CN111352195B - Intelligent optical cable monitoring system for optical cable protection - Google Patents

Abstract

The invention discloses an intelligent optical cable monitoring system for optical cable protection, which comprises an RTU unit, an alarm processing unit, a transmission monitoring unit, a server and a retrieval unit, wherein the RTU unit comprises an RTU module, an execution module and a matching switching module, the RTU module is used for a tail end detection instrument and acquiring remote data, the remote data comprises optical power data, fault point position information, fault time and monitoring point codes, the execution module is used for executing switching of optical paths, the matching switching module is used for retrieving and matching corresponding standby optical paths, and the alarm processing unit is used for carrying out grading processing according to fault information; the invention acquires remote data through the RTU unit, performs damaged level grading processing on the optical power data through the alarm processing unit, acquires the remote data of all monitoring points in an abnormal state by the server, has high automatic acquisition statistical degree, is convenient for integrated management, and can arrange the maintenance sequence according to the level state information of each monitoring point.

Description

Intelligent optical cable monitoring system for optical cable protection

Technical Field

The invention belongs to the field of intelligent distribution, relates to a big data technology, and particularly relates to an intelligent optical cable monitoring system for optical cable protection.

Background

In recent years, with the development of communication technology, optical fiber communication has become the most mainstream communication mode at present, which has the characteristics of fast communication speed, large communication capacity, good confidentiality, strong adaptability and the like, is comparable to other communication modes and has unique superiority, but with the rapid development of optical fiber communication networks, optical cables laid among various cities are more and more, so that the difficulty of monitoring whether the optical cables are damaged is higher and more, the original traditional monitoring mode mainly adopts manual means, not only has slow speed, but also has large workload and very high cost, cannot adapt to the monitoring requirements of the existing optical cables, faces the increasing current situations of data transmission and language communication, and the increasing requirements of consumers on communication quality, how to maintain and monitor the existing huge optical cable network, can timely eliminate optical cable faults, and becomes a problem of more and more concern to researchers, because the optical cable is more fine, mainly comprises glass in the material, receives external environment very easily and destroys, receives the damage rate than higher, and because remote communication requires, lays the distance very long, and the manual work is maintained the degree of difficulty and the very long optical cable of cycle and is in case receives the destruction, and whole communication line all will receive the influence, if the trouble can not be handled in time, wireless communication and computer network just will be interrupted, cause serious influence to communication industry and people's normal life.

However, currently, the optical cable monitoring method is manual monitoring, the automation degree is not high enough, the optical cable monitoring method does not have the characteristics of integrated management, the all-weather real-time online dynamic monitoring of the optical fiber communication condition cannot be realized, once a problem occurs, the optical cable maintenance personnel cannot be informed in time, the instantaneity of fault elimination cannot be realized, the optical cable maintenance efficiency is poor, the optical cable monitoring system cannot be arranged in a grading way according to the fault condition, the optical cable monitoring system cannot be further arranged according to the fault time, the maintenance personnel can not arrange maintenance work according to the damaged grade, the big data statistics cannot be carried out, the fault number of monitoring points in all areas cannot be counted, the fault number of the monitoring points in different areas cannot be counted in a classification way, the optical path switching speed is not rapid enough, the functions of the current monitoring system are still limited to monitoring and alarming, after the, maintenance technicians are still required to arrive at the site for maintenance, when a fault occurs late at night, the maintenance efficiency is certainly greatly influenced, automatic switching between a main line and a standby line cannot be realized, the stability of communication cannot be ensured constantly, and further improvement and reinforcement are required; in order to solve the above-mentioned drawbacks, a solution is now provided.

Disclosure of Invention

The invention aims to provide an intelligent optical cable monitoring system for optical cable protection.

All the technical problems solved by the invention are as follows:

(1): how to obtain the data information of the monitoring points in the abnormal state in each area, and realize the integrated management of the monitoring points in the abnormal state in each area;

(2): arranging the priority of how to maintain the monitoring points according to the fault condition and the fault time;

(3): how to realize big data statistics, the number of faults of monitoring points in all areas is counted, and the number of faults of monitoring points in different areas is classified and counted;

(4): how to timely complete the switching of the standby circuit when the optical cable has a problem.

The purpose of the invention can be realized by the following technical scheme:

an intelligent optical cable monitoring system for optical cable protection comprises an RTU unit, an alarm processing unit, a transmission monitoring unit, a server and a retrieval unit;

the RTU unit comprises an RTU module, an execution module and a matching switching module, the RTU module is used for a terminal detection instrument and collecting remote data, the remote data comprises optical power data, fault point position information, fault time and monitoring point codes, the execution module is used for executing switching of light paths, the matching switching module is used for retrieving and matching corresponding standby light paths, the alarm processing unit is used for carrying out classification processing according to the fault information, and the specific classification processing steps are as follows:

the method comprises the following steps: obtaining optical power data, labeled G_qinOptical power is impairedThe situation is divided into three levels, one level of power threshold labeled G_qin1The secondary power threshold is marked G_qin2The three-level power threshold is marked G_qin3；

Step two: according to the power threshold value pair G_qinPerforming judgment processing;

when G is_qin＜G_qin1If so, judging the state to be a normal state;

when G is_qin1≤G_qin＜G_qin2Judging to be in a first-level state, namely a common state;

when G is_qin2≤G_qin＜G_qin3Judging the state to be a second-level state, namely a middle-level situation;

when G is_qin≥G_qin3Judging the state to be a three-level state, namely emergency;

step three: the primary state, the secondary state and the tertiary state are all abnormal states, and when the primary state, the secondary state and the tertiary state are in the abnormal states, the level state information, the fault point position information, the fault time and the monitoring point codes under the same monitoring point are used as unified loading data to be transmitted;

the server comprises a main server and a standby server, wherein the main server and the standby server respectively comprise an arrangement module, a data statistics module, a retrieval module, a maintenance processing module, a real-time synchronization module and a display, the arrangement module is used for carrying out priority arrangement processing according to the level state information, and the specific arrangement processing steps are as follows:

a01: respectively acquiring the level state information of each monitoring point;

a02: according to the level state information of each monitoring point, the priority is arranged according to a third-level state, a second-level state and a first-level state;

a03: further acquiring the fault time of different monitoring points in the same stage state;

a04: arranging monitoring points in the same level state according to the fault time of different monitoring points, wherein the monitoring points with earlier fault time are arranged in priority, and the monitoring points with later fault time are arranged behind the monitoring points in the same level state;

the data statistics module is used for carrying out data statistics on the monitoring points in the abnormal states, and the specific data statistics process comprises the following steps:

b01: counting once every time one monitoring point in abnormal state is obtained, counting the total number of the monitoring points in abnormal state, and marking as F_z；

B02: performing regional statistics according to the position information of the fault points of the abnormal state monitoring points, accumulating the monitoring points in the same region to obtain the total number of the abnormal state monitoring points in each region, and marking the total number as GQY_z；

B03: respectively counting the number of monitoring points in a first-level state, a second-level state and a third-level state, wherein the total number of the monitoring points in the first-level state is marked as X₁The total number of monitoring points of the secondary state is marked as X₂The total number of monitoring points of the three-level state is marked as X₃：

The retrieval module is used for acquiring the keyword information and performing retrieval matching according to the keyword information, and the specific retrieval matching processing steps are as follows:

s1: when the information input by the user is in a primary state, retrieving and matching all remote data related to the primary state;

s2: when the information input by the user is in the 'second-level state', retrieving and matching all remote data related to the second-level state;

s3: when the information input by the user is in the 'three-level state', retrieving and matching all remote data related to the three-level state;

s4: when the information input by the user is 'region characters', retrieving and matching all remote data in the region;

s5: when the information input by the user is 'failure time', retrieving and matching all remote data under the failure time;

the maintenance processing module is used for transmission and storage processing of remote data, and the specific processing steps comprise:

h01: sending the stored remote data arranged in sequence to the mobile terminal;

h02: acquiring a monitoring point maintenance code fed back by the mobile terminal;

h03: the monitoring point maintenance code is expressed as a monitoring point after maintenance is finished, and the monitoring point after maintenance is deleted from the stored data;

the alarm processing unit is also used for switching the standby optical path, and the specific processing steps are as follows:

u01: when the monitoring point is in an abnormal state, generating a switching signal, matching a standby optical path according to a monitoring point code provided by the monitoring point in the abnormal state, and switching the optical path through an execution module;

u02: when the monitoring point is in a normal state, the optical path switching is not carried out.

Further, the transmission monitoring unit is used for switching between the main server and the standby server, and the specific switching processing steps are as follows:

q01: monitoring the uploading data of the alarm processing unit in real time, and judging the uploading state of the alarm processing unit;

QQ 01: when the monitored uploaded data of the alarm processing unit is larger than 0KB, judging that the alarm processing unit is in a data uploading state, monitoring the downloaded data of the main server at the moment, and judging according to the downloaded data;

when the downloaded data is larger than 0KB, judging that the data transmitted by the main server is normal;

when the downloaded data is equal to 0KB, judging that the data transmitted by the main server is abnormal, connecting the alarm processing unit with the standby server at the moment, generating a fault signal, and sending the fault signal to the mobile terminal;

QQ 02: when the monitored data uploaded by the alarm processing unit is equal to 0KB, no processing is executed;

q02: and respectively acquiring the uploading speed and the downloading speed, and displaying data through a display.

Further, the real-time synchronization module is used for data synchronization between the main server and the standby server, and the specific data synchronization steps are as follows:

k01: data sharing is carried out between the main server and the standby server, and data in the main server and data in the standby server are collated in real time;

when the correction missing object is a main server, the standby server serves as a supplier and transmits missing data to the main server;

when the verification missing object is a standby server, the main server serves as a supplier and transmits missing data to the standby server;

k02: the data transmission and proofreading priority is that the main server transmits data to the standby server for proofreading, and judgment processing is carried out according to the real-time proofreading state of the data;

when the main server cannot perform data correction transmission, judging that the standby server is in a normal state, and sharing data to the mobile terminal;

and when the main server is in a normal data correction transmission state, judging that the main server is in a normal state, and sharing data from the main server to the mobile terminal.

Furthermore, the RTU unit is a remote terminal unit, the terminal detection instrument is connected with the alarm processing unit through the RTU unit, the alarm processing unit is connected with the server through the transmission monitoring unit, the alarm processing unit transmits the remote data to the transmission monitoring unit, and the transmission monitoring unit transmits the remote data to the server.

The invention has the following beneficial effects;

(1): according to the invention, remote data are acquired through the RTU unit, the remote data comprise optical power data, fault point position information, fault time and monitoring point codes, the optical power data are subjected to damaged level grading processing through the alarm processing unit, the primary state, the secondary state and the tertiary state are all abnormal states, when the monitoring points are in the abnormal states, the server can acquire the remote data of the monitoring points in all regions in the abnormal states, the automatic acquisition statistical degree is high, and the integrated management is convenient;

(2): the maintenance sequence is arranged according to the level state information of each monitoring point through the arrangement module of the main server, the priority sequence is arranged according to the third-level state, the second-level state and the first-level state, the fault time of different monitoring points in the same-level state is further acquired, the monitoring points in the same-level state are arranged according to the fault time of different monitoring points, the monitoring points with earlier fault time are preferentially arranged, the monitoring points with later fault time are arranged behind the monitoring points in the same-level state, the arranged data are sent to the maintenance processing module, the maintenance processing module sends the stored remote data in the arranged sequence to the mobile terminal, and maintenance personnel can conveniently arrange maintenance work according to the damaged level;

(3): according to the invention, data statistics is carried out on the monitoring points in the abnormal states through the data statistics module in the server, the total number of the monitoring points in the abnormal states is counted once when each monitoring point in the abnormal states is obtained, regional statistics is carried out according to the fault point position information of the monitoring points in the abnormal states, the monitoring points in the same region are accumulated to obtain the total number of the monitoring points in the abnormal states in each region, the number statistics is carried out on the monitoring points in the first-stage state, the second-stage state and the third-stage state respectively, the big data statistics is realized, and the data observation of background personnel is more visual.

(4): when the monitoring point is in an abnormal state, the invention matches the standby optical path according to the monitoring point code provided by the monitoring point in the abnormal state, and switches the optical path through the execution module.

Drawings

In order to facilitate understanding for those skilled in the art, the present invention will be further described with reference to the accompanying drawings.

FIG. 1 is a block diagram of the system of the present invention.

Detailed Description

As shown in fig. 1, an intelligent optical cable monitoring system for optical cable protection includes an RTU unit, an alarm processing unit, a transmission monitoring unit, a server, and a retrieval unit;

the RTU unit comprises an RTU module, an execution module and a matching switching module, the RTU module is used for a terminal detection instrument to collect remote data, the remote data comprises optical power data, fault point position information, fault time and monitoring point codes, the execution module is used for executing switching of light paths, the matching switching module is used for retrieving and matching corresponding standby light paths, the alarm processing unit is used for carrying out hierarchical processing according to the fault information, and the specific hierarchical processing steps are as follows:

the method comprises the following steps: obtaining optical power data, labeled G_qinThe optical power damage condition is divided into three levels, and the first level power threshold value is marked as G_qin1The secondary power threshold is marked G_qin2The three-level power threshold is marked G_qin3；

Step two: according to the power threshold value pair G_qinPerforming judgment processing;

when G is_qin＜G_qin1If so, judging the state to be a normal state;

when G is_qin1≤G_qin＜G_qin2Judging to be in a first-level state, namely a common state;

when G is_qin2≤G_qin＜G_qin3Judging the state to be a second-level state, namely a middle-level situation;

when G is_qin≥G_qin3Judging the state to be a three-level state, namely emergency;

step three: the primary state, the secondary state and the tertiary state are all abnormal states, and when the primary state, the secondary state and the tertiary state are in the abnormal states, the level state information, the fault point position information, the fault time and the monitoring point codes under the same monitoring point are used as unified loading data to be transmitted;

the server comprises a main server and a standby server, wherein the main server and the standby server respectively comprise an arrangement module, a data statistics module, a retrieval module, a maintenance processing module, a real-time synchronization module and a display, the arrangement module is used for carrying out priority arrangement processing according to the level state information, and the specific arrangement processing steps are as follows:

a01: respectively acquiring the level state information of each monitoring point;

a02: according to the level state information of each monitoring point, the priority is arranged according to a third-level state, a second-level state and a first-level state;

a03: further acquiring the fault time of different monitoring points in the same stage state;

a04: arranging monitoring points in the same level state according to the fault time of different monitoring points, wherein the monitoring points with earlier fault time are arranged in priority, and the monitoring points with later fault time are arranged behind the monitoring points in the same level state;

the data statistics module is used for carrying out data statistics on the monitoring points in the abnormal states, and the specific data statistics process comprises the following steps:

b01: counting once every time one monitoring point in abnormal state is obtained, counting the total number of the monitoring points in abnormal state, and marking as F_z；

B02: performing regional statistics according to the position information of the fault points of the abnormal state monitoring points, accumulating the monitoring points in the same region to obtain the total number of the abnormal state monitoring points in each region, and marking the total number as GQY_z；

B03: respectively counting the number of monitoring points in a first-level state, a second-level state and a third-level state, wherein the total number of the monitoring points in the first-level state is marked as X₁The total number of monitoring points of the secondary state is marked as X₂The total number of monitoring points of the three-level state is marked as X₃：

The retrieval module is used for acquiring the keyword information and performing retrieval matching according to the keyword information, and the specific retrieval matching processing steps are as follows:

s1: when the information input by the user is in a primary state, retrieving and matching all remote data related to the primary state;

s2: when the information input by the user is in the 'second-level state', retrieving and matching all remote data related to the second-level state;

s3: when the information input by the user is in the 'three-level state', retrieving and matching all remote data related to the three-level state;

s4: when the information input by the user is 'region characters', retrieving and matching all remote data in the region;

s5: when the information input by the user is 'failure time', retrieving and matching all remote data under the failure time;

the maintenance processing module is used for transmission and storage processing of remote data, and the specific processing steps comprise:

h01: sending the stored remote data arranged in sequence to the mobile terminal;

h02: acquiring a monitoring point maintenance code fed back by the mobile terminal;

h03: the monitoring point maintenance code is expressed as a monitoring point after maintenance is finished, and the monitoring point after maintenance is deleted from the stored data;

the alarm processing unit is also used for switching the standby optical path, and the specific processing steps are as follows:

u01: when the monitoring point is in an abnormal state, generating a switching signal, matching a standby optical path according to a monitoring point code provided by the monitoring point in the abnormal state, and switching the optical path through an execution module;

u02: when the monitoring point is in a normal state, the optical path switching is not carried out.

The transmission monitoring unit is used for switching processing between the main server and the standby server, and the specific switching processing steps are as follows:

q01: monitoring the uploading data of the alarm processing unit in real time, and judging the uploading state of the alarm processing unit;

QQ 01: when the monitored uploaded data of the alarm processing unit is larger than 0KB, judging that the alarm processing unit is in a data uploading state, monitoring the downloaded data of the main server at the moment, and judging according to the downloaded data;

when the downloaded data is larger than 0KB, judging that the data transmitted by the main server is normal;

when the downloaded data is equal to 0KB, judging that the data transmitted by the main server is abnormal, connecting the alarm processing unit with the standby server at the moment, generating a fault signal, and sending the fault signal to the mobile terminal;

QQ 02: when the monitored data uploaded by the alarm processing unit is equal to 0KB, no processing is executed; q02: respectively acquiring an uploading speed and a downloading speed, and displaying data through a display;

the real-time synchronization module is used for data synchronization between the main server and the standby server, and the specific data synchronization steps are as follows:

k01: data sharing is carried out between the main server and the standby server, and data in the main server and data in the standby server are collated in real time;

when the correction missing object is a main server, the standby server serves as a supplier and transmits missing data to the main server;

when the verification missing object is a standby server, the main server serves as a supplier and transmits missing data to the standby server;

k02: the data transmission and proofreading priority is that the main server transmits data to the standby server for proofreading, and judgment processing is carried out according to the real-time proofreading state of the data;

when the main server cannot perform data correction transmission, judging that the standby server is in a normal state, and sharing data to the mobile terminal;

when the main server is in a normal data correction transmission state, judging that the main server is in a normal state, and sharing data from the main server to the mobile terminal;

the RTU unit is a remote terminal unit, and is connected with the terminal detection instrument and the alarm processing unit through the RTU unit, and the RTU unit has remote data acquisition, control and communication function, can receive the operating instruction of host computer, controls terminal actuating mechanism action, and the alarm processing unit is connected with the server through transmission monitoring unit, and the alarm processing unit gives transmission monitoring unit with remote data transfer, and transmission monitoring unit gives the server with remote data transfer.

An intelligent optical cable monitoring system for optical cable protection is prepared as using RTU unit to collect remote data including optical power data, fault point position information, fault time and monitor point code, carrying out damaged level grading treatment on optical power data by alarm processing unit, judging light power data to be normal state when light power data is less than primary power threshold, judging light power data to be general state when light power data is less than secondary power threshold and to be primary state when light power data is less than tertiary power threshold and to be secondary state when light power data is less than tertiary power threshold and to be emergency state when light power data is greater than tertiary power threshold, judging primary state, secondary state and tertiary state to be abnormal state, when the monitoring points are in abnormal state, matching of standby light path is carried out according to the monitoring point codes provided by the monitoring points in abnormal state, light path switching is carried out through an execution module, meanwhile, the level state information, the fault point position information, the fault time and the monitoring point codes in the same monitoring point are transmitted to a main server as unified loading data, an arrangement module of the main server carries out arrangement of maintenance sequence according to the level state information of each monitoring point, the priority sequence is arranged according to a third-level state, a second-level state and a first-level state, the fault time of different monitoring points in the same-level state is further obtained, the monitoring points in the same-level state are arranged according to the fault time of different monitoring points, the monitoring points with earlier fault time are arranged in priority, the monitoring points with later fault time are arranged behind the monitoring points in the same-level state, sending the arranged data to a maintenance processing module, sending the stored remote data in the arranged sequence to a mobile terminal by the maintenance processing module, acquiring monitoring point maintenance codes fed back by the mobile terminal, wherein the monitoring point maintenance codes represent monitoring points after maintenance is finished, deleting the monitoring points after maintenance is finished from the stored data, performing data statistics on the monitoring points in abnormal states by a data statistics module in a server, counting once every time one monitoring point in abnormal state is acquired, counting the total number of the monitoring points in abnormal states, performing regional statistics according to the fault point position information of the monitoring points in abnormal states, accumulating the monitoring points in the same region to obtain the total number of the monitoring points in abnormal states in each region, and performing quantity statistics on the monitoring points in primary state, secondary state and tertiary state respectively, the method comprises the steps of obtaining keyword information input by a user through a retrieval module, carrying out retrieval matching according to the keyword information, retrieving and matching all remote data related to a primary state when the information input by the user is in a primary state, retrieving and matching all remote data related to a secondary state when the information input by the user is in a secondary state, retrieving and matching all remote data related to a tertiary state when the information input by the user is in a tertiary state, retrieving and matching all remote data in the region when the information input by the user is in a region character, retrieving and matching all remote data in the failure time when the information input by the user is in the failure time, carrying out real-time proofreading of data between a main server and a standby server through a real-time synchronization module, and when a missing object is corrected as the main server, the standby server is used as a supplier to transmit missing data to the main server, when the checking missing object is the standby server, the main server is used as the supplier to transmit the missing data to the standby server, the data transmission checking priority is that the main server transmits the data to the standby server to check, the judgment processing is carried out according to the real-time checking state of the data, when the main server can not carry out the data checking transmission, the standby server is judged to be in a normal state, the data is shared to the mobile terminal, when the main server is in the normal data checking transmission state, the main server is judged to be in the normal state, the main server shares the data to the mobile terminal, the transmission monitoring unit is used for switching processing between the main server and the standby server, the uploading data of the alarm processing unit is monitored in real time, when the monitored uploading data of the alarm processing unit is more than 0KB, when the monitored data uploaded by the alarm processing unit is equal to 0KB, no processing is executed, the uploading speed and the downloading speed are respectively obtained, and data display is carried out through a display.

The foregoing is merely exemplary and illustrative of the present invention and various modifications, additions and substitutions may be made by those skilled in the art to the specific embodiments described without departing from the scope of the invention as defined in the following claims.

Claims (3)

1. An intelligent optical cable monitoring system for optical cable protection is characterized by comprising an RTU unit, an alarm processing unit, a transmission monitoring unit and a server;

the RTU unit is a remote terminal unit, a tail end detection instrument is connected with the alarm processing unit through the RTU unit, the alarm processing unit is connected with the server through the transmission monitoring unit, the alarm processing unit transmits remote data to the transmission monitoring unit, and the transmission monitoring unit transmits the remote data to the server;

the RTU unit comprises an RTU module, an execution module and a matching switching module, the RTU module is used for a terminal detection instrument and collecting remote data, the remote data comprises optical power data, fault point position information, fault time and monitoring point codes, the execution module is used for executing switching of light paths, the matching switching module is used for retrieving and matching corresponding standby light paths, the alarm processing unit is used for carrying out classification processing according to the fault information, and the specific classification processing steps are as follows:

the method comprises the following steps: obtaining optical power data, labeled G_qinThe optical power damage condition is divided into three levels, and the first level power threshold value is marked as G_qin1The secondary power threshold is marked G_qin2The three-level power threshold is marked G_qin3；

Step two: according to the power threshold value pair G_qinPerforming judgment processing;

when G is_qin＜G_qin1If so, judging the state to be a normal state;

when G is_qin1≤G_qin＜G_qin2Judging to be in a first-level state, namely a common state;

when G is_qin2≤G_qin＜G_qin3Judging the state to be a second-level state, namely a middle-level situation;

when G is_qin≥G_qin3Judging the state to be a three-level state, namely emergency;

step three: the primary state, the secondary state and the tertiary state are all abnormal states, and when the primary state, the secondary state and the tertiary state are in the abnormal states, the level state information, the fault point position information, the fault time and the monitoring point codes under the same monitoring point are used as unified loading data to be transmitted;

the server comprises a main server and a standby server, wherein the main server and the standby server respectively comprise an arrangement module, a data statistics module, a retrieval module, a maintenance processing module, a real-time synchronization module and a display, the arrangement module is used for carrying out priority arrangement processing according to the level state information, and the specific arrangement processing steps are as follows:

a01: respectively acquiring the level state information of each monitoring point;

a02: according to the level state information of each monitoring point, the priority is arranged according to a third-level state, a second-level state and a first-level state;

a03: further acquiring the fault time of different monitoring points in the same stage state;

a04: arranging monitoring points in the same level state according to the fault time of different monitoring points, wherein the monitoring points with earlier fault time are arranged in priority, and the monitoring points with later fault time are arranged behind the monitoring points in the same level state;

the data statistics module is used for carrying out data statistics on the monitoring points in the abnormal states, and the specific data statistics process comprises the following steps:

b01: counting once every time one monitoring point in abnormal state is obtained, counting the total number of the monitoring points in abnormal state, and marking as F_z；

B02: performing regional statistics according to the position information of the fault points of the abnormal state monitoring points, accumulating the monitoring points in the same region to obtain the total number of the abnormal state monitoring points in each region, and marking the total number as GQY_z；

B03: are respectively provided withCounting the number of monitoring points in the first-level state, the second-level state and the third-level state, wherein the total number of the monitoring points in the first-level state is marked as X₁The total number of monitoring points of the secondary state is marked as X₂The total number of monitoring points of the three-level state is marked as X₃；

The retrieval module is used for acquiring the keyword information and performing retrieval matching according to the keyword information, and the specific retrieval matching processing steps are as follows:

s1: when the information input by the user is in a primary state, retrieving and matching all remote data related to the primary state;

s2: when the information input by the user is in the 'second-level state', retrieving and matching all remote data related to the second-level state;

s3: when the information input by the user is in the 'three-level state', retrieving and matching all remote data related to the three-level state;

s4: when the information input by the user is 'region characters', retrieving and matching all remote data in the region;

s5: when the information input by the user is 'failure time', retrieving and matching all remote data under the failure time;

the maintenance processing module is used for transmission and storage processing of remote data, and the specific processing steps comprise:

h01: sending the stored remote data arranged in sequence to the mobile terminal;

h02: acquiring a monitoring point maintenance code fed back by the mobile terminal;

h03: the monitoring point maintenance code is expressed as a monitoring point after maintenance is finished, and the monitoring point after maintenance is deleted from the stored data;

the alarm processing unit is also used for switching the standby optical path, and the specific processing steps are as follows:

u01: when the monitoring point is in an abnormal state, generating a switching signal, matching a standby optical path according to a monitoring point code provided by the monitoring point in the abnormal state, and switching the optical path through an execution module;

u02: when the monitoring point is in a normal state, the optical path switching is not carried out.

2. An intelligent optical cable monitoring system for optical cable protection as claimed in claim 1, wherein the transmission monitoring unit is configured to perform a switching process between the primary server and the backup server, and the specific switching process steps are as follows:

q01: monitoring the uploading data of the alarm processing unit in real time, and judging the uploading state of the alarm processing unit;

QQ 01: when the monitored uploaded data of the alarm processing unit is larger than 0KB, judging that the alarm processing unit is in a data uploading state, monitoring the downloaded data of the main server at the moment, and judging according to the downloaded data;

when the downloaded data is larger than 0KB, judging that the data transmitted by the main server is normal;

when the downloaded data is equal to 0KB, judging that the data transmitted by the main server is abnormal, connecting the alarm processing unit with the standby server at the moment, generating a fault signal, and sending the fault signal to the mobile terminal;

QQ 02: when the monitored data uploaded by the alarm processing unit is equal to 0KB, no processing is executed;

q02: and respectively acquiring the uploading speed and the downloading speed, and displaying data through a display.

3. An intelligent optical cable monitoring system for optical cable protection as claimed in claim 1, wherein said real-time synchronization module is used for data synchronization between the primary server and the backup server, and the specific data synchronization steps are as follows:

k01: data sharing is carried out between the main server and the standby server, and data in the main server and data in the standby server are collated in real time;

when the correction missing object is a main server, the standby server serves as a supplier and transmits missing data to the main server;

when the verification missing object is a standby server, the main server serves as a supplier and transmits missing data to the standby server;

k02: the data transmission and proofreading priority is that the main server transmits data to the standby server for proofreading, and judgment processing is carried out according to the real-time proofreading state of the data;

when the main server cannot perform data correction transmission, judging that the standby server is in a normal state, and sharing data to the mobile terminal;

and when the main server is in a normal data correction transmission state, judging that the main server is in a normal state, and sharing data from the main server to the mobile terminal.

Images