KR100573197B1 - Method and System for Optimizing Location Based Service by Adjusting Maximum Antenna Range - Google Patents

Abstract

The present invention relates to a method and system for optimizing location-based services by adjusting a maximum radius covered by a base station antenna.

A test terminal for transmitting MAR value optimization data including C-GPS location information and A-GPS data received and stored from one or more GPS satellites using the C-GPS method and the A-GPS method; A base station transmitter configured to transmit and receive signals and data with the test terminal, wherein the MAR value is set; A base station controller for receiving and processing a signal transmitted from the base station transmitter and a mobile switching station connected to the base station controller; And receiving the MAR value optimization data through a mobile communication network, analyzing the received MAR value optimization data, and updating the MAR value of the wireless base station corresponding to the MAR value optimization condition to determine the location-based service. It provides a system for optimizing location-based services by adjusting the maximum radius covered by the base station antenna, characterized in that it comprises a server.

According to an embodiment of the present invention, the location-based service in the mobile communication system may be optimized by adjusting the MAR value of the wireless base station.

Location Based Service (LBS), MAR, C-GPS, A-GPS, Location Server, Optical Repeater

Description

Method and System for Optimizing Location Based Service by Adjusting Maximum Radius Covered by Base Station Antenna

1 is a block diagram schematically illustrating an LBS optimization system for optimizing LBS by adjusting a MAR value according to a preferred embodiment of the present invention;

2 is an exemplary diagram for explaining a MAR optimization concept according to an embodiment of the present invention;

3 is a flowchart illustrating a process of optimizing a MAR value set in a wireless base station according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

100: LBS optimization system 102: GPS satellite

110: test terminal 120, 212: base station transmitter

121, 250: Optical cable 122, 222: Optical repeater

130: base station controller 140: mobile switching center

150: STP 160: positioning server

162: MAR value database 164: Database for MAR value optimization

170: reference GPS antenna

The present invention provides a method for optimizing a location-based service (LBS: LBS) by adjusting a maximum arrival radius (MAR) value of a base station radio wave; It's about the system. More specifically, more A-GPS mobile communication terminals are used in order to accurately locate the Assisted-Global Positioning System (A-GPS) mobile communication terminal located in an area covered by an optical repeater connected to a specific wireless base station and an optical cable. The present invention relates to a method and system for optimizing LBS by adjusting a MAR value of a wireless base station to a predetermined value so as to receive a number of satellite signals.

In order to provide communication services such as the Internet regardless of the place, many companies are spurring the development of a new technology called wireless Internet. Wireless Internet refers to an environment and technology that enables users to use Internet services through a wireless network while the user is on the move. The development of mobile phone-related technology and the rapid increase in mobile phone penetration rate are further promoting the development of this wireless Internet environment.

Meanwhile, among various wireless Internet services using mobile communication terminals such as cellular phones, PDAs, and even notebook computers, LBS is in the spotlight due to its wide utility and convenience. In other words, LBS can be used for rescue requests, responding to crime reports, geographic information system (GIS) for providing information on neighboring areas, differentiating mobile communication fees according to location, traffic information, vehicle navigation and logistics control, location-based CRM. It is used in various fields and situations such as customer relationship management.

In order to use the LBS, it is essential to know the location of the mobile communication terminal. Currently, as a method of identifying the location of the mobile communication terminal, a method using GPS is representative.

GPS is a system that can locate anywhere in the world using 24 GPS satellites orbiting the earth at an altitude of about 20,000 kilometers. GPS uses radio waves in the 1.5 GHz band, and on the ground there is a coordination center called Control Station, which collects information from GPS satellites and synchronizes the transmission time. Know your current location. In general, triangulation is used as a method of positioning using a GPS system. Three satellites are required for triangulation, and a total of four GPS satellites are required, including one observational satellite to correct for time errors.

However, in urban areas with many skyscrapers, the ability to determine location is limited by multipath or lack of visibility, and accurate positioning is nearly impossible in places where satellites are invisible (such as out of radio waves), such as in tunnels or underground buildings. There is a problem. In addition, the time to first fix (TTFF), which is the actual time required for the GPS receiver to determine its location in the first place, sometimes takes about several minutes to ten minutes or more. There is a problem that causes great inconvenience.

In order to compensate for the disadvantages of the GPS method, an A-GPS method for determining a location of a mobile communication terminal by combining a resource of a wireless communication network with a GPS method has been developed and used. In the A-GPS method, since the mobile communication terminal collects information necessary for positioning at the same time from the GPS satellite and the wireless communication network, the location can be determined in three dimensions by using latitude, longitude, and altitude coordinates. Data and messages are transmitted and received using the parameters defined in IS (Interim Standard) -801-1.

Meanwhile, in a current CDMA communication network, one base station (BS) covers an area corresponding to a MAR of a base station antenna. Here, MAR refers to an area having a radius of the maximum distance that the radio wave transmitted from the base station antenna reaches.

However, the method of covering all regions of the country by installing a wireless base station based on MAR has a disadvantage in that a large cost is required for the installation of the wireless base station. That is, the MAR value of the wireless base station currently installed in the mobile communication network is uniformly set to 3 Km or 5 Km. Therefore, in order to provide high quality LBS service in the current mobile communication network, a wireless base station should be installed for each area unit covered by the MAR value.

However, the current mobile communication network is expensive to install the wireless base station, so that the coverage of the voice or data call of the wireless base station is increased by using one or more optical repeaters connected through the optical base station and the optical cable. It is structured. Here, since the optical repeater uses the same identification code as the wireless base station connected through the optical cable, when the mobile communication terminal is located in the jurisdiction of the optical repeater, the optical base station transmits the identification code of the wireless base station to the positioning server.

Therefore, in the current mobile communication network, when the mobile communication terminal is in an area covered by the optical repeater, it is very difficult to determine the location of the mobile communication terminal using the A-GPS method. That is, in the A-GPS method, the mobile communication terminal acquires an identification code (Address) of a wireless base station in the area where the mobile communication terminal is located without transmitting a separate GPS receiver and transmits it to the positioning server through the mobile communication network. The positioning server checks the identification code of the wireless base station received through the mobile communication network, and checks the MAR value set in the wireless base station.

Then, the coordinate information of the GPS satellites capable of receiving GPS signals in the area of the corresponding wireless base station is extracted based on the confirmed MAR value and transmitted to the mobile communication terminal through the mobile communication network as auxiliary data. The mobile communication terminal receiving the auxiliary data through the mobile communication network searches for the GPS signal using the coordinate information of the GPS satellites included in the auxiliary data.

Accordingly, the coordinate information of the GPS satellites received by the mobile communication terminal in the A-GPS method may be used as valid information only when the mobile communication terminal is located in an area having a radius of MAR set in the corresponding wireless base station. That is, when the mobile communication terminal is located in the boundary area outside the wireless base station or in the jurisdiction of the optical repeater using the same identification code as the wireless base station, the auxiliary data received is not appropriate. In this case, since the mobile communication terminal searches for the GPS signal using the coordinate information of the GPS satellite, which is not appropriate, the GPS signal is not searched well, and thus, the positioning is not made correctly.

In order to solve the above problems, the present invention provides a larger number of A-GPS mobile communication terminals in order to accurately locate the A-GPS mobile communication terminal located in the area covered by the optical repeater connected to the specific wireless base station and the optical cable. An object of the present invention is to provide a method and system for optimizing an LBS system by adjusting a maximum radius value covered by an antenna of a wireless base station to a predetermined value so as to receive a satellite signal.

To this end, the present invention is a system for optimizing location-based services by adjusting the maximum radius covered by the base station antenna, C-GPS location information received and stored from one or more GPS satellites using the C-GPS method and A-GPS method And a test terminal for transmitting MAR value optimization data including A-GPS data. A base station transmitter configured to transmit and receive signals and data with the test terminal, wherein the MAR value is set; A base station controller for receiving and processing a signal transmitted from the base station transmitter and a mobile switching station connected to the base station controller; And receiving the MAR value optimization data through a mobile communication network, analyzing the received MAR value optimization data, and updating the MAR value of the wireless base station corresponding to the MAR value optimization condition to determine the location-based service. It provides a system for optimizing location-based services by adjusting the maximum radius covered by the base station antenna, characterized in that it comprises a server.

According to another object of the present invention, a mobile terminal including a test terminal for receiving GPS radio waves using a C-GPS method and an A-GPS method, a wireless base station having a MAR value and a mobile switching center, and a location of the wireless base station. A method of optimizing a location-based service in a system consisting of a location server for resetting the MAR value in association with a MAR value database storing information and the MAR value, the method comprising: (a) C-GPS transmitted from the test terminal; Receiving and storing location information and A-GPS data; (b) determining an MAR value optimization target by analyzing the C-GPS location information and the A-GPS data for each wireless base station; (c) calculating a new MAR value using an embedded MAR value optimization algorithm; And (d) setting the new MAR value as an optimized MAR value of the corresponding wireless base station and storing the new MAR value in the MAR value database. Provide a method.

According to another object of the present invention, the C-GPS method and the A-GPS method using a test terminal for receiving GPS radio waves and the C-GPS location information and A-GPS data from the test terminal installed in the mobile communication network A method for optimizing a location-based service in a system consisting of a location determination server for resetting a MAR value set in a wireless base station, the method comprising: (a) C-GPS operation mode is set for every predetermined measurement point as the test terminal moves; Obtaining and storing GPS location information; (b) measuring at each measurement point in an A-GPS operating mode simultaneously with the C-GPS operating mode; (c) acquiring and storing A-GPS data using the A-GPS scheme; And (d) collecting the stored C-GPS location information and the A-GPS data and transmitting the collected C-GPS location information to the location server to optimize location-based services. Provide a way to.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

1 is a simplified block diagram of an LBS optimization system 100 for optimizing LBS by adjusting MAR values according to a preferred embodiment of the present invention.

The LBS optimization system 100 according to the preferred embodiment of the present invention includes a plurality of GPS satellites 102, a test terminal 110, a base transceiver system (BTS) 120, an optical repeater 122, and a base station controller. (BSC: Base Station Controller) 130, MSC (Mobile Station Center) 140, Signaling Point 150, and Positioning Determination Entity (PDE) connected with reference GPS antenna 170 ( 160, a MAR value database 162, a MAR value optimization database 164, a reference GPS antenna 170, and the like.

The test terminal 110 receives a GPS radio wave from one or more GPS satellites 102, extracts navigation data included in the GPS radio wave, and transmits the extracted navigation data to the positioning server 160 through a mobile communication network, It is a terminal equipped with a GPS receiver. Test terminal 110 according to an embodiment of the present invention is a terminal for optimizing the MAR value in a mobile communication system, the position to be described later by collecting the data required for the optimization of the MAR value while moving by a moving means such as a vehicle A function of transmitting to the decision server 160 is performed.

Here, the test terminal 110 according to an embodiment of the present invention is a mobile communication terminal capable of positioning using A-GPS and C (Conventional) -GPS. That is, the test terminal 110 has both a C-GPS receiver for the C-GPS scheme and an A-GPS receiving module for the A-GPS.

For reference, the advantages and disadvantages of the C-GPS method and the A-GPS method are described. The C-GPS method is capable of relatively accurate positioning on its own without the help of a communication network, and is normally determined in an open sky environment. While this is possible, the power consumption of the terminal is large, the TIFF takes up to about 10 minutes or more, and requires a separate C-GPS receiver.

On the other hand, the A-GPS method has the advantage that the position can be determined with the help of a communication network even in a place where GPS satellite signals such as a building are not easily captured, and the location accuracy is higher than that of the C-GPS method. In addition, the power consumption of the terminal is small, the TIFF is short within a few seconds, the A-GPS chip and the modem chip is integrated, there is an advantage that the manufacturing cost of the terminal is small. In other words, the A-GPS method is a location tracking method combining the C-GPS method using a GPS satellite and the network based method using a CDMA communication network.

The test terminal 110 is a satellite identification code, the number of satellites, the time, the strength of the satellite signal, pseudorange, NID (Network ID), BSID (Base Station ID) The C-GPS location information (latitude, longitude, number of satellites, etc.) obtained periodically by using the A-GPS data and the C-GPS method including the transmission is transmitted to the positioning server 160 through the mobile communication network.

When the test terminal 110 acquires the C-GPS location information and the A-GPS data according to an embodiment of the present invention in detail as follows. The test terminal 110 searches the GPS radio waves at predetermined positions using the C-GPS receiver and temporarily stores the C-GPS position information, which is a search result, in the internal memory.

In addition, the test terminal 110 transmits the approximate location information (identification code of the wireless base station) to the location determination server 160 through the mobile communication network to obtain the location data using the A-GPS method. The location determination server 160 searches for appropriate auxiliary data using the approximate location information received from the test terminal 110 and transmits the searched auxiliary data to the test terminal 110 through the mobile communication network. Here, the auxiliary data transmitted by the positioning server 160 refers to coordinate information of one or more GPS satellites extracted by using the identification code of the wireless base station transmitted by the test terminal 110. In addition, the coordinate information of one or more GPS satellites refers to coordinate information of the GPS satellites determined to be observed at the point where the test terminal 110 is located.

The test terminal 110 receiving predetermined auxiliary data from the positioning server 160 searches for and receives GPS radio waves of the corresponding GPS satellite 102 using the received auxiliary data. The test terminal 110 searches for GPS radio waves using the A-GPS receiving chip at the same place where the C-GPS location information is acquired by the C-GPS method, and temporarily stores the search result A-GPS data in the internal memory. The test terminal 110 uses a built-in wireless modem for C-GPS location information and A-GPS data (hereinafter referred to as 'MAR value optimization data') obtained using the C-GPS method and the A-GPS method. To periodically transmit to the location determination server 160.

On the other hand, the test terminal 110 according to an embodiment of the present invention is a PDA (Personal Digital Assistant), a cellular phone, a PCS (Personal Communication Service) phone, a hand-held PC (Hand-Held PC), GSM (Global System for Mobile) Phones, wideband CDMA (W-CDMA) phones, CDMA-2000 phones, Mobile Broadband System (MBS) phones, notebook computers, laptop computers, and the like. Here, MBS phone refers to a mobile phone to be used in the fourth generation system currently being discussed. That is, the method of optimizing the MAR value according to the embodiment of the present invention may be applied to not only a synchronous mobile communication system and an asynchronous mobile communication system but also a fourth generation ALL-IP system.

The base station transmitter 120 receives a call connection request signal from the test terminal 110 through a traffic channel of the signal channel and transmits it to the base station controller 130. The base station controller 130 controls the base station transmitter 120, assigns and releases radio channels to the test terminal 110, controls the transmission output of the test terminal 110 and the base station transmitter 120, and soft handoff between cells. It performs handoff and hard handoff decision, transcoding and vocoding, and operation and maintenance function for wireless base station.

On the other hand, the base station transmitter 120 and the base station controller 130 according to an embodiment of the present invention has a configuration capable of supporting both a synchronous mobile communication system and an asynchronous mobile communication system. Here, in the synchronous mobile communication system, the base station transmitter 120 is a base transceiver station (BTS), the base station controller 130 is a base station controller (BSC), and in the case of an asynchronous mobile communication system, the base station transmitter 120 is an RTS ( The Radio Transceiver Subsystem and the base station controller 130 are RNCs (Radio Network Controllers). Of course, the base station transmitter 120 and the base station controller 130 according to an embodiment of the present invention are not limited thereto, and may include an access network of a GSM network and a fourth generation mobile communication system to be implemented in the future. .

On the other hand, the radio wave transmitted from the antenna of the base station transmitter 120 can be received by the test terminal 110 located in the area A having a MAR value as a radius, and used for call processing of the test terminal 110 located in the area A. do. In addition, the MAR value set for each base station transmitter 120 is set and stored in the location determination server 160. Currently, the MAR value is generally set uniformly to 3 Km or 5 Km in urban areas or rural areas. to be.

The optical repeater 122 is connected to the base station transmitter 120 and the optical cable 121 to cover the mobile communication service of the area B region. The optical repeater 122 has the same PN (Pseudo Noise) code as the wireless base station including the base station transmitter 120 connected through the optical cable 121. That is, the CDMA communication network recognizes the optical repeater 122 as the same wireless base station as the wireless base station connected by the optical cable 121. Using the optical repeater 122 in this way, while reducing the cost of additional installation of the base station transmitter 120, which requires a large cost (more than 500 million per wireless base station), the coverage of the base station transmitter 120 The coverage may be extended as much as the area covered by the optical repeater 122.

The mobile switching center (MSC) 140 has a control function for enabling wireless base stations to operate efficiently and an interworking function with an electronic exchange installed in a public telephone network. The mobile switching center 140 receives data or a message transmitted from the test terminal 110 through the base station controller 130 and transmits the data or message to the positioning server 160 through the STP 150. The mobile switching center 140 performs basic and additional service processing, incoming and outgoing call processing of a subscriber, location registration and handoff procedures, and interworking with other networks. Mobile switching center 130 according to an embodiment of the present invention can support both IS (Interim Standard) -95 A / B / C system and 3G and 4G mobile communication network.

Signaling transfer point (STP) (hereinafter referred to as STP) 150 is a signal relay station for relaying and exchanging signal messages in the common line signaling scheme of ITU-T. The signal network constructed using the STP 150 operates in a non-corresponding mode in which a call line and a signal line do not correspond, and various signals are transmitted through an STP other than an exchange having a call line, thereby improving economic efficiency and reliability. have. In addition, the STP 150 converts the signaling message and also performs a function of notifying the other switching center of the signaling message when the signal relay is impossible.

The location determination server 160 receives and analyzes MAR optimization data transmitted from the test terminal 110 to identify a wireless base station requiring MAR optimization and performs MAR optimization. The MAR value of the wireless base station where the location determination server 160 performed the MAR optimization is updated with the new value and stored in the MAR value database 162. The MAR optimization operation performed by the positioning server 160 will be described in more detail with reference to FIG. 2.

On the other hand, the location determination server 160 performs a series of functions in the process of determining the location using the A-GPS method. That is, the location determination server 160 calculates the longitude and latitude coordinates of the test terminal 110 using the A-GPS data transmitted from the test terminal 110 via the mobile communication network. In more detail, when the location determination server 160 receives the approximate location information such as the identification code of the wireless base station from the test terminal 110, the location determination server 160 searches the MAR value database 162 for the MAR value set in the corresponding wireless base station. To read.

After determining the location information and the MAR value of the corresponding wireless base station, the location determination server 160 includes the information (coordinate information, identification code information, etc.) of the GPS satellite 102 capable of receiving GPS radio waves from the corresponding wireless base station. The "Provide GPS Acquisition Assistance" message defined in the -801-1 standard is transmitted to the test terminal 110 through the mobile communication network. That is, the positioning server 160 receives the orbit information of the GPS satellites 102 from the reference GPS antenna 170 that monitors all the GPS satellites 102 in real time. Then, using the latitude and longitude coordinates and the MAR value of the wireless base station in which the test terminal 110 is located, the test terminal 110 extracts information of the GPS satellite 102 that can receive GPS radio waves well. The location determination server 160 includes the extracted GPS satellite 102 information in the "Provide GPS Acquisition Assistance" message and transmits the information to the test terminal 110.

The test terminal 110 receiving the "Provide GPS Acquisition Assistance" message extracts the information of the GPS satellite 102 included in the message, searches for and receives the GPS radio waves transmitted from the GPS satellite 102.

The test terminal 110 receiving the GPS radio waves from the one or more GPS satellites 102 calculates the identification code and the number of satellites receiving the GPS radio waves, the strength and pseudo distance of the satellite signals, etc. using the received GPS radio waves. Then, the A-GPS data is transmitted to the positioning server 160 through the mobile communication network using the "Provide Pseudorange Measurement" message defined in the IS-801-1 standard. Receiving the "Provide Pseudorange Measurement" message from the test terminal 110, the location determination server 160 calculates the latitude and longitude coordinates of the test terminal 110 by selecting the data contained in the "Provide Pseudorange Measurement" message.

The MAR value database 162 stores a MAR value table set for each identification code of a plurality of wireless base stations. Therefore, when the location determination server 160 receives the A-GPS location request signal including the identification code of the wireless base station from the test terminal 110, the location determination server 160 searches the corresponding MAR base station stored in the MAR value database 162. The auxiliary data including the information of the GPS satellite which can be observed in the region of the transmission is transmitted to the test terminal 110.

In addition, the MAR value database 162 also receives a new MAR value of the wireless base station on which the MAR value optimization has been performed by the location determination server 160, and updates and stores the MAR value table.

The MAR value optimization database 164 stores the MAR value optimization data received by the positioning server 160 from the test terminal 110. The MAR value optimization database 164 classifies and stores MAR value optimization data by measurement date, measurement time, measurement equipment, and wireless base station. Therefore, the location determination server 160 searches the MAR value optimization database 164 to perform the MAR value optimization.

2 is an exemplary view for explaining a MAR optimization concept according to an embodiment of the present invention.

In order to optimize the MAR value according to an embodiment of the present invention, the operator moves the test terminal 110 described in FIG. 1 between each wireless base station using a moving means such as a vehicle. The worker obtains MAR value optimization data through the process described with reference to FIG. 1 using the test terminal 110 at a predetermined time during the movement. Here, the measurement point for acquiring the MAR value optimization data is preferably a point where the observation of the GPS satellites is easy, that is, a open area that can easily search for GPS satellite radio waves. The operator who has started to acquire the MAR value optimization data from the area A 210 transmits the MAR value optimization data acquired at every measurement point to the positioning server 160 through the mobile communication network.

Meanwhile, the location determination server 160 analyzes the MAR value optimization data received from the test terminal 110, classifies the wireless base station requiring MAR value optimization, and performs an operation of optimizing the MAR value. In FIG. 2, reference numeral 260 denotes a movement route of the measurement vehicle, a point (●) indicated on the movement route is a point where reception conditions of C-GPS location information and A-GPS data are good, and a scissors table (×) denotes C- The reception state of GPS location information is good, but the reception state of A-GPS data means a bad point.

That is, the point indicated by the point is a point where the test terminal 110 observes a predetermined number of GPS satellites in the positioning server 160 using the A-GPS method, and the point indicated by the scissors table uses the A-GPS method. To observe GPS satellites less than a preset number. Here, observing the GPS satellites means that the GPS radio waves transmitted from the GPS satellites are searched for and received. Therefore, in the wireless base station requiring MAR value optimization according to an embodiment of the present invention, a predetermined number of GPS satellites are observed in the C-GPS method, but less than a predetermined number of GPS satellites are observed in the A-GPS method. It will be wireless base station A 212 adjacent to the area indicated by the scissors in 2.

Meanwhile, referring to FIG. 2, it can be seen that the point indicated by the scissors table is mainly biased in the region B 220 that the optical repeater 222 has jurisdiction over. The point indicated by the scissors table is mainly biased in the area B 220 because the test terminal 110 is transmitted from the positioning server 160 when the test terminal 110 is located in the area A covered by the MAR value set in the wireless base station A 212. The information of the GPS satellites 102 included in the assistance data is appropriate so that multiple GPS satellites 102 can be observed. However, when the test terminal 110 moves out of the area A 210 to the area B 220 covered by the optical repeater 222 connected by the optical cable 250, the test terminal 110 may not properly position the A-GPS method. do.

That is, the test terminal 110 moved to the area B 220, the identification code of the wireless base station included in the location request signal transmitted to the positioning server 160 to obtain the A-GPS data is the wireless base station A ( 212). Therefore, the location determination server 160 retrieves and transmits the information of the GPS satellite 102 capable of receiving GPS radio waves using the MAR value and the position coordinates set in the wireless base station A 120. Here, since the information of the GPS satellite 102 transmitted from the positioning server 160 is extracted using the MAR value set in the wireless base station A 120, the GPS satellite 102 may be used as valid information only in the region A 210.

However, since the test terminal 110 is moving the area B 220 and searches for the GPS radio waves using the information of the improper GPS satellite 102 valid only in the area A 210, a sufficient number of GPS waves (approximately 3 More than) will not be received.

In order to solve this problem, a MAR value optimization operation for increasing the MAR value set in the radio transmitter A 212 is performed. In order to optimize the MAR value, the location determination server 160 analyzes the MAR value optimization data classified and stored for each wireless base station, calculates the distance from the location of the wireless base station to the farthest point of the scissors table, and calculates the new MAR of the wireless base station. Update with a value. In FIG. 2, the distance indicated by reference numeral 270 will be the new MAR value of wireless base station A 212. When the location determination server 160 updates the MAR value of a specific wireless base station, the area covered by the wireless base station in the future becomes an area having a newly updated MAR value as a radius.

3 is a flowchart illustrating a process of optimizing a MAR value set in a wireless base station according to an embodiment of the present invention.

In order to optimize the MAR value according to an embodiment of the present invention, the worker moves through a moving means such as a vehicle and stops at a certain distance or at a certain distance, and turns on the power of the test terminal 110 for a measurement operation. (S300). The operator sets the test terminal 110 to the C-GPS operation mode by using a program mounted on the test terminal 110 or by operating a predetermined key button formed on the outer surface of the test terminal 110 (S302). The test terminal 110 set to the C-GPS operation mode searches for GPS radio waves, extracts C-GPS location information included in the searched GPS radio waves, and temporarily stores them in an internal memory (S304).

When the acquisition operation of the C-GPS position information due to the C-GPS operation mode is terminated in step S304, the operator changes the test terminal 110 to the A-GPS operation mode (S306). Here, the change operation from the C-GPS operation mode to the A-GPS operation mode can be performed by using a program or operating a predetermined key button similarly to that described in step S302. Further, more preferably, the GPS measurement program built in the test terminal 110 is automatically switched to the A-GPS operation mode when the test terminal 110 finishes obtaining C-GPS location information in the C-GPS operation mode. Will be able to code The test terminal 110 changed to the A-GPS operation mode searches for GPS radio waves, extracts A-GPS data included in the searched GPS radio waves, and temporarily stores them in a temporary memory (S308).

In operation S308, the test terminal 110 transmits the A-GPS location request signal to the location determination server 160, receives the assistance data from the location determination server 160, and includes the information in the assistance data. GPS coordinates are searched using the coordinate information of the GPS satellites. Then, A-GPS data is generated and stored using the navigation data included in the GPS radio waves.

Meanwhile, in FIG. 3, the test terminal 110 operates first in the C-GPS mode and then operates in the A-GPS mode. However, the test terminal 110 may operate in the A-GPS mode first and then operate in the C-GPS mode. There will be.

The test terminal 110 transmits the data to the positioning server 160 using a wireless modem incorporating the MAR value optimization data obtained through steps S304 and S308 (S310). The location determination server 160 stores the MAR value optimization data received from the test terminal 110 in the MAR value optimization database 164 that interworks (S312).

The location determination server 160 reads and analyzes the MAR value optimization data stored in the MAR value optimization database 164 for each wireless base station for MAR value optimization at predetermined time intervals, and determines whether MAR value optimization is required. Determine (S314). If the determination server 160 determines that MAR value optimization is necessary as a result of the determination in step S314, the location server 160 calculates a distance to a measurement point farthest from the wireless base station (S316). Here, the coordinate information of the farthest measurement point may be found by searching the latitude and longitude coordinate information of the measurement point calculated using the latitude and longitude coordinate information of the measurement point included in the C-GPS location information or A-GPS data.

The positioning server 160 sets the maximum distance value calculated in step S318 to a new MAR value of the corresponding wireless base station. Then, the location determination server 160 updates and stores the maximum distance value calculated in step S318 with the new MAR value of the corresponding wireless base station in the MAR value table stored in the MAR value database (S320).

The above description is merely illustrative of the present invention, and those skilled in the art to which the present invention pertains may various modifications without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed herein are not intended to limit the present invention but to describe the present invention, and the spirit and scope of the present invention are not limited by these embodiments. It is intended that the scope of the invention be interpreted by the following claims, and that all descriptions within the scope equivalent thereto shall be construed as being included in the scope of the present invention.

As described above, in the conventional mobile communication network, the MAR value of each wireless base station is uniformly determined, so that the location determination often fails in the A-GPS method. However, according to the present invention, the A-GPS method is appropriately adjusted by adjusting the MAR value. In this case, it is possible to greatly reduce the case where the positioning fails.

Claims (35)

A system for optimizing location-based services by adjusting a maximum radius (hereinafter, referred to as a 'MAR (Maximum Antenna Range) value') covered by a base station antenna, Data for MAR value optimization including C-GPS location information and A-GPS data received and stored from one or more GPS satellites using C (Conventional) -GPS method and A (Assisted) -GPS method for each one or more measurement points. Test terminal for transmitting the; A base station transmitter configured to transmit and receive signals and data with the test terminal and to store the MAR value; A base station controller for receiving and processing a signal transmitted from the base station transmitter and a mobile switching station connected to the base station controller; And A location determination server that receives the MAR value optimization data through a mobile communication network, analyzes the received MAR value optimization data, and updates the MAR value of the wireless base station corresponding to the MAR value optimization condition to optimize the location based service. System for optimizing location-based services by adjusting the maximum radius covered by the base station antenna, characterized in that it comprises a. The method of claim 1, The positioning server includes a base station antenna, characterized in that the built-in MAR value optimization algorithm for setting the maximum distance value of the distance between the wireless base station including the base station transmitter and each of the measurement point to the new MAR value System to optimize location-based services by adjusting the maximum radius. The method of claim 2, The MAR value optimization algorithm calculates the distance between the latitude and longitude coordinates of the wireless base station including the base station transmitter and the latitude and longitude coordinates of each measurement point to calculate the maximum distance value. System that optimizes location-based services by adjusting the maximum radius. The method of claim 3, wherein Latitude and longitude coordinates of each of the measurement points is included in the C-GPS location information received by the positioning server to adjust the maximum radius covered by the base station antenna to optimize the location-based services. The method of claim 1, The test terminal is a system for optimizing location-based services by adjusting the maximum radius covered by the base station antenna, characterized in that the built-in C-GPS receiver. The method of claim 1, The test terminal is a system for optimizing location-based services by adjusting the maximum radius covered by the base station antenna, characterized in that the built-in A-GPS receiving module. The method of claim 1, The test terminal may include a personal digital assistant (PDA), a cellular phone, a personal communication service (PCS) phone, a hand-held PC (GPS), a global system for mobile (GSM) phone, a wideband CDMA (W-CDMA) phone, A system for optimizing location-based services by adjusting a maximum radius covered by a base station antenna, comprising a CDMA-2000 phone and a Mobile Broadband System (MBS) phone. The method of claim 1, The mobile communication network includes a synchronous mobile communication network, an asynchronous mobile communication network and a fourth generation ALL-IP communication network, the system for optimizing location-based services by adjusting the maximum radius covered by the base station antenna. The method according to claim 1 or 8, When the mobile communication network is a synchronous mobile communication network, the base station transmitter is a base transceiver station (BTS), the base station controller is a base station controller (BSC), and when the asynchronous mobile communication network, the base station transmitter is a radio transceiver subsystem (RTS), a base station controller The system optimizes the location-based service by adjusting the maximum radius covered by the base station antenna, characterized in that the Radio Network Controller (RNC). The method of claim 1, The positioning server adjusts the maximum radius covered by the base station antenna, characterized in that the interlocking with the MAR value database that stores the MAR value table (Table) is assigned to the MAR value for each identification code of one or more wireless base station System to optimize location-based services. The method of claim 10, The positioning server optimizes the location-based service by adjusting the maximum radius covered by the base station antenna, characterized in that for updating the MAR value table using the newly updated MAR value to store in the MAR value database. The method of claim 1, The location server is a system for optimizing location-based services by adjusting the maximum radius covered by the base station antenna, characterized in that in conjunction with the MAR value optimization database for storing the MAR value optimization data received from the test terminal. The method of claim 12, The base station antenna, characterized in that for storing the MAR value optimization data received by classifying by receiving one or more criteria of the measurement date, the measurement time and the identification code of the radio base station of the MAR value optimization data. System that optimizes location-based services by adjusting the maximum radius to cover. The method of claim 1, The positioning server optimizes the location-based service by adjusting the maximum radius covered by the base station antenna, characterized in that in conjunction with the reference GPS antenna for monitoring the location information in real time according to the identification code of the GPS satellites. A test terminal for receiving GPS radio waves using the C-GPS method and the A-GPS method, a mobile communication network including a wireless base station and a mobile switching center having a MAR value, and location information of the wireless base station and the MAR value are stored. A method for optimizing location-based services in a system configured with a location server that resets the MAR value in association with a MAR value database, (a) receiving and storing C-GPS location information and A-GPS data transmitted from the test terminal; (b) analyzing the C-GPS location information and the A-GPS data for each wireless base station to determine a MAR value optimization target; (c) calculating a new MAR value using an embedded MAR value optimization algorithm; And (d) setting the new MAR value as an optimized MAR value of the corresponding wireless base station and storing the new MAR value in the MAR value database Method for optimizing the location-based services by adjusting the maximum radius covered by the base station antenna comprising a. The method of claim 15, The C-GPS location information includes the latitude, longitude, and number information of one or more GPS satellites receiving the GPS radio waves, thereby adjusting the maximum radius covered by the base station antenna to optimize location-based services. The method of claim 15, The base station antenna, characterized in that the A-GPS data includes the identification code, number, measurement time, GPS signal strength, pseudorange, NID (Network ID) and BSID (Base Station ID) of the GPS satellites. To optimize location-based services by adjusting the maximum radius that is covered. The method of claim 17, The BSID is a method of optimizing location-based services by adjusting the maximum radius covered by the base station antenna, characterized in that the identification code information of the wireless base station where the test terminal that transmitted the C-GPS location information is located. The method of claim 15, wherein in step (a) The positioning server optimizes the location-based service by adjusting the maximum radius covered by the base station antenna, characterized in that for storing the received C-GPS location information and the A-GPS data interlocked in the database for MAR value optimization Way. The method of claim 19, The positioning server adjusts the maximum radius covered by the base station antenna, characterized in that the C-GPS location information and the A-GPS data is classified by the identification code of the wireless base station and stored in the MAR value optimization database. How to optimize your base services. The method of claim 15, wherein in step (b) The MAR value optimization target is the number of GPS satellites included in the C-GPS location information is greater than or equal to a preset number, and the number of GPS satellites included in the A-GPS data is less than the predetermined number. A method of optimizing location-based services by adjusting a maximum radius covered by a base station antenna, characterized in that the base station is adjacent to or adjacent to one or more measurement points transmitted. The method of claim 21, The MAR value optimization algorithm is an algorithm for setting a maximum distance value of the distance value between the wireless base station and each of the measurement points to the new MAR value. How to optimize it. The method of claim 22, The MAR value optimization algorithm calculates a distance between the latitude and longitude coordinates of the radio base station and the latitude and longitude coordinates of each of the measurement points, and calculates the maximum distance value. How to optimize your location-based services. The method of claim 23, Latitude and longitude coordinates of each of the measurement points is included in the C-GPS location information received by the location determination server to adjust the maximum radius covered by the base station antenna to optimize the location-based services. Receiving C-GPS location information and A-GPS data from the test terminal receiving GPS radio waves using the C-GPS method and the A-GPS method and resetting the MAR value set in the wireless base station installed in the mobile communication network. A method of optimizing location-based services in a system consisting of location servers, (a) acquiring and storing C-GPS location information by moving to the test terminal in a C-GPS operation mode for every predetermined measurement point; (b) changing and measuring an A-GPS operation mode for each measurement point; (c) acquiring and storing A-GPS data using the A-GPS scheme; And (d) collecting and storing the stored C-GPS location information and the A-GPS data to the location determination server; Method for optimizing the location-based services by adjusting the maximum radius covered by the base station antenna comprising a. The method of claim 25, The change to the C-GPS operation mode or the A-GPS operation mode is performed by operating a button related to the operation mode change formed on the outer surface of the test terminal. How to optimize location-based services by throttling. The method of claim 25, The change to the C-GPS operation mode or the A-GPS operation mode is performed by using a program that performs a function of changing the operation mode installed in the test terminal device. How to optimize location-based services by throttling. The method of claim 25, The C-GPS location information includes the latitude, longitude, and number information of one or more GPS satellites receiving the GPS radio waves, thereby adjusting the maximum radius covered by the base station antenna to optimize location-based services. The method of claim 25, The A-GPS data includes the identification code, number, measurement time, GPS signal strength, pseudo distance, NID, and BSID of the GPS satellites. How to optimize. The method of claim 29, The BSID is a method of optimizing location-based services by adjusting the maximum radius covered by the base station antenna, characterized in that the identification code information of the wireless base station where the test terminal that transmitted the C-GPS location information is located. The process of claim 25, wherein in step (c) (c1) transmitting an A-GPS location request signal to the location server; (c2) receiving ancillary data transmitted from the positioning server; (c3) searching GPS radio waves using coordinate information of GPS satellites included in the auxiliary data; And (c4) generating and storing A-GPS data using the navigation data included in the retrieved GPS radio waves. Method for optimizing the location-based services by adjusting the maximum radius covered by the base station antenna comprising a. The method of claim 31, wherein in step (c1) The method for optimizing location-based services by adjusting the maximum radius covered by the base station antenna, characterized in that the location request signal includes the identification code information of the wireless base station adjacent to or jurisdiction to the measurement point where the test terminal is located. . The method of claim 31 or 32, The auxiliary data includes the coordinate information and the identification code information of the GPS satellites that the test terminal can observe from the measurement point, the method of optimizing the location-based services by adjusting the maximum radius covered by the base station antenna . The method of claim 31, wherein in step (c2) The location determination server transmits the auxiliary data using a "Provide GPS Acquisition Assistance" message defined in the IS (Interim Standard) -801-1 standard. How to optimize your service. The method of claim 25,       The test terminal optimizes the location-based service by adjusting the maximum radius covered by the base station antenna, characterized in that after the operation is set to the A-GPS operation mode, the operation mode is changed to the C-GPS operation mode.

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