

carrying out data statistics on processing behaviors attached to all communication optical cables in a target area to obtain behavior statistical information, and carrying out data preprocessing on the behavior statistical information to obtain a behavior processing sequence;

synchronously updating the associated information attached to the communication optical cable at the corresponding position on the GIS map according to the behavior processing sequence, and carrying out monitoring analysis of different dimensionalities on the influence of the verification request corresponding to the communication optical cable of the same type at different positions according to the verification request signals received by the GIS map;

and carrying out dynamic alarm prompt on the same type of communication optical cable attachment verification at different positions according to the individual verification state analysis data and the overall verification state analysis data obtained by monitoring analysis.

Preferably, when data statistics is implemented on the processing behaviors of all the communication optical cable attachments in the target area, the geographic coordinates corresponding to the processed communication optical cable attachments are obtained;

acquiring a processing type of a processed communication optical cable attachment corresponding to a processing behavior and associating processing time, wherein the processing type comprises a new type, a maintenance type and a maintenance type; the optical cable model, the optical cable number and the installation time corresponding to the processed communication optical cable attachment are obtained;

and arranging and combining the geographical coordinates, the processing type and the processing time corresponding to the processed communication optical cable attachment, and the optical cable model, the optical cable number and the installation time corresponding to the communication optical cable attachment to obtain the behavior statistical information.

Preferably, when preprocessing data is implemented on the behavior statistical information, geographic coordinates corresponding to the processed communication optical cable attachment in the behavior statistical information are obtained, direction identification of the geographic coordinates and numerical values of longitude and latitude are extracted, and the geographic array is obtained by sequencing and combining and is set as a first identification mark;

acquiring the optical cable model and the processing type corresponding to the processed communication optical cable attachment, performing digital processing, and performing traversal matching on the optical cable model and the processing type with the corresponding optical cable model weight table and the processing type weight table respectively to acquire corresponding model weight and processing weight;

extracting the numerical value of the processing weight and the numerical value of the processing time, arranging the numerical values and the numerical values to be combined to obtain a processing array, and setting the processing array as a second identification mark;

extracting the numerical value of the model weight and the optical cable number, and arranging and combining the numerical value of the installation time to obtain an installation array and setting the installation array as a third identification mark;

the first, second and third signatures constitute a behavior processing sequence.

Preferably, when the associated information attached to the communication optical cable at the corresponding position on the GIS map is synchronously updated, the corresponding geographic position on the GIS map is obtained according to the first identification mark in the behavior processing sequence and marked as the selected position, and meanwhile, the updating of the data of the selected position is realized by adding one to the total maintenance times or adding one to the total maintenance times of the communication optical cable attached to the selected position according to the second identification mark and the third identification mark in the behavior processing sequence.

Preferably, when monitoring and analyzing the influence of the checking request corresponding to the same type of communication optical cable at different positions in different dimensions according to the checking request signal received by the GIS map, acquiring and analyzing the request type in the checking request data according to the checking request signal;

if the request type is the query type, generating a query request type; if the request type is the maintenance type, generating a maintenance request label; if the request type is the maintenance type, generating a maintenance request label;

the query request type, the maintenance request tag or the maintenance request tag form check analysis data corresponding to the check request data.

Preferably, monitoring and analyzing the influence of the maintenance request label or the maintenance request label in the check analysis data on the check request corresponding to the check request data;

obtaining the optical cable model and the corresponding model weight of the communication optical cable attached and checked in the checking request data, marking the model weight as a target model weight, performing traversal matching on the target model weight and the model weights related to all the optical cables in the GIS map, marking the optical cables corresponding to the matched same model weight as selected optical cables, numbering all the selected optical cables, and marking the optical cables as i, i=1, 2,3, … … and n; n is a positive integer;

and (3) acquiring the weight of the target model corresponding to the selected optical cable and marking the weight as XQi, acquiring the total maintenance times HZi and the total maintenance times XZi corresponding to different selected optical cables, and extracting the numerical value of each item of marked data and calculating and acquiring the individual checking influence coefficient Gy corresponding to the individual selected optical cable through the formula Gy= XQi × (HZi +2× XZi) when sequentially calculating and analyzing the abnormal influence corresponding to different selected optical cables.

Preferably, when the verification states of different selected optical cables in the aspects of self are analyzed in sequence according to the individual verification influence coefficients, the individual verification influence coefficients are compared with corresponding individual verification influence thresholds to obtain individual verification normal labels and state normal optical cables or individual verification abnormal labels and state abnormal optical cables;

and the individual checking influence coefficients of all the selected optical cables and corresponding individual checking normal labels or individual checking abnormal labels form individual checking state analysis data.

Preferably, counting the total number of the state-abnormal optical cables according to the individual checking abnormal labels in the individual checking state analysis data and marking the total number as the abnormal total number, calculating the ratio between the abnormal total number and the total number of the selected optical cables and setting the ratio as an overall checking influence coefficient;

and when the checking state of the whole aspect of the selected optical cable is analyzed according to the whole checking influence coefficient, comparing the whole checking influence coefficient with a corresponding whole checking influence threshold value to obtain whole checking state analysis data formed by the whole checking normal label and the whole checking abnormal label.

Preferably, when the dynamic alarm prompt is performed on the same type of communication optical cable attachment verification at different positions according to the individual verification state analysis data and the overall verification state analysis data, traversing the individual verification state analysis data and the overall verification state analysis data respectively, performing the same maintenance prompt on all the selected optical cables according to the overall verification abnormal labels obtained through traversing, and performing the same maintenance prompt on a plurality of state abnormal optical cables according to the overall verification normal labels obtained through traversing and a plurality of individual verification abnormal labels.

Compared with the prior art, the invention has the beneficial effects that:

according to the invention, through carrying out data statistics on the processing behaviors attached to all the communication optical cables in the target area from different aspects and carrying out data preprocessing on all the counted data, each item of data of the monitoring statistics is standardized and normalized, and the efficiency of subsequent data calculation and analysis can be effectively improved; the individual checking influence coefficients are obtained by carrying out calculation and integration on the data of different dimensions on all the individual communication optical cables of the same optical cable model, and the individual checking state types of different communication optical cables can be intuitively obtained and reliable local data support can be provided for the overall checking state analysis of the subsequent communication optical cables of the same optical cable model by analyzing and classifying the individual checking influence coefficients; the method and the device have the advantages that the analysis data of the inspection states of the individual communication optical cables in the early stage are calculated and integrated through the sub-total technical scheme to analyze and classify the overall inspection states of the communication optical cables with the same optical cable model, dynamic alarm prompt can be carried out for individual and overall inspection and maintenance of the communication optical cables with the subsequent corresponding optical cable models, and flexibility and comprehensiveness of the attachment inspection of the communication optical cables are improved.

Drawings

The invention is further described below with reference to the accompanying drawings.

Fig. 1 is a flow chart diagram of a communication optical cable attachment checking method based on a GIS map.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

As shown in fig. 1, the invention provides a communication optical cable attachment checking method based on a GIS map, comprising the following steps:

carrying out data statistics on processing behaviors attached to all communication optical cables in a target area to obtain behavior statistical information, and carrying out data preprocessing on the behavior statistical information to obtain a behavior processing sequence; comprising the following steps:

when data statistics is implemented on the processing behaviors of all the communication optical cable attachments in the target area, the target area can be a city or a region specifically, the area range can be determined according to the actual application scene, the geographic coordinates corresponding to the processed communication optical cable attachments are obtained, and the geographic coordinates can be represented by longitude and latitude;

acquiring a processing type of a processed communication optical cable attachment corresponding to a processing behavior and associating processing time, wherein the processing type comprises a new type, a maintenance type and a maintenance type; the representation of the processing time correspondence may be xxxx year/xx month/xx day;

the optical cable model, the optical cable number and the installation time corresponding to the processed communication optical cable attachment are obtained, and the representation corresponding to the installation time is the same as the representation corresponding to the processing time;

the method comprises the steps of arranging and combining geographic coordinates, processing types and processing time corresponding to processed communication optical cable attachment, and optical cable models, optical cable numbers and installation time corresponding to the processed communication optical cable attachment to obtain behavior statistical information;

when preprocessing the data of the behavior statistical information, obtaining the corresponding geographic coordinates of the processed communication optical cable attachment in the behavior statistical information, extracting the direction identification of the geographic coordinates and the numerical values of longitude and latitude, sequencing and combining to obtain a geographic array, and setting the geographic array as a first identification mark;

for example, 37 degrees 35 minutes north latitude and 79 degrees 42 minutes east longitude, the corresponding geographic array is [ N:37 DEG 35, E: 79 DEG 42];

acquiring the optical cable model and the processing type corresponding to the processed communication optical cable attachment, performing digital processing, and performing traversal matching on the optical cable model and the processing type with the corresponding optical cable model weight table and the processing type weight table respectively to acquire corresponding model weight and processing weight;

the optical cable model weight table is composed of a plurality of different optical cable models and corresponding model weights, one corresponding model weight is preset for the different optical cable models, and the specific numerical value of the model weight can be determined according to the influence of the application of the optical cable model weight table or according to the price of the corresponding optical cable;

the model weight is used for digitizing and differentially representing the text type optical cable models, so that data support in the type aspect can be provided for the optical cable state analysis corresponding to different subsequent optical cable models, and the accuracy of the optical cable state analysis of different models can be improved;

the construction mode of the processing type weight table is the same as that of the optical cable model weight table;

extracting the numerical value of the processing weight and the numerical value of the processing time, arranging the numerical values and the numerical values to be combined to obtain a processing array, and setting the processing array as a second identification mark;

for example, the processing weight has a value of 5, the processing time is 2020/06/01, and the corresponding geographic array is [5, 20200601];

extracting the numerical value of the model weight and the optical cable number, and arranging and combining the numerical value of the installation time to obtain an installation array and setting the installation array as a third identification mark;

for example, the model weight has a value of 20, the cable number has a value of 202032817, the processing time is 2020/01, and the corresponding geographic array is [20, 202032817, 20200101];

the first identification mark, the second identification mark and the third identification mark form a behavior processing sequence;

in the embodiment of the invention, the data statistics is implemented on the processing behaviors attached to all the communication optical cables in the target area from different aspects, and the data preprocessing is implemented on all the counted data, so that all the data of the monitoring statistics are standardized and normalized, and the efficiency of the calculation and analysis of the follow-up data can be effectively improved.

Synchronously updating the associated information attached to the communication optical cable at the corresponding position on the GIS map according to the behavior processing sequence, and carrying out monitoring analysis of different dimensionalities on the influence of the verification request corresponding to the communication optical cable of the same type at different positions according to the verification request signals received by the GIS map; comprising the following steps:

when the associated information of the communication optical cable attachment at the corresponding position on the GIS map is synchronously updated, the corresponding geographic position on the GIS map is obtained according to a first identification mark in the behavior processing sequence and marked as a selected position, and meanwhile, the updating of the selected position data is realized according to the fact that the total maintenance times of the communication optical cable attachment at the selected position are increased by one or the total maintenance times are increased by one according to a second identification mark and a third identification mark in the behavior processing sequence;

the specific optical cable at the selected position is determined according to the third identification mark, and the corresponding maintenance total times or maintenance total times of the specific optical cable are updated according to the second identification mark;

when monitoring and analyzing different dimensions of the influence of the verification request corresponding to the communication optical cables of the same type at different positions according to the verification request signals received by the GIS map, acquiring and analyzing the request type in the verification request data according to the verification request signals;

it should be noted that, the check request signal is generated when a worker inputs check request data including an optical cable model number, an optical cable number and a request type through a GIS map to implement a request query;

if the request type is the query type, generating a query request type; if the request type is the maintenance type, generating a maintenance request label; if the request type is the maintenance type, generating a maintenance request label;

the query request type, the maintenance request tag or the maintenance request tag form check analysis data corresponding to the check request data, and when monitoring and analyzing the influence of the maintenance request tag or the maintenance request tag in the check analysis data on the check request corresponding to the check request data;

it should be noted that, the verification request data is used for inquiring the position and related information of the maintenance or repair of the individual communication optical cable, unlike the prior art in which the maintenance is implemented on different communication optical cables only by fixed time, the embodiment of the invention can actively calculate and integrate the maintenance data and repair data of the individual communication optical cable with the same optical cable model to obtain the individual and integral verification state of the corresponding communication optical cable, so that the communication optical cable with different model can be dynamically maintained in a self-adaptive way;

obtaining the optical cable model and the corresponding model weight of the communication optical cable attached and checked in the checking request data, marking the model weight as a target model weight, performing traversal matching on the target model weight and the model weights related to all the optical cables in the GIS map, marking the optical cables corresponding to the matched same model weight as selected optical cables, numbering all the selected optical cables, and marking the optical cables as i, i=1, 2,3, … … and n; n is a positive integer;

acquiring the weight of a target model corresponding to the selected optical cable, marking the weight as XQi, acquiring the total maintenance times HZi and the total maintenance times XZi corresponding to different selected optical cables, extracting the numerical value of each item of marked data when sequentially performing calculation analysis on the abnormal influence corresponding to different selected optical cables, and calculating and acquiring the individual verification influence coefficient Gy corresponding to the individual selected optical cable through the formula Gy= XQi × (HZi +2× XZi);

it should be noted that the individual verification influence coefficient is a numerical value for integrating maintenance data and repair data in terms of the individual communication optical cable itself to analyze and evaluate the verification state of itself; the larger the individual checking influence coefficient is, the worse the checking state of the corresponding communication optical cable is;

when the checking states of different selected optical cables are analyzed in sequence according to the individual checking influence coefficients, the individual checking influence coefficients are compared with corresponding individual checking influence thresholds; the individual checking influence coefficient is obtained through training by the existing algorithm model or simulation by simulation software according to the historical maintenance big data of the corresponding optical cable model;

if the individual checking influence coefficient is not greater than the individual checking influence threshold, generating an individual checking normal label and marking the corresponding selected optical cable as a state normal optical cable;

if the individual checking influence coefficient is larger than the individual checking influence threshold, generating an individual checking abnormal label and marking the corresponding selected optical cable as a state abnormal optical cable;

the individual checking influence coefficients of all the selected optical cables and the corresponding individual checking normal labels or individual checking abnormal labels form individual checking state analysis data;

in the embodiment of the invention, the individual checking influence coefficients are obtained by carrying out calculation and integration on the data of different dimensions on all the individual communication optical cables of the same optical cable model, and the individual checking state types of different communication optical cables can be intuitively obtained and reliable local data support can be provided for the overall checking state analysis of the communication optical cables of the same optical cable model.

Counting the total number of the state abnormal optical cables according to the individual checking abnormal labels in the individual checking state analysis data, marking the total number as the abnormal total number, calculating the ratio between the abnormal total number and the total number of the selected optical cables, and setting the ratio as an integral checking influence coefficient;

when the checking state of the whole aspect of the selected optical cable is analyzed according to the whole checking influence coefficient, the whole checking influence coefficient is compared with a corresponding whole checking influence threshold value; the integral checking influence threshold is obtained by training an existing algorithm model or simulating by simulation software according to historical maintenance big data of all the optical cable models;

if the integral checking influence coefficient is not greater than the integral checking influence threshold, generating an integral checking normal label; if the overall checking influence coefficient is larger than the overall checking influence threshold, generating an overall checking abnormal label; the overall checking normal label acquires the overall checking abnormal label to form overall checking state analysis data;

in the embodiment of the invention, the analysis data of the checking state of the early-stage individual communication optical cable is calculated and integrated through the split-total technical scheme to analyze and classify the overall checking state of the communication optical cable with the same optical cable model, and dynamic alarm prompt can be carried out for the individual and overall checking and maintenance of the communication optical cable with the subsequent corresponding optical cable model; compared with the prior art, the method and the device only carry out single display and information prompt on the checking request data, the embodiment of the invention can realize more various and more efficient data expansion and utilization effects, so that the maintenance data and the maintenance data in different aspects are associated with each other, and the defect that the data in different aspects are isolated from each other in the conventional communication optical cable attachment checking is overcome.

Carrying out dynamic alarm prompt on the same type of communication optical cable attachment verification at different positions according to the individual verification state analysis data and the overall verification state analysis data obtained by monitoring analysis; comprising the following steps:

when the dynamic alarm prompt is carried out on the communication optical cable attachment verification of the same type at different positions according to the individual verification state analysis data and the overall verification state analysis data, traversing the individual verification state analysis data and the overall verification state analysis data respectively, carrying out the same maintenance prompt on all the selected optical cables according to the overall verification abnormal labels obtained through traversing, and carrying out the same maintenance prompt on a plurality of state abnormal optical cables according to the overall verification normal labels obtained through traversing and a plurality of individual verification abnormal labels.

In the embodiment of the invention, reliable data support is provided for the dynamic implementation of all the communication optical cable attachment checks of the same optical cable model by the individual checking state analysis data of the individual aspect and the overall checking state analysis data of the overall aspect, so that the flexibility and the comprehensiveness of the communication optical cable attachment checks are improved.

In addition, the formulas related in the above are all formulas for removing dimensions and taking numerical calculation, and are one formula closest to the actual situation obtained by collecting a large amount of data and performing software simulation.

In the several embodiments provided in the present invention, it should be understood that the disclosed method may be implemented in other manners. For example, the above-described embodiments of the invention are merely illustrative, and for example, the division of modules is merely a logical function division, and other manners of division may be implemented in practice.

The modules illustrated as separate components may or may not be physically separate, and components shown as modules may or may not be physical modules, i.e., may be located in one place, or may be distributed over a plurality of network modules. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of this embodiment.

In addition, each functional module in each embodiment of the present invention may be integrated into one processing module, or each module may exist alone physically, or two or more modules may be integrated into one module. The integrated modules may be implemented in hardware or in hardware plus software functional modules.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the essential characteristics thereof.

Finally, it should be noted that the above-mentioned embodiments are merely for illustrating the technical solution of the present invention and not for limiting the same, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications and equivalents may be made to the technical solution of the present invention without departing from the spirit and scope of the technical solution of the present invention.

Claims (9)

1. A communication optical cable attachment checking method based on a GIS map is characterized by comprising the following steps:

carrying out data statistics on processing behaviors attached to all communication optical cables in a target area to obtain behavior statistical information, and carrying out data preprocessing on the behavior statistical information to obtain a behavior processing sequence;

synchronously updating the associated information attached to the communication optical cable at the corresponding position on the GIS map according to the behavior processing sequence, and carrying out monitoring analysis of different dimensionalities on the influence of the verification request corresponding to the communication optical cable of the same type at different positions according to the verification request signals received by the GIS map;

and carrying out dynamic alarm prompt on the same type of communication optical cable attachment verification at different positions according to the individual verification state analysis data and the overall verification state analysis data obtained by monitoring analysis.

2. The GIS map-based communication cable attachment checking method as defined in claim 1, wherein when data statistics is implemented on the processing behaviors of all communication cable attachments in the target area, the geographic coordinates corresponding to the processed communication cable attachments are obtained;

acquiring a processing type of a processed communication optical cable attachment corresponding to a processing behavior and associating processing time, wherein the processing type comprises a new type, a maintenance type and a maintenance type; the optical cable model, the optical cable number and the installation time corresponding to the processed communication optical cable attachment are obtained;

and arranging and combining the geographical coordinates, the processing type and the processing time corresponding to the processed communication optical cable attachment, and the optical cable model, the optical cable number and the installation time corresponding to the communication optical cable attachment to obtain the behavior statistical information.

3. The GIS map-based communication optical cable attachment checking method is characterized by comprising the steps of obtaining geographic coordinates corresponding to the processed communication optical cable attachment in the behavior statistical information when the behavior statistical information is preprocessed, extracting direction identification of the geographic coordinates and numerical values of longitude and latitude, sequencing and combining to obtain a geographic array, and setting the geographic array as a first identification mark;

acquiring the optical cable model and the processing type corresponding to the processed communication optical cable attachment, performing digital processing, and performing traversal matching on the optical cable model and the processing type with the corresponding optical cable model weight table and the processing type weight table respectively to acquire corresponding model weight and processing weight;

extracting the numerical value of the processing weight and the numerical value of the processing time, arranging the numerical values and the numerical values to be combined to obtain a processing array, and setting the processing array as a second identification mark;

extracting the numerical value of the model weight and the optical cable number, and arranging and combining the numerical value of the installation time to obtain an installation array and setting the installation array as a third identification mark;

the first, second and third signatures constitute a behavior processing sequence.

4. The method for checking attachment of a communication cable based on a GIS map according to claim 3, wherein when the associated information of attachment of the communication cable in the corresponding position on the GIS map is updated synchronously, the corresponding geographic position on the GIS map is obtained according to the first identification mark in the behavior processing sequence and marked as the selected position, and meanwhile, the updating of the selected position data is realized by adding one to the total maintenance times or adding one to the total maintenance times of the communication cable in the selected position according to the second identification mark and the third identification mark in the behavior processing sequence.

5. The GIS map-based communication optical cable attachment checking method is characterized in that when monitoring and analyzing different dimensions are carried out on the checking request influences corresponding to the communication optical cables of the same type at different positions according to the checking request signals received by the GIS map, the request type in the checking request data is obtained and analyzed according to the checking request signals;

if the request type is the query type, generating a query request type; if the request type is the maintenance type, generating a maintenance request label; if the request type is the maintenance type, generating a maintenance request label;

the query request type, the maintenance request tag or the maintenance request tag form check analysis data corresponding to the check request data.

6. The GIS map-based communication optical cable attachment checking method according to claim 5, characterized in that when monitoring and analyzing the influence of the maintenance request label or the maintenance request label in the checking and analyzing data on the checking request corresponding to the checking request data;

obtaining the optical cable model and the corresponding model weight of the communication optical cable attached and checked in the checking request data, marking the model weight as a target model weight, performing traversal matching on the target model weight and the model weights related to all the optical cables in the GIS map, marking the optical cables corresponding to the matched same model weight as selected optical cables, numbering all the selected optical cables, and marking the optical cables as i, i=1, 2,3, … … and n; n is a positive integer;

and (3) acquiring the weight of the target model corresponding to the selected optical cable and marking the weight as XQi, acquiring the total maintenance times HZi and the total maintenance times XZi corresponding to different selected optical cables, and extracting the numerical value of each item of marked data and calculating and acquiring the individual checking influence coefficient Gy corresponding to the individual selected optical cable through the formula Gy= XQi × (HZi +2× XZi) when sequentially calculating and analyzing the abnormal influence corresponding to different selected optical cables.

7. The GIS map-based communication optical cable attachment checking method is characterized in that when checking states of different selected optical cables in turn are analyzed according to individual checking influence coefficients, the individual checking influence coefficients are compared with corresponding individual checking influence thresholds to obtain individual checking normal labels and state normal optical cables or individual checking abnormal labels and state abnormal optical cables;

and the individual checking influence coefficients of all the selected optical cables and corresponding individual checking normal labels or individual checking abnormal labels form individual checking state analysis data.

8. The GIS map-based communication cable attachment checking method according to claim 7, wherein the total number of the abnormal state optical cables is counted and marked as an abnormal total number according to the individual checking abnormal label in the individual checking state analysis data, and the ratio between the abnormal total number and the total number of the selected optical cables is calculated and set as an overall checking influence coefficient;

and when the checking state of the whole aspect of the selected optical cable is analyzed according to the whole checking influence coefficient, comparing the whole checking influence coefficient with a corresponding whole checking influence threshold value to obtain whole checking state analysis data formed by the whole checking normal label and the whole checking abnormal label.

9. The GIS map-based communication cable attachment checking method according to claim 8, wherein when the same type of communication cable attachment checking at different positions is dynamically alerted according to the individual checking state analysis data and the overall checking state analysis data, the individual checking state analysis data and the overall checking state analysis data are traversed respectively, the same maintenance prompt is implemented for all selected cables according to the overall checking abnormal label obtained by the traversing, and the same maintenance prompt is implemented for a plurality of state abnormal cables according to the overall checking normal label and the plurality of individual checking abnormal labels obtained by the traversing.