KR20090056232A - System and method for providing location base service in a broadband wireless access communication system - Google Patents

Abstract

An LBS offering system in a BRA(Broadband Radio Access) communication system and a method thereof are provided to offer the LBS to a mobile station without a location confirming function such as the GPS(Global Positioning System). A receiving stage receives a scan response message from a base station(120). The scan response message triggers the location measurement corresponding to an LBS(Location Based Service) offering request. A location agent performs the location measurement correspondingly to the scan response message. A location measurement reporting unit transmits a scan report message to the base station. The scan report message comprises a location measurement value corresponding to the location measurement. The location measurement value is the signal delay value of a downlink reference signal of the base station.

Description

System and Method for Providing Location Based Service in a Broadband Wireless Access Communication System}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a communication system, and in particular, to a location based service (LBS: LBS) in a broadband wireless access (BWA) communication system. System and method for providing the same.

In the next generation communication system, active researches are being conducted to provide users with services of various quality of service (QoS: QoS) having high transmission speeds. In particular, in the current generation communication system, a wireless local area network (WLAN) system and a wireless metropolitan area network (WMAN) will be referred to as "WMAN". Researches are being actively conducted to support high-speed services in the form of guaranteeing mobility and QoS to BWA communication systems such as systems, and the representative communication systems are IEEE (Institute of Electrical and Electronics Engineers) 802.16a / d communication system and IEEE 802.16e communication system.

The IEEE 802.16a / d communication system and the IEEE 802.16e communication system, which are the BWA communication system, orthogonal frequency division (OFDM) to support a broadband transmission network on a physical channel of the WMAN system. A multiplexing (hereinafter referred to as "OFDM") / orthogonal frequency division multiple access (OFDMA) scheme is a communication system employing the scheme. The IEEE 802.16a / d communication system currently considers only a single cell structure and a state in which a subscriber station (SS) (hereinafter referred to as SS) is fixed, i.e., does not consider SS mobility at all. System. In contrast, the IEEE 802.16e communication system is a system that considers the mobility of the SS in the IEEE 802.16a communication system, and the SS having the mobility is referred to as a mobile station (MS). .

On the other hand, in order to provide LBS, such as the location request of the MS and the location of the MS requesting the emergency service of the MS from a third party, a discussion about providing an LBS suitable for the next-generation communication system is in progress, There is no specific scheme for this, and therefore, there is a need for a specific scheme for providing the LBS in a next-generation communication system. In addition, if there is no function of a Global Positioning System (GPS) in the MS, a specific method for providing the LBS is needed.

Accordingly, an object of the present invention is to provide a system and method for providing location based service in a broadband wireless access communication system.

Another object of the present invention is to provide a system and method for providing a location-based service for a mobile station having no positioning function such as a satellite positioning system in a broadband wireless access communication system.

In accordance with an aspect of the present invention, a method for providing a location-based service of a broadband wireless access communication system includes: a server requesting location information of a mobile station to a base station through a control station; Transmitting a corresponding Scan Response (SCN-RSP) message to the mobile station, and when the mobile station receives the scan response message, measures the position of the mobile station with respect to the base station to determine location information of the mobile station. And generating a scan report (SCN-REP) message including the location information of the mobile station to the base station, and the base station receives the scan report message and is included in the scan report message. If the location information of the mobile station is transmitted to the server through the control station, the server is located of the mobile station. The information received, and a step of transmitting the location request to the mobile station the location information of the mobile station.

According to another aspect of the present invention, there is provided a method of supporting a location-based service of a broadband wireless access communication system, wherein a server requests a location of a location report of a mobile station from a control station. Transmitting a Location Report Request (REQ) message; and, after the control station performs paging through the base station to transition to an active mode when the mobile station is in an idle mode, the location report request message Transmitting a scan response (SCN-RSP: Scan-Response) message to the mobile station, and the mobile station receives the location report request message, and the mobile station receives the scan response message. When receiving the mobile station to measure the position of the mobile station with respect to the base station to generate the location information of the mobile station, Transmitting a scan report (SCN-REP) message including the location information of the mobile station to the base station, and the base station receives the scan report message and the location information of the mobile station included in the scan report message; Transmitting to the server via the control station.

Another method of the present invention for achieving the above objects is, in a base station of a broadband wireless access communication system, receiving a location report request message from a control station corresponding to a location request of a mobile station from a location server; Performing location measurement on the mobile station using a downlink reference signal corresponding to a location report request message, and transmitting a location report response message to the control station in response to the location report request message; The location report response message includes the base station identifier and the delay value of the reference signal.

According to an aspect of the present invention, there is provided a system of a broadband wireless access communication system, comprising: a receiving end receiving a scan response message from a base station for triggering a location measurement corresponding to a location-based service provision request; The mobile station includes a location agent for performing the location measurement in response to the response message, and a location measurement reporting means for transmitting a scan report message including the location measurement value corresponding to the location measurement to the base station. The value is a signal delay value of the downlink reference signal of the base station.

The present invention enables a location server to provide location based services to a mobile station by obtaining location information of the mobile station in a communication system. In addition, the present invention can stably provide location-based services to the mobile station by acquiring the location information of the mobile station even when the mobile station operates in the active / sleep mode and the idle mode or handovers in the communication system.

In addition, the present invention provides a specific method for providing a location-based service suitable for the next-generation communication system, even if there is no function of the Global Positioning System (GPS) in the communication system location-based services for the mobile station Can be provided.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that in the following description, only parts necessary for understanding the operation according to the present invention will be described, and descriptions of other parts will be omitted so as not to distract from the gist of the present invention.

The present invention provides a service in a communication system, for example, the Institute of Electrical and Electronics Engineers (IEEE) 802.16 communication system and the IEEE 802.3 communication system, which is a broadband wireless access (BWA) communication system. We propose a system and method for providing the same. Here, in the embodiment of the present invention to be described later, for convenience of description, the communication system will be described using an 802.16 communication system and an IEEE 802.3 communication system as an example, but the service providing system and method proposed by the present invention may be applied to other communication systems. Can be.

In addition, the present invention proposes a system and method for providing a location based service (LBS: hereinafter referred to as LBS) in a communication system. In an embodiment of the present invention to be described later, a location server (LS: Location Servser, hereinafter referred to as "LS") providing the LBS is a mobile station (MS: Mobile Station, hereinafter referred to as "MS") having fixed and mobility. A system and method for providing LBS to the MS corresponding to the position of

In an embodiment of the present invention to be described later, the LS requests the MS to transmit its own location information to the MS to provide an LBS, for example, an emergency service corresponding to the location of the MS, and the MS which has requested the location information. Is a location for a radio access station (RAS: Radio Station), which functions as a base station (BS: hereinafter referred to as 'BS') by administering itself and itself. After measuring and generating its own location information, the location information is transmitted to the LS, or after the RAS measures the location of itself and the MS to generate location information, the location information is transmitted to the LS. Then, the LS calculates the distance between the MS and the RAS using the location information and provides the LBS to the MS. Here, the MS calculates the distance between itself and the RAS to calculate the distance between the RAS and transmits the calculated distance to the LS by including the calculated distance in the location information, and the LS uses the distance included in the location information to the LBS. May be provided to the MS.

At this time, the present invention, an access control router (ACR) to perform the function of controlling the RAS, that is, a control station function to request the LS to transmit the location information of the MS (ACR) The ACR sends the request message to the RAS, and the RAS requests the MS to transmit the location information. Then, the MS measures the position of itself and the RAS by using a signal delay when transmitting / receiving a signal with the RAS, for example, a maximum distance through a round trip delay (RTD). After calculating a minimum distance and an average distance to measure the location with the RAS, location information is generated, and a report message including the location information is transmitted to the RAS. Here, the MS measures the position using a signal delay of a downlink reference signal, for example, a preamble signal, with the RAS. The RAS transmits the report message to the ACR, the ACR transmits the report message to the LS, and the LS obtaining the location information of the MS through the report message sends an LBS to the LBS requesting client according to the location information. to provide. Here, as described above, the RAS measures the position between the MS and the RAS by using a signal delay when transmitting and receiving a signal with the MS, for example, calculating the maximum distance, the minimum distance, and the average distance through the RTD, and then measuring the position. May be generated, and the location information may be included in the report message and transmitted to the ACR to provide the LBS. Next, the structure of the communication system according to an exemplary embodiment of the present invention will be described in more detail with reference to FIG. 1.

1 is a view schematically showing the structure of a communication system according to an embodiment of the present invention.

Referring to FIG. 1, the communication system includes an MS 110 that is connected to a communication system and receives a communication service, and performs a BS function as described above, and a RAS 120 that transmits and receives data with the MS 110. And an ACR 130 connected to the RAS 120 and controlling the RAS 120 through Ethernet, and providing a communication service, that is, an LBS, to the MS 110 through the ACR 130. LS 140 is included.

The MS 110 requests its location information from the RAS 120 in a state in which the MS 110 is connected to the RAS 120 through a connection identifier (CID) assigned to the MS 110. In response to the signal delay with the RAS 120, for example, the minimum distance, the maximum distance, and the average distance with the RAS 120 are calculated in the cell managed by the RAS 120 through the RTD. After measuring his location, he reports his location information to RAS 120.

The RAS 120 and the MS 110 to access the communication system and the radio access standard, in the embodiment of the present invention supports the IEEE 802.16 standard since the communication system is assumed to be an IEEE 802.16 communication system, the function of the base station, An IEEE 802.16 CID is allocated through an initial procedure for transmitting / receiving data with the MS 110, and the function of managing the allocated CID and performing data transmission / reception are performed. In other words, the RAS 120 processes RF signals with the MS 110 and physically (PHYsical) a PHY Layer and a Media Access Control (MAC). MAC ') functions in the MAC layer, scheduling and ranging with the MS 110, and the like. In addition, the RAS 120 transmits cell and communication system information capable of receiving a communication service from the MS 110 to the MS 110, and when the MS 110 moves between cells or sectors within the cell, the MS ( Inter-sectoral handoff is supported. When the RAS 120 receives the location information of the MS 110 from the ACR 130, the RAS 120 requests the location information from the MS 110, and reports the location information according to the request to the ACR 130. do.

The ACR 130 performs a function of controlling the RAS 120, and the single ACR 130 may control a plurality of RASs. In addition, ACR (130) is not only LS (140) for providing LBS, but also other servers, such as VoD / AoD server for providing video and audio services, Web server for providing Internet web services. By providing a service provided by the VoIP / VT server for providing a voice and video service to the RAS (120) to provide a communication service to the MS 110 connected to the communication system, for this purpose, the MS connected to the communication system It performs functions such as authentication for the 110, MAC protocol processing, Internet protocol (IP) address allocation, and routing. In addition, the ACR 130 is connected to the RAS 120 and the LS 140, and in this embodiment of the present invention, conforms to the IEEE 802.3 standard. In addition, the ACR 120 checks the RAS 120 serving as the serving RAS for the MS 110, and upon receiving the position information of the MS 110 from the LS 140, sends the MS to the RAS 120. When the location information of the 110 is requested and the location information is received in response to the request, the LS 140 is reported.

The LS 140 manages a mapping table including access information between the MS 110 and the ACR 130 and control information related to service provision, and provides the LBS for the MS 110. If location information of the MS 110 is required, for example, although not shown, a location client (LC) may be called, for example, different, and the functions of a global positioning system (GPS) are different. When the location information of the MS 110 is requested from an MS different from the MS 110 that cannot acquire location information for the MS 110 because it does not exist, the ACR 130 is checked to the ACR 130. When the location information of the MS 110 is requested and the location information is reported and received according to the request, it is provided to the LC. Next, the LBS related protocol in the communication system according to the embodiment of the present invention will be described with reference to FIG. 2.

2 is a diagram schematically showing an LBS related protocol stack in a communication system according to an embodiment of the present invention.

Referring to FIG. 2, the LBS related protocol stack in the MS 210 of the communication system includes a location agent related protocol (LA), a WiMax (WiMaX: Worldwide Interoperability for Microwave Access) link related protocol (WiMax R6), User Datagram Protocol (UDP: hereinafter referred to as 'UDP'), IP, WiMAX Medium Access Control (MAC) protocol (WiMaX MAC), and WiMax Physical (hereinafter referred to as 'PHY') protocol (WiMaX PHY).

In the RAS 220 of the communication system, the LBS related protocol stack includes: a location agent related protocol (LA), a WiMAX link related protocol (WiMax R6), UDP, IP, a WiMAX medium access control protocol (WiMaX MAC), and a WiMAX. PHY protocol (WiMaX PHY), IEEE 802.3 MAC protocol (802.3 MAC), and IEEE 802.3 PHY protocol (802.3 PHY). In addition, the LBS-related protocol stack in the ACR 230 may be referred to as a location controller (LC) protocol, an IEEE 802.3 link related protocol (R6, R3), a transmission control protocol (TCP). / UDP, IP, IEEE 802.3 MAC protocol (802.3 MAC), and IEEE 802.3 PHY protocol (802.3 PHY), the LBS-related protocol stack in LS 240, the position controller related protocol (LC), IEEE 802.3 link related protocol (R3), TCP / UDP, IP, IEEE 802.3 MAC protocol (802.3 MAC), and IEEE 802.3 PHY protocol (802.3 PHY). Next, a procedure of providing an LBS in a communication system according to an embodiment of the present invention will be described with reference to FIG. 3.

3 is a diagram schematically illustrating a procedure for providing an LBS in a communication system according to an embodiment of the present invention. 3 is a diagram illustrating a procedure for providing LBS by transmitting and receiving location information of the MS when the MS receiving LBS operates in an active mode after performing an initial access procedure. Since the procedure is not directly related to the present invention, a detailed description thereof will be omitted here.

Referring to FIG. 3, as described above in the communication system, the MS 301, the RAS 303, and the ACR 305 perform an initial access procedure to operate in an active mode, that is, set to an active mode (step S311). ). Then, between the ACR 305 and the LS 307 in order to provide the LBS for the MS 301, the serving ACR, i.e., the ACR 305, to the LS 307 corresponding to the MS 301 in an active mode. ) Is requested by the LC 309 to confirm the location of the MS 301, so that the LS 307 starts the location procedure with the registered ACR 305, i.e., the MS 301. A periodic location session for acquiring location information is established (step S313). In this case, the LS 307 is a network access information (NAI: hereinafter referred to as "NAI") of the MS 301 and the link CID for each MAC of the MS 301 (hereinafter referred to as 'LCID') The identification information of the ACR 305 is managed.

Next, if the location information of the MS 301 is needed to provide the LBS for the MS 301, the LC 309 transmits a location data request message to the LS 307. A request is made to transmit the location information of the MS 301 (step S315). Here, the location data request message includes identification information of the location information identifying MS 301, that is, the MS 301 to which location information is to be transmitted.

After receiving the location data request message, the LS 307 checks the ACR 305 serving as the ACR for the MS 301 to transmit the location information through the mapping table as described above (step S317). A location report request (Location REP-REQ) message is requested to the ACR 305 to report the location information of the MS 301 (S319). step). In this case, the Location REP-RSP message includes the MAC identifier (hereinafter referred to as 'MAC ID (Identifier)') and the LCID of the MS 301. Next, the ACR 305 having received the Location REP-REQ message checks the serving RAS of the MS 301 to transmit the location information, that is, the RAS 303 (step S321), and from the LS 307. The received Location REP-REQ message is transmitted to the checked RAS 303 (step S323). In this case, the ACR 305 manages the MAC ID of the MS 301 and the identification information of the serving RAS, and the MAC ID of the MS 301 and the MS (301) in the Location REP-REQ message transmitted to the RAS 303. Identification information of the RAS 303 which is the serving RAS of 301 is included.

The RAS 303 that receives the Location REP-REQ message from the ACR 305 manages the CID assigned to the MS 301 as described above, and lists information of neighboring RASs to be scanned, including itself as a serving RAS. And a scan response (SCN-RSP: Scan-Response, hereinafter 'SCN-RSP') message requesting the MS 301 to transmit its location information to the MS 301 to send the MS. Triggering (301) the position measurement of (301) (S325).

Then, the MS 301 scans the RASs according to the SCN-RSP message, and measures its position with respect to the RAS 303 when the RASs are scanned (step S327). In this case, the position measurement of the MS 301 is performed through a signal delay when transmitting and receiving a signal to and from the RAS 303, that is, a distance from the RAS 303 using the RTD, that is, the maximum distance and the minimum distance and the maximum distance. The average distance is calculated through the minimum distance, and the position of the MS 301 itself is measured from the RAS 303 through the calculated distance. Then, the MS 301 generates location information corresponding to its location measurement, and includes a scan report (SCN-REP: Scan-Report, hereinafter 'SCN-REP') including the generated location information and scanning information. The message is transmitted to the RAS 303 (step S329).

Upon receiving the SCN-REP message, the RAS 303 receives a location report response including a MAC ID of the MS 301 and location information of the MS 301 (Location REP-RSP). -RSP ') message is transmitted to the ACR 305 (step S331). Here, although the MS 301 calculates the maximum distance, the minimum distance, and the average distance through the RTD, the MS 301 measures only the position of the MS 301 itself from the RAS 303. As described above, the RAS 303 Calculates the maximum distance, the minimum distance, and the average distance using the signal delay, that is, the RTD, and measures the position with the MS 301 using the calculated distance to generate the position information of the MS 301, and then Information may be included in the Location REP-RSP message and transmitted. Next, the ACR 305 checks the received Location REP-RSP message to determine the location information of the MS 301 included in the Location REP-RSP message and the RAS that transmitted the Location REP-RSP message, that is, the Location The Location REP-RSP message including the identification information of the RAS 303 serving RAS of the MS 301 corresponding to the location information included in the REP-RSP message is transmitted to the LS 307 (step S333).

Then, the LS 307 transmits a location data response message including the location information of the MS 301 to the LC 309 (step S335), and acquires the location information of the MS 301. The periodic location session between the ACR 307 and the LS 307 established for this purpose ends (step S337).

As such, the communication system according to the embodiment of the present invention establishes a periodic location session between the ACR 305 and the LS 307 in order to acquire the location information of the MS 301 in the active mode, and then locates the MS 301. Request to transmit the information, and the MS 301 measures its position by calculating the distance with the RAS 303 when scanning the RAS 303 corresponding to the SCN-RSP message including the request. After generating the information, the LS 307 acquires the location information of the MS 301 by sending the message including the location information to the RAS 303, and converts the location information of the MS 301 into LC. 309 to provide the LBS for the MS 301. In addition, in FIG. 3, the case where the MS 301 operates in the active mode has been described. However, the operation as described above after transitioning to the active mode even when the MS 301 operates in the sleep mode. LS 307 obtains location information of MS 301 to provide LBS for MS 301. Next, a procedure of providing an LBS in a communication system according to another embodiment of the present invention will be described with reference to FIG. 4.

4 is a diagram schematically illustrating a procedure for providing an LBS in a communication system according to another embodiment of the present invention. Here, FIG. 4 is a diagram illustrating a procedure for transmitting and receiving the location information of the MS and providing the LBS when the MS receiving the LBS operates in the idle mode after performing the initial access procedure. Since the procedure is not directly related to the present invention, a detailed description thereof will be omitted here.

Referring to FIG. 4, as described above in the communication system, if the MS 401, the RAS 403, and the ACR 405 perform an initial access procedure and there is no data to transmit / receive with the MS 301. The MS 401 operates in an idle mode (step S411). Next, if location information of the MS 401 is needed to provide an LBS for the MS 401 operating in the idle mode, the LC 407 requests a location data request to the LS 407. Request to transmit the location information of the MS 401 by transmitting a message (step S413). Here, the location data request message includes the MS 401 for identifying the location information, that is, identification information of the MS 401 to which the location information is to be transmitted.

After receiving the location data request message, the LS 407 checks the ACR 405 serving as the serving ACR for the MS 401 to transmit the location information through the mapping table as described above (step S417). The Location REP-REQ message requesting the ACR 405 to report the location information of the MS 401 is transmitted (step S417). Here, the Location REP-RSP message includes the MAC ID and LCID of the MS 401, that is, identification information of the ACR 405 serving as the serving ACR.

Next, the ACR 405 that receives the Location REP-REQ message awakes the MS 401 operating in the idle mode because the MS 401 that transmitted the location information operates in the idle mode. In operation S419, a Paging Request message is transmitted to the RAS 403 to operate in the mode. At this time, the ACR 405 manages group identification information of MSs requesting paging and identification information of a serving ACR when the MS 401 transitions from an idle mode to an active mode. For convenience of explanation, the serving ACR when the MS 401 operates in the idle mode and the active mode will be assumed to be the same ACR 405.

Receiving a paging request message from the ACR (405) RAS 403 is a paging advertisement (PAG-) indicating that there is data to be transmitted and received by the MS 401 so that the MS 401 transitions from the idle mode to the active mode. A ADV: Paging Advertisement (hereinafter referred to as PAG-ADV) message is transmitted to the MS 401 (step S421). Then, the MS 401 transitions from the idle mode to the active mode, that is, the MS 401, the RAS 403, and the ACR 405 are set to the active mode (step S423). Then, the ACR 405 and the LS 407 register the position of the ACR 405 with the LS 407 corresponding to the MS 401 in the active mode to provide the LBS to the MS 401. When the position request of the MS 401 is requested from the LC 409, the LS 407 starts the positioning procedure with the registered ACR 405, that is, obtains the position information of the MS 401. Periodic Location Session (Location Session) for is established (step S425). In this case, the LS 407 manages NAI of the MS 401 and LCID for each MAC of the MS 401, that is, identification information of the ACR 405.

Next, the ACR 405 checks the serving RAS of the MS 401 to transmit the location information, that is, the RAS 403, and checks the Location REP-REQ message received from the LS 407. 403) (step S427). At this time, the ACR 405 manages the MAC ID of the MS 401 and the identification information of the serving RAS, and the MAC ID of the MS 401 and the MS (401) in the Location REP-REQ message transmitted to the RAS 403. Identification information of the RAS 403 which is the serving RAS of the 401 is included. The RAS 403 receiving the Location REP-REQ message from the ACR 405 manages the CID assigned to the MS 401 as described above, and lists information of neighboring RASs to be scanned, including itself as a serving RAS. Is included and the MS 401 transmits an SCN-RSP message requesting the MS 401 to transmit its location information to the MS 401 to trigger the MS 401 location measurement (step S429).

Then, the MS 401 scans the RASs according to the SCN-RSP message, and measures its position with respect to the RAS 403 when the RASs are scanned (step S431). In this case, the position measurement of the MS 401 is performed through a signal delay when transmitting and receiving a signal to and from the RAS 403, that is, the distance with the RAS 403, that is, the maximum distance and the minimum distance and the maximum distance, using an RTD. The average distance is calculated through the minimum distance, and the position of the MS 401 itself is measured from the RAS 403 through the calculated distance. Then, the MS 401 generates location information corresponding to its location measurement, and transmits a SCN-REP message including the generated location information and scanning information to the RAS 403 (step S433). .

Upon receiving the SCN-REP message, the RAS 403 transmits a Location REP-RSP message including the MAC ID of the MS 401 and the location information of the MS 401 to the ACR 405 (step S435). ). Here, the MS 401 calculates the maximum distance, the minimum distance, and the average distance by using the RTD, and has only been described as measuring the position of the MS 401 itself from the RAS 403 through the calculated distance. As described above, the RAS 403 calculates a maximum distance, a minimum distance, and an average distance using a signal delay, that is, an RTD, and measures the position with the MS 401 based on the calculated distance. After the location information is generated, the location information may be included in the Location REP-RSP message and transmitted. Next, the ACR 405 checks the received Location REP-RSP message to determine the location information of the MS 401 included in the Location REP-RSP message and the RAS that transmitted the Location REP-RSP message, that is, the Location The Location REP-RSP message including the identification information of the RAS 403 serving RAS of the MS 401 corresponding to the location information included in the REP-RSP message is transmitted to the LS 407 (step S437).

Then, the LS 407 transmits a location data response message including the location information of the MS 401 to the LS 407 (step S439), and acquires the location information of the MS 401. The periodic location session between the ACR 405 and the LS 407 established for this purpose ends (step S441).

As such, the communication system according to another embodiment of the present invention transmits a PAG-ADV message to the MS 401 to acquire the location information of the MS 401 in the idle mode, thereby allowing the MS 401 to be active in the idle mode. After transitioning to, establish a periodic location session between ACR 405 and LS 407 as described above, request to send location information to the MS 401, and the MS 401 contains the request. When the scanning of the RAS 403 corresponding to the SCN-RSP message, the location is measured by calculating the distance with the RAS 403, and then generates its own location information. LS 407 acquires the location information of MS 401 by transmitting to 403, and transmits the location information of MS 401 to LC 409 to provide LBS for MS 401. . Next, a procedure of providing an LBS in a communication system according to another embodiment of the present invention will be described with reference to FIG. 5.

5 is a diagram schematically illustrating a procedure for providing an LBS in a communication system according to another embodiment of the present invention. Here, FIG. 5 is a diagram illustrating a procedure for transmitting and receiving the location information of the MS and providing the LBS when the MS receiving the LBS performs handover between ACRs after performing the initial access procedure. Since it is not directly related to the present invention it will be omitted herein.

Referring to FIG. 5, as described above in the communication system, the MS 401, the RAS 403, and the serving ACR 507 operate in an active mode, that is, set to an active mode by performing an initial access procedure (S521). step). Then, between the target ACR 505, the serving ACR 507, and the LS 509 to provide the LBS for the MS 501, a serving ACR corresponding to the MS 501 in the active mode. When the location of 507 is registered and a request for positioning of the MS 501 is received from the LC 511, the LS 509 starts the positioning procedure with the registered serving ACR 507, that is, the MS ( A periodic location session for acquiring the location information of 501 is established (step S523). At this time, the LS 507 identifies the NAI of the MS 501 and the LCID for each MAC of the MS 501, that is, the serving ACR 505 that is the current serving ACR and the target ACR 505 that is the serving ACR after handover. Manage your information.

Next, if the location information of the MS 501 is needed to provide the LBS for the MS 501, the LC 511 transmits a location data request message to the LS 509. A request is made to transmit the location information of the MS 501 (step S525). Here, the location data request message includes identification information of the location information determination target MS 501, that is, MS 501 to which location information is to be transmitted.

Then, the LS 509 receiving the location data request message checks the serving ACR 507 of the MS 501 to transmit the location information through the mapping table as described above (step S527). Next, after the MS 501 and the RAS 503 have handed over from the serving ACR 529 to the target ACR 505 (step S529), the LS 509 checks the serving ACR 507 in step S527. In step S531, a Location REP-REQ message requesting to report the location information of the MS 501 is transmitted. Here, the Location REP-RSP message includes the MAC ID and LCID of the MS 501, that is, identification information of the serving ACR 507.

Next, the serving ACR 507 receiving the Location REP-REQ message checks that the MS 501 and the RAS 503 to which the location information is to be transmitted are handed over to confirm that they are not the serving ACR. The RSP message is transmitted to the LS 509 to inform that the serving ACR for the current MS 501 is not itself, that is, the target ACR 505 is the serving ACR for the current MS 501 (step S533). That is, the serving ACR507 tells the LS 509 to transmit the Location REP-REQ message to the target ACR 505, that is, the target ACR 505 requests a report of the location information of the MS 501. Inform. Here, the Location REP-RSP message includes the MAC ID and LCID of the MS 501, that is, the identification information of the target ACR 505 and the identification information of the RAS 503 serving as the serving RAS.

Then, the periodic location session between the serving ACR 507 and the LS 509 established to transmit and receive the location information of the MS 501 is terminated (step S535), and the LS 509 is a target ACR (the serving ACR). In step S537, a location REP-REQ message requesting to report the location information of the MS 501 is transmitted. Here, the Location REP-REQ message includes the MAC ID and LCID of the MS 501, that is, identification information of the target ACR 505. Then, the target ACR 505 checks the RAS 503 serving as the serving RAS of the MS 501 to transmit the location information, and sends the Location REP-REQ message received from the LS 509 to the RAS 503. (Step S539). At this time, the target ACR 505 manages the MAC ID of the MS 501 and the identification information of the serving RAS, and the MAC ID of the MS 501 and the MS in the Location REP-REQ message transmitted to the RAS 503. Identification information of the RAS 503 that is the serving RAS of 501 is included.

The RAS 503 receiving the Location REP-REQ message from the target ACR 505 manages the CID assigned to the MS 501 as described above, and includes a list of neighboring RASs to be scanned, including itself as a serving RAS. Information is included and the MS 501 sends a SCN-RSP message requesting the MS 501 to transmit its location information to the MS 501 to trigger the MS 501's location measurement (step S541). Then, the MS 501 scans the RASs according to the SCN-RSP message, and measures its position with respect to the RAS 503 when the RASs are scanned (step S543). In this case, the position measurement of the MS 501 is performed through a signal delay during signal transmission and reception with the RAS 503, that is, the distance with the RAS 503, that is, the maximum distance and the minimum distance and the maximum distance, using the RTD. The average distance is calculated through the minimum distance, and the position of the MS 501 itself is measured from the RAS 503 through the calculated distance. Then, the MS 501 generates location information corresponding to its location measurement, and transmits a SCN-REP message including the generated location information and scanning information to the RAS 503 (step S545). .

Upon receiving the SCN-REP message, the RAS 503 transmits a Location REP-RSP message including the MAC ID of the MS 501 and the location information of the MS 501 to the target ACR 505 (S547). step). Here, the MS 501 calculates the maximum distance, the minimum distance, and the average distance by using the RTD, and has only been described as measuring the position of the MS 501 itself from the RAS 503 through the calculated distance. As described above, the RAS 503 calculates a maximum distance, a minimum distance, and an average distance using a signal delay, that is, an RTD, and measures the position with the MS 501 based on the calculated distance. After the location information is generated, the location information may be included in the Location REP-RSP message and transmitted. Next, the target ACR 505 checks the received Location REP-RSP message to determine the location information of the MS 501 included in the Location REP-RSP message and the RAS that transmits the Location REP-RSP message, that is, the The Location REP-RSP message including the identification information of the RAS 503 serving as the serving RAS of the MS 501 corresponding to the location information included in the Location REP-RSP message is transmitted to the LS 509 (step S549).

Then, the LS 509 transmits a location data response message including the location information of the MS 501 to the LC 511 (step S551), and acquires the location information of the MS 401. The periodic location session between the target ACR 505 and the LS 509 established for this purpose is terminated (step S553).

As described above, the communication system according to another embodiment of the present invention is configured between the serving ACR 507 and the LS 509 before the handover to obtain the location information of the MS 501 in the handover between the ACRs in the active mode. After ending the periodic location session, request to send location information to the MS 501 via a serving ACR after handover, i.e., a periodic location session between the target ACR 505 and the LS 509, and the MS 501 ) Generates its own location information by measuring the location by calculating the distance with the RAS 503 when scanning the RAS 503 corresponding to the SCN-RSP message including the request, and then includes the location information. By sending the message to the RAS 503, the LS 509 acquires the location information of the MS 501, and transmits the location information of the MS 501 to the LC 511 to the MS 501. Provide LBS for. Next, the operation of the MS in the communication system according to the embodiment of the present invention will be described in more detail with reference to FIG. 6.

6 is a diagram illustrating an operation process of an MS in a communication system according to an exemplary embodiment of the present invention.

Referring to FIG. 6, first, in step S610, the MS receives an SCN-RSP message that triggers the MS's location measurement from the serving RAS managing the MS. In this case, the SCN-RSP message includes the serving RAS, as described above, and request information for transmitting the list information of neighbor RASs to be scanned and the location information of the MS itself. Then, in step S620, when the MS scans the serving RAS, the MS performs a signal delay when transmitting and receiving a signal with the serving RAS, for example, a signal delay of a preamble signal that is a downlink reference signal, that is, by using the RTD. An average distance is calculated from a distance, that is, a maximum distance, a minimum distance from the serving RAS, and the maximum distance and a minimum distance, and the position of the self is measured with respect to the serving RAS. In addition, in step S620, the MS scans neighbor RASs using the list information, calculates a signal delay with neighbor BSs, that is, a distance from the scanned neighbor RASs through RTD, for the neighbor BSs. Measure your position. In this case, the distance measurement with the RAS is measured using a delay of the downlink signal received from the RAS, for example, RTD. Here, as described above, the MS can measure the distance between the serving RAS and the neighboring RASs through signal delay, and the serving RAS and the neighboring RASs can also measure the distance of the MS by measuring the distance from the MS.

Next, in step S630, the MS generates its own location information corresponding to its location measurement, and then proceeds to step S640. Then, in step S640, the MS includes the generated location information and the scanning information in the SCN-REP message and transmits it to the serving RAS.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the scope of the following claims, but also by the equivalents of the claims.

1 schematically illustrates the structure of a communication system according to an embodiment of the invention.

2 is a schematic illustration of an LBS related protocol stack in a communication system according to an embodiment of the invention.

3 is a diagram schematically illustrating a procedure for providing an LBS in a communication system according to an embodiment of the present invention.

4 is a diagram schematically illustrating a procedure for providing an LBS in a communication system according to another embodiment of the present invention.

5 is a diagram schematically illustrating a procedure for providing an LBS in a communication system according to another embodiment of the present invention.

6 is a diagram illustrating an operation of an MS in a communication system according to an embodiment of the present invention.

Claims (22)

A method for providing location based service in a broadband wireless access communication system, a) the server requesting the base station for location information of the mobile station through the control station, and the base station sending a scan response (SCN-RSP: Scan-Response) message corresponding to the request to the mobile station; b) When the mobile station receives the scan response message, the mobile station measures the position of the mobile station with respect to the base station, generates location information of the mobile station, and includes a scan report (SCN-REP: Scan-Report) including the location information of the mobile station. Sending a message to the base station; c) when the base station receives the scan report message and transmits the location information of the mobile station included in the scan report message to the server through the control station, the server receives the location information of the mobile station and And transmitting the location information to the mobile station requesting the location confirmation. The method of claim 1, The request to the base station in step a) is characterized in that the location information of the mobile station is requested to the base station after establishing a location session between the control station and the server in the active mode of the mobile station. How to Deliver Foundation Services. The method of claim 2, In step a), the server sends a Location Report Request (Location REP-REQ) message to the base station through the control station and requests the location information of the mobile station, and receives the location report request message. Wherein the base station transmits the SCN-RSP (Scan-Response) message to the mobile station. The method of claim 3, In step c), receiving the location information of the mobile station, the base station includes the location information of the mobile station included in the scan report message in a Location Report Response (Location REP-RSP: Location Report Response) message to the control station; Transmitting to the server through the server, wherein the server receives the location report response message to receive location information of the mobile station. The method of claim 4, wherein The location report request message includes a media access control (MAC) identifier of the mobile station and identification information of the base station and the control station, and the location report response message includes a media access control identifier of the mobile station. Location-based service providing method characterized in that. The method of claim 4, wherein In step b), the location measurement of the mobile station calculates a maximum distance, a minimum distance, and an average distance from the base station by using a round trip delay (RTD) of a signal received from the base station. And measuring the location of the mobile station over one distances. The method according to any one of claims 1 to 6, d) when the server requests the location information of the mobile station from the control station after the mobile station and the base station hand over to the target control station, the control station requests the target control station to request location information of the mobile station; Responding to the server, e) the server receiving the response to request location information of the mobile station to the base station through the target control station, and the base station sending the scan response message to the mobile station in response to the request; f) when the mobile station receives the scan response message, measures the location of the mobile station relative to the base station to generate location information of the mobile station, and transmits the scan report message including the location information of the mobile station to the base station. Steps, g) the base station receiving the scan report message and transmitting the location information of the mobile station included in the scan report message to the server through the target control station. . The method of claim 7, wherein In step d), the request to the control station establishes a location session between the control station, the target control station, and the server in the active mode of the mobile station, and then requests the serving control station for location information of the mobile station. Location-based service providing method, characterized in that. The method of claim 8, And the response to the server in step d) transmits the location report response message including the identification information of the mobile station, the base station and the target control station to the server. The method of claim 8, In the step e), the request to the base station, after the location session established between the control station and the server, the location-based service, characterized in that requesting the base station the location information of the mobile station through the target control station How to Provide. The method of claim 10, In step e), the server transmits a location report request message for requesting location information of the mobile station to the base station through the target control station, and the base station receiving the location report request message receives the scan response message. And transmitting to the mobile station. The method of claim 11, Receiving the location information of the mobile station in step g), the base station includes the location information of the mobile station included in the scan report message in the location report response message to transmit to the server through the target control station, And receiving a location report response message from the server to receive location information of the mobile station. The method of claim 12, The location report request message includes a medium access control identifier of the mobile station and identification information of the base station and the target control station, and the location report response message includes a medium access control identifier of the mobile station. How we deliver the service. In a broadband wireless access communication system, a method for supporting location-based services, a) the server sending a Location Report Request (Location REP-REQ) message to the control station requesting the location information of the mobile station; b) after the control station performs paging through the base station to transition to an active mode when the mobile station is in an idle mode, and transmits the location report request message to the base station; c) the base station receiving the location report request message and transmitting a scan response (SCN-RSP) message to the mobile station; d) When the mobile station receives the scan response message, the mobile station measures the location of the mobile station with respect to the base station to generate location information of the mobile station, and includes a scan report (SCN-REP: Scan-Report) including the location information of the mobile station. Sending a message to the base station; e) receiving, by the base station, the scan report message and transmitting location information of the mobile station included in the scan report message to the server through the control station. The method of claim 14, In step b), the control station transmits a paging request message to the base station, and the base station receiving the paging request message transmits a paging advertisement message (PAG-ADV) to the mobile station. Location-based service support method characterized in that. The method of claim 15, The transmitting of the location report request message in step c) may include transmitting a location report request message to the base station after establishing a location session between the base station, the control station, and the server in an active mode of the mobile station. How to support location-based services. The method of claim 16, Receiving location information of the mobile station in step e), the base station includes the location information of the mobile station included in the scan report message in a location report response (Location REP-RSP: Location Report Response) message to the control station; Transmitting to the server through the server, wherein the server receives the location report response message to receive location information of the mobile station. A base station of a broadband wireless access communication system, a) receiving from the location server a location report request message corresponding to the location request of the mobile station from the control station; b) performing location measurement on the mobile station using a downlink reference signal corresponding to the location report request message, and transmitting a location report response message to the control station in response to the location report request message; Include, Wherein the location report response message includes a base station identifier and a delay value of the reference signal. The method of claim 18, The delay value is at least one of a round trip maximum value, a round trip minimum value, or a round trip average value. A mobile station supporting location based services in a broadband wireless access communication system, A receiving end receiving a scan response message from the base station triggering a location measurement corresponding to the location-based service provision request; A location agent for performing the location measurement in response to the scan response message; Location measurement report means for transmitting a scan report message including a location measurement value corresponding to the location measurement to the base station; The location measurement value is a mobile station supporting a location-based service, characterized in that the signal delay value of the downlink reference signal of the base station. The method of claim 20, The delay value is at least one of a round trip maximum value, a round trip minimum value, or a round trip average value. The method of claim 20, The downlink reference signal is a mobile station supporting a location-based service, characterized in that the preamble signal.

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