CN113836248A - Communication line emergency repair method and equipment based on Internet of things and computer readable storage medium - Google Patents

Abstract

The application relates to a communication line rush-repair method based on the Internet of things, which comprises the following steps: acquiring optical cable laying information and displaying a communication optical cable laying diagram and an optical cable routing distribution diagram on a Geographic Information System (GIS) map; acquiring position information of each cable well, and displaying a cable well distribution diagram on a Geographic Information System (GIS) map; combining the communication optical cable laying diagram, the optical cable routing distribution diagram and the cable well distribution diagram to generate a cable first-aid repair information diagram; acquiring optical cable fault information in real time, and calculating the geographical position information of the optical cable fault point according to the routing distribution map and a preset fault point positioning algorithm; acquiring position information of a plurality of cable wells near an optical cable fault point, measuring and calculating the pipeline distance between each cable well and the optical cable fault point, and selecting an emergency repair inlet; and sending the position information of the emergency repair inlet to an idle emergency repair group. The communication line emergency repair current situation in the current underground pipeline can be effectively improved, and the effect of improving the optical cable emergency repair efficiency is achieved.

Description

Communication line emergency repair method and equipment based on Internet of things and computer readable storage medium

Technical Field

The application relates to the technical field of communication line maintenance, in particular to a communication line rush-repair method and equipment based on the Internet of things and a computer readable storage medium.

Background

The communication line is a path for ensuring information transfer. At present, the cable in the long-distance trunk line mainly uses a large-core optical cable and other wireless lines such as a satellite, a microwave and the like. The provincial and intra-provincial long distance is also mainly optical cable, and is additionally provided with microwave and satellite circuits. With the large-scale application of optical fiber communication technology in power communication networks, the optical cable scale of the power communication network is rapidly enlarged, and the distribution of optical cable lines is more and more complicated. With the rapid development of communication, the importance of a line is greater and greater, the influence caused by the occurrence of optical cable faults is greater and greater, and the requirements on line maintenance, fault first-aid repair and service restoration are higher and higher.

Therefore, when the optical cable is damaged due to human factors (mainly construction and excavation at a construction site), natural factors (animal damage, geological disasters and the like) or natural aging, an emergency repair group is required to perform emergency repair on the communication line with the fault in the fault area according to the fault position provided by the maintenance center. But present communication line often divide into wiring and pipeline wiring on the pole because of it is for satisfying city planning demand, and the most underground pipe wiring of following of main communication line in the city, and communication line maintenance in the underground pipe often need get into through the cable shaft, but the maintainer often can't confirm the best position of salvageing the cable shaft fast, consequently leads to communication line to salvage the degree of difficulty and improves greatly.

Aiming at the related technologies, the inventor considers that the difficulty of rush-repair of the communication line in the existing underground pipeline is high, so that the rush-repair efficiency of the optical cable is low.

Disclosure of Invention

In order to solve the problem that the optical cable rush-repair efficiency is low due to the fact that the communication line in an existing underground pipeline is difficult to rush-repair, the application provides a communication line rush-repair method and equipment based on the Internet of things and a computer readable storage medium.

In a first aspect, the application provides a communication line rush-repair method based on the internet of things, which adopts the following technical scheme:

a communication line emergency repair method based on the Internet of things comprises the following steps:

establishing an optical cable information platform, acquiring optical cable laying information, and displaying a communication optical cable laying diagram and an optical cable routing distribution diagram on a Geographic Information System (GIS) map;

acquiring position information of each cable well, and displaying a cable well distribution diagram on a Geographic Information System (GIS) map;

calibrating the optical cable laying diagram by taking the cable well distribution diagram as a reference, and combining the communication optical cable laying diagram, the optical cable routing distribution diagram and the cable well distribution diagram to generate a cable first-aid repair information diagram;

the optical cable information platform acquires optical cable fault information in real time, and calculates the geographical position information of the optical cable fault point according to the routing distribution map and a preset fault point positioning algorithm;

acquiring position information of a plurality of cable wells near an optical cable fault point, measuring and calculating the pipeline distance between each cable well and the optical cable fault point according to an electric cable emergency repair information diagram, and selecting an emergency repair inlet;

and the optical cable information platform sends the position information of the emergency repair inlet and the optical cable fault point to an idle emergency repair group.

By adopting the technical scheme, the optical cable laying information and the cable well position information are arranged by establishing the optical cable information platform, the optical cable laying information and the cable well position information are combined and overlapped to be displayed on a Geographic Information System (GIS) map in real time, the method is visual and simple, the communication line is convenient to monitor and maintain, meanwhile, the cable well position is positioned, when an optical cable fault occurs, an optimal emergency repair inlet is matched for emergency repair personnel in time, the emergency repair personnel do not need to search the cable well near an optical cable fault point, the current situation of emergency repair of the communication line in the existing underground pipeline is effectively improved, and the effect of improving the optical cable emergency repair efficiency is achieved.

Preferably, the acquiring the position information of each cable well specifically includes:

arranging a GPS positioning device on each cable well cover and periodically sending the position information of the well cover to the optical cable information platform through the GPS positioning device;

arranging an NFC serial number label on each cable well cover, and uploading real-time position information of the cable well cover to an optical cable information platform after reading the NFC serial number label of the cable well cover when an inspector periodically inspects the cable well;

and the optical cable information platform compares and calibrates the real-time position information of the cable well lid with the position information sent by the GPS positioning device of the cable well lid.

Through adopting above-mentioned technical scheme, periodically acquire the positional information of cable well lid through GPS positioner to regularly fix a position the calibration through patrolling and examining personnel, guaranteed that optical cable information platform can acquire the correct positional information of each cable well, when being convenient for when the optical cable fault point appears, optical cable information platform can in time inform the personnel of salvageing and repair the positional information who enters the mouth for it provides the best, guarantees optical cable maintenance efficiency. And through the setting of NFC serial number label, be convenient for patrol and examine personnel and acquire the relevant information of this cable shaft, promote it and patrol and examine efficiency.

Preferably, the optical cable information platform compares and calibrates the real-time position information of the cable well lid with the position information sent by the GPS positioning device of the cable well lid, and specifically includes the following steps:

a1: the optical cable information platform compares the real-time position information of the cable well cover with the position information sent by the GPS positioning device of the cable well cover, calculates an error value, and compares the error value with a reference threshold value preset in the optical cable information platform;

a2: when the error value is smaller than the preset reference threshold value, the position information of the cable well cover in the optical cable information platform is not updated by calibration;

a3: when the error value is larger than the preset reference threshold value, reading the NFC number label of the cable well cover through the inspection equipment of the inspection personnel again, acquiring real-time position information of the cable well cover, recalculating the error value to be compared with the preset reference threshold value, entering the step A2 when the error value is smaller than the preset reference threshold value, and entering the step A4 when the error value is larger than the preset reference threshold value;

a4: and the optical cable information platform updates the position information of the cable well cover into real-time position information read by inspection equipment of an inspector.

By adopting the technical scheme, the positioning and calibration are regularly carried out by inspection personnel, and when the error value is greater than the preset reference threshold value, the verification is carried out for a plurality of times, the correctness of the information can be effectively ensured, the optical cable information platform can acquire the correct position information of each cable well, when the optical cable fault point appears, the optical cable information platform can timely inform emergency repair personnel and provide the best position information of the emergency repair inlet for the emergency repair personnel, and the maintenance efficiency of the optical cable is ensured.

Preferably, the calibrating the cable laying diagram with the cable well distribution diagram as the reference specifically includes:

and (4) carrying out coincidence calibration on the punctuations representing the cable wells in the cable distribution diagram and the optical cable laying diagram on a Geographic Information System (GIS) map, and if the punctuations of the cable wells and the optical cable laying diagram do not coincide, sending error reports to responsible personnel.

Through adopting above-mentioned technical scheme to the cable well distribution map is calibrated to the optical cable and is laid the picture as the benchmark, can ensure the exactness of optical cable laying information, has effectively promoted optical cable and has salvageed efficiency simultaneously.

Preferably, the method of measuring and calculating the pipeline distance between each cable well and the optical cable fault point according to the cable emergency repair information diagram and selecting an emergency repair inlet specifically comprises the following steps: and calculating the pipeline distance between each cable well and the fault point of the optical cable according to the trend of the optical cable in the cable emergency repair information diagram, setting the cable well with the shortest distance as an emergency repair inlet, and setting the cable well with the next shortest distance as an alternative emergency repair inlet.

Through adopting above-mentioned technical scheme to the optical cable trend is the basis, and then calculates the pipeline distance of optical cable fault point rather than each cable shaft near, can effectively ensure to salvage the superiority of entry and optical cable fault point distance, reduces to salvage personnel and selects the inside comparatively complicated and longer phenomenon that leads to salvageing time of pipeline distance of the nearest actual pipeline of straight-line distance, reaches the effect that improves efficiency of salvageing.

Preferably, the optical cable information platform sends the position information of the emergency repair entrance and the optical cable fault point to an idle emergency repair group, and the method specifically comprises the following steps:

the optical cable information platform acquires the position of each emergency repair group in an idle state in real time;

calculating the distance between the emergency repair entrance and each emergency repair group, and generating the predicted commuting time when each emergency repair group reaches the emergency repair entrance;

and sending the emergency repair task and the emergency repair entrance position to an emergency repair group with the shortest expected commute time.

By adopting the technical scheme, the estimated commute time when the rush-repair group in each idle state reaches the rush-repair inlet is measured, the rush-repair task and the rush-repair inlet position are sent to the rush-repair group with the shortest estimated commute time, and the optical cable rush-repair efficiency is further effectively improved.

Preferably, the generating of the predicted commute time for each emergency repair team to arrive at the emergency repair entrance specifically includes: and the optical cable information platform is accessed into map navigation software, and the coordinates of the emergency repair group and the emergency repair entrance position are input into the map navigation software to obtain the predicted scheduled commuting time of different emergency repair groups in real time.

By adopting the technical scheme, the map navigation software can effectively combine real-time road condition information, and calculate the estimated commuting time when the emergency repair group in each idle state reaches the emergency repair entrance in real time, so that the estimated commuting time is more accurate, and the efficiency of optical cable emergency repair is further improved.

Preferably, the optical cable information platform acquiring the positions of the emergency repair groups in each idle state in real time specifically includes: the optical cable information platform acquires the position information of each first-aid repair group in real time; when the emergency repair group does not accept the emergency repair task, the emergency repair group marks the idle state, when the emergency repair group accepts the emergency repair task, the emergency repair group marks the working state, and when the emergency repair group applies for finishing the emergency repair task, the emergency repair group marks the idle state again.

Through adopting above-mentioned technical scheme, through marking each state of salvageing the group, effectively avoid same salvageing the group to carry out the phenomenon of two optical cable fault point salvage tasks simultaneously for each salvagees the group and divides the branch work clear and definite, and then promotes each salvagees the efficiency of salvageing of group.

In a second aspect, the application provides a communication line rush-repair device based on the internet of things, which adopts the following technical scheme:

an internet-of-things-based communication line emergency repair device comprising a memory and a processor, the memory having stored thereon a computer program that can be loaded by the processor and that executes the method of any one of claims 1 to 8.

By adopting the technical scheme, the optical cable laying information and the cable well position information are arranged by establishing the optical cable information platform, the optimal emergency repair inlet is matched for emergency repair personnel in time, the emergency repair personnel do not need to search the cable well near the optical cable fault point, the current situation of emergency repair of communication lines in the existing underground pipeline is effectively improved, and the effect of improving the efficiency of emergency repair of the optical cable is achieved.

In a third aspect, the present application provides a computer-readable storage medium, which adopts the following technical solutions:

a computer-readable storage medium storing a computer program which can be loaded by a processor and which performs the method of any one of claims 1 to 8.

By adopting the technical scheme, the optical cable laying information and the cable well position information are arranged by establishing the optical cable information platform, the optimal emergency repair inlet is matched for emergency repair personnel in time, the emergency repair personnel do not need to search the cable well near the optical cable fault point, the current situation of emergency repair of communication lines in the existing underground pipeline is effectively improved, and the effect of improving the efficiency of emergency repair of the optical cable is achieved.

In summary, the present application includes at least one of the following beneficial technical effects:

1. optical cable laying information and cable well position information are arranged by establishing an optical cable information platform, are combined and overlapped to be displayed on a Geographic Information System (GIS) map in real time, are visual and simple, and are convenient for monitoring and maintaining a communication line;

2. the position information of the cable well cover is periodically acquired through the GPS positioning device, and the inspection personnel regularly perform positioning calibration, so that the optical cable information platform can acquire correct position information of each cable well, when an optical cable fault point appears, the optical cable information platform can timely inform emergency repair personnel and provide position information of an optimal emergency repair inlet for the emergency repair personnel, and the optical cable maintenance efficiency is ensured;

3. by adopting the map navigation software, real-time road condition information can be effectively combined, and the expected commuting time when each emergency repair group in an idle state reaches an emergency repair inlet can be measured and calculated in real time, so that the expected commuting time is more accurate, and the efficiency of optical cable emergency repair is further improved.

Drawings

Fig. 1 is a flowchart of a communication line emergency repair method in an embodiment of the present application;

FIG. 2 is a flow chart of a method for obtaining wireline well location information in an embodiment of the present application;

FIG. 3 is a flow chart of a wireline well calibration in an embodiment of the present application;

fig. 4 is a flowchart of a method for allocating a repair task in an embodiment of the present application.

Detailed Description

The present application is described in further detail below with reference to figures 1-4.

The embodiment of the application discloses a communication line rush-repair method based on the Internet of things. Referring to fig. 1, a communication line emergency repair method based on the internet of things includes the following steps:

s1, obtaining optical cable laying information: establishing an optical cable information platform, acquiring optical cable laying information, and displaying a communication optical cable laying diagram and an optical cable routing distribution diagram on a Geographic Information System (GIS) map; the communication optical cable laying diagram comprises the laying trend of the optical cables, and the optical cable routing distribution diagram comprises the routing distribution condition of the communication optical cables. In addition, the optical cable laying information comprises optical cable laying line information, router distribution position information and optical cable line attribute information, wherein the optical cable line attribute information comprises optical cable line names, URLs, codes, types, lengths, commissioning states, commissioning time, maintenance periods, overhaul periods and remarks.

S2, acquiring cable well position information: acquiring position information of each cable well, and displaying a cable well distribution diagram on a Geographic Information System (GIS) map;

s3, generating a cable first-aid repair information graph: calibrating the optical cable laying diagram by taking the cable well distribution diagram as a reference, and combining the communication optical cable laying diagram, the optical cable routing distribution diagram and the cable well distribution diagram to generate a cable first-aid repair information diagram; specifically, the punctuations representing the cable wells in the cable distribution diagram are superposed with the optical cable laying diagram on a Geographic Information System (GIS) map for calibration, and if the punctuations of the cable wells are not superposed with the optical cable laying diagram, an error report is sent to a responsible person. The optical cable laying diagram is calibrated by taking the cable well distribution diagram as a reference, so that the correctness of the optical cable laying information can be ensured, and meanwhile, the optical cable rush-repair efficiency is effectively improved.

S4, calculating the position information of the optical cable fault point: the optical cable information platform acquires optical cable fault information in real time, and calculates the geographical position information of the optical cable fault point according to the routing distribution map and a preset fault point positioning algorithm; the positioning algorithm for the optical cable fault point is the prior art, and is not described herein.

S5, determining an emergency repair inlet: acquiring position information of a plurality of cable wells near an optical cable fault point, measuring and calculating the pipeline distance between each cable well and the optical cable fault point according to an electric cable emergency repair information diagram, and selecting an emergency repair inlet; specifically, the pipeline distance between each cable well and the optical cable fault point is calculated according to the trend of the optical cable in the cable emergency repair information diagram, the cable well with the shortest distance from the optical cable fault point is set as an emergency repair inlet, and the cable well with the next shortest distance from the optical cable fault point is set as an alternative emergency repair inlet. The advantage of can effectively ensure to salvage entry and optical cable fault point distance reduces salvage personnel and selects the inside comparatively complicated and longer phenomenon that leads to salvage the time of pipeline distance of the nearest actual pipeline of straight line distance, reaches the effect that improves salvage efficiency. Meanwhile, if the emergency repair inlet cannot enter due to an accident, emergency repair personnel can still perform emergency repair on the optical cable fault point through the alternative emergency repair inlet, and the timeliness of optical cable emergency repair is ensured.

S6, allocating a first-aid repair task: and the optical cable information platform sends the position information of the emergency repair inlet and the optical cable fault point to an idle emergency repair group. The optical cable laying information and the cable well position information are arranged by establishing an optical cable information platform, the optical cable laying information and the cable well position information are combined and overlapped to be displayed on a Geographic Information System (GIS) map in real time, the system is visual and concise, the monitoring and the maintenance of communication lines are convenient, meanwhile, the positioning of the cable well position is realized, when an optical cable fault occurs, an optimal emergency repair inlet is matched for emergency repair personnel in time, the emergency repair personnel do not need to search the cable well near an optical cable fault point, the current situation of emergency repair of the communication lines in the existing underground pipeline is effectively improved, and the effect of improving the optical cable emergency repair efficiency is achieved.

Referring to fig. 2, the step S2 of acquiring the location information of each cable well specifically includes:

l1, arranging a GPS positioning device on each cable well cover, and periodically sending the position information of the well cover to the optical cable information platform through the GPS positioning device;

l2, arranging NFC serial number labels on the cable well covers, and uploading real-time position information of the cable well covers to an optical cable information platform after reading the NFC serial number labels of the cable well covers when an inspector periodically inspects the cable wells;

and L3, comparing and calibrating the real-time position information of the cable well lid with the position information sent by the GPS positioning device of the cable well lid by the optical cable information platform. The position information of the cable well cover is periodically acquired through the GPS positioning device, and the regular positioning and calibration are carried out through inspection personnel, so that the correct position information of each cable well can be acquired by the optical cable information platform, when an optical cable fault point appears, the optical cable information platform can timely inform emergency repair personnel and provide the best position information of an emergency repair inlet for the emergency repair personnel, and the optical cable maintenance efficiency is ensured. And through the setting of NFC serial number label, be convenient for patrol and examine personnel and acquire the relevant information of this cable shaft, promote it and patrol and examine efficiency.

Referring to fig. 3, the step L3 specifically includes the following steps:

a1: the optical cable information platform compares the real-time position information of the cable well cover with the position information sent by the GPS positioning device of the cable well cover, calculates an error value, and compares the error value with a reference threshold value preset in the optical cable information platform;

a2: when the error value is smaller than the preset reference threshold value, the position information of the cable well cover in the optical cable information platform is not updated by calibration;

a3: when the error value is larger than the preset reference threshold value, reading the NFC number label of the cable well cover through the inspection equipment of the inspection personnel again, acquiring real-time position information of the cable well cover, recalculating the error value to be compared with the preset reference threshold value, entering the step A2 when the error value is smaller than the preset reference threshold value, and entering the step A4 when the error value is larger than the preset reference threshold value;

a4: and the optical cable information platform updates the position information of the cable well cover into real-time position information read by inspection equipment of an inspector. Meanwhile, the optical cable information platform sends out warning information to the inspection personnel so that the inspection personnel can overhaul the GPS positioning device of the cable well cover

Referring to fig. 4, the step S6 of sending the location information of the emergency repair entrance and the optical cable fault point to an idle emergency repair group by the optical cable information platform specifically includes the following steps:

b1: the optical cable information platform acquires the position of each emergency repair group in an idle state in real time;

b2: calculating the distance between the emergency repair entrance and each emergency repair group, and generating the predicted commuting time when each emergency repair group reaches the emergency repair entrance;

b3: and sending the emergency repair task and the emergency repair entrance position to an emergency repair group with the shortest expected commute time. The estimated commuting time of each emergency repair group in an idle state reaching an emergency repair inlet is measured, and the emergency repair task and the position of the emergency repair inlet are sent to the emergency repair group with the shortest estimated commuting time, so that the optical cable emergency repair efficiency is further effectively improved.

In addition, in step B1, the position where the cable information platform acquires the first-aid repair group in each idle state in real time specifically includes: the optical cable information platform acquires the position information of each first-aid repair group in real time; when the emergency repair group does not take the emergency repair task, marking the emergency repair group as an idle state; when the emergency repair group receives the emergency repair task, the emergency repair group marks the emergency repair task as a working state, and the emergency repair group marks the emergency repair task as an idle state again until the emergency repair group applies for finishing the emergency repair task. Through marking each state of salvageing the group, effectively avoid same salvageing the group to carry out the phenomenon of two optical cable fault point salvage tasks simultaneously for each salvagees the group and divides the work to make clear and definite, and then promotes each salvagees the efficiency of salvageing of group.

The step B2 of generating the expected commute time for each emergency repair team to arrive at the emergency repair entrance specifically includes: and the optical cable information platform is accessed into map navigation software, and the coordinates of the emergency repair group and the emergency repair entrance position are input into the map navigation software to obtain the predicted scheduled commuting time of different emergency repair groups in real time. By adopting the map navigation software, real-time road condition information can be effectively combined, and the expected commuting time when each emergency repair group in an idle state reaches an emergency repair inlet can be measured and calculated in real time, so that the expected commuting time is more accurate, and the efficiency of optical cable emergency repair is further improved.

The embodiment of the application also discloses communication line emergency repair equipment based on the Internet of things, which comprises a memory and a processor, wherein a computer program which can be loaded by the processor and can execute the method is stored in the memory.

The embodiment of the present application further discloses a computer-readable storage medium, which stores a computer program that can be loaded by a processor and executed in the method as described above, and the computer-readable storage medium includes, for example: various media capable of storing program codes, such as a usb disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk, or an optical disk.

The above examples are only used to illustrate the technical solutions of the present invention, and do not limit the scope of the present invention. It is to be understood that the described embodiments are merely exemplary of the invention, and not restrictive of the full scope of the invention. All other embodiments, which can be derived by a person skilled in the art from these embodiments without making any inventive step, fall within the scope of the present invention. Although the present invention has been described in detail with reference to the above embodiments, those skilled in the art may still make various combinations, additions, deletions or other modifications of the features of the embodiments of the present invention according to the situation without conflict, so as to obtain different technical solutions without substantially departing from the spirit of the present invention, and these technical solutions also fall within the protection scope of the present invention.

Claims (10)

1. A communication line emergency repair method based on the Internet of things is characterized by comprising the following steps:

establishing an optical cable information platform, acquiring optical cable laying information, and displaying a communication optical cable laying diagram and an optical cable routing distribution diagram on a Geographic Information System (GIS) map;

acquiring position information of each cable well, and displaying a cable well distribution diagram on a Geographic Information System (GIS) map;

calibrating the optical cable laying diagram by taking the cable well distribution diagram as a reference, and combining the communication optical cable laying diagram, the optical cable routing distribution diagram and the cable well distribution diagram to generate a cable first-aid repair information diagram;

the optical cable information platform acquires optical cable fault information in real time, and calculates the geographical position information of the optical cable fault point according to the routing distribution map and a preset fault point positioning algorithm;

acquiring position information of a plurality of cable wells near an optical cable fault point, measuring and calculating the pipeline distance between each cable well and the optical cable fault point according to an electric cable emergency repair information diagram, and selecting an emergency repair inlet;

and the optical cable information platform sends the position information of the emergency repair inlet and the optical cable fault point to an idle emergency repair group.

2. The communication line emergency repair method based on the internet of things according to claim 1, wherein the acquiring of the position information of each cable well specifically comprises:

arranging a GPS positioning device on each cable well cover and periodically sending the position information of the well cover to the optical cable information platform through the GPS positioning device;

arranging an NFC serial number label on each cable well cover, and uploading real-time position information of the cable well cover to an optical cable information platform after reading the NFC serial number label of the cable well cover when an inspector periodically inspects the cable well;

and the optical cable information platform compares and calibrates the real-time position information of the cable well lid with the position information sent by the GPS positioning device of the cable well lid.

3. The communication line emergency repair method based on the internet of things of claim 2, wherein the optical cable information platform compares and calibrates the real-time position information of the cable well lid with the position information sent by the GPS positioning device of the cable well lid, and specifically comprises the following steps:

a1: the optical cable information platform compares the real-time position information of the cable well cover with the position information sent by the GPS positioning device of the cable well cover, calculates an error value, and compares the error value with a reference threshold value preset in the optical cable information platform;

a2: when the error value is smaller than the preset reference threshold value, the position information of the cable well cover in the optical cable information platform is not updated by calibration;

a3: when the error value is larger than the preset reference threshold value, reading the NFC number label of the cable well cover through the inspection equipment of the inspection personnel again, acquiring real-time position information of the cable well cover, recalculating the error value to be compared with the preset reference threshold value, entering the step A2 when the error value is smaller than the preset reference threshold value, and entering the step A4 when the error value is larger than the preset reference threshold value;

a4: and the optical cable information platform updates the position information of the cable well cover into real-time position information read by inspection equipment of an inspector.

4. The communication line emergency repair method based on the internet of things according to claim 1, wherein the calibration of the cable laying diagram with the cable well distribution diagram as a reference specifically comprises:

and (4) carrying out coincidence calibration on the punctuations representing the cable wells in the cable distribution diagram and the optical cable laying diagram on a Geographic Information System (GIS) map, and if the punctuations of the cable wells and the optical cable laying diagram do not coincide, sending error reports to responsible personnel.

5. The communication line emergency repair method based on the internet of things according to claim 1, wherein the step of measuring and calculating the pipeline distance between each cable well and the optical cable fault point according to the cable emergency repair information graph and selecting an emergency repair inlet specifically comprises the steps of: and calculating the pipeline distance between each cable well and the fault point of the optical cable according to the trend of the optical cable in the cable emergency repair information diagram, setting the cable well with the shortest distance as an emergency repair inlet, and setting the cable well with the next shortest distance as an alternative emergency repair inlet.

6. The communication line emergency repair method based on the internet of things of claim 1, wherein the step of sending the position information of the emergency repair entrance and the optical cable fault point to an idle emergency repair group by the optical cable information platform specifically comprises the following steps:

the optical cable information platform acquires the position of each emergency repair group in an idle state in real time;

calculating the distance between the emergency repair entrance and each emergency repair group, and generating the predicted commuting time when each emergency repair group reaches the emergency repair entrance;

and sending the emergency repair task and the emergency repair entrance position to an emergency repair group with the shortest expected commute time.

7. The communication line emergency repair method based on the internet of things of claim 6, wherein the generating of the predicted commute time for each emergency repair group to reach the emergency repair entrance specifically comprises: and the optical cable information platform is accessed into map navigation software, and the coordinates of the emergency repair group and the emergency repair entrance position are input into the map navigation software to obtain the predicted scheduled commuting time of different emergency repair groups in real time.

8. The communication line emergency repair method based on the internet of things according to claim 6, wherein the optical cable information platform acquiring the positions of emergency repair groups in each idle state in real time specifically comprises: the optical cable information platform acquires the position information of each first-aid repair group in real time; when the emergency repair group does not take the emergency repair task, marking the emergency repair group as an idle state; when the emergency repair group receives the emergency repair task, the emergency repair group marks the emergency repair task as a working state, and the emergency repair group marks the emergency repair task as an idle state again until the emergency repair group applies for finishing the emergency repair task.

9. The utility model provides a communication line salvagees equipment based on thing networking which characterized in that: comprising a memory and a processor, said memory having stored thereon a computer program which can be loaded by the processor and which performs the method of any of claims 1 to 8.

10. A computer-readable storage medium characterized by: a computer program which can be loaded by a processor and which performs the method according to any one of claims 1 to 8.

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