KR100626225B1 - Method and System for Providing Navigation Service by Mobile Station Based Global Positioning System - Google Patents

Abstract

The present invention relates to a method and system for providing a navigation service using a terminal-based GPS.

GPS satellites to transmit GPS radio waves; An external GPS receiver for generating first location information data measured via navigation data in GPS radio waves; A mobile communication terminal displaying a user's location in consideration of the first location information data measured using the MS-Based GPS method and the second location information data of the external GPS receiver received from the external GPS receiver; A mobile communication network including a wireless base station and a mobile switching center receiving terminal information from the mobile communication terminal; And a location determination server for generating and transmitting auxiliary data using terminal information.

According to the present invention, when the location information data measured by the external GPS receiver inputted to the mobile communication terminal is not good, the mobile communication terminal provides a high quality navigation service to the user in consideration of the location information data measured by the MS-based GPS. It is effective to provide.

MS-Based GPS, Mobile Terminal, GPS Satellite, GPS Receiver

Description

Method and system for providing navigation service using terminal-based GPS {Method and System for Providing Navigation Service by Mobile Station Based Global Positioning System}

1 is a block diagram schematically illustrating a car navigation service system using a mobile communication network;

2 is a block diagram schematically illustrating a navigation service system using a terminal-based GPS according to an embodiment of the present invention;

3 is a block diagram briefly illustrating an internal configuration of a mobile communication terminal according to an embodiment of the present invention;

4 is a flowchart illustrating a method for providing a navigation service using a terminal-based GPS according to an exemplary embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

100: navigation unit 110, 210: GPS satellites

102, 230: mobile communication terminal 104: navigation box

106: GPS receiver 120: mobile communication network

130: information providing server 220: external GPS receiver

240: wireless base station 241: base station transmitter

243: base station controller 250: mobile switching center

260: positioning server 310: GPS antenna

311: GPS receiver 312: program unit

313: EEPROM 314: ROM

315: key input unit 316: LCD display unit

317: external data input unit 320: microprocessor

330: digital signal processing unit 340: baseband conversion unit

350: RF signal processing unit 360: speaker

370: microphone 380: RF antenna

The present invention relates to a navigation system and method using a mobile station based global positioning system (MS-based GPS). More specifically, when the location information data measured by the external GPS receiver input to the mobile communication terminal is not good, the navigation of the mobile terminal is considered good quality to the user in consideration of the location information data measured by the MS-based GPS method. The present invention relates to a navigation system and a method using a terminal-based GPS to provide a service.

In order to provide communication services such as the Internet beyond the recent space, 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 technologies and the rapid increase in mobile phone penetration have further accelerated the development of this wireless Internet environment.

Meanwhile, among various wireless Internet services using a mobile communication terminal such as a cellular phone or a PDA, a location based service (LBS) has gained much attention due to its wide utility and convenience. Location-based wireless Internet services can be used for rescue requests, response to crime reports, geographic information systems (GIS) for providing information on neighboring areas, differentiation of mobile communication charges according to location, traffic information, vehicle navigation and logistics control, location It can be used in various fields and situations such as customer relationship management (CRM).

In order to use the location-based wireless Internet service, it is essential to know the location of the wireless communication terminal. At present, a method of determining a location using wireless communication is a method using a global positioning system (GPS).

GPS is a system that can be located anywhere in the world by 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 and synchronizes information transmitted from GPS satellites. do. In general, triangulation is used as a method of positioning using a GPS system. Three satellites are required for triangulation, which requires a total of four GPS satellites, including one observational satellite for time error.

1 is a block diagram schematically illustrating a vehicle navigation service system using a mobile communication network.

A vehicle navigation service system using a mobile communication network includes a navigation unit 100, a GPS satellite 110, a mobile communication network 120, and an information providing server 130.

The navigation unit 100 is a mobile communication terminal 102 for receiving a predetermined traffic service (road guide, traffic situation guide, main building guide, etc.) through the mobile communication network 120 from the information providing server 130, road information. And a navigation box 104 for notifying various car navigation information by voice or video, a GPS receiver 106 for receiving GPS data signals from the GPS satellites 110, and the like. Accordingly, the GPS data signal received by the GPS receiver 106 from the GPS satellite 110 is input to the controller (not shown) to calculate the position and speed of the vehicle. In addition, the GPS data signal is transmitted from the mobile communication terminal 102 of the vehicle 100 to the information providing server 130 through the mobile communication network 120, so that the occupant of the vehicle receives a predetermined transportation service from the information providing server 130. Can be provided.

In addition, the information providing server 130 includes a route and speed calculation module for providing various transportation services to the vehicle, and manages an electronic numerical map database and a member information database.

However, the vehicle navigation service system using such a mobile communication network has an initial driving time of 30 seconds to about 60 seconds, so it is difficult to quickly locate a location, and it is almost impossible to provide a navigation service in an area where GPS cannot be received.

In order to solve the above problems, the present invention considers the location information data measured by the mobile communication terminal using the MS-based GPS method when the location information data measured by the external GPS receiver inputted to the mobile communication terminal is not good. The present invention provides a navigation system and method using a terminal-based GPS for providing a high quality navigation service to a user.

According to a first object of the present invention, a navigation service providing system using a mobile station based GPS (MS-Based GPS), comprising: a GPS satellite for transmitting a GPS radio wave containing navigation data; An external GPS receiver which extracts navigation data from GPS radio waves received from a GPS satellite to measure location and generates location information data; User's location considering first position information data measured by extracting navigation data from GPS radio wave received from GPS satellite using MS-Based GPS method and second position information data of external GPS receiver received from external GPS receiver A mobile communication terminal displaying a; A mobile communication network including a wireless base station and a mobile switching center receiving terminal information from the mobile communication terminal; And a location determination server for generating and transmitting auxiliary data using terminal information received from a mobile communication terminal.

According to a second aspect of the present invention, there is provided a navigation service providing method using a terminal-based GPS, which provides a navigation service to a mobile communication terminal using a terminal-based GPS, comprising the steps of: (a) applying power to an external GPS receiver and Connecting a mobile communication terminal; (b) determining whether the external GPS receiver operates by receiving the first location information data measured by the external GPS receiver input to the mobile communication terminal; (c) determining whether there is an error in the first location information data of the external GPS receiver when determining that the external GPS receiver is activated in step (b); And (d) when the mobile communication terminal determines that there is an error in the first location information data of the external GPS receiver in step (c), displays the location of the user using the second location information data measured by the MS-Based GPS. It provides a navigation service providing method using a terminal-based GPS, characterized in that it comprises a step.

According to a third object of the present invention, a mobile communication terminal for displaying a user's location in consideration of both the first location information data of the external GPS receiver and the second location information data measured through the MS-Based GPS method, comprising: A GPS antenna for receiving GPS radio waves transmitted from the GPS satellites; A GPS receiver for generating second position information data measured by extracting navigation data from GPS radio waves received by a GPS antenna; A program unit for storing operating system software having a real-time processing function for an operation of a mobile communication terminal; An external data input unit configured to receive first location information data measured by an external GPS receiver; An EEPROM in which first position information data of an external GPS receiver input to the mobile communication terminal and second position information data measured by an MS-Based GPS scheme are stored; A microprocessor for checking an error of the location information data of the external GPS receiver stored in EPIROM; And an LCD display unit for displaying a user's location using the location information data selected by the microprocessor.

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.

2 is a block diagram schematically illustrating a navigation service system 200 using a terminal-based GPS according to a preferred embodiment of the present invention.

A navigation service system using a mobile station based global positioning system (MS-Based GPS) according to a preferred embodiment of the present invention is a GPS satellite 210, an external GPS receiver 220, a mobile communication terminal 230. , A wireless base station 240, a mobile switching center 250, and a location determination server 260.

The GPS satellites 210 according to the preferred embodiment of the present invention are satellites used to determine the position of the mobile communication terminal 230 in GPS. In GPS, the GPS satellite 210 is composed of 24 satellites that continuously transmit the navigation data necessary for position calculation to the mobile communication terminal 230 through a carrier wave, of which 21 satellites are used for navigation. The three satellites are reserved for reserve.

The arrangement of the GPS satellites 210 is designed so that at least four satellites are always visible all over the earth in order to calculate the three-dimensional position of the mobile communication terminal 230 and the error of the clock embedded in the mobile communication terminal 230. . Data transmitted in the form of radio waves in each GPS satellite 210 includes PRN codes (Pseudo Random Noise) uniquely designed according to the number of each GPS satellite. That is, since the navigation data is transmitted to the mobile communication terminal 230 through the GPS radio waves transmitted to the GPS satellites 210 in the code division multiple access (CDMA), the mobile communication terminal 230 each has a radio wave form. The navigation data transmitted by the GPS satellites can be clearly received.

The external GPS receiver 220 according to a preferred embodiment of the present invention is equipment for calculating the position and speed of the external GPS receiver 220 by receiving navigation data in the form of radio waves from the GPS satellites 210. In addition, the external GPS receiver 220 is connected to the mobile communication terminal 230, the position information data of the external GPS receiver 220 measured using the navigation data from the GPS satellites 210 to the mobile communication terminal 230. Send.

The mobile communication terminal 230 according to a preferred embodiment of the present invention transmits terminal information (MS information) to the location determination server 260 through the mobile communication network to determine the location using the MS-Based GPS method. The location server 260 generates auxiliary data for positioning the mobile communication terminal 230 using the received terminal information and transmits the auxiliary data to the mobile communication terminal 230 through the mobile communication network. The mobile communication terminal 230 receives GPS radio waves from one or more GPS satellites 210 using the received auxiliary data, extracts navigation data included in the received GPS radio waves, and measures its position.

In addition, the mobile communication terminal 230 is a GPS satellite 210 by using the location information data of the external GPS receiver 220 measured by the external GPS receiver 220 and the mobile communication terminal 230 itself using the MS-Based GPS method. The location of the user is displayed in consideration of all the location information data of the mobile communication terminal 230 measured through the GPS radio waves received from In this case, the mobile communication terminal 230 basically displays the user's location using the location information data of the external GPS receiver 220, and then the external GPS receiver 220 communicates with the GPS satellite 210 such as a mountain or a tunnel. When entering an impossible region or when the reception rate (or accuracy) of the radio wave is low, it is determined that there is an error in the location information data of the GPS receiver 220 and the location information data of the mobile communication terminal 230 measured through the MS-Based GPS method is measured. To display the user's location.

In this general MS-based GPS method, the mobile communication terminal 230 extracts navigation data from GPS radio waves received from the GPS satellites 210 to determine its latitude and longitude coordinates, and needs to update auxiliary data values or download a map. If not, the longitude and latitude coordinates are not transmitted to the positioning server 260. Therefore, the MS-Based GPS method is suitable for the personal navigation system because the mobile communication terminal 230 measures the position of the mobile communication terminal 230 by itself, so that the use of the communication network is reduced, resulting in less time delay or load. The personal navigation system is a system for providing various LBS (LBS) services to an individual who has a predetermined navigation terminal. The personal navigation system can display an individual's location on a map and a certain range based on the current location. It is a system for displaying a map of the map and guiding the shortest distance route to the destination. Therefore, the mobile communication terminal having determined its location in the MS-Based GPS method transmits the location information to the communication network, and downloads a map of a predetermined range based on the current location from a predetermined map server (not shown) installed in the communication network. To display. In addition, the mobile communication terminal does not connect to the communication network until the mobile communication terminal deviates from the downloaded range of maps, and displays the positioning result performed by itself on the downloaded map.

However, unlike the mobile communication terminal using the general MS-Based GPS method mentioned above, the mobile communication terminal 230 in the embodiment of the present invention is mobile communication with the location information data of the external GPS receiver 220 input from the outside. The terminal 230 displays the location of the user in consideration of all the location information data of the mobile communication terminal 230 measured using the MS-Based GPS method.

In addition, the mobile communication terminal 230 according to an embodiment of the present invention is not limited to downloading a map from a map server through a mobile communication network, unlike a mobile communication terminal using a general MS-Based GPS method, and a memory card storing map information. The same storage medium may be combined with a mobile communication terminal to provide a map.

In addition, the mobile communication terminal 230 according to the embodiment of the present invention may measure the location information data measured by the external GPS receiver 220 and the location information data measured by the mobile communication terminal 230 using the MS-Based GPS method. In consideration of both, the mobile communication terminal 230 is limited to the mobile communication terminal 230. However, the location of the user may be displayed using only the location information data input from the external GPS receiver 220, or the mobile communication terminal 230 may display the MS. The location of the user can be displayed using only the location information data measured by the base GPS method.

Here, the mobile communication terminal 230 may be 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 W-CDMA ( Wideband CDMA phones, CDMA-2000 phones, Mobile Broadband System (MBS) phones, notebook 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 MS-Based GPS method according to an embodiment of the present invention can 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 internal structure and function of the mobile communication terminal 230 according to the preferred embodiment of the present invention will be described in more detail with reference to FIG. 3.

The base station (BS) 240 includes a base station transmitter 241 and a base station controller 243. The base station transmitter 241 receives location information transmitted from the mobile communication terminal 230 and transmits it to the base station controller 243. The base station controller 243 controls the base station transmitter 241, allocates and releases radio channels for the mobile communication terminal 230, controls the transmission output of the mobile communication terminal 230 and the base station transmitter 241, and inter-cell soft handoff. It performs soft handoff and hard handoff decision, transcoding and vocoding, and operation and maintenance of wireless access network.

Meanwhile, the base station transmitter 241 and the base station controller 243 according to the embodiment of the present invention have a configuration capable of supporting both a synchronous mobile communication system and an asynchronous mobile communication system. Here, in a synchronous mobile communication system such as CDMA 2000 1X, CDMA 2000 1x Evolution-Data Only (EV-DO), the base station transmitter 241 is a base transceiver station (BTS), and the base station controller 243 is a base station BSC (base station). Controller. In addition, in the case of an asynchronous mobile communication system such as WCDMA, the base station transmitter 241 is a Radio Transceiver Subsystem (RTS), and the base station controller 243 is a Radio Network Controller (RNC). Of course, the base station transmitter 241 and the base station controller 243 according to the 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. .

The mobile switching center (MSC) 250 has a control function for enabling wireless base stations to operate efficiently and an interworking function with an electronic switch installed in a public switched telephone network (PSTN). The mobile switching center 250 receives data or a message transmitted from the mobile communication terminal 230 through the base station controller 243 and transmits it to the positioning server 260. The mobile switching center 250 performs basic and additional service processing, incoming call origination call processing of a subscriber, location registration procedure and handoff procedure, and interworking with other networks. Mobile switching center 250 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.

The Positioning Determination Entity (PDE) 260 performs overall control and management of the location information of the mobile communication terminal 230. In addition, the position of the mobile communication terminal 230 is calculated and the data regarding the position is transmitted to the mobile communication terminal 230 through the wireless Internet network. In more detail, the location determination server 260 receives terminal information such as resolution of the wireless base station 240 from the mobile communication terminal 230 and transmits auxiliary data to the mobile communication terminal 230. In more detail, a reference GPS antenna (not shown) is provided on the positioning server 260 side. Therefore, the positioning server 260 that has received the terminal information of the wireless base station 240 from the mobile communication terminal 230, the information of the GPS satellites (coordinate information, ID code information, etc.) is retrieved and included in the "Provide Ephemeris" message defined in the IS-801-1 standard and transmitted to the mobile communication terminal 230. In this case, the terminal information is specifically information about a pilot phase capability, a GPS acquisition capability, a position calculation capability, and the like of the terminal.

On the other hand, the server connection period that the mobile communication terminal 230 periodically connects to the positioning server 260 is a process of initially exchanging the MS-Based GPS-related parameter values between the mobile communication terminal 210 and the LBS platform 260 Can be received in the middle. That is, the LBS platform (not shown) may exchange server connection periods in the process of exchanging parameter values such as positioning periods related to MS-Based GPS with the mobile communication terminal 210.

The mobile communication terminal 230 receiving the "Provide Ephemeris" message extracts the information of the GPS satellites included in the message, receives the GPS satellites transmitted by searching for the GPS satellites.

The mobile communication terminal 230 receiving GPS radio waves from one or more GPS satellites determines its location using a built-in GPS receiver. Then, if there is no map information stored in the mobile communication terminal 230, the determined location information is transmitted to the LBS platform (not shown) through the mobile communication network to request a map download. The LBS platform transmits the received location information to a map server (not shown), and the map server generates a range of maps based on the location of the mobile communication terminal 230 using the received location information as a reference point, thereby moving the LBS platform and moving. It transmits to the mobile communication terminal 230 through a communication network.

3 is a block diagram schematically illustrating an internal configuration of a mobile communication terminal 230 according to a preferred embodiment of the present invention.

The mobile communication terminal 230 according to the preferred embodiment of the present invention includes a GPS antenna 310, a GPS receiver 311, a program unit 312, an EPI 313, a ROM 314, a key input unit 315, LCD display unit 316, external data input unit 317, microprocessor 320, digital signal processor 330, baseband converter 340, RF signal processor 350, speaker 360, microphone 370 ) And an RF antenna 380 and the like.

The GPS antenna 310 receives GPS radio waves from one or more satellites and transmits them to the GPS receiver 311. In general, a satellite may be associated with a parabolic antenna, but GPS requires receiving radio waves from various satellites orbiting the earth, so it is not possible to use a high-gain, high-gain antenna such as a parabolic antenna. . The GPS antenna 310 usually has a semi-circular directivity on the top of the ground plain, and receives the primary source polarization transmitted from the satellite.

The GPS receiver 311 receives the navigation data included in the received GPS radio waves from the GPS antenna 310 and transmits the latitude and longitude position information and the time information of the mobile communication terminal 230 calculated through a predetermined process to the microprocessor 320. To pass). That is, the GPS radio waves transmitted from the GPS satellites include ID codes, orbital positions, and visual information of the GPS satellites, and the GPS receiver 311 detects a difference in arrival speed between radio waves emitted from a plurality of GPS satellites. Compute the position coordinates of the vehicle. Of course, the GPS processor 311 may be mounted on the digital signal processor 330, which will be described later, without the GPS receiver 311 as a separate device.

The program unit 312 is a non-volatile memory having a high data processing speed, and has an operating system (OS) having a real-time processing function for the operation of the mobile communication terminal 230. ), And call processing software that handles functions related to call processing.

The EEPROM 313 is a non-volatile memory in which data for storage such as NAM (Number Assignment Module) parameters, phone numbers, names, and short messages are recorded.

The ROM 314 stores variable and state information of a program generated in connection with driving various kinds of software mounted in the program unit 312.

The key input unit 315 is provided with a plurality of key buttons for inputting various data such as numbers and letters.

The LCD (Liquid Crystal Display) display unit 316 displays the operation state of the mobile communication terminal 230 including the reception strength, the date, and the time of the radio wave.

The external data input unit 317 receives information data from an external device through a connection means. Here, the external data input unit 317 receives the position information data of the external GPS receiver 220 measured by the external GPS receiver 220 and transmits it to the microprocessor 320.

The microprocessor 320 controls the overall operation of the mobile communication terminal 230. In addition, the microprocessor 320 checks the data input from the external GPS receiver 220 for an error, and if there is an error, the microprocessor 320 uses the position information data measured by the mobile communicator using the MS-Based GPS method. 316) indicates the location of the user.

The digital signal processor 330 encodes or decodes voice and data, functions as an equalizer for removing multipath noise, and processes a digital data processing processor. to be. In addition, the digital signal processor 330 exchanges voice data with the baseband converter 340 and receives data from the baseband converter 340 (RX DATA). The digital signal processor 330 performing the above-described function includes a mobile station modem (MSM) chip manufactured by Qualcomm.

The baseband converter 340 converts a signal transmitted and received between the digital signal processor 330 and the RF signal processor 350, the speaker 360, and the microphone 370 into a signal of the baseband band, and converts the digital-analog signal. It performs functions such as (DAC: Digital to Analog Conversion) and Analog to Digital Conversion (ADC). In addition, the baseband converter 340 transmits the transmission data (TXIQ) to the RF signal processor 350, and controls the power of the RF signal processor 350 (POWER) or automatically controls the gain (AGC). . The RF signal processor 350 receives the received signal RXIQ.

The RF signal processor 350 demodulates and amplifies the RF signal received from the RF antenna 380, modulates a transmission signal applied from the baseband converter 340, and transmits the modulated signal to a propagation space.

The speaker 360 outputs sound data transmitted from the baseband converter 340 as an audible sound, and the microphone 370 converts a user's voice input into an electrical signal.

4 is a flowchart illustrating a method for providing a navigation service using a terminal-based GPS according to an exemplary embodiment of the present invention.

Referring to FIG. 2 to FIG. 3, first, a user applies power to the external GPS receiver 220 and connects to the mobile communication terminal 230 by using a connection means (S410). At this time, the connection means may be a communication cable for the terminal and connects the output terminal (not shown) of the external GPS receiver 220 and the external data input unit 317 of the mobile communication terminal 230 to enable data communication. In addition, the location information data of the external GPS receiver 220 measured using the navigation data extracted from the GPS radio waves received from the GPS satellites 210 is input to the mobile communication terminal 230.

Subsequently, the microprocessor 320 of the mobile communication terminal 230 checks whether or not the location information data of the external GPS receiver 220 inputted to the external data input unit 317 is received to determine whether the external GPS receiver 220 operates normally. It is determined whether or not (S420). In general, since the external GPS receiver 220 takes about 30 seconds to 60 seconds to operate and the initial driving time required for normal operation is required, it is necessary to check whether the external GPS receiver 220 operates normally.

If it is determined in step S420 that the external GPS receiver 220 does not operate normally through the microprocessor 320 of the mobile communication terminal 230, the mobile communication terminal 230 in the GPS radio wave directly received by the GPS satellites 210. The location of the mobile communication terminal 230 is measured based on the extracted navigation data and the current location is displayed on the LCD display unit 316 of the mobile communication terminal 230 (S430).

In this case, since step S430 generally takes about 30 seconds to 60 seconds for the initial driving time of the external GPS receiver 220, it is difficult to measure the position immediately and the error is large at the stop position, thereby using the MS-based GPS method. The user's location is displayed on the LCD display unit 316 using the location information data measured by the 230-second period.

When it is determined in step S420 that the external GPS receiver 220 operates normally through the microprocessor 320 of the mobile communication terminal 230, the mobile communication terminal 230 uses the position information data of the external GPS receiver to display the LCD display ( While displaying the current position in 316, it is checked whether there is an error in the location information data of the external GPS receiver (S450). An error here occurs when the GPS receiver is unable to receive GPS radio waves from GPS satellites due to mountains, tunnels or other obstacles, or the reception rate (or accuracy) of GPS radio waves is low.

If it is determined in step S450 that there is an error in the location information data of the external GPS receiver 220 through the microprocessor 320 of the mobile communication terminal 230, the mobile communication terminal 230 itself by using the MS-Based GPS method. Based on the navigation data extracted from the GPS radio waves received from the GPS satellites 210, the position information data of the mobile communication terminal 230 is measured and displayed on the LCD display unit 316 of the mobile communication terminal 230. (S450).

If it is determined in step S450 that there is no error in the location information data of the external GPS receiver 220 through the microprocessor 320 of the mobile communication terminal 230, the location information data input from the external GPS receiver 220 is used. The user's position is displayed on the LCD display unit 316 of the mobile communication terminal 230 (S480).

Subsequently, it is determined whether the user wants to continue using the navigation service (S470). If the user wants to terminate, all processes are terminated, and if the user wants to continue using the navigation service, the process proceeds to step 450.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

As described above, according to the present invention, when the location information data measured by the external GPS receiver inputted to the mobile communication terminal is not good, the mobile communication terminal considers the location information data measured by the MS-based GPS to the user. It is effective to provide high quality navigation service.

Claims (14)

In the navigation service providing system using a mobile station based GPS (MS-Based GPS), A GPS satellite for transmitting GPS radio waves containing navigation data; An external GPS receiver for generating location information data by measuring a location through the navigation data extracted from the GPS radio waves received from the GPS satellites; Receiving the first location information data measured by extracting the navigation data from the GPS radio waves received from the GPS satellites using the external GPS receiver, and also receiving the second location data measured using the MS-Based GPS method. A mobile communication terminal for receiving and checking a first location information data reception rate and determining and displaying a user's location with the second location information data if the first location information data reception rate is less than or equal to a specific reference; A mobile communication network including a wireless base station and a mobile switching center receiving terminal information from the mobile communication terminal; And Positioning server for generating ancillary data using the terminal information received from the mobile communication terminal to transmit to the mobile communication terminal Navigation service providing system using a terminal-based GPS, including a. The method of claim 1, wherein the mobile communication terminal System for providing a navigation service using a terminal-based GPS, it is possible to download a map from a map server through the mobile communication network or to combine a storage medium in which map information is stored. The method of claim 1, wherein the mobile communication terminal The location of the user may be displayed using only the first location information data measured by the external GPS receiver, or the location of the user may be displayed using only the second location information data measured by the mobile communication terminal through the MS-Based GPS method. Navigation service providing system using a terminal-based GPS. The method of claim 1, wherein the mobile communication terminal PDA (Personal Digital Assistant), Cellular Phone, Personal Communication Service (PCS) Phone, Hand-Held PC, Global System for Mobile (GSM) Phone, Wideband CDMA (W-CDMA) Phone, CDMA-2000 Phone , MBS (Mobile Broadband System) phone, a notebook computer, a navigation service providing system using a terminal-based GPS, characterized in that at least one. The method of claim 1, wherein the external GPS receiver The mobile communication terminal and the navigation service providing system using a terminal-based GPS, characterized in that the data communication is connected to each other through a connection means such as a communication cable. The method of claim 1, wherein the wireless base station And a base station transmitter for receiving terminal information from the mobile communication terminal and a base station controller for controlling the base station transmitter. The method of claim 1, wherein the terminal information System for providing a navigation service using terminal-based GPS, characterized in that the resolution information including at least one of pilot phase capability information, GPS acquisition capability information and position calculation capability information of the mobile communication terminal. . The method of claim 1, wherein the auxiliary data And at least one of coordinate information and identification code information of the GPS satellites capable of receiving the GPS radio waves at the wireless base station. In the navigation service providing method using a terminal-based GPS to provide a navigation service to a mobile communication terminal using a mobile station based GPS (MS-Based GPS), (a) applying power to an external GPS receiver and connecting the external GPS receiver to the mobile communication terminal; (b) determining whether the external GPS receiver operates normally by receiving first location information data measured by the external GPS receiver input to the mobile communication terminal; (c) determining that the reception rate of the first location information data of the external GPS receiver is lower than or equal to a specific reference when it is determined in step (b) that the external GPS receiver is normally operated; And (d) when it is determined in step (c) that the reception rate of the first location information data of the external GPS receiver is equal to or less than a specific reference, the second location information data measured by the mobile communication terminal through the MS-Based GPS; Displaying your location using Method for providing a navigation service using a terminal-based GPS, characterized in that it comprises a. The method of claim 9, wherein the service providing method is (c1) if it is determined in step (b) that the external GPS receiver does not operate normally, the mobile terminal displays the location of the user using the second location information data measured by the MS-Based GPS; step Method for providing a navigation service using a terminal-based GPS, characterized in that it further comprises. The method of claim 9, wherein the service providing method is (e) if it is determined in step (c) that the reception rate of the first location information data of the external GPS receiver is greater than or equal to a certain reference value, the mobile communication terminal uses the first location information data measured by the external GPS receiver; Displaying your location Method for providing a navigation service using a terminal-based GPS, characterized in that it further comprises. delete The mobile communication terminal displaying the user's location in consideration of both the first location information data of the external GPS receiver and the second location information data measured through the MS-Based GPS (MS-Based GPS) method. In A GPS antenna for receiving GPS radio waves transmitted from one or more GPS satellites; A GPS receiver for generating the second position information data measured by extracting navigation data from the GPS radio waves received by the GPS antenna; A program unit storing operating system software having a real-time processing function for the operation of the mobile communication terminal; An external data input unit configured to receive the first location information data measured by the external GPS receiver; An EEPROM in which the first location information data of the external GPS receiver input to the mobile communication terminal and the second location information data measured by the MS-Based GPS method are stored; A microprocessor for checking a first positional information data reception rate of the external GPS receiver stored in the YPyrom; And LCD display unit for displaying the location of the mobile communication terminal using the location information data selected by the microprocessor Mobile communication terminal using a terminal-based GPS, characterized in that it comprises a. The microprocessor of claim 13, wherein the microprocessor is And displaying the location of the mobile communication terminal on an LCD display by using the second location information data to the GPS receiver when the first location information reception rate of the external GPS receiver is equal to or less than a specific criterion. Mobile communication terminal using.

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