CN113409482B - Optical cable line inspection monitoring and working quantification assessment method - Google Patents

Abstract

The invention discloses an optical cable line inspection monitoring and working quantification assessment method, which comprises the following steps: planning an inspection line corresponding to an optical cable inspection task based on the GIS map and combining with the optical cable resource line, and forming a GIS visible picture; analyzing the position of the optical cable resource line relative to the inspection area corresponding to the inspection line, performing route calculation according to the position, and reserving an optical cable resource line segment in the inspection area as an optical cable route line; positioning information is obtained, and track optimization is performed; performing coverage calculation on the optimized routing track and the optical cable routing line to obtain the routing progress proportion relative to the optical cable routing task, and displaying the routing track in real time based on a GIS visual picture; and calculating according to the positioning information to obtain a quantization index in the inspection process, and comprehensively evaluating the execution quality of the optical cable inspection task. By the technical scheme, the quality of the inspection process is improved, the inspection work is scientifically and quantitatively checked, and the tracking management cost of inspection personnel is reduced.

Description

Optical cable line inspection monitoring and working quantification assessment method

Technical Field

The invention relates to the technical field of telecommunication operation, in particular to an optical cable line inspection monitoring and working quantification assessment method.

Background

The optical cable faults have a large influence on the telecommunication industry, the optical cable line faults possibly cause large-area station breakage to bring bad influence on the customer satisfaction degree and society of operators, most optical cable line faults are caused by external force construction, a large amount of manpower and financial resources are input for line maintenance and inspection work for preventing the operators from suffering from the faults, supervision means of the line inspection work are limited, the operators can only go to inspection field tracking inspection at an irregular period, the quality and standardability of inspection work of maintenance staff cannot be considered, a large amount of input cannot acquire ideal operation and maintenance results, and particularly the line maintenance work is always stronger than process management and control and is more than post-inspection, so the technical means are needed to solve the problems of line inspection process management and control and quality analysis.

In addition, in the prior art, the process monitoring and quality data acquisition of the patrol personnel depend on the positioning capability of the mobile phone terminal, network signals and GPS signals are needed, and the situation that the positioning is inaccurate or the data acquisition fails due to the fact that signals are not available in certain road sections, so that the line patrol cannot be effectively monitored and the work examination cannot be carried out is avoided.

Disclosure of Invention

Aiming at the problems, the invention provides an optical cable line inspection monitoring and working quantification assessment method, which is used for planning an inspection route based on a GIS (geographic information system) visualization means, realizing real-time GIS visualization monitoring of an inspection task according to comparison and calculation between positioning information of a positioning terminal and an optical cable route, and simultaneously automatically updating the current inspection progress proportion, thereby improving the inspection process quality, reducing the optical cable fault rate, automatically acquiring inspection process data for monitoring and operating analysis, enabling inspection work to be scientifically and quantitatively assessed, and reducing the tracking management cost of inspection personnel.

In order to achieve the above purpose, the present invention provides a method for inspecting, monitoring and quantitatively checking the operation of an optical cable line, comprising: planning an inspection line corresponding to an optical cable inspection task based on the GIS map and combining with the optical cable resource line, and forming a GIS visible picture; analyzing the position of the optical cable resource line relative to a patrol area corresponding to the patrol line, performing route calculation according to the position, and reserving an optical cable resource line segment in the patrol area as an optical cable route line; positioning information of a positioning terminal held by a patrol personnel is obtained, and track optimization is carried out according to the positioning information; performing coverage calculation on the optimized routing track and the optical cable routing line in the routing area to obtain routing progress proportion relative to the optical cable routing task, and displaying the routing track in real time based on the GIS visual picture; and calculating and obtaining a quantization index in the inspection process according to the positioning information, and comprehensively evaluating the execution quality of the optical cable inspection task.

In the above technical solution, preferably, the method for inspecting, monitoring and quantitatively checking the operation of the optical cable line further includes: calculating the shortest distance between the positioning terminal and the optical cable route according to the positioning information; judging whether the shortest distance accords with a preset threshold range, so as to judge the patrol validity and the completion condition of the current position.

In the above technical solution, preferably, the specific process of analyzing the position of the optical cable resource line relative to the routing inspection area corresponding to the routing inspection line, and performing route calculation according to the position, and reserving the optical cable resource line segment in the routing inspection area as the optical cable route line includes:

determining a patrol area according to the patrol line and the geographic information of the GIS map; judging whether the optical cable resource line is in the inspection area point by point, specifically: for each point on the optical cable resource line, if the current point is in the inspection area, judging whether the previous point is in the inspection area, if so, storing the current point, and if not, taking coordinates of the point intersecting with the inspection area and creating a line segment; if the current point is not in the inspection area, judging whether the previous point is in the inspection area, if so, taking and storing coordinates of points intersected with the inspection area, if not, judging whether the current point is intersected with the inspection area, if so, calculating coordinates of the intersection point, and storing the coordinates of the intersection point to a newly built line segment; fitting the saved points and the newly-built line segments to form the optical cable routing line.

In the above technical solution, preferably, the performing trajectory optimization according to the positioning information specifically includes: acquiring longitude and latitude, positioning time and inspection speed of an positioning point where the inspection personnel are located according to the positioning information; and analyzing according to the distance between adjacent positioning points and the inspection speed, removing the coincident points and the offset points, and completing the optimization of the inspection track.

In the above technical solution, preferably, the specific process of performing coverage calculation on the optimized routing track and the optical cable routing line in the routing area to obtain the routing progress ratio relative to the optical cable routing task includes: calculating the coverage length of the routing track relative to the optical cable routing line according to the routing track and a preset routing coverage radius; and counting the total length of the optical cable routing line, calculating the proportion of the coverage length relative to the optical cable routing line, and taking the proportion as the patrol progress proportion of the optical cable patrol task.

In the above technical solution, preferably, displaying the inspection track in real time based on the GIS visual image specifically includes: displaying the inspection track and the optical cable routing line as a new layer on the upper layer of the GIS visual picture; the positioning points and the inspection tracks are synchronously updated along with the positioning information, the original positioning points and the original inspection tracks are deleted, and the updated positioning points and the updated inspection tracks are displayed; the inspection line and the inspection track are respectively displayed in different colors.

In the above technical solution, preferably, the specific process of calculating the quantization index of the inspection process according to the positioning information and comprehensively evaluating the execution quality of the optical cable inspection task includes: judging whether the communication network of the positioning terminal is normal or not according to the updating frequency of the positioning point and the inspection speed; judging whether the current patrol personnel execute a task online or not according to comparison of the patrol track and the patrol line; calculating the actual patrol distance, patrol duration, patrol average speed, patrol highest speed and overspeed violation times of the current patrol personnel according to the positioning information and the patrol track; and comprehensively evaluating the execution quality of the current inspection task according to a preset quality evaluation method.

In the above technical solution, preferably, the real-time inspection speed of the current inspection personnel is calculated according to the positioning information, and when the real-time inspection speed exceeds the preset upper limit of the inspection speed, the inspection violation information is sent to the current inspection personnel, and meanwhile, the manager is notified, and the inspection violation information is recorded for subsequent inspection.

In the above technical solution, preferably, the method for inspecting, monitoring and quantitatively checking the operation of the optical cable line further includes: tracking and replaying the inspection process of the inspector according to the inspection speed of the current inspector in the whole inspection track and the equal proportion of the inspection speed; and displaying the inspection distance, the inspection duration and the inspection speed index on any inspection track point selected in the playback inspection process.

In the above technical solution, preferably, the method for inspecting, monitoring and quantitatively checking the operation of the optical cable line further includes: and generating a data report from the routing track, the optical cable routing line, the positioning information of each positioning point and the quantization index of the routing process in the optical cable routing task, and generating a routing report of the current routing personnel aiming at the optical cable routing task according to the data report.

Compared with the prior art, the invention has the beneficial effects that: based on GIS visual means planning inspection route, according to the contrast and calculation between positioning information and the optical cable route of locating terminal, realize the real-time GIS visual control of inspection task, the automatic current progress proportion of patrolling and examining that updates simultaneously to improve inspection process quality, thereby reduced the optical cable fault rate, automatic acquisition inspection process data monitor and operation analysis, make inspection work obtain scientific, quantitative examination, reduced inspection personnel's tracking management cost.

Drawings

FIG. 1 is a schematic flow chart of an optical cable line inspection monitoring and working quantification assessment method disclosed in an embodiment of the present invention;

FIG. 2 is a schematic diagram of an example of a patrol circuit according to an embodiment of the present invention;

FIG. 3 is a schematic illustration of an example of a patrol trace disclosed in an embodiment of the present invention;

FIG. 4 is a schematic diagram of an example of route computation disclosed in one embodiment of the invention;

FIG. 5 is a schematic flow chart of inspection trace optimization according to an embodiment of the present invention;

FIG. 6 is a schematic diagram illustrating an example of overlay calculation in a patrol schedule according to an embodiment of the present invention;

FIG. 7 is a schematic illustration of an example of a patrol report disclosed by an embodiment of the invention.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are some embodiments of the present invention, but not all embodiments of the present invention. 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.

The invention is described in further detail below with reference to the attached drawing figures:

as shown in fig. 1, the method for monitoring and quantitatively evaluating the inspection of an optical cable line according to the present invention includes: planning an inspection line corresponding to an optical cable inspection task based on the GIS map and combining with the optical cable resource line, and forming a GIS visible picture; analyzing the position of the optical cable resource line relative to the inspection area corresponding to the inspection line, performing route calculation according to the position, and reserving an optical cable resource line segment in the inspection area as an optical cable route line; positioning information of a positioning terminal held by a patrol personnel is obtained, and track optimization is performed according to the positioning information; performing coverage calculation on the optimized routing track and the optical cable routing line in the routing area to obtain routing progress proportion relative to an optical cable routing task, and displaying the routing track in real time based on a GIS visual picture; and calculating according to the positioning information to obtain a quantization index in the inspection process, and comprehensively evaluating the execution quality of the optical cable inspection task.

In the embodiment, the routing inspection route is planned based on the GIS visualization means, real-time GIS visualization monitoring of the routing inspection task is realized according to comparison and calculation between the positioning information of the positioning terminal and the optical cable routing route, and meanwhile, the current routing inspection progress proportion is automatically updated, so that the quality of the routing inspection process is improved, the optical cable fault rate is reduced, the routing inspection process data are automatically acquired to monitor and operate and analyze, the routing inspection work is scientifically and quantitatively inspected, and the tracking management cost of routing inspection personnel is reduced.

As shown in fig. 2 and fig. 3, specifically, the capability of the GIS picture is used to plan a patrol route, support the real-time location of the investigation site or the searching and locating of the target area of interest, map and provide api to modify the area, and accurately record the target area. And displaying a corresponding effective area when a user executes a patrol task, then displaying an optical cable resource layer through a GIS (geographic information system) visualization capability by inquiring optical cable resources associated with the area, realizing the optical cable resource route in the extraction area through a GIS line-surface intersection algorithm when the patrol is executed, extracting a line guide serving as line patrol, calculating the patrol optical cable mileage, the patrol predicted path mileage and the like according to the patrol area.

The method comprises the steps that a patrol personnel performs positioning through a mobile phone or a positioning terminal, and adopts a native GPS positioning when the mobile phone is positioned, so that partial mobile phone GPS positioning inaccuracy is considered, and network positioning is supported simultaneously when GPS signals are weak so as to improve the accuracy of patrol track acquisition; when the positioning terminal is used for positioning, professional positioning equipment is adopted, a mobile phone is associated with the equipment, and the longitude and latitude of the positioning equipment are obtained in real time through an interface and stored; continuous positioning is carried out in the inspection process, the positioning interval can be set in a self-defined mode, preferably 5-10 seconds is set, the high-density track, namely the inspection track with a short distance, can be periodically uploaded to the management system, and meanwhile, the automatic uploading and track saving of the system after the completion of the card punching can be realized through manual card punching.

In the foregoing embodiment, preferably, the method for inspecting, monitoring and quantitatively evaluating the operation of the optical cable line further includes: calculating the shortest distance between the positioning terminal and the optical cable route according to the positioning information; judging whether the shortest distance accords with a preset threshold range so as to judge the patrol validity and the completion condition of the current position. If the shortest distance does not accord with the preset threshold range, the current position of the inspection personnel is not in the inspection area, and the inspection of the optical cable cannot be effectively realized.

In the above embodiment, when the inspection area is planned, the optical cable resource line information in the inspection area needs to be saved, so that the layer display and rendering are required to be performed when the inspection is performed, only the paragraphs in the area need to be saved, and in order to prevent the breakpoint, the points where the line surfaces intersect need to be saved.

Therefore, as shown in fig. 4, preferably, the specific process of analyzing the position of the optical fiber resource line relative to the routing inspection area corresponding to the routing inspection line, and performing the routing calculation according to the position, and reserving the optical fiber resource line segment in the routing inspection area as the optical fiber routing line includes:

determining a patrol area according to the geographical information of the patrol line and the GIS map;

when the picture of the inspection area is stored, the layer adaptive amplification can only display the level of the whole inspection area, then all optical cable sections of the level are inquired,

judging whether the optical cable resource line is in the inspection area point by point, specifically: for each point on the cable resource line, each point is divided into two cases:

if the current point is in the inspection area, judging whether the previous point is in the inspection area, if so, storing the current point, and if not, taking coordinates of the point intersecting with the inspection area and creating a line segment;

if the current point is not in the inspection area, judging whether the previous point is in the inspection area, if so, taking and storing the coordinates of the points intersected with the inspection area, if not, judging whether the current point is intersected with the inspection area, if so, calculating the coordinates of the intersection points, and storing the coordinates of the intersection points to a newly built line segment; and fitting the saved points and the newly-built line segments to form the optical cable routing line.

As shown in fig. 5, in the above embodiment, preferably, performing trajectory optimization according to positioning information specifically includes: acquiring longitude and latitude, positioning time and inspection speed of an positioning point where an inspection personnel is located according to the positioning information; and analyzing according to the distance between adjacent positioning points and the inspection speed, removing the coincident points and the offset points, and completing the optimization of the inspection track.

As shown in fig. 6, in the foregoing embodiment, preferably, the specific process of performing coverage calculation on the optimized routing track and the optical cable routing line in the routing area to obtain the routing progress ratio relative to the optical cable routing task includes:

calculating the coverage length of the patrol track relative to the optical cable route line according to the patrol track and a preset patrol coverage radius, wherein the coverage radius can be set to be 100 meters, and the coverage radius can be set according to a specific implementation mode so as to realize the progress view of interface visualization;

counting the total length of the optical cable routing lines, calculating the proportion of the coverage length relative to the optical cable routing lines, and taking the proportion as the patrol progress proportion of the optical cable patrol task;

meanwhile, as the patrol track increases, the optical cable route coverage calculation is updated, so that the patrol progress proportion is continuously updated.

Wherein, the patrol schedule ratio=patrol coverage length/total length of optical cable route x 100%.

In the foregoing embodiment, preferably, displaying, in real time, the inspection track based on the GIS visual screen specifically includes:

the inspection track and the optical cable route are used as new layers to be displayed on the upper layer of the GIS visual picture;

synchronously updating the positioning points and the inspection tracks along with the positioning information, deleting the original positioning points and the original inspection tracks, and displaying the updated positioning points and the updated inspection tracks;

the inspection lines and the inspection tracks are respectively displayed in different colors, so that the completed inspection lines are distinguished from the unfinished lines through the colors, and the inspection progress of a user is clear at a glance.

In the foregoing embodiment, preferably, the specific process of calculating the quantization index of the inspection process according to the positioning information and comprehensively evaluating the execution quality of the optical cable inspection task includes:

judging whether the communication network of the positioning terminal is normal or not according to the updating frequency and the inspection speed of the positioning point;

judging whether the current patrol personnel execute the task on line according to the comparison of the patrol track and the patrol line, if the patrol track is consistent with the patrol line, the patrol personnel are considered to be in a state of executing the task on line, and if the patrol track is inconsistent with the patrol line, the patrol personnel are considered not to be in a state of executing the task on line;

according to the positioning information and the inspection track, calculating the quantization indexes such as the actual inspection distance, the inspection duration, the inspection average speed, the inspection highest speed, the overspeed violation number and the like of the current inspection personnel;

and comprehensively evaluating the execution quality of the current inspection task by adopting a preset quality evaluation method according to the quantization index.

In the above embodiment, preferably, the real-time inspection speed of the current inspection personnel is calculated according to the positioning information, and when the real-time inspection speed exceeds the preset upper limit of the inspection speed, for example, 40Km/h, the inspection violation information is sent to the current inspection personnel, and meanwhile, the management personnel is notified, and the inspection violation information is recorded for subsequent inspection, so that the management and control of the inspection process are enhanced.

In the foregoing embodiment, preferably, the method for inspecting, monitoring and quantitatively evaluating the operation of the optical cable line further includes:

tracking and replaying the inspection process of the inspector according to the current inspection speed of the inspector in the whole inspection track and the equal proportion of the inspection speed;

and displaying the inspection distance, the inspection time and the inspection speed index of the current point in the inspection process on the track point according to any selected inspection track point in the playback inspection process.

As shown in fig. 7, in the foregoing embodiment, preferably, the method for monitoring and quantitatively evaluating the inspection of the optical cable line further includes:

and generating a data report from the routing track, the optical cable routing line, the positioning information of each positioning point and the quantization index of the routing process in the optical cable routing task, and generating a routing report of the current routing personnel aiming at the optical cable routing task according to the data report.

According to the optical cable line inspection monitoring and workload assessment method provided by the embodiment, in the implementation process, the quality of the inspection process is improved by strengthening line inspection process control, the optical cable fault rate is reduced, and compared with 2019 in the same period, the optical cable fault in Guangzhou city in 2020 has a month fault number reduced by 28.3%, and the total fault number in the last half year is reduced as shown in the following table.

The optical cable line inspection monitoring and workload assessment method can achieve the following effects:

a) Reduces the influence of optical cable faults on customer production, and has obvious economic and social benefits

b) The effect of line maintenance work is improved, and the cost investment of optical cable resource barrier repair is greatly reduced.

c) The problem of tracking management cost of line inspection personnel is reduced, and one person can monitor one area.

In addition, the invention can be applied to the situations that pipelines and lines such as electric power, water conservancy, municipal administration and the like need to be subjected to line inspection.

The above is only a preferred embodiment of the present invention, and is not intended to limit the present invention, but various modifications and variations can be made to the present invention by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. The method for inspecting, monitoring and quantitatively checking the work of the optical cable line is characterized by comprising the following steps:

planning an inspection line corresponding to an optical cable inspection task based on the GIS map and combining with the optical cable resource line, and forming a GIS visible picture;

analyzing the position of the optical cable resource line relative to the inspection area corresponding to the inspection line, and performing route calculation according to the position, and reserving the optical cable resource line segment in the inspection area as an optical cable route line, wherein the specific process comprises the following steps:

determining a patrol area according to the patrol line and the geographic information of the GIS map;

judging whether the optical cable resource line is in the inspection area point by point, specifically:

for each point on the optical cable resource line, if the current point is in the inspection area, judging whether the previous point is in the inspection area, if so, storing the current point, and if not, taking coordinates of the point intersecting with the inspection area and creating a line segment;

if the current point is not in the inspection area, judging whether the previous point is in the inspection area, if so, taking and storing coordinates of points intersected with the inspection area, if not, judging whether the current point is intersected with the inspection area, if so, calculating coordinates of the intersection point, and storing the coordinates of the intersection point to a newly built line segment;

fitting the saved points and newly-built line segments to form the optical cable routing line;

the method comprises the steps of obtaining positioning information of a positioning terminal held by a patrol personnel, and performing track optimization according to the positioning information, and specifically comprises the following steps:

acquiring longitude and latitude, positioning time and inspection speed of an positioning point where the inspection personnel are located according to the positioning information;

analyzing according to the distance between adjacent positioning points and the inspection speed, removing overlapping points and offset points, and completing the optimization of the inspection track;

according to a preset routing inspection coverage radius, performing coverage calculation on the optimized routing inspection track and the optical cable routing lines in the routing inspection area to obtain routing inspection progress proportion relative to the optical cable routing inspection task, and displaying the routing inspection track in real time based on the GIS visual picture;

and calculating and obtaining a quantization index in the inspection process according to the positioning information, and comprehensively evaluating the execution quality of the optical cable inspection task.

2. The method for monitoring and quantitatively evaluating the operation of the optical cable line according to claim 1, further comprising:

calculating the shortest distance between the positioning terminal and the optical cable route according to the positioning information;

judging whether the shortest distance accords with a preset threshold range, so as to judge the patrol validity and the completion condition of the current position.

3. The method for monitoring and quantitatively evaluating the operation of an optical cable line according to claim 2, wherein the specific process of performing coverage calculation on the optimized routing track and the optical cable routing line in the routing area to obtain the routing progress ratio of the optical cable routing task comprises the following steps:

calculating the coverage length of the routing track relative to the optical cable routing line according to the routing track and a preset routing coverage radius;

and counting the total length of the optical cable routing line, calculating the proportion of the coverage length relative to the optical cable routing line, and taking the proportion as the patrol progress proportion of the optical cable patrol task.

4. The method for monitoring and quantitatively evaluating the inspection of the optical cable line according to claim 3, wherein the displaying the inspection track in real time based on the GIS visual image specifically comprises:

displaying the inspection track and the optical cable routing line as a new layer on the upper layer of the GIS visual picture;

the positioning points and the inspection tracks are synchronously updated along with the positioning information, the original positioning points and the original inspection tracks are deleted, and the updated positioning points and the updated inspection tracks are displayed;

the inspection line and the inspection track are respectively displayed in different colors.

5. The method for monitoring and quantitatively evaluating the operation of an optical cable line according to claim 3, wherein the specific process of calculating the quantitative index of the inspection process according to the positioning information and comprehensively evaluating the execution quality of the optical cable inspection task comprises the following steps:

judging whether the communication network of the positioning terminal is normal or not according to the updating frequency of the positioning point and the inspection speed;

judging whether the current patrol personnel execute a task online or not according to comparison of the patrol track and the patrol line;

calculating the actual patrol distance, patrol duration, patrol average speed, patrol highest speed and overspeed violation times of the current patrol personnel according to the positioning information and the patrol track;

and comprehensively evaluating the execution quality of the current inspection task according to a preset quality evaluation method.

6. The method for monitoring and quantitatively checking the operation of an optical cable line according to claim 5, wherein the real-time checking speed of a current checking person is calculated according to the positioning information, and when the real-time checking speed exceeds the upper limit of a preset checking speed, checking violation information is sent to the current checking person, meanwhile, a manager is notified, and the checking violation information is recorded for subsequent checking.

7. The method for monitoring and quantitatively evaluating the operation of the optical cable line according to claim 5, further comprising:

tracking and replaying the inspection process of the inspector according to the inspection speed of the current inspector in the whole inspection track and the equal proportion of the inspection speed;

and displaying the inspection distance, the inspection duration and the inspection speed index on any inspection track point selected in the playback inspection process.

8. The method for monitoring and quantitatively evaluating the operation of the optical cable line according to claim 7, further comprising:

and generating a data report from the routing track, the optical cable routing line, the positioning information of each positioning point and the quantization index of the routing process in the optical cable routing task, and generating a routing report of the current routing personnel aiming at the optical cable routing task according to the data report.