KR20050061270A - Quality management system for in-building - Google Patents

Abstract

The present invention discloses an in-building quality control system.

According to the present invention, an in-building quality management system for collecting geographic information and call quality information for in-building for each zone; A regional network management server for managing a network of an in-building quality management system in a corresponding zone and uploading geographic information and call quality information provided by each in-building quality management system for each region through a communication network; A network operation server configured to perform network operation of the local network management server and to collect geographic information for each region uploaded through the communication network and call quality information for each specific region; Extract in-building information about the area based on geographic information for each area, extract measurement data for each router (Router) based on the call quality information, and based on the measurement data for each router (RF) A management server for generating regional coverage based on the haptic success rate for each region, haptic quality measurement information according to the haptic success rate, and the haptic quality measurement information after calculating statistics on a parameter; A first database linked with the management server to store the building information; A second database for storing measurement data for each router of the inbuilding; A third database for storing the haptic quality measurement information and coverage information; And an administrator terminal connected to the network operation server to display measurement result information of the management server as predetermined graphic information and to manage each database.

Accordingly, the present invention receives geographic information and call quality information for in-building quality management of a corresponding area from a regional network formed for each area on a communication network, and collects them, thereby immersing in in-building according to the radio environment. By measuring the success rate and quality of service, it is possible to analyze service coverage by PN, handoff situation and abnormal signal inflows for the quality of each point in the in-building building, and to analyze geographic information and geographic information using GIS. It is possible to show the router in the corresponding absolute coordinates, thereby providing a three-dimensional analysis of the measurement results.

Description

In-building quality management system {QUALITY MANAGEMENT SYSTEM FOR IN-BUILDING}

The present invention relates to a call quality management system for mobile communication, and more particularly, to a database of inbuilding building information without GPS location information, and a database of in-building measurement data linked to a GIS map using absolute coordinates. The present invention relates to an in-building quality management system capable of comprehensively analyzing and managing the in-building haptic quality measurement results and coverage.

In general, there is an explosive increase in subscriber acceptance since the commencement of wireless communications services such as Digital Celluar Service (DCS), Personal Communication Service (PCS), Wireless Local Loop (WLL), and IMT-2000 (or FPLMTS) in commercial service. To achieve. When a wireless communication service provider wants to install a plurality of base stations in each area in order to guarantee call quality, a cell planner designing a callable area that each base station can cover is performed. In accordance with such cell planning, efforts will be made to improve call quality in the shadow area by expanding base stations, installing optical micro-cells, and adjusting hand-off parameters.

Call quality measurement relies on out-door measurement. For reference, a method of measuring call quality in the out-door uses a digital road map used by a GPS (GPS) receiver and a vehicle navigation system. More specifically, the out-door measurement method measures by having a measurement agent mount a GPS receiver in a vehicle and move around a selected area for cell planning. At this time, the GPS receiver tracks the location where the vehicle moves to provide the tracked vehicle location information, and maps and records the call quality measured through the terminal measured at each moved location to the absolute location of the numerical road map. By repeating the operation, the call quality measurement is performed for the area selected for cell planning.

The call quality of mobile communication service is managed by road, region, building type, building size and building outline quality level (quality level by floor, measurement location, map mapping location, competitor quality level, etc.). On the other hand, if you look at the process of measuring call quality in in-building, first measure the quality of the in-building call through a measuring instrument, and then transfer the measured data to Microsoft Excel or Microsoft Access. After the database, the relevant department was used as a reference in the form of documents based on the data.

However, in the related art, data sharing was difficult due to the management of call quality management in an in-building wireless terminal in the form of a document (Microsoft Excel or Microsoft Access). Not only was it not visually viable, it was also difficult to determine whether the call quality was good or bad in the relevant department, not the measurement department. From this, in-building quality analysis was not objective and accurate. Therefore, the existing in-building measurement data has a significant error, so the in-building coverage cannot be accurately determined, and there is a problem in that it is not actively used for quality improvement, reengineering, and investment decision.

The present invention has been created to solve the above problems, and an object of the present invention is to database the in-building information and the measurement data in the in-building, and through the measurement router analysis of the in-building measurement data using absolute coordinates It is to provide an in-building quality management system that can improve quality of service and satisfaction in RF environment by conducting quality situation analysis for each building point.

In-building quality management system according to an aspect of the present invention for achieving the above object, in the quality control system according to the propagation environment of the in-building, geographic information and call quality information for each in-building (In-Building) In-building quality management system for collecting; A regional network management server for managing a network of an in-building quality management system in a corresponding zone and uploading geographic information and call quality information provided by each in-building quality management system for each region through a communication network; A network operation server configured to perform network operation of the local network management server and to collect geographic information for each region uploaded through the communication network and call quality information for each specific region; Extract in-building information about the area based on geographic information for each area, extract measurement data for each router (Router) based on the call quality information, and based on the measurement data for each router (RF) A management server for generating regional coverage based on the haptic success rate for each region, haptic quality measurement information according to the haptic success rate, and the haptic quality measurement information after calculating statistics on a parameter; A first database linked with the management server to store the building information; A second database for storing measurement data for each router of the inbuilding; A third database for storing the haptic quality measurement information and coverage information; And an administrator terminal connected to the network operation server to display measurement result information of the management server as predetermined graphic information and to manage each database.

According to a preferred embodiment of the present invention, the RF (RF) parameter is characterized in that the CDF / PDF information on the Ec / lo, Rx Power, sound quality MOS value, etc. and trend information for each measurement date.

In addition, the in-building quality management system receives the measurement information on the call quality from the in-building meter for each zone, and the in-building meter measures the position of the router in the in-building for each zone using absolute coordinates and for each of the corresponding routers. Characterized in that it provides a call quality information.

In addition, the network operation server is characterized in that connected to the manager terminal to enable the inquiry and analysis of the measurement data by providing the haptic quality measurement information and regional coverage information generated by the management server on the Web.

In addition, the haptic quality measurement information is displayed at a predetermined rate based on the mobile and land voice files for the sound quality bad numbers (BQ, CBQ), or incomplete calls such as connection failure, disconnection, and sound quality bad. It is characterized by being displayed at a predetermined rate based on the analysis of the CAI (CAI) message for.

In addition, the coverage is characterized in that the service coverage for each PN through the PN mapping, PN plotting (Plotting), Active PN number chart, etc. based on the geographic information, in-building building information and call quality information of the route.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. 1 is a network diagram illustrating a quality control system according to the present invention.

As shown, the in-building quality management system 109 for collecting geographic information and call quality information for in-building by area, and manages the network of the in-building quality management system 109 in the corresponding area. And a local network management server 107 and a network of the local network management server 107 for uploading geographic information and call quality information provided by each in-building quality management system 109 for each region through the communication network 101. A network operation server 103 for collecting the geographic information for each region uploaded through the communication network 101 and the respective call quality information for a specific region, and for the region based on the geographic information for each region. Extract building information from buildings, extract measurement data for each router of the building based on the call quality information, and based on the measurement data for each router After calculating the haptic success rate by region, it is linked with the management server 105 and the management server 105 to generate haptic quality measurement information according to haptic success rate, and to generate coverage by region based on the haptic quality measurement information A first database 115 for storing the inbuilding building information, a second database 117 for storing measurement data for each router of the inbuilding, a third database for storing the haptic quality measurement information and coverage information ( 119) and a manager terminal 121 connected to the network operation server 103 to display the measurement result information of the management server 105 as predetermined graphic information and to manage the respective databases 115, 117 and 119. It consists of.

On the other hand, the in-building quality management system 109 receives the measurement information on the call quality from the in-building measuring unit 113 for each zone, the in-building measuring unit 113 in the in-building router by zone using absolute coordinates It provides location measurement and each call quality information about the router. In addition, the in-building quality management system 109 is interlocked with the N-th database 111 to store location information of the routers for each zone and call quality information for each router.

Hereinafter, the operation of the present invention will be described.

The in-building quality management system 109 holds the geographic information of the corresponding area using the GIS, including the building information for the in-building for each zone, and generates coordinate information of the in-building through the in-building measuring unit 113 Generates information on the location and call quality of the router based on the coordinate information. The router coordinate information of the in-building is absolute coordinates, and virtual coordinate information for applying the same coordinates on the out-door using GPS to the in-building. Accordingly, the inbuilding quality management system 109 generates the measured router coordinates in the same building as the coordinate information on the out-door by using the virtual coordinate information, and measures the call quality information of the corresponding router.

Geographic information for each zone allocated to each inbuilding quality management system 109, call quality information of each router including the in-building information of the corresponding zone and the router coordinates in the in-building may be stored in the N-th data storage unit. The in-building measurement data is stored in the database 111 and uploaded to the management server 105 through a local network management server 107 managing and managing a network of a corresponding area.

Here, the building information for the inbuilding includes a building name, a large classification name of a building, a small classification name, an address, a east, a ground floor number, a basement floor number, a longitude and latitude coordinates, and each of Seoul and six major metropolitan cities including the metropolitan area. It is divided into sections of. From this, the network operation server 103 receives building information about inbuildings collected for each zone, router location information in the corresponding inbuildings, and call quality information of the routers, and transmits them to the management server 105. Thereafter, the management server 105 codes and stores the inbuilding building information for each zone and region to the first database 115. The first database 115 is a large classification information for distinguishing a building code, a building name, a building or an apartment granted from the management server 105, a small classification information for classifying whether it is a general office building or a corridor apartment or a staircase apartment, Stores building address information and coordinate information of in-building indicating longitude and latitude.

In addition, the management server 105 accumulates the call quality information of the in-building measured for each zone from the in-building quality management system 109 to the in-building measurement data 117 for each zone and for each zone. As shown in FIG. 2A, the call quality information is accumulated in the N-th database 111 by the management server 105 including regional geographic information and inbuilding building information provided from the regional network management server 107. By generating mapping information for each PN of the base station based on the in-building measurement data, the in-building measurement data without a bearing concept is illustrated in a route method.

In addition, the management server 105 performs PN mapping, PN plotting, active PN number charts, and the like, after performing service coverage for each PN, handoff situation, abnormal signal inflow analysis, and executing the third database ( 119) stores the sensory quality measurement information and coverage information according to the analysis result. In addition, the management server 105 shows an MSC boundary and a BSC boundary as shown in FIG. 2B based on geographic information based on the second database 117 and the third database 119 and measurement data of the inbuilding, and the system boundary. Quality analysis according to the region.

The quality analysis consists of statistical analysis based on RF parameters, and based on CDF / PDF analysis and trend analysis by measurement date for Ec / lo, Rx Power, sound quality MOS value, etc. do. Based on this, tangible quality control items such as haptic success rate, power failure rate, and poor sound quality rate are calculated through tangible quality statistics for each building by floor / apartment complex and administrative district. 3 shows RF parameter statistics and graphs according to the present invention, and statistical information for each competitor for haptic success rate.

On the other hand, the manager terminal 121 is provided with the network quality management information and coverage information including the in-building building information collected or managed from the management server 105, the measurement data for the corresponding inbuilding and the coverage information from the network operation server 101 Inquiry and analysis through a web page, as shown in Figure 4 (a), the network management server 101 is the geographic information of the in-building and the in-building quality management through the initial screen of the quality management system It provides data uploaded from the system 109, RF parameters, output of results of measurement data, statistics, and the like.

4 (b) shows the geographic information of the inbuilding, and is displayed on the manager terminal 121 by clicking the corresponding item shown on the initial screen of the quality control system. The geographic information is the topographical information on the inbuilding building, and the haptic success rate for the entire building (by floor, elevator, etc.) is shown by clicking on a specific building. In addition, the manager clicks on a specific floor and receives route analysis information and chart analysis information for each communication company of the corresponding floor to the manager terminal 121. Therefore, the manager can analyze the building topographic information of the in-building and the haptic quality statistics for each floor and the routes and charts for each floor through the manager terminal 121.

While the invention has been shown and described with respect to specific preferred embodiments thereof, the invention is not limited to the embodiments described above, and is commonly used in the art to which the invention pertains without departing from the spirit of the invention as claimed in the claims. Anyone with knowledge will be able to make various variations.

As described above, the in-building quality management system according to the present invention receives the geographic information and call quality information for the in-building quality management of the area from the regional network formed for each area on the communication network, By gathering, it is possible to measure haptic success rate and service quality in in-building according to the radio environment, and it is possible to analyze service coverage, hand-off situation and abnormal signal inflow by PN on the quality of each point in the in-building building. In addition, it is possible to show the router on the geographic information using the GIS and the absolute coordinate corresponding to the geographic information, thereby providing a three-dimensional analysis of the measurement results.

1 is a block diagram showing an in-building quality management network according to the present invention.

2A and 2B illustrate a base station PN mapping and a service coverage boundary based on the same according to the present invention.

3 is a view showing the RF parameter statistics and graphs used in the present invention and the statistics of haptic success rate.

4A and 4B are views for explaining inquiry and analysis of measurement data according to the present invention.

<Explanation of symbols for main drawings>

101: communication network 103: network operation server

105: management server 107: local network management server

109: In-building quality control system 111: N-database

113: measuring instrument 115: first database

117: second database 119: third database

Claims (8)

In the quality control system according to the radio wave environment of the in-building, An in-building quality management system for collecting geographic information and call quality information on in-building by area; A regional network management server for managing a network of an in-building quality management system in a corresponding zone and uploading geographic information and call quality information provided by each in-building quality management system for each region through a communication network; A network operation server configured to perform network operation of the local network management server and to collect geographic information for each region uploaded through the communication network and call quality information for each specific region; Extract in-building information about the area based on geographic information for each area, extract measurement data for each router (Router) based on the call quality information, and based on the measurement data for each router (RF) A management server for generating regional coverage based on the haptic success rate for each region, haptic quality measurement information according to the haptic success rate, and the haptic quality measurement information after calculating statistics on a parameter; A first database linked with the management server to store the building information; A second database for storing measurement data for each router of the inbuilding; A third database for storing the haptic quality measurement information and coverage information; And And a manager terminal for accessing the network operation server to display the measurement result information of the management server as predetermined graphic information and to manage each database. The in-building quality control system as claimed in claim 1, wherein the RF parameters are CDF / PDF information about Ec / lo, Rx Power, sound quality MOS value, and trend information by measurement date. The method of claim 1, wherein the in-building quality management system receives the measurement information on the call quality from the in-building measuring device for each zone, and the in-building measuring device measures the position of the router in the in-building by zone using absolute coordinates and the corresponding. In-building quality management system, characterized in that to provide each call quality information for the router. The network management server of claim 3, wherein the network operation server is connected to a manager terminal to provide the quality of experience measurement information generated by the management server and coverage information for each region on the web to enable inquiry and analysis of the measurement data. Building Quality Management System. 5. The in-building quality control according to claim 1 or 4, wherein the haptic quality measurement information is displayed at a predetermined ratio based on the mobile and land voice files for the sound quality defects BQ and CBQ. system. The method of claim 1 or 4, wherein the haptic quality measurement information is displayed at a predetermined rate based on analysis of CAI messages for incomplete calls such as connection failure, disconnection, and poor audio quality. In-building quality management system. The building information of claim 1, wherein the building information includes a building name, a large classification name for the building, a small classification name for the building, an address, a building, a ground floor number, an underground floor number, coordinate information, and unique code information. The server is an in-building quality management system, characterized in that for each parameter extraction for the in-building building information. The method according to claim 1, wherein the coverage is service coverage for each PN through PN mapping, PN plotting, active PN number charts, etc. based on the geographic information, inbuilding building information, and call quality information of a route. In-building quality management system.