CN112505485A - Fault testing system for mobile communication transmission equipment - Google Patents

Fault testing system for mobile communication transmission equipment Download PDF

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CN112505485A
CN112505485A CN202011405940.0A CN202011405940A CN112505485A CN 112505485 A CN112505485 A CN 112505485A CN 202011405940 A CN202011405940 A CN 202011405940A CN 112505485 A CN112505485 A CN 112505485A
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mobile communication
communication transmission
transmission equipment
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fault
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CN112505485B (en
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李凡
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Shanghai Jitie Network Technology Co ltd
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    • G01RMEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
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Abstract

The invention discloses a mobile communication transmission equipment fault testing system, which comprises an alarm module, a maintenance distribution module, a data analysis module and a fault diagnosis module, wherein the alarm module is used for detecting the fault of mobile communication transmission equipment; the data analysis module is used for carrying out data analysis on the mobile communication transmission equipment; the fault diagnosis module receives the deviation value of the mobile communication transmission equipment obtained by the analysis of the data analysis module, and carries out fault diagnosis on the mobile communication transmission equipment by combining the deviation value; the mobile communication transmission equipment maintenance method and the mobile communication transmission equipment maintenance system have the advantages that when the communication transmission equipment breaks down, the fault position can be quickly detected, the use effect of the mobile communication transmission equipment is improved, reasonable distribution of maintenance resources is realized, and the maintenance efficiency of the mobile communication transmission equipment is greatly improved.

Description

Fault testing system for mobile communication transmission equipment
Technical Field
The invention belongs to the technical field of mobile communication, relates to a fault testing technology, and particularly relates to a fault testing system of mobile communication transmission equipment.
Background
Mobile communications communicate the way communications between a mobile user and a fixed-point user or between mobile users. Both parties of the communication have one or both parties in motion. Including land, sea, and air mobile communications. The frequency bands used are spread over low, medium, high, very high and very high frequencies. The mobile communication system is composed of mobile station, base station and mobile exchange. If communication with a mobile station is desired, the mobile exchange sends a call to the whole network through each base station, the called station sends an answer signal after receiving the answer, the mobile exchange assigns a channel to the mobile station after receiving the answer and transmits a signaling to make it ring from the channel of the speech channel.
When the communication transmission equipment fails, the fault position cannot be quickly detected, the use effect of the mobile communication transmission equipment is reduced, the information transmission efficiency is reduced, and economic loss is caused; when a mobile communication transmission device breaks down, a telephone often communicates with a certain maintenance person for maintenance, and when the maintenance person cannot maintain the mobile communication transmission device in time, the mobile communication transmission device influences processing production due to long-time stagnation, searches for other maintenance persons again, wastes a large amount of time, cannot reasonably and effectively distribute maintenance resources, and greatly reduces the maintenance efficiency of the mobile communication transmission device.
Disclosure of Invention
Aiming at the defects in the prior art, the invention aims to provide a mobile communication transmission equipment fault testing system.
The technical problem to be solved by the invention is as follows:
when the communication transmission equipment fails, the fault position cannot be quickly detected, the use effect of the mobile communication transmission equipment is reduced, the information transmission efficiency is reduced, and economic loss is caused; when the mobile communication transmission equipment breaks down, the mobile communication transmission equipment often communicates with a certain maintenance person for maintenance, and when the maintenance person cannot maintain the mobile communication transmission equipment in time, the mobile communication transmission equipment influences processing production due to long-time stagnation, searches other maintenance persons again, wastes a large amount of time, cannot reasonably and effectively distribute maintenance resources, and greatly reduces the maintenance efficiency of the mobile communication transmission equipment.
The purpose of the invention can be realized by the following technical scheme:
a mobile communication transmission equipment fault test system comprises a registration login module, an alarm module, a data acquisition module, a grading display module, a maintenance distribution module, a data analysis module, a fault diagnosis module and a server;
the registration login module is used for registering and logging after the mobile communication user and the mobile communication maintenance personnel submit personnel information, and sending the personnel information which is successfully registered into the server, wherein the personnel information comprises personnel names, positions and mobile phone numbers of real-name authentication; the data acquisition module is used for acquiring equipment data and transmission data of the mobile communication transmission equipment and sending the equipment data and the transmission data to the server; the data analysis module is used for carrying out data analysis on the mobile communication transmission equipment, and the analysis steps are as follows:
the method comprises the following steps: marking the mobile communication transmission equipment as Tu, u-1, 2, … …, n;
step two: acquiring a voltage value of the mobile communication transmission equipment, and marking the voltage value as YTu;
step three: acquiring the resistance value of the mobile communication transmission equipment, and marking the resistance value as ZTu; acquiring a temperature value of the mobile communication transmission equipment, and marking the temperature value as WTu;
step four: acquiring a voltage threshold YY, a resistance threshold ZY and a temperature threshold WY of mobile communication transmission equipment;
step five: calculating an offset value PCTu of the mobile communication transmission equipment by using a formula, wherein the formula is as follows:
Figure BDA0002818518820000031
step six: the deviation value PCTu obtained by the analysis of the data analysis module is sent to the fault diagnosis module;
the fault diagnosis module receives the deviation value of the mobile communication transmission equipment obtained by the analysis of the data analysis module, and carries out fault diagnosis on the mobile communication transmission equipment by combining the deviation value; the grading display module is used for grading display of the alarm signal; the overhaul distribution module is used for distributing the mobile communication transmission equipment to be overhauled to maintenance personnel.
Further, the fault diagnosis process of the fault diagnosis module is specifically as follows:
step S1: acquiring a fault information record of the mobile communication transmission equipment uploaded in the server each time, and marking the fault information as i, i is 1, 2, … …, m;
step S2: acquiring a fault temperature value Gwi, a fault voltage value GYi and a fault resistance value GZi in each fault information record, and adding and averaging to obtain a fault temperature average value GW, a fault voltage average value GY and a fault resistance average value GZ of the mobile communication transmission equipment;
step S3: acquiring a voltage value, a resistance value, a temperature value and an offset value of mobile communication transmission equipment;
step S4: the fault coefficient value GTu of the mobile communication transmission equipment is calculated by using a formula, wherein the formula is as follows:
Figure BDA0002818518820000032
wherein a1 is a fixed value of a preset proportionality coefficient;
step S5: if the fault coefficient value GTu exceeds the set fault coefficient threshold value, the server generates a self-checking signal, and the fault diagnosis module carries out fault diagnosis after receiving the self-checking signal;
step S6: the method comprises the steps that a fault diagnosis module obtains a voltage value, a resistance value and a temperature value of the mobile communication transmission equipment, if the voltage value, the resistance value and the temperature value are all in a normal range value, a safety command signal is generated, if the voltage value is not in the normal range value, a primary alarm signal is generated, if the resistance value, the voltage value, the resistance value, the temperature value, the voltage value and the temperature value are not in the normal range value, a secondary alarm signal is generated, and if the voltage value, the resistance value and the temperature value are not in the normal range value, a tertiary alarm signal is generated;
step S7: the primary alarm signal, the secondary alarm signal and the tertiary alarm signal are all fed back to the server and the alarm module.
Further, the hierarchical display process of the hierarchical display module is specifically as follows:
p1: when the display module receives the three-level alarm signal, the display module displays the character eye of the three-level alarm signal, the character style is thickened and inclined, and the background color is set to be red;
p2: when the display module receives the secondary alarm signal, the display module displays the character eye of the secondary alarm signal, the character style is thickened, and the background color is set to be orange;
p3: when the display module receives the primary alarm signal, the display module displays a character eye of the primary alarm signal and a standard character, and sets the background color to yellow;
p4: when the display module receives the safety instruction signal, the display module displays the safety instruction character eye and the standard character, and sets the background color to green.
Further, the overhaul distribution steps of the overhaul distribution module are as follows:
SS 1: acquiring a maintenance person of the mobile communication transmission equipment, and marking the maintenance person to be maintained as o, o is 1, 2, … …, v;
SS 2: acquiring the position of the mobile communication transmission equipment to be maintained and the position of a maintenance worker, and calculating by using a distance formula to obtain a maintenance distance JJo;
SS 3: acquiring the number to be maintained WSo and a maintenance value WZo of maintenance personnel;
SS 4: obtaining the maintenance duration WTo and the maintenance price WGo of the maintenance personnel, and calculating the coincidence value WHo of the maintenance personnel by using a formula, wherein the formula is as follows:
Figure BDA0002818518820000051
wherein c1, c2, c3 and c4 are all preset fixed proportional coefficient values;
SS 5: selecting a maintainer with the largest coincidence value to maintain the mobile communication transmission equipment to be maintained, simultaneously sending the position of the mobile communication transmission equipment to be maintained to a mobile terminal of the maintainer by a maintenance distribution module, and increasing the total amount to be maintained of the maintainer by one when the maintainer reaches the maintenance position of the mobile communication transmission equipment to be maintained, the position of the maintainer and the position of the mobile communication transmission equipment to be maintained;
SS 6: after the maintenance personnel maintain the mobile communication transmission equipment, the maintenance personnel upload the fault information records of the mobile communication transmission equipment to the server when the mobile communication transmission equipment is normal in function, and after the fault information records are submitted, the maintenance personnel reduce the maintenance quantity to one.
Further, the maintenance value calculation method is as follows:
SS 31: acquiring the total maintenance amount and the successful maintenance number of the maintenance personnel, and dividing the successful maintenance number by the total maintenance amount to obtain a successful maintenance rate CGo;
s32: calculating to obtain a maintenance failure rate SBo of the maintenance personnel;
s33: the repair value WZo of the repair crew is calculated by using the formula WZo (CGo × b1)/(SBo × b 2).
Further, the recording of the fault information of the mobile communication transmission device specifically includes: fault cause, fault number, fault time, fault temperature value, fault voltage value, fault resistance value, operating condition value and overhaul time.
Compared with the prior art, the invention has the beneficial effects that:
1. when the communication transmission equipment fails, the method can quickly detect the fault, improve the use effect of the mobile communication transmission equipment, avoid the reduction of information transmission efficiency and increase the efficiency of inspection work;
2. when the mobile communication transmission equipment breaks down, the invention does not need telephone communication to maintenance personnel for maintenance, thereby avoiding the long-time stagnation of the mobile communication transmission equipment caused by the failure of timely maintenance of the maintenance personnel, influencing the mobile communication transmission, realizing the reasonable distribution of maintenance resources and greatly increasing the maintenance efficiency of the mobile communication transmission equipment.
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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 an overall system block diagram of the present invention.
Detailed Description
The technical solutions of the present invention will be described clearly and completely with reference to the following embodiments, and it should be understood that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
Referring to fig. 1, a mobile communication transmission device fault testing system includes a registration login module, an alarm module, a data acquisition module, a grading display module, an overhaul allocation module, a data analysis module, a fault diagnosis module, and a server;
the registration login module is used for registering and logging after the mobile communication user and the mobile communication maintenance personnel submit personnel information, and sending the personnel information which is successfully registered into the server, wherein the personnel information comprises personnel names, positions and mobile phone numbers of real-name authentication; the data acquisition module is used for acquiring equipment data and transmission data of the mobile communication transmission equipment and sending the equipment data and the transmission data to the server; the data analysis module is used for carrying out data analysis on the mobile communication transmission equipment, and the analysis steps are as follows:
the method comprises the following steps: marking the mobile communication transmission equipment as Tu, u-1, 2, … …, n;
step two: acquiring a voltage value of the mobile communication transmission equipment, and marking the voltage value as YTu;
step three: acquiring the resistance value of the mobile communication transmission equipment, and marking the resistance value as ZTu; acquiring a temperature value of the mobile communication transmission equipment, and marking the temperature value as WTu;
step four: acquiring a voltage threshold YY, a resistance threshold ZY and a temperature threshold WY of mobile communication transmission equipment;
step five: calculating an offset value PCTu of the mobile communication transmission equipment by using a formula, wherein the formula is as follows:
Figure BDA0002818518820000071
step six: the deviation value PCTu obtained by the analysis of the data analysis module is sent to the fault diagnosis module;
the specific test mode is as follows:
w1: the voltage of the mobile communication transmission equipment is measured by using the voltage feedback device, when the voltage feedback device detects that the voltage is normal, the green warning lamp works to light up, the resistance of a connecting line of the mobile communication transmission equipment can be further detected, when the voltage feedback device detects that the voltage of the mobile communication transmission equipment is abnormal, the red warning lamp works to light up, firstly, the power supply of the mobile communication transmission equipment is maintained, so that the power supply is in a normal state, and the resistance of the connecting line of the mobile communication transmission equipment is detected;
w2: the resistance measurer is used for measuring the resistance of the connecting line of the mobile communication transmission equipment, a data signal measured by the resistance measurer is transmitted to the resistance feedback device, when the line resistance feedback device detects that the resistance of the connecting line is normal, the green warning lamp works and lights up, other parts of the mobile communication transmission equipment are detected, when the line resistance feedback device detects that the resistance of the connecting line is infinite, the red warning lamp works and lights up to indicate that the connecting line of the mobile communication transmission equipment is broken or an electronic element on the connecting line of the mobile communication transmission equipment is in fault, the specific position of the fault of the mobile communication transmission equipment is detected by repeatedly using the method, and then maintenance is carried out;
w3: the method comprises the following steps that two metal chucks are clamped on a mobile communication transmission equipment connecting line, a mobile communication transmission equipment fault detector is used for detecting the mobile communication transmission equipment connecting line on the two metal chucks, when the mobile communication transmission equipment connecting line does not have a fault, the resistance is in direct proportion to the length of the mobile communication transmission equipment connecting line, the resistance of the mobile communication transmission equipment connecting line can be accurately measured, when the mobile communication transmission equipment connecting line breaks, the resistance of the mobile communication transmission equipment connecting line is positive and cannot be increased, then the two metal chucks are gradually pushed inwards, and therefore the specific position of the mobile communication transmission equipment connecting line breaking is detected;
the fault diagnosis module receives the deviation value of the mobile communication transmission equipment obtained by the analysis of the data analysis module, and carries out fault diagnosis on the mobile communication transmission equipment by combining the deviation value, wherein the fault diagnosis process specifically comprises the following steps:
step S1: acquiring a fault information record of the mobile communication transmission equipment uploaded in the server each time, and marking the fault information as i, i is 1, 2, … …, m;
the recording of the fault information of the mobile communication transmission equipment specifically comprises the following steps: fault reason, fault number, fault time, fault temperature value, fault voltage value, fault resistance value, running condition value, maintenance time and the like;
step S2: acquiring a fault temperature value Gwi, a fault voltage value GYi and a fault resistance value GZi in each fault information record, and adding and averaging to obtain a fault temperature average value GW, a fault voltage average value GY and a fault resistance average value GZ of the mobile communication transmission equipment;
step S3: acquiring a voltage value, a resistance value, a temperature value and an offset value of mobile communication transmission equipment;
step S4: the fault coefficient value GTu of the mobile communication transmission equipment is calculated by using a formula, wherein the formula is as follows:
Figure BDA0002818518820000081
wherein a1 is a fixed value of a preset proportionality coefficient;
step S5: if the fault coefficient value GTu exceeds the set fault coefficient threshold value, the server generates a self-checking signal, and the fault diagnosis module carries out fault diagnosis after receiving the self-checking signal;
step S6: the method comprises the steps that a fault diagnosis module obtains a voltage value, a resistance value and a temperature value of the mobile communication transmission equipment, if the voltage value, the resistance value and the temperature value are all in a normal range value, a safety command signal is generated, if the voltage value is not in the normal range value, a primary alarm signal is generated, if the resistance value, the voltage value, the resistance value, the temperature value, the voltage value and the temperature value are not in the normal range value, a secondary alarm signal is generated, and if the voltage value, the resistance value and the temperature value are not in the normal range value, a tertiary alarm signal is generated;
step S7: the primary alarm signal, the secondary alarm signal and the tertiary alarm signal are all fed back to the server and the alarm module;
the grading display module is used for grading display of the alarm signal, and the grading display process is as follows:
p1: when the display module receives the three-level alarm signal, the display module displays the character eye of the three-level alarm signal, the character style is thickened and inclined, and the background color is set to be red;
p2: when the display module receives the secondary alarm signal, the display module displays the character eye of the secondary alarm signal, the character style is thickened, and the background color is set to be orange;
p3: when the display module receives the primary alarm signal, the display module displays a character eye of the primary alarm signal and a standard character, and sets the background color to yellow;
p4: when the display module receives the safety instruction signal, the display module displays the safety instruction character eye and the standard character, and sets the background color to green;
the overhaul distribution module is used for distributing the mobile communication transmission equipment to be overhauled to maintenance personnel, and the overhaul distribution steps are as follows:
SS 1: acquiring a maintenance person of the mobile communication transmission equipment, and marking the maintenance person to be maintained as o, o is 1, 2, … …, v;
SS 2: acquiring the position of the mobile communication transmission equipment to be maintained and the position of a maintenance worker, and calculating by using a distance formula to obtain a maintenance distance JJo;
SS 3: acquiring the number to be maintained WSo and a maintenance value WZo of maintenance personnel; the maintenance value calculation method of the maintenance personnel comprises the following steps:
SS 31: acquiring the total maintenance amount and the successful maintenance number of the maintenance personnel, and dividing the successful maintenance number by the total maintenance amount to obtain a successful maintenance rate CGo;
s32: calculating to obtain a maintenance failure rate SBo of the maintenance personnel;
s33: calculating a maintenance value WZo of a maintenance worker by using a formula WZo of (CGo × b1)/(SBo × b 2);
SS 4: obtaining the maintenance duration WTo and the maintenance price WGo of the maintenance personnel, and calculating the coincidence value WHo of the maintenance personnel by using a formula, wherein the formula is as follows:
Figure BDA0002818518820000101
wherein c1, c2, c3 and c4 are all preset fixed proportional coefficient values;
SS 5: selecting a maintainer with the largest coincidence value to maintain the mobile communication transmission equipment to be maintained, simultaneously sending the position of the mobile communication transmission equipment to be maintained to a mobile terminal of the maintainer by a maintenance distribution module, and increasing the total amount to be maintained of the maintainer by one when the maintainer reaches the maintenance position of the mobile communication transmission equipment to be maintained, the position of the maintainer and the position of the mobile communication transmission equipment to be maintained;
SS 6: after the maintenance personnel maintain the mobile communication transmission equipment, the maintenance personnel upload the fault information records of the mobile communication transmission equipment to the server when the mobile communication transmission equipment is normal in function, and after the fault information records are submitted, the maintenance personnel reduce the maintenance quantity to one.
A mobile communication transmission equipment fault test system is characterized in that when the system works, data analysis is carried out on mobile communication transmission equipment through a data analysis module, a voltage value YTu, a resistance value ZTu and a temperature value WTu of the mobile communication transmission equipment are obtained, then a voltage threshold YY, a resistance threshold ZY and a temperature threshold WY of the mobile communication transmission equipment are obtained, and a formula is utilized
Figure BDA0002818518820000102
Calculating to obtain a deviation value PCTu of the mobile communication transmission equipment, and sending the deviation value PCTu obtained by the analysis of the data analysis module to the fault diagnosis module;
the fault diagnosis module receives the deviation value of the mobile communication transmission equipment obtained by the analysis of the data analysis module, carries out fault diagnosis on the mobile communication transmission equipment by combining the deviation value, firstly acquires the fault information record i of the mobile communication transmission equipment uploaded in the server, then acquires the fault temperature value Gwi, the fault voltage value GYi and the fault resistance value GZi in each fault information record, adds the average values to obtain the fault temperature average value GW, the fault voltage average value GY and the fault resistance average value GZ of the mobile communication transmission equipment, and then acquires the voltage value, the resistance value, the temperature value and the fault resistance value of the mobile communication transmission equipmentDeviation value, using formula
Figure BDA0002818518820000111
Calculating a fault coefficient value GTu of the mobile communication transmission equipment, if the fault coefficient value GTu exceeds a set fault coefficient threshold value, generating a self-detection signal by the server, receiving the self-detection signal by the fault diagnosis module, performing fault diagnosis, generating a primary alarm signal by the fault diagnosis module according to the voltage value of the mobile communication transmission equipment if the voltage value is not in a normal range value, generating a secondary alarm signal according to the resistance value of the mobile communication transmission equipment if the resistance value is not in the normal range value, generating a tertiary alarm signal according to the temperature value of the mobile communication transmission equipment if the temperature value is not in the normal range value, and feeding the primary alarm signal, the secondary alarm signal and the tertiary alarm signal back to the server and the alarm module;
the alarm signal is displayed in a grading way through a grading display module, when the display module receives a three-grade alarm signal, the display module displays a character eye of a 'three-grade alarm signal', a character style is thickened and inclined, and the background color is set to be red, when the display module receives a two-grade alarm signal, the display module displays a character eye of a 'two-grade alarm signal', the character style is thickened, and the background color is set to be orange, when the display module receives a first-grade alarm signal, the display module displays a character eye of a 'one-grade alarm signal', a standard character style, and the background color is set to be yellow, and when the display module receives a safety instruction signal, the display module displays a character eye of a 'safety instruction', a standard character style, and sets the background color to be green;
the mobile communication transmission equipment to be overhauled is distributed to maintenance personnel through an overhauling distribution module, the maintenance personnel o of the mobile communication transmission equipment is firstly obtained, then the position of the mobile communication transmission equipment to be maintained and the position of the maintenance personnel are obtained, a maintenance interval JJo is obtained through calculation of a distance formula, the number to be maintained WSo, a maintenance value WZo, maintenance duration WTo and maintenance price WGo of the maintenance personnel are obtained, and the formula is used for calculating the maintenance interval, the maintenance interval and the maintenance price of the maintenance personnel
Figure BDA0002818518820000121
The method comprises the steps that an agreement value WHo of maintenance personnel is obtained through calculation, the maintenance personnel with the largest agreement value is selected to maintain the mobile communication transmission equipment to be maintained, meanwhile, a maintenance distribution module sends the position of the mobile communication transmission equipment to be maintained to a mobile terminal of the maintenance personnel, when the maintenance personnel reach the maintenance position of the mobile communication transmission equipment to be maintained, the position of the maintenance personnel and the position of the mobile communication transmission equipment to be maintained are increased by one, after the maintenance personnel maintain the mobile communication transmission equipment, the function of the mobile communication transmission equipment to be normal, the maintenance personnel upload the fault information records of the mobile communication transmission equipment to a server, and after the fault information records are submitted, the number of the maintenance personnel to be maintained is reduced by one.
The above formulas are all calculated by taking the numerical value of the dimension, the formula is a formula which obtains the latest real situation by acquiring a large amount of data and performing software simulation, and the preset parameters in the formula are set by the technical personnel in the field according to the actual situation.
The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims (6)

1. A mobile communication transmission equipment fault test system is characterized by comprising a registration login module, an alarm module, a data acquisition module, a grading display module, an overhaul distribution module, a data analysis module, a fault diagnosis module and a server;
the registration login module is used for registering and logging after the mobile communication user and the mobile communication maintenance personnel submit personnel information, and sending the personnel information which is successfully registered into the server, wherein the personnel information comprises personnel names, positions and mobile phone numbers of real-name authentication; the data acquisition module is used for acquiring equipment data and transmission data of the mobile communication transmission equipment and sending the equipment data and the transmission data to the server; the data analysis module is used for carrying out data analysis on the mobile communication transmission equipment, and the analysis steps are as follows:
the method comprises the following steps: marking the mobile communication transmission equipment as Tu, u-1, 2, … …, n;
step two: acquiring a voltage value of the mobile communication transmission equipment, and marking the voltage value as YTu;
step three: acquiring the resistance value of the mobile communication transmission equipment, and marking the resistance value as ZTu; acquiring a temperature value of the mobile communication transmission equipment, and marking the temperature value as WTu;
step four: acquiring a voltage threshold YY, a resistance threshold ZY and a temperature threshold WY of mobile communication transmission equipment;
step five: calculating an offset value PCTu of the mobile communication transmission equipment by using a formula, wherein the formula is as follows:
Figure FDA0002818518810000011
step six: the deviation value PCTu obtained by the analysis of the data analysis module is sent to the fault diagnosis module;
the fault diagnosis module receives the deviation value of the mobile communication transmission equipment obtained by the analysis of the data analysis module, and carries out fault diagnosis on the mobile communication transmission equipment by combining the deviation value; the grading display module is used for grading display of the alarm signal; the overhaul distribution module is used for distributing the mobile communication transmission equipment to be overhauled to maintenance personnel.
2. The system according to claim 1, wherein the fault diagnosis process of the fault diagnosis module specifically includes:
step S1: acquiring a fault information record of the mobile communication transmission equipment uploaded in the server each time, and marking the fault information as i, i is 1, 2, … …, m;
step S2: acquiring a fault temperature value Gwi, a fault voltage value GYi and a fault resistance value GZi in each fault information record, and adding and averaging to obtain a fault temperature average value GW, a fault voltage average value GY and a fault resistance average value GZ of the mobile communication transmission equipment;
step S3: acquiring a voltage value, a resistance value, a temperature value and an offset value of mobile communication transmission equipment;
step S4: the fault coefficient value GTu of the mobile communication transmission equipment is calculated by using a formula, wherein the formula is as follows:
Figure FDA0002818518810000021
wherein a1 is a fixed value of a preset proportionality coefficient;
step S5: if the fault coefficient value GTu exceeds the set fault coefficient threshold value, the server generates a self-checking signal, and the fault diagnosis module carries out fault diagnosis after receiving the self-checking signal;
step S6: the method comprises the steps that a fault diagnosis module obtains a voltage value, a resistance value and a temperature value of the mobile communication transmission equipment, if the voltage value, the resistance value and the temperature value are all in a normal range value, a safety command signal is generated, if the voltage value is not in the normal range value, a primary alarm signal is generated, if the resistance value, the voltage value, the resistance value, the temperature value, the voltage value and the temperature value are not in the normal range value, a secondary alarm signal is generated, and if the voltage value, the resistance value and the temperature value are not in the normal range value, a tertiary alarm signal is generated;
step S7: the primary alarm signal, the secondary alarm signal and the tertiary alarm signal are all fed back to the server and the alarm module.
3. The system according to claim 1, wherein the hierarchical display process of the hierarchical display module specifically comprises:
p1: when the display module receives the three-level alarm signal, the display module displays the character eye of the three-level alarm signal, the character style is thickened and inclined, and the background color is set to be red;
p2: when the display module receives the secondary alarm signal, the display module displays the character eye of the secondary alarm signal, the character style is thickened, and the background color is set to be orange;
p3: when the display module receives the primary alarm signal, the display module displays a character eye of the primary alarm signal and a standard character, and sets the background color to yellow;
p4: when the display module receives the safety instruction signal, the display module displays the safety instruction character eye and the standard character, and sets the background color to green.
4. The system for testing the faults of the mobile communication transmission equipment according to claim 1, wherein the overhaul allocation steps of the overhaul allocation module are as follows:
SS 1: acquiring a maintenance person of the mobile communication transmission equipment, and marking the maintenance person to be maintained as o, o is 1, 2, … …, v;
SS 2: acquiring the position of the mobile communication transmission equipment to be maintained and the position of a maintenance worker, and calculating by using a distance formula to obtain a maintenance distance JJo;
SS 3: acquiring the number to be maintained WSo and a maintenance value WZo of maintenance personnel;
SS 4: obtaining the maintenance duration WTo and the maintenance price WGo of the maintenance personnel, and calculating the coincidence value WHo of the maintenance personnel by using a formula, wherein the formula is as follows:
Figure FDA0002818518810000031
wherein c1, c2, c3 and c4 are all preset fixed proportional coefficient values;
SS 5: selecting a maintainer with the largest coincidence value to maintain the mobile communication transmission equipment to be maintained, simultaneously sending the position of the mobile communication transmission equipment to be maintained to a mobile terminal of the maintainer by a maintenance distribution module, and increasing the total amount to be maintained of the maintainer by one when the maintainer reaches the maintenance position of the mobile communication transmission equipment to be maintained, the position of the maintainer and the position of the mobile communication transmission equipment to be maintained;
SS 6: after the maintenance personnel maintain the mobile communication transmission equipment, the maintenance personnel upload the fault information records of the mobile communication transmission equipment to the server when the mobile communication transmission equipment is normal in function, and after the fault information records are submitted, the maintenance personnel reduce the maintenance quantity to one.
5. The system of claim 4, wherein the maintenance value is calculated by the following method:
SS 31: acquiring the total maintenance amount and the successful maintenance number of the maintenance personnel, and dividing the successful maintenance number by the total maintenance amount to obtain a successful maintenance rate CGo;
s32: calculating to obtain a maintenance failure rate SBo of the maintenance personnel;
s33: the repair value WZo of the repair crew is calculated by using the formula WZo (CGo × b1)/(SBo × b 2).
6. The system according to claim 1, wherein the recording of the fault information of the mobile communication transmission device specifically comprises: fault number, fault time, fault temperature value, fault voltage value, fault resistance value and maintenance time.
CN202011405940.0A 2020-12-05 2020-12-05 Fault testing system for mobile communication transmission equipment Active CN112505485B (en)

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