CN107801150B - GPS positioning polling base station alarm-based acquisition method and system - Google Patents
GPS positioning polling base station alarm-based acquisition method and system Download PDFInfo
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Abstract
The invention relates to a method and a system for collecting alarm of a polling base station based on GPS positioning, wherein the collecting method comprises the following steps: acquiring a real-time GPS position of a vehicle, and calculating a cell list in a preset range through a GIS algorithm; summarizing a cell list, sequencing and distributing a base station alarm acquisition task group according to a BSC network element to which the cell belongs, converting the base station alarm acquisition task into a BSC operation instruction, logging in the BSC network element through a Telnet thread for operation, and acquiring a base station alarm event; and filtering the collected base station alarm events according to the alarm problem library to generate an alarm event table, and storing the alarm event table in a database for the corresponding system module to inquire and call. The base station needing polling alarm acquisition in a corresponding range is determined through GPS positioning information of the vehicle and base station information distributed on the periphery, the alarm generated by the mobile communication base station is automatically acquired through a TELNET thread, and an information source is provided for system service modules such as alarm reminding and GIS layer display.
Description
Technical Field
The invention relates to the technical field of alarm information acquisition of mobile communication base stations, in particular to a method and a system for acquiring alarm based on GPS positioning polling base stations.
Background
Along with the large-scale construction of a mobile network, how to master the condition of the whole network in real time and how to sense the performance of the network from the perspective of users become the first problem that wireless network optimizers must solve. The automatic drive test system is used as a new network test means and plays an important role in the optimization work of the wireless network. Traditional manual drive test needs professional test engineers to carry drive test instruments (notebook computer, test mobile phone, inverter, MOS box, GPS), and needs the cooperation of vehicle and driver, needs to spend a large amount of manpower, material resources and time, but the data bulk of gathering is generally less, can't obtain the statistics to Key Performance Index (KPI) of whole network.
Disclosure of Invention
Therefore, a method and a system for acquiring the alarm based on the GPS positioning polling base station are needed to solve the problems that a large amount of manpower, material resources and time are needed, the amount of acquired data is generally small, and the statistics on Key Performance Indicators (KPIs) of the whole network cannot be obtained.
In order to achieve the above object, the inventor provides a method for polling base station alarm acquisition based on GPS positioning, which includes the following steps:
acquiring a real-time GPS position of a vehicle, and calculating a cell list in a preset range through a GIS algorithm;
summarizing a cell list, sequencing and distributing a base station alarm acquisition task group according to a BSC network element to which the cell belongs, converting the base station alarm acquisition task into a BSC operation instruction, logging in the BSC network element through a Telnet thread for operation, and acquiring a base station alarm event;
and filtering the collected base station alarm events according to the alarm problem library to generate an alarm event table, and storing the alarm event table in a database for the corresponding system module to inquire and call.
And further optimizing, wherein the base station alarm acquisition task group comprises a plurality of base station alarm acquisition subtask groups.
Further optimization, the step of acquiring the real-time GPS position of the vehicle and calculating a cell list in a preset range through a GIS algorithm specifically comprises the following steps:
determining longitude and latitude data of all cells involved in the vehicle traveling process;
acquiring a real-time GPS position of a vehicle and predicting longitude and latitude information of the position of the vehicle in the next minute;
calculating and sequencing the distances from all the cells to the current position and the estimated position of the vehicle;
and screening to obtain corresponding cell lists with both distances within a preset range and removing the repetition.
Further optimizing, the summarizing cell list is used for sequencing and distributing a base station alarm acquisition task group according to the BSC network element to which the cell belongs, converting the base station alarm acquisition task into a BSC operation instruction, logging in the BSC network element for operation through a Telnet thread, and acquiring the base station alarm event comprises the following steps:
summarizing a cell list, and acquiring an information list of target network elements to which the cell belongs according to a network element configuration information base, wherein the information list comprises the number of the target network elements and network parameters;
creating a base station alarm acquisition task according to the information list of the target network element;
matching a Telnet command format set in a command configuration library according to the type of the target network element;
and automatically executing Telnet thread login according to the acquired network element parameters, and acquiring a network alarm event according to the matched Telnet command format set.
Further optimization, the filtering the collected base station alarm events according to the alarm problem library to generate an alarm event table, and storing the alarm event table in the database specifically includes:
filtering the alarm time generated by the non-coverage base station and filtering the alarm events with equal intervals of general alarms according to the data question bank;
obtaining the grade of a base station from a database, and grading the filtered alarm event to obtain a weight value Va;
grading according to the influence degree of the filtered alarm event on the call quality to obtain a weighted value Vb;
scoring the filtered alarm event according to an alarm weight configuration table to obtain a weight value Vc;
determining a weighted value V (x Va + y Vb + z Vc) of each alarm time, wherein x, y and z are specific gravity values of each scoring standard;
and sending the alarm event exceeding the threshold value and the corresponding weight value V to the corresponding system module.
The inventor also provides another technical scheme, and the system for acquiring the alarm of the polling base station based on the GPS positioning comprises the following steps:
the acquisition module is used for acquiring the real-time GPS position of the vehicle;
the calculation module is used for calculating a cell list in a preset range through a GIS algorithm;
the task module is used for summarizing a cell list and sequencing and distributing a base station alarm acquisition task group according to the BSC network element to which the cell belongs;
the acquisition module is used for converting the base station alarm acquisition task into a BSC operation instruction, logging in a BSC network element through a Telnet thread for operation and acquiring a base station alarm event;
a screening module for filtering the collected base station alarm event according to the alarm question bank,
and the generating module is used for generating an alarm event table from the screened alarm events, storing the alarm event table into a database and inquiring and calling the corresponding system module.
And further optimizing, wherein the base station alarm acquisition task group comprises a plurality of base station alarm acquisition subtask groups.
Further optimized, the calculation module is configured to:
determining longitude and latitude data of all cells involved in the vehicle traveling process;
the real-time GPS position of the vehicle is obtained through the obtaining module, and the longitude and latitude information of the position of the vehicle in the next minute is estimated;
calculating and sequencing the distances from all the cells to the current position and the estimated position of the vehicle;
and screening to obtain corresponding cell lists with both distances within a preset range and removing the repetition.
Further optimizing, the task module is used for summarizing a cell list, acquiring an information list of a target network element to which the cell belongs according to a network element configuration information base, wherein the information list comprises the number of the target network elements and network parameters, and creating a base station alarm acquisition task according to the information list of the target network elements;
the acquisition module is used for matching a Telnet command format set in a command configuration library according to the type of the target network element;
and automatically executing Telnet thread login according to the acquired network element parameters, and acquiring a network alarm event according to the matched Telnet command format set.
Further preferably, the screening module is further configured to:
obtaining the grade of a base station from a database, and grading the filtered alarm event to obtain a weight value Va;
grading according to the influence degree of the filtered alarm event on the call quality to obtain a weighted value Vb;
scoring the filtered alarm event according to an alarm weight configuration table to obtain a weight value Vc;
determining a weighted value V (x Va + y Vb + z Vc) of each alarm time, wherein x, y and z are specific gravity values of each scoring standard;
and sending the alarm event exceeding the threshold value and the corresponding weight value V to the corresponding system module.
Different from the prior art, the technical scheme determines the base station needing polling alarm acquisition in the corresponding range through the GPS positioning information of the vehicle and the information of the base stations distributed on the periphery, automatically acquires the alarm generated by the mobile communication base station through the TELNET thread, and provides information sources for system service modules such as alarm reminding and GIS layer display. Manpower, material resources and time are saved, and statistics on Key Performance Indicators (KPI) of the whole network can be obtained.
Drawings
FIG. 1 is a schematic flow chart of a method for polling base station alarm acquisition based on GPS positioning according to an embodiment;
FIG. 2 is a list of surrounding cells of the vehicle at point A according to an embodiment;
FIG. 3 is a list of surrounding cells at point B for the vehicle according to the embodiment;
FIG. 4 is a list of surrounding cells at point C for the vehicle according to the embodiment;
FIG. 5 is a list of surrounding cells for a one minute trip at point A for a vehicle according to an embodiment;
fig. 6 shows the number of cells for which each BSC network element needs to collect an alarm in the embodiment;
FIG. 7 is a flowchart illustrating a method for polling base station alarm acquisition based on GPS positioning according to an embodiment;
fig. 8 is a schematic structural diagram of an acquisition system for polling base station alarms based on GPS positioning according to an embodiment.
Detailed Description
To explain technical contents, structural features, and objects and effects of the technical solutions in detail, the following detailed description is given with reference to the accompanying drawings in conjunction with the embodiments.
Referring to fig. 1, the present embodiment is a method for polling base station alarm acquisition based on GPS positioning, including the following steps:
step S110: acquiring a real-time GPS position of a vehicle, and calculating a cell list in a preset range through a GIS algorithm; according to the acquired GPS position of the vehicle, a cell list with the periphery of 2-3 Km is selected by a GIS algorithm, calculation is carried out once every 5-20 seconds, the old cell list is discarded, and a latest monitoring cell list is formed and is stored in a database.
Step S120: summarizing a cell list, sequencing and distributing a base station alarm acquisition task group according to a BSC network element to which the cell belongs, converting the base station alarm acquisition task into a BSC operation instruction, logging in the BSC network element through a Telnet thread for operation, and acquiring a base station alarm event; and summarizing the list of each group of monitoring cells, sequencing and distributing a base station alarm acquisition task group according to the BSC network elements to which the cells belong, converting the base station alarm acquisition task into a BSC operation instruction, logging in the BSC network elements to operate through a Telnet thread, reading the monitoring cells again after all instructions are operated every time, and circularly operating all the times. When the monitored cells are more, the base station alarm acquisition task group is divided into a plurality of base station alarm acquisition task subgroups. Wherein the BSC manages the control unit for the base stations.
Step S130: and filtering the collected base station alarm events according to the alarm problem library to generate an alarm event table, and storing the alarm event table in a database for the corresponding system module to inquire and call. The alarm fields of a plurality of equipment manufacturers are unified to form an alarm question bank, and alarm events can be increased or decreased and monitored. And matching the base station alarm event acquired in each cycle with an alarm problem library, and if the alarm event in the problem library is the alarm event needing attention processing, storing the alarm event in a database for the corresponding module query and call of the system.
The base station needing polling alarm acquisition in a corresponding range is determined through GPS positioning information of the vehicle and base station information distributed on the periphery, the alarm generated by the mobile communication base station is automatically acquired through a TELNET thread, and an information source is provided for system service modules such as alarm reminding and GIS layer display. Manpower, material resources and time are saved, and statistics on Key Performance Indicators (KPI) of the whole network can be obtained.
In step S110, the cell list is obtained by a cell monitoring range algorithm, which specifically includes: determining longitude and latitude data of all cells involved in the vehicle traveling process; acquiring a real-time GPS position of a vehicle and predicting longitude and latitude information of the position of the vehicle in the next minute; calculating and sequencing the distances from all the cells to the current position and the estimated position of the vehicle; and screening to obtain corresponding cell lists with both distances within a preset range and removing the repetition.
In step S120, generating a base station alarm acquisition task through an acquisition task generation algorithm, specifically comprising a summary cell list, and acquiring an information list of a target network element to which a cell belongs according to a network element configuration information base, wherein the information list comprises the number of the target network elements and network parameters; creating a base station alarm acquisition task according to the information list of the target network element; matching a Telnet command format set in a command configuration library according to the type of the target network element; and automatically executing Telnet thread login according to the acquired network element parameters, and acquiring a network alarm event according to the matched Telnet command format set.
In step S130, the alarm is filtered through an alarm event screening algorithm, specifically including filtering the alarm time generated by the non-coverage base station, and filtering the alarm events with equal distances to general alarms according to the data question bank; obtaining the grade of a base station from a database, and grading the filtered alarm event to obtain a weight value Va; grading according to the influence degree of the filtered alarm event on the call quality to obtain a weighted value Vb; scoring the filtered alarm event according to an alarm weight configuration table to obtain a weight value Vc; determining a weighted value V (x Va + y Vb + z Vc) of each alarm time, wherein x, y and z are specific gravity values of each scoring standard, and x + y + z is 1; and sending the alarm event exceeding the threshold value and the corresponding weight value V to the corresponding system module.
The rapid collection and accurate positioning of the base station alarm are realized through a cell monitoring range algorithm, a collection task generation algorithm and an alarm event screening algorithm, and the navigation judgment is supported efficiently.
For example, referring to fig. 2 to 6, the longitude and latitude (119.321732,26.055861) of the point a where the vehicle is currently located are obtained, and the number of surrounding (3Km) cells is calculated to be 430. According to the current vehicle speed of 23.1KM/s and the navigation route coordinate, the longitude and latitude (119.321404,26.055889) passing through the B point and the longitude and latitude (119.320892,26.05592) of the terminal point C in one minute are calculated, and 436 cells and 441 cells around the two longitude and latitude are calculated respectively. And (5) taking the acquisition results of the three longitude and latitude, and performing repeated calculation to obtain the final cell number of 444. And the number of the BSC network elements needing to be acquired is 9, and the cells needing to be acquired by each BSC network element are irregular, so that the task allocation acquisition needs to be performed by performing optimal efficiency acquisition calculation when the task allocation of the BSC network elements is performed. The alarms and weighted values obtained by matching the alarm question bank and the weighted value bank are as follows:
referring to fig. 7, in another embodiment, a method for polling base station alarm acquisition based on GPS positioning in a mobile communication base station monitoring system includes the following steps:
step S210: acquiring task information and creating a main monitoring task thread; and acquiring the GPSID of the relevant vehicle according to the vehicle configuration information required to be monitored, and creating a corresponding number of main monitoring threads according to the number of tasks.
Step S220: acquiring a base station list; the method comprises the steps of obtaining real-time GPS position information of a vehicle, and calculating all base station lists in a preset range through a base station information database based on a GIS position information algorithm, wherein the preset range is 2-3 Km.
The detailed steps of calculating all base station lists in the preset range are as follows: determining longitude and latitude data of all cells involved in the vehicle traveling process; acquiring a real-time GPS position of a vehicle and predicting longitude and latitude information of the position of the vehicle in the next minute; calculating and sequencing the distances from all the cells to the current position and the estimated position of the vehicle; and screening to obtain corresponding cell lists with both distances within a preset range and removing the repetition.
Step S230: creating a base station information acquisition subtask thread; and acquiring an information list of the target network element according to the acquired base station list and a mobile communication network element configuration information base of the implementation environment, wherein the information list comprises the number of the target network elements and network parameters, and the network parameters comprise an IP (Internet protocol), a user name and a password.
Step S240: the base station information acquisition subtask thread runs; according to the type of the target network element, a Telnet command format set is matched in a command configuration library in the command configuration library, according to the obtained network element parameters, Telnet thread login is automatically executed, according to the matched Telnet command format set, a network alarm event is obtained, and the obtained network alarm event is packaged in a unified format.
Because the base station belongs to different BSC (base station management control unit) network element management, the alarm acquisition of each base station can be acquired only by logging in the BSC network element, therefore, the acquired base stations need to be classified to generate different tasks to be operated on each BSC network element, and the detailed steps are as follows:
(1) acquiring the equipment information of all target BSCs based on the obtained base station list, wherein the equipment information comprises the following steps: IP, account number and password.
(2) And entering an acquisition process by adopting a mode that the base station under the same BSC is an independent task.
(3) And performing parallel multi-task acquisition in a mode that each BSC is an independent running thread.
(4) The collection process comprises the following steps:
a. and automatically matching and acquiring the command set of the mml according to the base station list.
b. Logging in corresponding BSC network element in an automatic Telnet mode, executing corresponding command, and obtaining
And taking the current alarm information data stream of the base station.
c. And analyzing the acquired alarm information data stream to acquire effective alarm information elements.
d. And packaging all the alarm information in a unified format.
Step S250: processing network alarm information; and weighting the network alarm event acquired by each subtask thread through an event weighting library, and filtering out alarm time with high level according to the priority level.
The method has the following detailed steps that the collected alarm events are more, and the alarm has the largest influence on the call quality and needs to be filtered by certain calculation:
(1) screening based on the alarm event information obtained by the acquisition module:
a. filtering alarm events generated by non-covered road base stations, e.g. "indoor covered base stations"
b. And filtering the event information of the general alarm level according to an alarm library configured by the system.
(2) Grading the influence degree of the screened alarm event result:
a. and (4) obtaining the alarm event corresponding to the grade (the proportion of the coverage road surface, whether the main control cell exists or not and the fault rate) of the base station according to the historical test database, and grading to obtain a weight value Va.
b. And scoring according to the influence degree of the alarm on the call quality to obtain a weighted value Vb.
c. And scoring the alarm event according to an alarm weight configuration table of artificial subjective judgment to obtain a weight value Vc.
d. Determining the weight V of each alarm event: v ═ Va) + (y × Vb) + (z × Vc), where x, y, z are specific gravity values for each scoring criterion, and can be configured by the system according to empirical values of practical application.
(3) And sending the alarm event exceeding the threshold value and the corresponding weight V to the corresponding system module.
Step S260: distributing alarm information; and issuing the screened network alarm time to corresponding terminal equipment according to the corresponding relation between the base station number and the ID of the terminal.
The method comprises the steps that a vehicle driver carries out acquisition according to terminal navigation prompts after data are issued by a server and tasks are customized and terminal data are synchronized, the server collects information such as network alarms in real time according to a polling algorithm and sends the information to a front end, the terminal issues an alarm information machine according to the server and gives weights to all road sections, optimal routes are generated for acquiring problem road sections according to a problem path automatic algorithm, and navigation prompts are generated; the server carries out signaling tracking, analyzes the cause of the problem in real time, monitors the GIS presentation in a background, tracks the vehicle track and navigation information in real time, and monitors the network and network alarm events generated by testing; the server collects structural statistics, automatically commands scheduling and presents the problem reasons in real time.
Referring to fig. 8, in another embodiment, a system 300 for polling base station alarms based on GPS positioning includes:
an obtaining module 310, configured to obtain a vehicle real-time GPS location; and acquiring the GPSID of the vehicle and acquiring the GPS position information of the vehicle in real time.
A calculating module 320, configured to calculate a cell list within a preset range through a GIS algorithm; according to the acquired GPS position of the vehicle, a cell list with the periphery of 2-3 Km is selected by a GIS algorithm, calculation is carried out once every 5-20 seconds, the old cell list is discarded, and a latest monitoring cell list is formed and is stored in a database.
The calculation module 320 is used for determining longitude and latitude data of all cells involved in the vehicle traveling process; acquiring a real-time GPS position of a vehicle and predicting longitude and latitude information of the position of the vehicle in the next minute; calculating and sequencing the distances from all the cells to the current position and the estimated position of the vehicle; and screening to obtain corresponding cell lists with both distances within a preset range and removing the repetition.
The task module 330 is used for summarizing a cell list and performing sequencing and distributing a base station alarm acquisition task group according to a BSC network element to which the cell belongs; and summarizing the monitoring cell lists of each group, and sequencing and distributing the base station alarm acquisition task groups according to the BSC network elements to which the cells belong. When the monitored cells are more, the base station alarm acquisition task group is divided into a plurality of base station alarm acquisition task subgroups.
The acquisition module 340 is used for converting the base station alarm acquisition task into a BSC operation instruction, logging in a BSC network element for operation through a Telnet thread, and acquiring a base station alarm event; the acquisition module converts the base station alarm acquisition task into a BSC operation instruction, logs in a BSC network element through a Telnet thread to operate, acquires the base station alarm event, reads the monitoring cell again after all instructions are operated each time, and operates circularly all the time.
The task module 330 generates a base station alarm acquisition task through an acquisition task generation algorithm, specifically includes summarizing a cell list, and acquiring an information list of a target network element to which a cell belongs according to a network element configuration information base, including the number of the target network elements and network parameters; creating a base station alarm acquisition task according to the information list of the target network element; the acquisition module 340 matches a Telnet command format set in a command configuration library according to the type of the target network element; and automatically executing Telnet thread login according to the acquired network element parameters, and acquiring a network alarm event according to the matched Telnet command format set.
A filtering module 350, configured to filter the collected base station alarm events according to the alarm question bank,
the filtering module 350 is configured to filter alarms through an alarm event filtering algorithm, specifically including filtering alarm time generated by the non-coverage base station, and filtering alarm events at equal intervals of general alarms according to a data question bank; obtaining the grade of a base station from a database, and grading the filtered alarm event to obtain a weight value Va; grading according to the influence degree of the filtered alarm event on the call quality to obtain a weighted value Vb; scoring the filtered alarm event according to an alarm weight configuration table to obtain a weight value Vc; determining a weighted value V (x Va + y Vb + z Vc) of each alarm time, wherein x, y and z are specific gravity values of each scoring standard, and x + y + z is 1; and sending the alarm event exceeding the threshold value and the corresponding weight value V to the corresponding system module.
And the generating module 360 is configured to generate an alarm event table from the screened alarm events, store the alarm event table in a database, and provide the alarm event table for the corresponding system module to query and call. The alarm fields of a plurality of equipment manufacturers are unified to form an alarm question bank, and alarm events can be increased or decreased and monitored. Matching the base station alarm event collected in each circulation with the alarm question bank, if the alarm event in the question bank is the alarm event needing attention processing, storing the alarm event in the database for the corresponding system module to inquire and call
The base station needing polling alarm acquisition in a corresponding range is determined through GPS positioning information of the vehicle and base station information distributed on the periphery, the alarm generated by the mobile communication base station is automatically acquired through a TELNET thread, and an information source is provided for system service modules such as alarm reminding and GIS layer display. Manpower, material resources and time are saved, and statistics on Key Performance Indicators (KPI) of the whole network can be obtained. Meanwhile, the rapid acquisition and the accurate positioning of the base station alarm are realized through a cell monitoring range algorithm, an acquisition task generation algorithm and an alarm event screening algorithm, and the navigation judgment is supported efficiently.
It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or terminal that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or terminal. Without further limitation, an element defined by the phrases "comprising … …" or "comprising … …" does not exclude the presence of additional elements in a process, method, article, or terminal that comprises the element. Further, herein, "greater than," "less than," "more than," and the like are understood to exclude the present numbers; the terms "above", "below", "within" and the like are to be understood as including the number.
As will be appreciated by one skilled in the art, the above-described embodiments may be provided as a method, apparatus, or computer program product. These embodiments may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. All or part of the steps in the methods according to the embodiments may be implemented by a program instructing associated hardware, where the program may be stored in a storage medium readable by a computer device and used to execute all or part of the steps in the methods according to the embodiments. The computer devices, including but not limited to: personal computers, servers, general-purpose computers, special-purpose computers, network devices, embedded devices, programmable devices, intelligent mobile terminals, intelligent home devices, wearable intelligent devices, vehicle-mounted intelligent devices, and the like; the storage medium includes but is not limited to: RAM, ROM, magnetic disk, magnetic tape, optical disk, flash memory, U disk, removable hard disk, memory card, memory stick, network server storage, network cloud storage, etc.
The various embodiments described above are described with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems), and computer program products according to embodiments. It will be understood that each flow and/or block of the flow diagrams and/or block diagrams, and combinations of flows and/or blocks in the flow diagrams and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to a processor of a computer apparatus to produce a machine, such that the instructions, which execute via the processor of the computer apparatus, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.
These computer program instructions may also be stored in a computer-readable memory that can direct a computer device to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.
These computer program instructions may also be loaded onto a computer apparatus to cause a series of operational steps to be performed on the computer apparatus to produce a computer implemented process such that the instructions which execute on the computer apparatus provide steps for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.
Although the embodiments have been described, once the basic inventive concept is obtained, other variations and modifications of these embodiments can be made by those skilled in the art, so that the above embodiments are only examples of the present invention, and not intended to limit the scope of the present invention, and all equivalent structures or equivalent processes using the contents of the present specification and drawings, or any other related technical fields, which are directly or indirectly applied thereto, are included in the scope of the present invention.
Claims (10)
1. A GPS positioning polling base station alarm-based acquisition method is characterized by comprising the following steps:
acquiring a real-time GPS position of a vehicle, and calculating a cell list in a preset range through a GIS algorithm;
summarizing a cell list, sequencing and distributing a base station alarm acquisition task group according to a BSC network element to which the cell belongs, converting the base station alarm acquisition task into a BSC operation instruction, logging in the BSC network element through a Telnet thread for operation, and acquiring a base station alarm event;
and filtering the collected base station alarm events according to the alarm problem library to generate an alarm event table, and storing the alarm event table in a database for the corresponding system module to inquire and call.
2. The method for polling base station alarm acquisition based on GPS positioning as recited in claim 1, wherein said base station alarm acquisition task group comprises a plurality of base station alarm acquisition subtask groups.
3. The method for polling base station alarm acquisition based on GPS positioning according to claim 1, wherein the "acquiring the real-time GPS position of the vehicle and calculating the cell list within the preset range by the GIS algorithm" specifically comprises:
determining longitude and latitude data of all cells involved in the vehicle traveling process;
acquiring a real-time GPS position of a vehicle and predicting longitude and latitude information of the position of the vehicle in the next minute;
calculating and sequencing the distances from all the cells to the current position and the estimated position of the vehicle;
and screening to obtain corresponding cell lists with both distances within a preset range and removing the repetition.
4. The method for acquiring GPS positioning polling base station alarm according to claim 1, wherein the step of summarizing the cell list, sorting and distributing the base station alarm acquisition task group according to the BSC network element to which the cell belongs, converting the base station alarm acquisition task into a BSC operation instruction, logging in the BSC network element for operation through a Telnet thread, and acquiring the base station alarm event comprises the steps of:
summarizing a cell list, and acquiring an information list of target network elements to which the cell belongs according to a network element configuration information base, wherein the information list comprises the number of the target network elements and network parameters;
creating a base station alarm acquisition task according to the information list of the target network element;
matching a Telnet command format set in a command configuration library according to the type of the target network element;
and automatically executing Telnet thread login according to the acquired network element parameters, and acquiring a network alarm event according to the matched Telnet command format set.
5. The method for collecting GPS positioning polling base station alarm according to claim 1, wherein the step of filtering the collected base station alarm event according to the alarm problem database to generate the alarm event table and storing the alarm event table in the database includes:
filtering the alarm time generated by the non-coverage base station and filtering the alarm events with equal intervals of general alarms according to the data question bank;
obtaining the grade of a base station from a database, and grading the filtered alarm event to obtain a weight value Va;
grading according to the influence degree of the filtered alarm event on the call quality to obtain a weighted value Vb;
scoring the filtered alarm event according to an alarm weight configuration table to obtain a weight value Vc;
determining a weighted value V (x Va + y Vb + z Vc) of each alarm time, wherein x, y and z are specific gravity values of each scoring standard;
and sending the alarm event exceeding the threshold value and the corresponding weight value V to the corresponding system module.
6. A GPS positioning based base station alarm polling acquisition system is characterized by comprising:
the acquisition module is used for acquiring the real-time GPS position of the vehicle;
the calculation module is used for calculating a cell list in a preset range through a GIS algorithm;
the task module is used for summarizing a cell list and sequencing and distributing a base station alarm acquisition task group according to the BSC network element to which the cell belongs;
the acquisition module is used for converting the base station alarm acquisition task into a BSC operation instruction, logging in a BSC network element through a Telnet thread for operation and acquiring a base station alarm event;
a screening module for filtering the collected base station alarm event according to the alarm question bank,
and the generating module is used for generating an alarm event table from the screened alarm events, storing the alarm event table into a database and inquiring and calling the corresponding system module.
7. The system for polling base station alarms based on GPS positioning of claim 6 wherein the set of base station alarm collection tasks includes a plurality of base station alarm collection subtasks.
8. The GPS location based polling base station alarm acquisition system of claim 6, wherein the computing module is configured to:
determining longitude and latitude data of all cells involved in the vehicle traveling process;
the real-time GPS position of the vehicle is obtained through the obtaining module, and the longitude and latitude information of the position of the vehicle in the next minute is estimated;
calculating and sequencing the distances from all the cells to the current position and the estimated position of the vehicle;
and screening to obtain corresponding cell lists with both distances within a preset range and removing the repetition.
9. The GPS-based positioning polling base station alarm acquisition system of claim 6, wherein the task module is used for summarizing a cell list, acquiring an information list of a target network element to which the cell belongs according to a network element configuration information base, wherein the information list comprises the number of the target network elements and network parameters, and creating a base station alarm acquisition task according to the information list of the target network element;
the acquisition module is used for matching a Telnet command format set in a command configuration library according to the type of the target network element;
and automatically executing Telnet thread login according to the acquired network element parameters, and acquiring a network alarm event according to the matched Telnet command format set.
10. The system for polling base station alarm acquisition based on GPS location of claim 6 wherein the filtering module is further configured to:
obtaining the grade of a base station from a database, and grading the filtered alarm event to obtain a weight value Va;
grading according to the influence degree of the filtered alarm event on the call quality to obtain a weighted value Vb;
scoring the filtered alarm event according to an alarm weight configuration table to obtain a weight value Vc;
determining a weighted value V (x Va + y Vb + z Vc) of each alarm time, wherein x, y and z are specific gravity values of each scoring standard;
and sending the alarm event exceeding the threshold value and the corresponding weight value V to the corresponding system module.
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