KR20120051469A - Positioning system and positioning method for terminal, wlan apparatus and driving method thereby - Google Patents

Abstract

PURPOSE: A terminal positioning system, a method thereof, a wireless LAN apparatus, and an operating method thereof are provided to increases positioning accuracy and to reduce manufacturing costs. CONSTITUTION: A first AP(Access Point)(111) has a predetermined coverage. A second AP(112) has a coverage which is smaller than the first AP coverage. The first AP and the second AP perform local area communication with a terminal. A communication network(120) transfers the first AP and the second AP information as positioning information.

Description

Terminal positioning system and method, WLAN device and driving method thereof {Positioning System and Positioning Method for Terminal, WLAN Apparatus and Driving Method Thereby}

An embodiment of the present invention relates to a terminal positioning system and method, a wireless LAN device and a method of driving the device. More specifically, for example, when a request for positioning is performed on a specific terminal through a friend search service, a fixed short distance such as a television or a game machine that performs short range communication such as Bluetooth in addition to an access point for Wi-Fi communication for performing the positioning. The present invention relates to a terminal positioning system and method for improving positioning accuracy using a communication device, a wireless LAN device, and a method of driving the device.

The contents described in the following sections provide background information related to the embodiments of the present invention, but it does not constitute a prior art.

With the rapid development of electronic and communication technology, various wireless communication services using a wireless network have been provided. Accordingly, a service provided by a mobile communication system using a wireless communication network is developing into a multimedia communication service that transmits packet data as well as voice service.

Among various wireless Internet services using a terminal, in particular, LBS (Location Based Service) has gained much attention due to its wide usability and convenience. Location-based service refers to a communication service that locates a terminal such as a mobile phone and a personal digital assistant (PDA) and provides additional information related to the identified location.

Positioning technology for providing location-based services uses a network-based method and a GPS receiver mounted on a terminal to determine the location in software using a radio environment, which is the cell radius of a base station of a wireless communication network, to measure the location of the terminal. Is classified into a handset based method using a hybrid method and a hybrid method using a combination of these two methods.

Among them, network-based positioning technology is being used a lot in the shaded areas where GPS cannot reach. However, such a network-based positioning technology may have a disadvantage in that positioning performance may be degraded due to a repeater environment, and the base station itself may not be installed in a compact manner, thereby reducing the accuracy of positioning.

An embodiment of the present invention is a fixed short-range communication device, such as a television and a game machine that performs communication such as Bluetooth, in addition to a Wi-Fi communication access point, which is installed at a separate cost to provide a service such as a friend search. It is an object of the present invention to provide a terminal positioning system and method for improving the positioning accuracy of a terminal, a wireless LAN device, and a method of driving the device.

In a terminal positioning system according to an embodiment of the present invention, when a terminal requests a positioning, a first access point (AP) having a certain coverage and a second AP having a smaller coverage than the first AP are in short-range communication with the terminal. A communication network configured to receive and transmit at least one of the AP information of the first AP and the second AP provided by the terminal as positioning information; A positioning device for requesting positioning of the terminal, receiving and transmitting the AP information from the communication network, and receiving the positioning result of the terminal and transmitting it to a service requester; And pre-store WLAN information about the first AP and the second AP, search and extract the WLAN information based on the AP information provided as the positioning information, and extract the WLAN information to the first AP. When the wireless LAN information of the AP and the second AP, the wireless LAN device that calculates and provides the positioning result of the terminal in a manner that gives a higher weight to the wireless LAN information of the second AP than the first AP; It is characterized by.

In addition, in the WLAN apparatus according to the embodiment of the present invention, when the terminal requests a positioning, a first access point (AP) having a certain coverage and a second AP having a coverage smaller than the first AP perform near field communication with the terminal. Receiving at least one of the AP information of the first AP and the second AP provided by the terminal as positioning information, and receiving and transmitting WLAN information based on the AP information provided as the positioning information. Call processing unit; When the WLAN information is provided and the WLAN information is WLAN information of the first AP and the second AP, the WLAN information is divided into WLAN information of the first AP and the second AP. WLAN information classification unit; And receiving the WLAN information of the first AP and the second AP, and calculating the positioning result of the terminal by giving a weight to the WLAN information of the second AP higher than the WLAN information of the first AP. It characterized in that it comprises an algorithm performing unit.

The terminal positioning method according to an embodiment of the present invention stores the WLAN information about a first access point (AP) having a certain coverage for performing short-range communication with the terminal and a second AP having a smaller coverage than the first AP. Making; Receiving at least one AP information of the AP information of the first AP and the second AP as location information provided when the location request of the terminal is performed; Search and extract the WLAN information based on the positioning information, and when the extracted WLAN information is WLAN information of the first and second APs, the WLAN of the second AP rather than the first AP. Calculating a positioning result of the terminal in a manner of weighting information; And providing a location result of the terminal to a service requester.

In addition, the method of driving a WLAN device according to an embodiment of the present invention is a radio for a first access point (AP) having a certain coverage for performing short-range communication with the terminal and a second AP having a smaller coverage than the first AP Storing the LAN information; Receiving at least one AP information among the AP information of the first AP and the second AP as location information provided when the location request is made by the terminal, and searching and extracting the WLAN information based on the location information; Determining whether the WLAN information of the second AP exists in the extracted WLAN information; And if the WLAN information of the second AP exists, calculating the positioning result of the terminal using the WLAN information of the second AP.

According to an embodiment of the present invention, positioning accuracy can be improved by utilizing a fixed short-range communication device such as a television and a game machine that performs communication such as Bluetooth, in addition to Wi-Fi communication.

In addition, since it utilizes a fixed type of short-range communication device that is already installed, it may be possible to save cost because it does not need to install a separate access point to increase positioning accuracy.

1 is a view showing the structure of a terminal positioning system according to an embodiment of the present invention;
FIG. 2 is a diagram illustrating a DB structure of a WLAN device of FIG. 1;
3 is a view illustrating a driving unit structure of the WLAN device of FIG. 1;
4 is a view showing a positioning process of the terminal positioning system of FIG.
FIG. 5 is a diagram illustrating a method of driving the WLAN device of FIG. 1.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a diagram illustrating a structure of a terminal positioning system according to an exemplary embodiment of the present invention, and FIG. 2 is a diagram illustrating a DB structure of a WLAN device of FIG. 1.

1 and 2, a terminal positioning system according to an embodiment of the present invention includes a communication network 120, a positioning device 130, and a WLAN device 140. Furthermore, the terminal location system may further include an access point (AP) 110 and a location based service platform (LBSP) 150, and the WLAN device 140 may include a DB 140a. have.

In an embodiment of the present invention, the terminal 100 is a personal digital assistant (PDA), a cellular phone, a smartphone, and the like, which are classified according to terminal types so as to be applicable to various wired and wireless environments, and a personal communication service (PCS) that is classified by a communication method of the terminal. ) Includes a phone, a Global System for Mobile (GSM) phone, a Wideband CDMA (W-CDMA) phone, a CDMA-2000 phone, and a Mobile Broadband System (MBS) phone. The MBS phone here represents a terminal 100 to be used in the next generation system currently being discussed. Furthermore, the terminal 100 according to the embodiment of the present invention may further include a laptop computer.

The terminal 100 may include a wireless communication module and a wireless LAN module, and further include a GPS module. As the wireless communication module is provided, the terminal 100 connects to the communication network 120 to perform normal voice call and data communication with the other party. In addition, since the terminal 100 includes a wireless LAN module, the terminal 100 may receive various web page data by accessing the communication network 120 via the AP 110 recognized therein. Furthermore, the terminal 100 may be classified into a first terminal 101 which is a GPS terminal and a second terminal 102 which is a non-GPS terminal according to whether a GPS module is provided. Receive the data provided.

The terminal 100 includes a wireless application protocol (WAP), which is an internet access protocol, a Microsoft Internet Explorer (MIE) based on HTML using an HTTP protocol, a handheld device transport protocol (HDPT), and an NTT. DoKoMo's i-Mode or a specific carrier's wireless Internet connection browser is used to access the Internet via the communication network 120. Among the Internet access protocols used in the terminal 100, MIE uses m-HTML, which is shortened by slightly modifying HTML, and in the case of i-Mode, a language called compact HTML (c-HTML), which is a subset of HTML, is used. do.

Recently, a terminal 100 such as a smartphone uses a browser for wireless Internet access of a specific telecommunication company such as Opera Mini for iPhone to provide a faster wireless Internet, or in close proximity to the terminal 100 in connection with it. Wi-Fi and WiBro networks are also used to provide wireless high-speed Internet.

The terminal 100 performs network-based positioning or handset-based positioning according to the positioning request from the positioning device 130. For example, the terminal 100 may provide GPS information, base station information, and AP information to the positioning device 130 via the communication network 120 to perform network-based positioning. Here, the AP information includes address information of the AP 110 performing short range communication such as Wi-Fi, Bluetooth, Zigbee communication, and the like. When performing network-based positioning, a positioning protocol message of a specific standard is used between the terminal 100 and the positioning device 130. Here, the positioning protocol is a protocol standardizing the standard of the application layer for positioning of the terminal 100.

For example, in the case of an asynchronous (WCDMA) network, the first terminal 101 capable of receiving a GPS signal may provide SUPL (Secure) to provide positioning information requested by the positioning device 130, for example, GPS information, base station information, and AP information. The second terminal 102 using the User Plane Location (GPS) message and unable to receive the GPS signal may use the Positioning Calculation Application Part (PCAP) to provide the positioning information requested by the positioning device 130, for example, the base station information and the AP information. Use a message. In the case of a synchronous (CDMA) network, the first terminal 101 provides location information to the positioning device 130 using an Interim Standard-801 (IS-801) message, and the second terminal 102 provides a PSM. The positioning information is provided to the positioning device 130 using a Pilot Strength Measurement message. Here, since the first terminal 101 can use various positioning protocols such as Radio Resource Location Services Protocol (RRLP) and Radio Resource Control (RRC) in addition to SUPL and IS-801, the first terminal 101 will not be particularly limited thereto.

In the case of the synchronous type, the positioning information provided by the first terminal 101 to the positioning device 130 through the IS-801 message includes system information currently being serviced, a pilot signal of an adjacent base station, signal strength (Ec / lo), and the like. . Here, the system information includes, for example, a system ID (SID), a network ID (NID), a base station ID (BSID), a base station sector number (Ref_PN) currently being serviced, a pilot phase and signal strength in Ref_PN, and the like. In addition, the pilot signal of the neighboring base station includes a neighboring base station sector number (Measurement PN) collected from the first terminal 101, a pilot phase and signal strength in each neighboring base station sector number. If asynchronous, the location information provided by the first terminal 101 through the SUPL message may be Mobile Country Code (MCC), Mobile Network Code (MCC), UC-ID, Primary Scrambling Code (PSC), or Received Signal Code (RSCP). The present invention may be data such as power, signal strength (Ec / No), observed time difference between system frame numbers (SFN), or time difference between transmission and reception (RX-TX) of the first terminal 101. An embodiment of the present invention may include location related data used for all other communication systems without being limited thereto. Of course, the second terminal 102 also provides the positioning device 130 with the same positioning information as the positioning information provided by the first terminal 101 to the positioning device 130 through a PCAP message or a PSM message.

When the first terminal 101 performs the positioning using the SUPL or IS-801 message according to the request of the positioning device 130, the positioning message (hereinafter, referred to as the first positioning message) such as the SUPL message is the communication network 120 For example, if the second terminal 102 performs the positioning using a PCAP or PSM message, the call processing is performed through each network node such as NodeB, RNC, and MSC. Since the message (hereinafter referred to as the second positioning message) is called through all the respective network nodes, the first positioning message may be called as quickly as compared to the second positioning message.

The AP 110 includes a first AP 111 and a second AP 112. The first AP 111 is a small base station such as a femto or pico base station installed in a building, and may serve to relay a signal for communication between two different devices. Here, the femto or pico base station is classified according to how many terminals 100 can be connected in the classification of the small base station. According to an embodiment of the present invention, the first AP 111 may include a short range communication module for performing Wi-Fi short range communication with the terminal 100. Accordingly, the first AP 111 may extract the location of the data packet, designate the best communication path for the extracted location, and forward the data packet to the next device, for example, the terminal 100, along the designated communication path. The first AP 111 may share several lines in a general network environment, and may include, for example, a router, a repeater, a repeater, and the like. In addition, a bridge product of a specific manufacturer such as MiFi of Verizon may also be included in the first AP 111.

The second AP 112 is, for example, an electronic device such as a television, a game machine, or a desktop computer, which is typically fixed to a specific area or does not leave a certain area. In this regard, unlike the first AP 111, the second AP 112 may have a feature of transmitting and receiving a signal to one device rather than relaying a signal for communication between two different devices. . According to an embodiment of the present invention, the short range communication of the second AP 112 may be different from the first AP 111. For example, Bluetooth communication, Zigbee communication, infrared communication (IrDA), and UHF (UlF) may be used. It may be performed in various standards such as Radio Frequency (RF) and Ultra Wide Band Communication (UWB) such as Frequency (Very High Frequency) and VHF (Very High Frequency), and at this time, it is preferable to have a smaller coverage than the first AP 111. Do. Of course, coverage refers to the distance or range of propagation.

Although these APs 110 are illustrated as being separately configured from the communication network 120 in FIG. 1, since the AP 110 may be included in the communication network 120, the AP 110 is not particularly limited thereto. will be.

The communication network 120 may include a public telephone network (PSTN) and an Internet network as a wired communication network, and may include a synchronous (CDMA) network, an asynchronous (WCDMA) network, a GSM network, and a Long Term Evolution (LTE) network as a wireless communication network. It can contain everything. In the embodiment of the present invention, as long as the location information from the terminal 100 can be transmitted to the positioning device 130, any communication network may be used, and the present invention is not particularly limited thereto.

Among them, for example, the WCDMA network may include a NodeB, a Radio Network Controller (RNC), a Mobile Switching Center (MSC), and a Serving GPRS Support Node (SGSN). Furthermore, the WCDMA network may further include a Visitors Location Register (VLR) and a Home Location Register (HLR). Here, the RNC relays voice or data calls between the NodeB and the MSC or between the NodeB and the SGSN. Of course, NodeB and RNC in a WCDMA network may be replaced by a base station transmission system (BTS) and a base station controller (BSC) in the case of a CDMA network. In the EPC (Evolved Packet Core) network, it can be replaced by an evolved base station (e-NodeB) and mobility management entity (MME). The MME is an integrated form of RNC and MSC in a WCDMA network. Do almost the same.

For example, each NodeB is arranged in units of cells and receives a call request signal from the terminal 100 through a traffic channel among the signal channels, and transmits the received call request signal to the RNC. Location registration is performed to determine the location of the terminal 100 existing in the cell area under jurisdiction. In addition, NodeB is a network endpoint device directly connected to the terminal 100 and performs baseband signal processing, wired and wireless conversion, and transmission and reception of wireless signals. The NodeB transmits a call request signal transmitted through the RNC from the MSC after determining the location of the terminal 100 if the terminal 100 existing in its cell area corresponds to the receiving side.

In addition, the NodeB can obtain information such as latitude and longitude where the NodeB is located by using a signal from a GPS satellite, and can transmit the location information of the NodeB to the terminal 100 through a system parameter message of a forward link call channel. The terminal 100 may register the new location information by calculating the moving distance of the terminal 100 using the location information of the NodeB of the cell to which the terminal 100 belongs. Here, the location registration is a processing procedure for notifying the MSC of the location, status, identifier, slot period, and other features of the terminal 100 through the NodeB, when the NodeB attempts to set up a received signal to the terminal 100. This procedure allows you to call 100 effectively. The location registration of the terminal 100 may be performed when the terminal 100 is powered on or off, when the terminal 100 moves between MSCs, and when the parameters of the terminal 100 are changed. Can be implemented.

The RNC controls the NodeB, assigns and releases radio channels to the terminal 100, controls transmission outputs of the terminal 100 and NodeB, determines soft handoff and hard handoff between cells, and transcodes. (Transcoding) and Vocoding, GPS clock distribution, and operation and maintenance of NodeB. In addition, the RNC transmits subscriber information of the location registered terminal 100 to the MSC. The RNC transfers the call request signal transmitted from the terminal 100 through the NodeB to the MSC, and on the contrary, the RNC transfers the call request signal transmitted from the MSC to the terminal 100 through the NodeB.

MSC performs basic and additional service processing, receiving and originating call processing of subscriber, location registration and handoff procedure, interworking with other network. For example, MSCs in IS-95 / A / B / C systems include access switching subsystem (ASS) that performs distributed call processing, interconnection network subsystem (INS) that performs centralized call processing, operations and Subsystems such as Central Control Subsystem (CCS), which is responsible for the centralization of maintenance, and Location Registration Subsystem (LRS), which perform storage and management of information on mobile subscribers. In addition, MSCs for 3rd and 4th generations can include an Asynchronous Transfer Mode (ATM) switch, which increases the transmission rate and efficiency of circuit usage by cell-by-cell packet transfer. When the location registration of the terminal 100 is performed through the NodeB and the RNC, the MSC temporarily stores the subscriber information of the terminal 100 in the VLR and then requests the location registration of the terminal 100 from the HLR.

The VLR receives and stores the location information of the visited subscriber where the location information registration is performed from the MSC. When the terminal 100 registers the location information, the VLR temporarily stores subscriber information and notifies the HLR. The VLR receives a copy of the terminal identification number, the terminal unique number, and service information of the terminal 100 from the HLR. While managing, it performs a function to utilize the position control, call processing, external operation processing of the terminal 100.

The HLR receives location information of the terminal 100 from the VLR and performs functions such as registration recognition, registration deletion, and location verification. In addition, the subscriber information of the terminal 100 waiting for a call is stored in the HLR. Here, the subscriber information refers to a mobile identification number (MIN), an electronic serial number (ESN) and / or subscribed additional service information of the terminal 100.

The SGSN may include a Gateway GPRS Support Node (GGSN). SGSN supports the mobility management of the terminal 100, a call processing procedure for incoming / outgoing calls, a session for processing transmission and reception of packet data, authentication and billing functions, etc., for a general packet radio service (GPRS) service. It also has a routing process for packet data. Here, the GGSN is a serving node of an IP-based packet network that provides a high speed packet data service for GPRS. The GGSN performs session management and packet data routing for the packet data service and connects the communication network 120. GPRS is an asynchronous communication system that supports 384 Kbps data transmission speed, provides multimedia mail, and maximizes transmission line efficiency by packet data transmission.

The positioning device 130 may interwork with the communication network 120 and the WLAN device 140 in the form of a server, and may additionally interwork with the LBSP 150. The positioning device 130 requests positioning to the terminal 100 for handset-based positioning or network-based positioning according to the instruction of the LBSP 150, GPS information, AP information, and the like corresponding to radio environment information from the terminal 100. Part or all of the base station information is received as positioning information. Here, the AP information may be divided into information of the first AP 111 performing Wi-Fi communication and information of the second AP 112 performing short-range communication such as Bluetooth and Wi-Fi, and the AP information and the base station information. Signal strength information and the like. Furthermore, the AP information may include identification number, address, and frequency information for the AP 110, and may further include information such as latitude and longitude.

The WLAN device 140 includes a DB 140a in which WLAN information about the AP 110 is stored. Here, the DB 140a may be divided into a primary DB and a secondary DB, as shown in FIG. 2. The primary DB collects wireless LAN information such as locations of APs 110 installed in all regions using mobile vehicles, without distinguishing between fixed and mobile types, and matches them with grid cells classified by pCell ID. The secondary DB represents the DB arranged by processing the WLAN information of the primary DB and sorting by address to form a table. As described above, the wireless LAN information of the AP 110 built in the primary DB and the secondary DB may be adjusted according to the timing of building the WLAN information. Here, the WLAN information includes information such as an identification number, an address, a received signal strength, frequency information, and latitude and longitude of the AP 110. In addition, the WLAN information may further include Bluetooth information about the second AP 112 as shown in FIG.

When constructing the secondary DB, the WLAN device 140 may construct a separate DB 140a for managing items that can distinguish the second AP 112 which is a fixed device. For example, the second AP 112 may be distinguished by using a specific field of the MAC address. Since the information about the fixed device may be added and deleted, the second AP 112 may be separately managed. 100) can be used for positioning.

In addition, the WLAN device 140 receives the positioning information provided when the terminal 100 requests the positioning from the positioning device 130 to determine whether the corresponding information exists in the DB 140a, and to determine the positioning information existing in the DB 140a. For the service requester, the latitude and longitude coordinate values of the optimal lattice cell selected in a manner of giving different weights according to the base station information, the Wi-Fi AP information or the Bluetooth AP information are provided to the service requester. Here, the weighting scheme may be differently applied according to the accuracy level. The accuracy level may be a date and time when data is collected in the DB 140a, an area covered by the corresponding device, and the number of times of use. For example, high weight is given to information collected relatively recently, high weight is given to information having a small area covered by the device, and high weight is applied to information with a large number of times.

3 is a view illustrating a structure of a driver of the WLAN device of FIG. 1.

Referring to FIG. 3 together with FIG. 1, the WLAN device 140 according to the embodiment of the present invention may include a call processor 300 and a positioning result calculator 310 as a driver in addition to the DB 140a. Here, the call processing unit 300 may include a control unit (not shown) and an interface unit (not shown), and the positioning result calculator 310 may include a memory unit 311, a WLAN information division unit 313, and an algorithm. The execution unit 315 may be included.

The call processing unit 300 may control the overall call being processed in connection with the positioning device 130 through the control unit, and may perform functions such as transmission and reception of a message or information and protocol conversion through the interface unit. In addition, the positioning result calculating unit 310 may receive the positioning information of the terminal 100 provided when the positioning request is received through the call processing unit 300 and may provide the positioning result by utilizing AP information. For example, in order to improve positioning accuracy, when the AP information of the second AP 112 includes Bluetooth information, the coordinate value of the grid cell selected by giving a high weight to the Bluetooth information is selected. As a result of the positioning.

The memory unit 311 may store and store location information, more precisely, AP information provided when the terminal 100 requests a location request from the call processing unit 300, and extracted from the DB 140a based on the AP information. The WLAN information of the AP 110 may be stored. In this case, the WLAN information includes Bluetooth information about the second AP 112. In addition, the memory unit 311 may include the AP information of the second AP 112 having the base station information, the AP information of the first AP 111 having the Wi-Fi information, the Bluetooth information, and the like, which are distinguished by the WLAN information division unit 313. Can be stored separately. Furthermore, the memory unit 311 may store a comparison value to distinguish whether the second AP 112 is a fixed type or a mobile type, and the comparison value is a manufacturer-specific ID and a device-specific identification ID for the second AP 112. And the like.

In addition, the WLAN information division unit 313 receives the WLAN information of the AP 110 extracted from the DB 140a under the control of the call processing unit 300 or receives the WLAN information stored in the memory unit 311. The WLAN information is analyzed to distinguish the base station information, the AP information of the first AP 111 and the second AP 112, respectively. In this case, the WLAN information division unit 413 may analyze the ID of the WLAN information extracted from the DB 140a to distinguish the base station information, the AP information of the first AP 111 and the second AP 112, and further, The comparison value stored in the memory unit 311 may be used to distinguish whether the second AP 112 is mobile or fixed.

For example, if the AP information is extracted from the DB 140a under the control of the call processor 300 without discriminating whether it is mobile or fixed, the WLAN information separator 313 according to an embodiment of the present invention. ) Distinguishes only the Bluetooth information of the fixed second AP 112 by using the comparison value stored in the memory unit 311. For example, if there is a portable laptop computer that performs Bluetooth communication in the vicinity of the requested terminal 100, the terminal 100 performs Bluetooth communication with the laptop computer, and then the address information or the device ID of the laptop computer is determined. In the embodiment of the present invention, it is preferable not to utilize the Bluetooth information about the mobile device. Such separation of the fixed and mobile types of the second AP 112 may be made through a filtering device such as a comparator. The divided result, that is, the WLAN information, may be stored in the memory 311 or provided to the algorithm performing unit 315 under the control of the call processing unit 300. In this regard, like the second AP 112, the first AP 111 may also be classified into a mobile type and a fixed type. Therefore, the WLAN information division unit 313 may use a device ID or a manufacturer-specific ID for the first AP 111 stored in the memory unit 311 to distinguish the mobile and stationary first APs 111. There will be.

The algorithm performing unit 315 is stored in the memory unit 311 and provided under the control of the call processing unit 300, or wirelessly provided under the control of the call processing unit 300 by being divided in the WLAN information separating unit 313. A weighting algorithm is performed using the LAN information, and a positioning result for the terminal 100 for which the positioning is requested is calculated. For example, if the WLAN information provided by the WLAN information separating unit 313 has only the Bluetooth information of the second AP 112, the positioning result is calculated using the Bluetooth information. In addition, if the WLAN information includes the Wi-Fi information of the first AP 111 and the Bluetooth information of the second AP 112, for example, the candidate information is primarily applied to the candidate group using the Bluetooth information of the second AP 112, which is given a high weight. The corresponding grid cell may be selected, and the final grid cell may be selected using Wi-Fi information of the first AP 111 among the candidate groups, and location information of the selected final grid cell may be provided as a positioning result. Of course, the algorithm performing unit 315 may finally select one lattice cell by weighting and provide position information to the selected lattice cell as a positioning result. Alternatively, a plurality of lattices selected by weighting may be selected. The location information of the selected optimal cell may be provided as a positioning result by calculating a weighted average of the cells.

4 is a diagram illustrating a positioning process of the terminal positioning system of FIG. 1.

Referring to FIG. 4 together with FIG. 1, the terminal positioning system includes a first AP 111 and a first AP having a certain coverage for communicating with the terminal 100 in the DB 140a of the WLAN device 140. In operation S401, WLAN information about the second AP 112 having a coverage smaller than that of 111 is stored. The AP information about the first AP 111 and the second AP 112 may be collected by a mobile vehicle and matched and stored for each pCell. Here, if the AP information of the first AP 111 is the address information of the first AP 111 performing Wi-Fi communication, the AP information of the second AP 112 may have a smaller coverage than that of the Wi-Fi communication, for example, Bluetooth. It may include address information for the second AP 112 that performs the communication. In this case, the second AP 112 performs a Bluetooth communication, for example, but not a mobile device such as a laptop computer, but a fixed device such as a television or a game machine, which can transmit and receive signals to and from a single device such as the terminal 100. Represents an electronic device.

 The positioning device 130 performs positioning of the terminal 100 according to a positioning request for the terminal 100 (S403). In this process, the positioning device 130 distinguishes between whether the requested terminal 100 is a GPS terminal or a non-GPS terminal and requests positioning information using different protocol messages according to the type of the terminal 100. In this regard, since it has been sufficiently described with reference to FIG. 1, further description thereof will be omitted.

The terminal 100 receives the AP information for the first AP 111 by operating the internal short-range communication module according to the instruction of the positioning device 130 to perform Wi-Fi communication with the first AP 111 (S405). After receiving the AP information for the second AP 112 by performing Bluetooth communication with the second AP 112 (S407), the AP information for the first AP 111 and the second AP 112 is received. It provides the positioning information to the positioning device 130 (S409). In this case, when only the AP information about the second AP 112 is collected, the terminal 100 may provide only the AP information of the second AP 112 to the positioning device 130, but which manages the communication of the terminal 100. When information on a base station or node is collected, the base station or node information may also be provided, and in the case of a GPS terminal, GPS information may also be provided as positioning information.

The positioning device 130 receives the AP information provided from the terminal 100, more precisely, the positioning information including node information or GPS information, and then transmits the positioning information to the WLAN device 140 (S411).

The WLAN device 140 utilizes only the AP information for the second AP 112 provided by the positioning device 130 or uses the AP information for the second AP 112 or the AP information or node for the first AP 111. The optimal cell may be selected in a manner of giving a weight higher than the information (S413). Here, selecting the optimal cell may mean selecting WLAN information matching the corresponding cell. For example, when only the AP information for the second AP 112 performing the Bluetooth communication as the location information is received, the optimal cell may be selected by giving the maximum weight to the Bluetooth information. If the AP information on the first AP 111 and the AP information on the second AP 112 are received at the same time, the cell of the candidate group is selected by using the AP information on the second AP 112 with a high weight. In addition, the optimal cell may be selected using the AP information on the first AP 111 that is given a low weight. Of course, node information could be used in a similar way.

Thereafter, the WLAN device 140 provides the location information about the selected optimal cell, that is, the latitude-longitude coordinate value, to the positioning device 130 as a positioning result of the terminal 100 (S415), and the positioning device 130 receives the received positioning result. To the service requester.

FIG. 5 is a diagram illustrating a method of driving the WLAN device of FIG. 1.

Referring to FIG. 5 in conjunction with FIGS. 1 and 3, the WLAN device 140 may include, for example, a first AP 111 performing Wi-Fi communication and a second AP 112 having a smaller communication coverage than the first AP 111. AP information is stored in the DB 140a as WLAN information (S501). In this case, the WLAN information may be stored in a pCell DB having a grid cell type, and the WLAN information is matched for each unit cell.

In addition, the WLAN device 140 receives the AP information provided by the positioning device 130 as the location information when requesting the location of the terminal 100, and searches and extracts the WLAN information based on the AP information (S503). . As a result of the extraction, for example, when there is WLAN information of the second AP 112 performing Bluetooth communication (S505), the WLAN device 140 assigns a high weight to the WLAN information of the corresponding second AP 112. In step S507, an optimal cell is selected. For example, when only the WLAN information of the second AP 112 is retrieved, the optimal cell may be selected using only the WLAN information of the second AP 112, but the WLAN of the first AP 111 may be selected. When information or node information about a node that manages communication of the terminal 100 is searched together, the optimal cell may be selected in such a manner as to weight the WLAN information of the second AP 112 with a high weight. Accordingly, if the grid cell of the candidate group is selected through the WLAN information of the second AP 112, the optimal cell may be selected by further utilizing the remaining WLAN information or node information of the first AP 111. Furthermore, the weighting degree may be adjusted according to the time for collecting the WLAN information of the second AP 112, the WLAN information of the second AP 112, more precisely the number of times the Bluetooth information is used, and the like. In the embodiment of the present invention will not be particularly limited with respect to the weighting method.

If the location information is received and the DB 140a of the WLAN device 140 is searched based on the location information, the wireless LAN information of the second AP 112 is not retrieved and the wireless information of the first AP 111 is not found. If only LAN information or node information is retrieved, an optimal cell may be selected using these information (S509). For example, an optimal cell may be selected by giving a weight to the WLAN information of the first AP 111 higher than the node information, and the WLAN information or the node information of the first AP 111 may provide three or more pieces of information. If so, the optimal cell may be selected using triangulation or the like.

Thereafter, the WLAN device 140 provides the positioning device 130 with the location information of the optimal cell selected according to the weighting algorithm or the triangulation technique, that is, the latitude-longitude coordinate value as the positioning result of the terminal 100 (S511). The device 130 will provide the location result to the service requester.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. That is, within the scope of the present invention, all of the components may be selectively combined to operate in one or more, and those skilled in the art to which the present invention pertains without departing from the essential characteristics of the present invention Various modifications and variations will be possible in the. 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.

An embodiment of the present invention is applicable to a terminal positioning system and method, a wireless LAN device, and a method of driving the device. According to an embodiment of the present invention, a television that performs communication, such as Bluetooth, in addition to Wi-Fi communication for positioning, and Positioning accuracy can be increased by utilizing a fixed near field communication device such as a game machine, and since a fixed near field communication device is installed, it is not necessary to install a separate access point to increase positioning accuracy, thereby saving costs.

100: terminal 110: access point (AP)
120: communication network 130: positioning device
140: WLAN device 150: LBSP
300: call processing unit 310: positioning result calculation unit
311: memory unit 313: WLAN information division unit
315: algorithm execution unit

Claims (15)

In the request for positioning of the terminal, a first access point (AP) having a certain coverage and a second AP having a coverage smaller than the first AP perform short-range communication with the terminal to provide the first terminal provided by the terminal. A communication network configured to receive and transmit at least one of AP information of the AP and the second AP as positioning information;
A positioning device for requesting positioning of the terminal, receiving and transmitting the AP information from the communication network, and receiving the positioning result of the terminal and transmitting it to a service requester; And
Pre-store WLAN information about the first AP and the second AP, search and extract the WLAN information based on the AP information provided as the positioning information, and extract the WLAN information to the first AP. And a wireless LAN apparatus for calculating and providing a positioning result of the terminal in a manner of giving a weight to wireless LAN information of the second AP higher than the first AP when the wireless LAN information of the second AP.
Terminal positioning system comprising a. In the request for positioning of the terminal, a first access point (AP) having a certain coverage and a second AP having a coverage smaller than the first AP perform short-range communication with the terminal to provide the first terminal provided by the terminal. A call processing unit for receiving at least one information of AP information of an AP and the second AP as positioning information, and receiving and transmitting WLAN information based on the AP information provided as the positioning information;
When the WLAN information is provided and the WLAN information is WLAN information of the first AP and the second AP, the WLAN information is divided into WLAN information of the first AP and the second AP. WLAN information classification unit; And
Computing the positioning result of the terminal by receiving the WLAN information of the first AP and the second AP, and assigning a higher weight to the WLAN information of the second AP than the WLAN information of the first AP. Algorithm Execution Unit
Wireless LAN device comprising a. The method of claim 2,
The first AP performs Wi-Fi communication with the terminal,
The second AP communicates with the terminal by any one of Bluetooth communication, Zigbee communication, infrared communication (IrDA), RF (Radio Frequency), and ultra-wideband communication (UWB). WLAN device. The method of claim 2,
The WLAN device further includes a memory unit,
The memory unit is a wireless LAN device, characterized in that for storing the separated WLAN information of the first AP and the second AP. The method of claim 4, wherein
The memory unit further comprises a device ID or manufacturer ID for identifying whether the second AP is fixed or mobile. The method of claim 5,
The WLAN information division unit may distinguish whether the second AP is fixed or mobile by using the device ID or the manufacturer ID, and provide WLAN information of the second AP corresponding to the fixed type to the algorithm execution unit. Wireless LAN device. The method of claim 2,
The WLAN device further includes a pCell database,
The pCell database matches and stores the WLAN information for each grid cell, and provides the WLAN information upon request of the call processor. The method of claim 7, wherein
Positioning result of the terminal is a wireless LAN device, characterized in that the position information of the grid cell selected in such a way that gives a high weight. The method of claim 2,
When the location information and the wireless LAN information includes node information for a node that manages communication of the terminal, the weight given to the node information is smaller than the weight given to the wireless LAN information of the first AP. Wireless LAN device. The method of claim 2,
The second AP is a stationary electronic device fixedly installed in a specific area,
The WLAN information of the second AP includes the Bluetooth information of the electronic device. Storing WLAN information about a first access point (AP) having a certain coverage for performing short-range communication with a terminal and a second AP having a smaller coverage than the first AP;
Receiving at least one AP information of the AP information of the first AP and the second AP as location information provided when the location request of the terminal is performed;
Search and extract the WLAN information based on the positioning information, and when the extracted WLAN information is WLAN information of the first and second APs, the WLAN of the second AP rather than the first AP. Calculating a positioning result of the terminal in a manner of weighting information; And
Providing the service requester with the positioning result of the terminal;
Terminal positioning method comprising a. The method of claim 11,
The location information and the wireless LAN information includes node information for a node (node) that manages communication of the terminal,
And the weight given to the node information is smaller than the weight given to the WLAN information of the first AP. Storing WLAN information about a first access point (AP) having a certain coverage for performing short-range communication with a terminal and a second AP having a smaller coverage than the first AP;
Receiving at least one AP information among the AP information of the first AP and the second AP as location information provided when the location request is made by the terminal, and searching and extracting the WLAN information based on the location information;
Determining whether the WLAN information of the second AP exists in the extracted WLAN information; And
Calculating the positioning result of the terminal using the WLAN information of the second AP when the WLAN information of the second AP exists;
Method of driving a wireless LAN device comprising a. The method of claim 13,
Determining whether the WLAN information of the second AP exists,
And determining whether there is WLAN information of the first AP. The method of claim 14,
As a result of determining whether the WLAN information of the first AP exists, calculating the location result of the terminal when the WLAN information of the first AP exists,
The positioning result is calculated by giving a weight to the WLAN information of the second AP higher than the first AP.

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