KR20050061269A - Installation for display of router position using the absolute coordinate system and method for measuring router - Google Patents

Abstract

Disclosed is a display device and a method of measuring coordinates of a measurement router using absolute coordinates in an in-building.

According to the present invention, a position measuring sensor for calculating a measurement position displacement in the in-building; A fourth memory for storing geographic information including a cross-sectional view of the building relative to the measurement location; A third memory for storing call quality measurement information at a specific location; A second memory for storing measurement coordinates of the current position detected from the position measurement sensor; A watch screen for dividing and displaying geographic information into pixels of a predetermined unit, displaying a router location in an in-building, and inputting location information of the corresponding router; A first memory for storing pixel size information on the watch screen and actual information corresponding to the pixel size; And using the position measuring sensor to measure the router position from a predetermined reference position in the in-building, and store the measurement coordinates according to the measurement result in the second memory, and determine the scaling of the measurement coordinates based on the actual information and the pixel size information. It consists of a microprocessor for displaying the measured coordinates of the router according to scaling on the watch screen.

Therefore, the present invention applies the geographical division coordinates divided into pixels of a predetermined unit on the monitor of the measuring device into the in-building, and after calculating the scaling ratio between the pixel and the scale, the inter-router position measured by the real-world measurement in the in-building. By scaling the information according to the scale ratio, correcting the position information of the router according to the error pixel between the building coordinates and the monitor coordinates shown on the monitor coordinates, and displaying the actual position of each router and call quality measurement information of the corresponding router. In addition, the router location in the in-building can be shown on the map without the GPS location information, thereby providing the effect of accurately measuring the service coverage for each PN through the mapping of the PN for each sector of the base station and the measurement data.

In addition, it is possible to capture the exact location of the router, it is possible to analyze the handoff situation and abnormal signal inflow in the in-building to provide the effect of improving the service quality of the call.

Description

INSTALLATION FOR DISPLAY OF ROUTER POSITION USING THE ABSOLUTE COORDINATE SYSTEM AND METHOD FOR MEASURING ROUTER}

The present invention relates to the generation of location information for call quality management in in-building, and more specifically, based on virtual coordinates set on a monitor of a computer utilized as an analysis equipment (QMS-IB). The present invention relates to a display device and a method of measuring coordinates of a measurement router using absolute coordinates in the in-building to generate location information of the in-building so as to extend with the coordinates of the in-building.

In general, when a wireless communication service provider wants to install a plurality of base stations for each region in order to guarantee call quality, a cell planner performs cell planning for a coverage area that each base station can cover. According to the cell planning, it contributes to improving the call quality for the shadow area by adding a base station, installing an optical repeater, and adjusting handoff parameters.

In order to measure the call quality, each measurement process is performed in the out-door and in-building. The first method of measuring the call quality in the out-door is GPS. Use the numerical road map used by the receiver and car navigation system. This is accomplished by measuring personnel equipped with a GPS receiver in the vehicle and traveling around the area selected for cell planning, where the GPS receiver tracks where the vehicle is moving and provides tracked vehicle location information. By repeating the operation of recording the measured call quality measured through the terminal measured at each moved location to the absolute position of the numerical road map, the call quality measurement is performed for the area selected for cell planning.

On the other hand, the call quality measurement process in the in-building, first measures the in-building call quality through a measuring instrument, database the measurement data in Microsoft Excel or Microsoft Access, and then related departments based on the database data Use it as a reference in document form. However, the call quality measurement in the in-building has a difficulty in setting a plurality of router locations in the absence of the GPS data, in order to overcome this, after setting a specific location in the in-building, the set location It sets the virtual position through the direction sensor and the acceleration sensor from the database, and the database of the location information of the plurality of routers installed as the virtual position.

Therefore, the databased router location information is arbitrary virtual information and requires separate data setting between the measuring device and the analyzer (QMS-IB). That is, since the location information measured by the measuring device is not public data that can be recognized by the analyzer, there is a problem that substantial data compatibility is not achieved. In addition, there is a problem that the accuracy of the mapping of the measurement router based on the arbitrary location information, the lack of objectivity for the call quality analysis of the in-building is caused.

The present invention was created to solve the above problems, and an object of the present invention is the absolute coordinates of the in-building based on the virtual coordinates on the computer monitor used as an analysis device or the measurement data on the out-door using GPS. By creating a simple mapping between the actual geographic information and the router location information in the in-building, it is possible to secure the accuracy of the quality analysis results based on the accurate visibility of the quality of each point in the in-building. The present invention provides a display device and a method of measuring coordinates of a measurement router using absolute coordinates in an in-building.

A method of displaying a measurement router using absolute coordinates in an inbuilding according to the first aspect of the present invention for achieving the above object is to extract the coordinates of a measurement router in an inbuilding without GPS information. A measuring method for a method comprising the steps of: a) receiving geographic information of a measurement area; b) receiving pixel information on coordinates partitioned on the monitor; c) receiving actual information about the pixel information; d) measuring actual coordinates of said measurement router from predetermined reference coordinates in an inbuilding; e) performing scaling of actual coordinates of the measurement router based on the actual information; And f) the location information of the measurement router according to the scaled actual coordinates and the call quality measurement information of the corresponding router on the geographic information.

According to a preferred embodiment of the present invention, the coordinates partitioned on the monitor in step b) is characterized in that the coordinates compatible with the analysis equipment (QMS-IB).

On the other hand, the display device of the measurement router using the absolute coordinates in the in-building according to the second aspect of the present invention for achieving the above object is to measure the coordinates of the measurement router (Router) in the in-building without GPS information (GPS) An apparatus for extraction, comprising: a position measuring sensor for calculating a measurement position displacement in an inbuilding; A fourth memory storing geographic information including a cross-sectional view of the building relative to the measurement location; A third memory for storing call quality measurement information at a specific location; A second memory for storing measurement coordinates of a current position detected by the position measuring sensor; A watch screen for dividing and displaying the geographic information into pixels of a predetermined unit, displaying a router location in an in-building, and inputting location information of the corresponding router; A first memory for storing pixel size information on the watch screen and actual information corresponding to the pixel size; And using the position measuring sensor to measure the router position from a predetermined reference position in the in-building, and store the measurement coordinates according to the measurement result in the second memory and store the measured coordinates based on the actual information and pixel size information. And a microprocessor for determining scaling and displaying the measured coordinates of the router according to the scaling on the watch screen.

According to a preferred embodiment of the present invention, the position measuring sensor comprises a direction sensor and an acceleration sensor to perform numerical detection according to the movement trajectory of the measurer.

In addition, the monitor coordinates composed of pixels of a predetermined unit displayed on the monitor and the measurement coordinates of the router are coordinates of the same size arbitrarily partitioned, or the same coordinates composed of distance information of a predetermined unit received from GPS. It is characterized by.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. 1 is a configuration diagram illustrating a measuring device according to the present invention.

As shown, the measuring device 100 includes a position measuring sensor 101 for calculating a measuring position displacement in an in-building, a fourth memory 117 in which geographic information including a cross-sectional view of a building with respect to the measuring position is stored, A third memory 111 for storing call quality measurement information at a specific location, a second memory 109 for storing measurement coordinates of the current location detected by the location sensor 101, and the geographic information in a predetermined unit A display screen 113 for displaying a router position in an in-building set by dividing the pixel and inputting the position information of the router, and pixel size information on the watch screen (monitor) and the pixel size. The first memory 107 stores the actual information corresponding to the position of the router from the position sensor 101 based on the actual information about the pixels divided into the predetermined unit And a microprocessor 103 for measuring, storing, and controlling call quality information for the corresponding router, and a key input unit 105 for setting an initial position setting of the position sensor 101.

On the other hand, the predetermined unit of pixels displayed on the monitor may have a arbitrarily partitioned size, but may be replaced by the predetermined unit of distance information received from the GPS. That is, the coordinates in the in-building can be measured according to pixels of the same size arbitrarily partitioned on the monitor, and the predetermined unit measured from the GPS on the out-door. It may be measured corresponding to the distance information of. In addition, the position measuring sensor 101 consists of a direction sensor and an acceleration sensor to perform numerical detection according to the movement trajectory of the measurer.

Hereinafter, the operation of the present invention will be described in detail with reference to the accompanying drawings. 2 is a flowchart for explaining the main operation of the present invention. 3 is a view showing the coordinates of the watch skin (113) for explaining the principle of the present invention.

As shown, in step S201, the microprocessor 103 receives a measurement instruction command for measuring coordinates in in-building through the key input unit 105, and then the fourth memory 117. Enable to patch geographic information for the area, including the cross section of the building. The microprocessor 103 provides geographic information of the region to the watch screen 113 and sets a section composed of pixels having a predetermined same section on the watch screen 113.

The above section may be the same as the coordinate information of the analysis equipment (QMS-IB) for measuring the call quality by receiving the coordinate information of the in-building detected from the measuring device (100). Therefore, according to the coordinate section of the analysis equipment (QMS-IB), the coordinate section on the watch screen 113 may be set to any setting value, and may be based on the geographical coordinate information provided from the GPS as necessary. This is to use the same coordinates between the analyzer (QMS-IB) and the measuring device 100.

Meanwhile, in steps S203 and S205, the microprocessor 103 inputs the monitor coordinates shown on the watch screen 113, that is, the size information of the pixel and the actual size information corresponding to the pixel size, to the first memory 107. do. The pixel information stored in the first memory 107 indicates coordinate information about pixels on the monitor, and may be stored as information that is preset by the manufacturer or tabled corresponding to pixel settings on the monitor. For example, when the size of the pixel representing the coordinates on the monitor is 1 cm 2, and the scale of the pixel is 1 m 2, the microprocessor 103 recognizes a scale ratio of 1: 100.

Coordinates of these inbuildings are set to virtual coordinates, and the coordinates in the out-door are applied in the inbuilding. That is, as shown in Figure 3, the coordinates formed on the monitor apply equally in the in-building. Thereafter, the microprocessor 103 proceeds to step S207 and sets the positions of the plurality of routers based on the coordinates applied in the inbuilding. To this end, the measurer carries the measuring device 100 to set coordinates from a specific location in the building, and the location measuring sensor 101 forms measurement coordinates based on actual information corresponding to the pixels from the specific location.

For example, in the in-building, the measurer 100 measures the position in units of horizontal / vertical 1m, which is preset actual measurement information, using the position measuring sensor 101 and generates location information of the router based on this. The location information of the router thus measured is stored in the second memory 109. Therefore, the second memory 109 stores position information of each router as X-axis and Y-axis coordinate information. Of course, if the geographic location is underground in the building, the location information is stored, including the number of underground floors. In addition, in the present invention, it is only one embodiment to measure the measured information in units of 1 m, and it is obvious that the measurement information may be changed as necessary.

The microprocessor 103 proceeds to step S209 to calculate an error pixel for the pixel coordinates on the monitor and the coordinates of the building shown on the monitor. This represents T1 and T2 in FIG. 3, and determines how much error the location of the building has from the coordinates on the monitor. For example, if the position of the building shown in the monitor coordinates, i.e., T1 and T2 are 0.5 pixels apart from each other, i.e., considering the scale ratio of 1: 100, the distance of 0.5m from the coordinates of the pixels close to the outer circumference of the building Indicates distance.

Therefore, in step S211, the microprocessor 103 shifts the measured coordinates of the in-building previously measured by the separation distance, and sets the coordinates of the in-building equal to the coordinates of the monitor. Then, the coordinate of the inbuilding is scaled to 100: 1 to display the router of the corresponding inbuilding on the watch screen 113 in which the geographic information is shown. In addition, after the microprocessor 103 stores the call quality measurement information detected from each router into the third memory 111, in step S213, the measuring device 100 is analyzed by the analyzer QMS-IB to the corresponding router. It provides in-building measurement coordinates and call quality measurement information for each router.

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 display device and the method of measuring the coordinates of the measurement router using the absolute coordinates in the in-building according to the present invention applies the geographic subdivision coordinates divided into predetermined units of pixels on the monitor of the measuring device into the in-building. After calculating the scaling ratio between the corresponding pixel and the actual scale, the location information between routers measured in the real building in the in-building is scaled according to the scaling ratio, and according to the error pixel between the building coordinates and the monitor coordinates shown on the monitor coordinates. By correcting the location information of the router and displaying the actual location of each router and call quality measurement information of the corresponding router, the router location in the in-building can be shown on a map without the GPS location information. Providing the effect of accurately measuring service coverage by PN through the mapping of each PN and measurement data .

In addition, it is possible to capture the exact location of the router, it is possible to analyze the handoff situation and abnormal signal inflow in the in-building to provide the effect of improving the service quality of the call.

1 is a block diagram showing a display device of a measurement router according to the present invention.

2 is a flowchart showing a method of measuring coordinates using absolute coordinates according to the present invention.

3 is a view for explaining the principle of the present invention.

<Explanation of symbols for main drawings>

101: position measuring sensor 103: microprocessor

105: key input unit 107: first memory

109: second memory 111: third memory

113: watch screen 117: fourth memory

Claims (8)

An apparatus for extracting coordinates of a measurement router in an in-building without GPS information, A positioning sensor for calculating a measuring position displacement in the inbuilding; A fourth memory storing geographic information including a cross-sectional view of the building relative to the measurement location; A third memory for storing call quality measurement information at a specific location; A second memory for storing measurement coordinates of a current position detected by the position measuring sensor; A watch screen for dividing and displaying the geographic information into pixels of a predetermined unit, displaying a router location in an in-building, and inputting location information of the corresponding router; A first memory for storing pixel size information on the watch screen and actual information corresponding to the pixel size; And The actual position of the router is measured from the predetermined reference position in the in-building using the position measuring sensor, the measurement coordinates according to the measurement result are stored in the second memory, and scaling of the measurement coordinates based on the actual information and the pixel size information. And a microprocessor for displaying the measured coordinates of the router according to scaling on the watch screen. The display apparatus of claim 1, wherein the position measuring sensor comprises a direction sensor and an acceleration sensor to perform numerical detection according to a movement trajectory of the measurer. According to claim 1, wherein the monitor coordinates consisting of a predetermined unit of pixels displayed on the monitor and the measurement coordinates of the router are coordinates of the arbitrarily divided equal size of the measurement router of the in-building, characterized in that Display. According to claim 1, wherein the monitor coordinates composed of a predetermined unit of pixels displayed on the monitor and the measurement coordinates of the router is characterized in that the same coordinates composed of distance information of a predetermined unit received from the GPS (GPS) Display of measuring router using absolute coordinates in building. In the measurement method for extracting the coordinates of the measurement router (Router) in the in-building that does not have GPS information, a) receiving geographic information of a measurement area; b) receiving pixel information on coordinates partitioned on the monitor; c) receiving actual information about the pixel information; d) measuring actual coordinates of said measurement router from predetermined reference coordinates in an inbuilding; e) performing scaling of actual coordinates of the measurement router based on the actual information; And and f) displaying the position information of the measurement router according to the scaled actual coordinates and the call quality measurement information of the corresponding router on the geographic information. The method of claim 5, wherein the coordinates partitioned on the monitor in step b) are coordinates compatible with the analysis equipment (QMS-IB). The measurement using the absolute coordinates of the in-building, characterized in that the coordinates partitioned on the monitor is composed of pixels of a predetermined unit and the coordinates in the inbuilding is formed based on the pixels of the predetermined unit. How to display your router. The method of claim 7, wherein the pixel of the predetermined unit is a coordinate configured based on distance information of the predetermined unit received from the GPS. 9.