CN109167688B - Geographical monitoring platform for wireless network optimization analysis and implementation method - Google Patents

Abstract

The invention discloses a geographical monitoring platform for wireless network optimization analysis and an implementation method thereof, and relates to the technical field of wireless network communication. The method has the advantages that the real-time embedding of the geographic satellite images is realized on the map, so that the analysis work combined with the geography is simplified and accurate, and the analysis efficiency of field workers is improved; through the presentation of the geographical indexes, the indexes can indicate position information, so that field personnel can quickly locate an area with a communication fault; by establishing the switching pull line based on the geographic picture, the user changes the monotonous and complicated form once, so that the analysis of the switching problem becomes visual and efficient; therefore, by adopting the monitoring platform and the implementation method provided by the invention, in the wireless network optimization work, a user can finish the rapid presentation, analysis and positioning of various index problems based on the geographical information so as to improve the accuracy of analysis and the operability of work.

Description

Geographical monitoring platform for wireless network optimization analysis and implementation method

Technical Field

The invention relates to the technical field of wireless network communication, in particular to a geographical monitoring platform for wireless network optimization analysis and an implementation method.

Background

The wireless network optimization is to analyze the traffic data of the existing running network, find out the reasons influencing the network quality by means of road test, parameter check, hardware monitoring and the like, ensure the high-quality running of the system by means of parameter modification, network structure or equipment configuration adjustment and certain technical means (adopting MRP planning method and the like), ensure the best benefits of the existing network resources and obtain the maximum benefits by the most economic investment.

At present, many works in wireless network optimization analysis need to combine geographical pictures to perform index presentation and analysis. Generally, the adopted method is that a thematic map layer is created to present indexes of a single time point, and index analysis also needs to utilize longitude and latitude information of a site to open a google map to position to an approximate position area. For example, when monitoring and analyzing a problem with the condition of a wireless network in a city, an engineer is usually required to perform the following steps:

step 1, manually inquiring a network management database to obtain index condition data of a network in a certain period and storing the index condition data in an EXCEL type table form.

And 2, matching and combining the EXCEL table with the index information and the engineering parameter information table (containing site position information) into a table which not only contains site position information but also contains site network condition.

And 3, importing the information in the table into map software, and creating a base station layer by the map software according to the imported work parameter information so as to realize the presentation of a simple base station layer on the geographical position.

And 4, setting thresholds of various indexes (such as call completing rate and switching success rate) in the table by using the thematic map layer function of the map software, wherein the base station completing rate is lower than 90% of filling red, more than 90% of filling yellow and less than 100% of filling yellow, and is equal to 100% of filling green.

And step 5, through the operation, an engineer can see the position situation of the relevant sites and the index deterioration situation of each site on a map, so that the further analysis of the network problem deterioration is carried out according to the distance between the sites, the antenna direction and the like. If the blocking of the signal by buildings and mountain bodies is considered, Google earth software needs to be additionally started to indirectly acquire the topographic information.

This workflow has the following disadvantages: the index monitoring and analyzing is a routine work, and an engineer needs to operate the operation according to the procedures at intervals, so that the field working efficiency is extremely low, the data collection and presentation processes are complicated and time-consuming, and the handling control of the network is seriously delayed. Meanwhile, because similar map software does not provide a live-action map, the analysis cannot take the influence of factors such as geographic landform, street view and the like on the wireless signals into consideration. Even if Google earth software is additionally started, because the Google earth and the map software cannot be completely synchronized when an operator operates in real time, analysis errors can be caused, and the analysis accuracy is influenced. In addition, the method can lead the time point of the indicator presentation to be single, the information of the base station layer to be monotonous, and the combination with the geographic analysis operation to be complicated and the positioning position to be inaccurate and unintuitive.

Disclosure of Invention

The invention aims to provide a geographical monitoring platform for wireless network optimization analysis and an implementation method thereof, so as to solve the problems in the prior art.

In order to achieve the purpose, the technical scheme adopted by the invention is as follows:

a geographic monitoring platform for wireless network optimization analysis, comprising:

the main map module is used for developing a map by taking the general map component as a main body and providing the presentation of a data layer, the information query and the function operation of a thematic layer for a user;

the geographic and physical landscape real-time presentation module is used for constructing a corresponding online map in real time according to the acquired map information inquired by the user, intercepting a geographic landscape photo presented by the online map, and embedding the photo into the bottom layer of a main map interface inquired by the user;

the geographical index presentation module is used for transmitting geographical index data inquired from the remote network management database to the main map module in an array form and presenting the geographical index data on the main map in a thematic map layer form;

and the switching pull line module is used for accessing the remote network management database by using the ADO, transmitting the inquired switching index data to the main map module, and drawing a switching pull line capable of expressing the switching index data on the main map in real time according to the switching index data.

Preferably, the monitoring platform further comprises a Baidu map module, which is used for realizing the connection between the Baidu map and the main map module by using longitude and latitude data, and realizing the query of the place name on the main map by using the Baidu map.

Preferably, the real-time presentation method including the geographic map is implemented as follows:

a1, monitoring the dragging operation of a user on a map in real time, and acquiring the longitude and latitude of the center where the map is located last and the visual field range presented by the map after the user finishes the operation of dragging the map, wherein the visual field range is the longitude and latitude of the upper left, lower left, upper right and lower right fixed points of the map interface;

a2, constructing an online map corresponding to the obtained data of the central longitude and latitude and the visual field range in real time according to the obtained data of the central longitude and latitude and the visual field range, and displaying a geographical picture under the central longitude and latitude and the visual field range on the online map;

a3, acquiring a photo of a geographical picture;

a4, performing longitude and latitude calibration correction on the geographic physiognomy photo and the visual field range through a rasterization layer function provided by MapX;

and A5, embedding the geographic landscape photo into the bottom layer of the main map interface of the user, and realizing the presentation of the geographic landscape information of the map.

Preferably, a2 includes:

a201, transmitting the acquired data of the central longitude and latitude and the field of view to a Webbrower component;

a202, constructing a Google online map in the Webbrower component in real time by a JavaScript language according to the data information, and presenting a geographical map appearance presented by the Google map under the central longitude latitude and the visual field range.

Preferably, a202 further comprises the steps of: and acquiring altitude information in the geographic landform.

Preferably, the method for presenting the geographical index comprises the following steps:

b1, according to the user's request, making access inquiry to the remote network management database to obtain the needed geographic index data;

and B2, performing association binding on the obtained geographic index data and the layer information, so that the layer has the geographic index data information.

Preferably, in B1, the request of the user is specifically that the user writes or selects an index database script that needs to be queried by himself; the access query of the remote network management database is specifically carried out on the basis of an ADO component; b2, performing association binding on the obtained geographic index data and the layer information, specifically, performing association binding on the obtained geographic index data and the layer information by a datasets.

Preferably, the method further includes a step B3 of filling different colors to show the network status of each site in the current network according to the numerical conditions of each index of each site by using a thematic map layer method provided by mapx.

Preferably, the geographical indicators that can be presented are all indicators related to the base station, including: user access success rate, handover success rate, disconnection rate, ERAB establishment success rate, uplink and downlink data delay and flow.

Preferably, the method for drawing the switching pull line based on the map is implemented as follows:

c1, configuring an information selection frame on the map interface, wherein the information selection frame comprises a layer selection frame and a data set information selection frame, and when a user clicks any one base station on the map or selects a plurality of base stations in a frame, the map interface can be combined with the layer and the data set selected by the user to quickly identify the switching index between the source base station and the target base station which the user needs to check;

c2, after the base station list is obtained, accessing a remote network management database to obtain the switching index data of the station;

c3, after completing the acquisition of the switching index, accessing the latitude and longitude, the direction angle and the lobe length information of the target base station and the source base station stored in the local database;

c4, according to the acquired longitude and latitude, direction angle and lobe length data of the source base station and the target base station, determining the position data of the source base station and the target base station by the criterion of two points and one line, and connecting the two points to complete drawing of a solid arrow of the switching relation;

c5, obtaining the switching index data of the source base station and the target base station according to the switching index data, and binding the data on the drawn solid arrows in a manner of data sets.add of mapx, so that each solid arrow carries corresponding switching index information;

and C6, modifying the thickness and the color of the drawn line to represent the number of times of switching and the switching success rate respectively.

The invention has the beneficial effects that: the embodiment of the invention provides a geographic monitoring platform for wireless network optimization analysis and an implementation method thereof, which realize real-time embedding of geographic satellite images on a map, simplify and correct analysis work combined with geography, and improve the analysis efficiency of field workers; through the presentation of the geographical indexes, the indexes can indicate position information, so that field personnel can quickly locate an area with a communication fault; by establishing the switching pull line based on the geographic picture, the user changes the monotonous and complicated form once, so that the analysis of the switching problem becomes visual and efficient; therefore, by adopting the monitoring platform and the implementation method provided by the invention, in the wireless network optimization work, a user can finish the rapid presentation, analysis and positioning of various index problems based on the geographical information so as to improve the accuracy of analysis and the operability of work.

Drawings

FIG. 1 is a schematic structural diagram of a geographic monitoring platform provided by the present invention;

FIG. 2 is a schematic diagram of a layer structure of a main map provided by the present invention;

FIG. 3 is a flow chart diagram of a method of geographic landscape presentation;

FIG. 4 is a schematic illustration of information presentation on a data map layer;

FIG. 5 is a schematic diagram of a map effect for real-time presentation of geographic features;

FIG. 6 is a schematic diagram showing the effect of geographic metric data;

fig. 7 is a flow chart diagram of a drawing method of a map-based switching pull line;

FIG. 8 is a diagram illustrating the effect of configuring an information selection box on a map interface;

fig. 9 is a plot of handover index data presentation for a site in a remote OMC database;

FIG. 10 is a diagram of information presentation for sites in a local OMC database;

fig. 11 is a diagram illustrating the effect of the map with the switching pull line.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail below with reference to the accompanying drawings. It should be understood that the detailed description and specific examples, while indicating the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention.

Aiming at the problems that the data collection and presentation processes are complicated, the problem analysis is not comprehensive enough and the like in the prior art, the working process is expected to be concentrated into a unified platform through programming, a program replaces an engineer to quickly realize the collection and presentation of the data, meanwhile, information such as geographical pictures and appearances are fused into the platform, the analysis range of the engineer is expanded, and the problem analysis and positioning are more direct and accurate.

Example one

As shown in fig. 1, an embodiment of the present invention provides a geographic monitoring platform for wireless network optimization analysis, including:

the main map module is used for developing a map by taking the general map component as a main body and providing the presentation of a data layer, the information query and the function operation of a thematic layer for a user;

the geographic and physical landscape real-time presentation module is used for constructing a corresponding online map in real time according to the acquired map information inquired by the user, intercepting a geographic landscape photo presented by the online map, and embedding the photo into the bottom layer of a main map interface inquired by the user;

the geographical index presentation module is used for transmitting geographical index data inquired from the remote network management database to the main map module in an array form and presenting the geographical index data on the main map in a thematic map layer form;

and the switching pull line module is used for accessing the remote network management database by using the ADO, transmitting the inquired switching index data to the main map module, and drawing a switching pull line capable of expressing the switching index data on the main map in real time according to the switching index data.

In a preferred embodiment of the present invention, the monitoring platform further includes a Baidu map module, which is configured to utilize longitude and latitude data to implement the connection between the Baidu map and the main map module, and utilize the Baidu map to implement the query of the place name on the main map.

In the monitoring platform of the above-mentioned structure,

the main map module is a map development module taking a general map component as a main body, and performs deep function development through a function library provided by the general map component and a control group provided by a VB (visual basic) to provide functional operations such as data layer presentation, information query, thematic layer and the like for a user. The effect it exhibits is shown in figure 2.

The geographic and physical landscape real-time presentation module is used for constructing a corresponding online map in real time according to the acquired map information inquired by the user, intercepting a geographic landscape photo presented by the online map, and embedding the photo into the bottom layer of a main map interface inquired by the user;

the geographical index presentation module has the query function of a network management database and presents the current index situation on the main map in the form of a thematic layer, the data transmission of the index data and the main map is realized by transmitting the index data to the main map in the form of an array, and the geographical presentation of the index is realized by the thematic layer function of the main map module. And the switching pull line module accesses a remote network management database by using the ADO, transmits the inquired switching index to the main map module in an ADODB (advanced data base) mode, and then draws an arrow straight line in real time by the main map module according to the index value.

The Baidu map module provides the connection between the Baidu map and the main map module, the connection is realized by transmitting longitude and latitude data between the two modules, and the Baidu map module can be mainly used for realizing the function of inquiring the place name.

Example two

As shown in fig. 3, an embodiment of the present invention provides an implementation method of a geographic monitoring platform for wireless network optimization analysis, including a real-time geographic map presentation method, which can be implemented according to the following method:

a1, monitoring the dragging operation of a user on a map in real time, and acquiring the longitude and latitude of the center where the map is located last and the visual field range presented by the map after the user finishes the operation of dragging the map, wherein the visual field range is the longitude and latitude of the upper left, lower left, upper right and lower right fixed points of the map interface;

a2, constructing an online map corresponding to the obtained data of the central longitude and latitude and the visual field range in real time according to the obtained data of the central longitude and latitude and the visual field range, and displaying a geographical picture under the central longitude and latitude and the visual field range on the online map;

a3, acquiring a photo of a geographical picture;

a4, performing longitude and latitude calibration correction on the geographic physiognomy photo and the visual field range through a rasterization layer function provided by MapX;

and A5, embedding the geographic landscape photo into the bottom layer of the main map interface of the user, and realizing the presentation of the geographic landscape information of the map.

In a preferred embodiment of the present invention, a2 may include:

a201, transmitting the acquired data of the central longitude and latitude and the field of view to a Webbrower component;

a202, constructing a Google online map in the Webbrower component in real time by a JavaScript language according to the data information, and presenting a geographical map appearance presented by the Google map under the central longitude latitude and the visual field range.

Wherein, a202 may further include the steps of: and acquiring altitude information in the geographic landform.

In this embodiment, the method for presenting geographic features in real time has the following beneficial effects and meanings:

in the wireless network optimization analysis, for example, in the signal attenuation analysis, the propagation of wireless network signals is blocked by mountains and buildings, so that serious attenuation occurs, and in the terminal user, the signal is weak, and the call making is disconnected or the internet surfing speed is slow. When no geographic landform is introduced, when an engineer finds that the coverage index of a certain base station is deviated or a certain area has user complaints, whether a walking path of a wireless signal from a transmitting end to a receiving end is influenced by buildings and mountains or not can not be known from a single data map layer, so that the analysis idea is single. As shown in fig. 4, the engineer can only see the base station location and the approximate distance between the base station and the user complaint location, and cannot perform further refinement analysis.

By adopting the method provided by the embodiment of the invention, after the geographical landform can be presented on the map in real time, as shown in fig. 5, engineers can see the wireless signal wave transmitted from the site, which is blocked by multiple rows of residential buildings, the elevation of the site relative to users is low, and the signal is blocked by mountains, so that when the wireless signal of the site reaches the served user area, the signal strength is seriously weakened, and the problems of poor wireless signal coverage index and user complaint are caused.

Therefore, by inserting geographic features, engineers can accurately analyze the problems of poor user signal and poor base station coverage as mountain body blockage and wireless signal attenuation of buildings, and further provide a reasonable solution of moving the base station to a mountain body with a raised middle, so that the signal can directly reach a user residential area, and meanwhile, the transmission power is provided to reduce the signal attenuation of the buildings.

The implementation method of the geographic monitoring platform for wireless network optimization analysis provided by the embodiment of the invention further comprises a presentation method of geographic and physical indicators, and can be implemented according to the following method:

b1, according to the user's request, making access inquiry to the remote network management database to obtain the needed geographic index data;

and B2, performing association binding on the obtained geographic index data and the layer information, so that the layer has the geographic index data information.

In B1, the request of the user may specifically be that the user writes or selects an index database script that needs to be queried by himself; the access query of the remote network management database can be specifically carried out on the basis of an ADO component; b2, the obtained geographic index data and the layer information are associated and bound, specifically, the obtained geographic index data and the layer information are associated and bound by a datasets.

In the embodiment of the present invention, step B3 may also be included, in which different colors are filled to show the network status of each site in the current network according to the numerical condition of each index of each site by using a thematic map layer method provided by mapx.

The geographic indexes that can be presented are all indexes related to the base station, including: user access success rate, handover success rate, disconnection rate, ERAB establishment success rate, uplink and downlink data delay and flow.

In the prior art, although the daily index presentation can also be presented in a range that different index values are represented by color blocks of a thematic map layer on a map, the disadvantages of the presentation modes are mentioned before, one is that the operation flow is too long, the data collection and presentation steps are tedious, the repeatability is high, no geographical landform is presented, meanwhile, the possibility of drawing on the map for multiple continuous periods is not provided, and the index change situation of each site in each period cannot be presented naturally,

by adopting the method provided by the embodiment of the invention, the display of the map on the geographical landform is realized in a mode of inserting the picture in real time on the landform, and meanwhile, the data collection and mapping automation of daily index analysis can be realized by binding the data sets of the Mapx and accessing the remote database of the ADO, so that the daily work content is simplified, and the work efficiency is improved.

In the practical implementation process of the method, a database script read-write rule can be compiled, after a user compiles the database script according to a certain rule, a program can automatically understand the database script compiled by the user, then automatically accesses a network management remote database to fetch data, binds the data in the existing layer through data.

By adopting the method provided by the invention, the effect of presenting the geographic index data can be shown in fig. 6. In the figure, for example, for the presentation of the switching success rate, the indicator situation is presented by filling in different colors. If the sites with degraded indexes are located in busy important blocks (with huge influence on people) such as pedestrian streets, the problems of degraded switching success rate and the influence degree of the problems on the sites on the map can be intuitively known by combining geographical features.

As shown in fig. 7, the implementation method of the geographic monitoring platform for wireless network optimization analysis according to the embodiment of the present invention further includes a method for drawing a switching pull line based on a map, which can be implemented as follows:

c1, configuring an information selection box on the map interface, including a layer selection box and a data set information selection box, as shown in fig. 8, when a user clicks any one base station on the map or selects a plurality of base stations by frames, the map interface can combine the layer and the data set selected by the user to quickly identify the switching index between the source base station and the target base station that the user needs to check;

c2, after the base station list is obtained, accessing a remote network management database to obtain the switching index data of the station; wherein, the switching index data of the sites in the remote network management database can be seen in fig. 9;

c3, after completing the acquisition of the handover index, accessing the latitude and longitude, the direction angle and the lobe length information of the target base station and the source base station stored in the local database, as shown in fig. 10;

c4, according to the acquired longitude and latitude, direction angle and lobe length data of the source base station and the target base station, determining the position data of the source base station and the target base station by the criterion of two points and one line, and connecting the two points to complete drawing of a solid arrow of the switching relation;

c5, obtaining the switching index data of the source base station and the target base station according to the switching index data, and binding the data on the drawn solid arrows in a manner of data sets.add of mapx, so that each solid arrow carries corresponding switching index information;

and C6, modifying the thickness and the color of the drawn line to represent the number of times of switching and the switching success rate respectively.

In the above method, it is necessary to explain what is the handover, and the definition of the handover pull line.

A large wireless network is constructed by thousands of base stations, the geographical position change of a user in the network can transfer a mobile phone terminal from the service area of the base station A to the service area of the base station B, in order to avoid the problems of call drop and disconnection of the user in the position change process, the source base station A carries out communication negotiation with the target station B, the next call and internet data packet of the user are cached in the source base station, and after the user accesses the target station, the data packet is transferred to the target station to keep communication connection, and the process is called switching.

The switching index indicates whether the user can successfully complete the conversion between the data packet information and the control information, and the index directly reflects whether the user has the problems of call drop and internet access drop in the moving process.

In the present invention, the switching cord is defined as follows: according to the switching index data, the switching relation between the cells is expressed in a one-to-one mode by drawing solid line arrows on a map, then the index value of the switching success rate between the cells is represented by different colors of the solid line arrows, and the switching times between the cells (namely the switching frequency between the cells) are reduced by the thickness degree of the solid line.

In the prior art, daily switching index conditions are read in a form of a table, geographic directions, landforms and other factors cannot be fused together, the analysis mode is boring and single and extremely unintuitive, engineers need to have extremely high space imagination, and the analysis difficulty of switching indexes is further increased.

The following table shows daily switching index data of a certain station which is touched by an engineer daily, and it can be seen that a switching relationship occurs between the source base station xiaana jiao-LNHN-1 and 30 peripheral stations at 12 points (if a time period is prolonged to a whole day or the station is in a dense area in the city center, hundreds of rows of data exist), for ordinary people, reading the data is disordered, and on the basis, information such as longitude and latitude, direction angle and the like of the station is combined, and the relative position, distance, azimuth angle and switching index condition between the station and the peripheral stations are constructed in the brain sea.

Aiming at the problem, in the method provided by the invention, the switching index information is automatically read through a program, then the switching relation between the sites is presented on a map in a solid line arrow drawing mode, and the close relation and the switching success rate condition of switching between the sites are respectively presented through the thickness and the color of the arrows, as shown in fig. 11, boring data is changed into a colorful color line with a space vector, and visual and concise reading analysis experience is provided for engineers.

The monitoring platform and the implementation method provided by the invention have the following beneficial effects:

1. the real-time embedding of the geographic satellite images simplifies and accuracies the analysis work of the geography, and improves the analysis efficiency of field workers.

2. The indexes are displayed geographically, so that the indexes can indicate position information, and field personnel can quickly locate an area with a communication fault.

3. The switching pull line established based on the geographic map changes the monotonous and complex form of the user, and the analysis of the switching problem becomes intuitive and efficient.

4. The introduction of the attached hundredth map can quickly locate the base station which is responsible for the coverage of the area by combining the rough position described by the complaint of the user.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, various modifications and improvements can be made without departing from the principle of the present invention, and such modifications and improvements should also be considered within the scope of the present invention.

Claims (6)

1. A geographic monitoring platform for wireless network optimization analysis, comprising:

the main map module is used for developing a map by taking the general map component as a main body and providing the presentation of a data layer, the information query and the function operation of a thematic layer for a user;

the geographic and physical landscape real-time presentation module is used for constructing a corresponding online map in real time according to the acquired map information inquired by the user, intercepting a geographic landscape photo presented by the online map, and embedding the photo into the bottom layer of a main map interface inquired by the user;

the geographical index presentation module is used for transmitting geographical index data inquired from the remote network management database to the main map module in an array form and presenting the geographical index data on the main map in a thematic map layer form;

the switching pull line module is used for accessing a remote network management database by using ADO (Adado data acquisition), transmitting the inquired switching index data to the main map module, and drawing a switching pull line capable of expressing the switching index data on the main map in real time according to the switching index data;

the real-time presentation of the geographic map is implemented according to the following method:

a1, monitoring the dragging operation of a user on a map in real time, and acquiring the longitude and latitude of the center where the map is located last and the visual field range presented by the map after the user finishes the operation of dragging the map, wherein the visual field range is the longitude and latitude of the upper left, lower left, upper right and lower right fixed points of the map interface;

a2, constructing an online map corresponding to the obtained data of the central longitude and latitude and the visual field range in real time according to the obtained data of the central longitude and latitude and the visual field range, and displaying a geographical picture under the central longitude and latitude and the visual field range on the online map;

a3, acquiring a photo of a geographical picture;

a4, performing longitude and latitude calibration correction on the geographic physiognomy photo and the visual field range through a rasterization layer function provided by MapX;

a5, embedding the geographic landscape photo into the bottom layer of a main map interface of a user, and realizing the presentation of geographic landscape information of the main map;

the presentation of the geographic index is implemented according to the following method:

b1, according to the user's request, making access inquiry to the remote network management database to obtain the needed geographic index data;

b2, performing association binding on the obtained geographic index data and the layer information to enable the layer to have the geographic index data information;

the drawing of the switching pull line based on the map is implemented according to the following method:

c1, configuring an information selection frame on the map interface, wherein the information selection frame comprises a layer selection frame and a data set information selection frame, and when a user clicks any one base station on the map or selects a plurality of base stations in a frame, the map interface can be combined with the layer and the data set selected by the user to quickly identify the switching index between the source base station and the target base station which the user needs to check;

c2, after the base station list is obtained, accessing a remote network management database to obtain the switching index data of the station;

c3, after completing the acquisition of the switching index, accessing the latitude and longitude, the direction angle and the lobe length information of the target base station and the source base station stored in the local database;

c4, according to the acquired longitude and latitude, direction angle and lobe length information of the source base station and the target base station, determining the position data of the source base station and the target base station by the criterion of two points and one line, and connecting the two points to complete drawing of a solid arrow of the switching relation;

c5, obtaining the switching index data of the source base station and the target base station according to the switching index data, and binding the data on the drawn solid arrows in a manner of data sets.add of mapx, so that each solid arrow carries corresponding switching index information;

and C6, modifying the thickness and the color of the drawn line to represent the number of times of switching and the switching success rate respectively.

2. The method for implementing the geographic monitoring platform for wireless network optimization analysis according to claim 1, wherein a2 comprises:

a201, transmitting the acquired data of the central longitude and latitude and the field of view to a Webbrower component;

a202, constructing a Google online map in the Webbrower component in real time by a JavaScript language according to the data information, and presenting a geographical map appearance presented by the Google map under the central longitude latitude and the visual field range.

3. The method for implementing the geographic monitoring platform for wireless network optimization analysis according to claim 2, wherein a202 further comprises the steps of: and acquiring altitude information in the geographic map.

4. The method for implementing the geographic monitoring platform for wireless network optimization analysis according to claim 1, wherein in B1, the user request is specifically that the user writes or selects an index database script to be queried; the access query of the remote network management database is specifically carried out on the basis of an ADO component; b2, performing association binding on the obtained geographic index data and the layer information, specifically, performing association binding on the obtained geographic index data and the layer information by a datasets.

5. The method for implementing the geographic monitoring platform for wireless network optimization analysis according to claim 1, further comprising a step B3 of filling different colors to show the network status of each station according to the numerical conditions of each index of each station by using a thematic map layer method provided by mapx.

6. The method of claim 1, wherein the geographic indicators that can be presented are all indicators associated with the base station, including: user access success rate, handover success rate, disconnection rate, ERAB establishment success rate, uplink and downlink data delay and flow.

Images