KR20090072697A - Mobile communication system and method for providing location information of mobile station of serving gprs support node - Google Patents

Abstract

A mobile communication system and a method for providing location information of a mobile station of serving a GPRS support node are provided to supply the location information of a mobile station to a gateway device at a regular interval. A network control processor(341) processes a GTP(GPRS Tunneling Protocol) message, and an access network processor(342) manages the resources between an SGSN(Serving GPRS Support Node) and an RNC(Radio Network Controller). A packet handler(343) processes a traffic, and a storage unit(344) stores the location information of each MS(Mobile Station) according to the control from an SGSN controller(345).

Description

MOBILE COMMUNICATION SYSTEM AND METHOD FOR PROVIDING LOCATION INFORMATION OF MOBILE STATION OF SERVING GPRS SUPPORT NODE}

The present invention relates to a mobile communication system, and more particularly, to a method for providing mobile station location information of a packet switching support apparatus in a mobile communication system.

UMTS (Universal Mobile Telecommunication System) is a third generation mobile communication system evolved from the European standard Global System for Mobile communications (GSM). Based on the core technology of GSM, Radio Access Network (RAN) ) Provides various services by incorporating Wideband CDMA (WCDMA) technology, and these services are called asynchronous IMT (International Mobile Telecommunication) -2000 services.

UMTS is a mobile station (MS), a base station (Node B) for wireless communication with the MS, a Radio Network Controller (RNC) for controlling Node B, a packet switching support apparatus for providing a packet call service through the RNC ( Serving GPRS Support Node (SGSG)) and packet switched gateway devices.

According to the 3rd Generation Partnership Project (3GPP) standard of the mobile communication system, the MS periodically transmits location information to the SGSN through the RNC, and the SGSN stores and updates the location information of the MS for each MS. When the MS uses a packet service, the SGSN transmits the location information of the MS to the GGSN or, when the MS changes its location, transmits the changed location information of the MS to the GGSN.

As described above, since the SGSN transmits the location information of the MS to the GGSN only when the MS uses the packet service or when the location information of the MS is changed, the GGSN periodically clears the location information of the MS in a state in which there is no location movement. Could not be confirmed.

The present invention provides a mobile communication system and a method for providing mobile station position information of a packet switching support apparatus for providing the position information of a mobile station to a packet switching gateway device at regular intervals in a mobile communication system.

The packet switching support apparatus of the mobile communication system of the present invention extracts the location information of the mobile station from the mobile station location information report message received from the mobile station and transmits the location information of the mobile station to the packet switching gateway device, and the packet switching gateway device transmits the location information of the mobile station. To the external network monitoring device.

According to the following embodiment, the packet-switching gateway device periodically receives the location information of the mobile station from the packet-switching support device and transmits the location information of the mobile station to the network monitoring apparatus to analyze the positional variation of the mobile station and use the analysis result as data for cell design. .

Hereinafter, various embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, in the following description, when there is a risk of unnecessarily obscuring the gist of the present invention, a detailed description of well-known functions and configurations will be omitted.

1 illustrates a configuration of a UMTS to which the present invention is applied. As shown in FIG. 1, the UMTS includes a mobile station (MS) 10, a UMTS terrestrial radio access network (UTRAN) 20, and a core network (CN) 30. It includes. CN 30 is connected to an external network 40. The external network 40 may include a public land mobile network (PLMN), a public switched telephone network (PSTN), an integrated service digital network (ISDN), or the Internet.

The UTRAN 20 includes a plurality of Node Bs 21 and a plurality of Radio Network Controllers (RNCs) 22, and the RNC 22 performs control and management of the base stations 21. do.

The CN 30 is logically divided into a Circuit Switched Domain (CS) and a Packet Switched Domain (PS), and handles all voice calls and data connections in the UMTS. Perform exchange with 40 and route establishment. CN 30 is a Mobile Services Switching Center / Visitor Location Register (MSC / VLR) 31 that performs functions such as control, management, authentication, and encryption in the CS area. Or a packet switching support device (SGSG) (34) connected to an MSC manager (GMSC) 32 and a UTRAN 20 to perform control and management functions in the CS area. ), A packet switching gateway device (Gateway General Packet Radio Service (GPRS) Support Node (GGSN) 35), which is connected to a plurality of SGSNs 34 and is an external IP packet network 40 interface.

Circuit traffic is processed via the MSC / VLR 31 centering on the RNC / Node Bs 21 and 22, and packet traffic is handled by the Serving GPRS Support Node (SGSN) 34 and the GGSN. (Gateway GPRS Support Node) 35 connects to the Internet. According to one embodiment, the SGSN 34 provides the location information of the MS 10 to the GGSN 35 at regular intervals.

SGSN 34 is a system that performs packet data processing in an asynchronous network (W-CDMA, UMTS, GPRS, etc.), and plays a role corresponding to MSC 31 for switching voice calls. SGSN (34) is a system that enables high-speed Internet service in the GPRS network with the GGSN (35). In addition, the SGSN 34 is connected to several RNCs 22 to manage mobility and packet sessions of the MS 10, establishes a packet data protocol (PDP) context with the GGSN 35, and uses a PDU using tunneling. (Protocol Data Unit), performs IP routing technology, and is connected and interact with the MSC / VLR (31).

The GGSN 35 is connected to the Internet 42 to support interworking with external packets and operates based on a Packet Data Protocol (PDP) session establishment request from the SGSN 34. A session is a GPRS service that enables a set of services such as PDP context and traffic path resource allocation, which are created for one packet service. The interface between SGSN 34 and GGSN 35 is based on the GPRS Tunneling Protocol (GTP).

2 is a diagram illustrating an internal configuration of the SGSN 34 according to an embodiment. As shown in FIG. 3, the SGSN 34 includes a network control processor 341, an access network processor 342, a packet handler 343, a storage unit 344, and an SGSN. The control unit 345 is included.

The network control processor 341 processes a GPRS Tunneling Protocol (GTP) message, and performs a session control function and a resource management function between the SGSN 34 and the GGSN 35.

The access network processing unit 342 cooperates with the RNC 22 to perform a Radio Access Network Application Part (RANAP) matching function and a resource management function between the SGSN 34 and the RNC 22.

The packet handler 343 performs a traffic processing function, and performs a real traffic processing for a fixed service (or a fixed traffic class) such as an interactive / background service, and performs the network control processing unit ( 341) and the access network processing unit 342.

The storage unit 344 stores the position information of the MS 10 for each mobile station of the MS 10 under the control of the SGSN controller 345.

The SGSN controller 345 stores and updates the location information of the MS 10 transmitted from the MS 10 through the RNC 22 for each MS, and transmits the location information of the MS 10 to the GGSN 35 at regular intervals. do. According to one embodiment, the location information of the MS 10 is represented as data of the user location information parameter (location information related parameter) of the 3GPP Release 6 Protocol message (eg, PDP context update request message).

The SGSN control unit 345 sends a location information of the MS 10 to the GGSN 35, and a PDP context creation request (Create Packet Data Protocol), which is a 3GPP GTP protocol message transmitted when a session opening request for a packet service is made. Context Request) message using the mobile station location information parameter of the 3GPP Release 6 standard. The creation of the context means that a path through which the MS 10 can transmit and receive a packet data service with the GGSN 35 is set and is in a state capable of receiving service.

3 is a flowchart illustrating a method of activating a PDP context in SGSN 34 of a mobile communication system.

The method for activating the PDP context in the SGSN 34 includes the following steps. The MS 10 sends a PDP context activation request message to the SGSN 34. The PDP context activation request message includes QoS information, parameters for establishing tunneling, which is a passage between the MS 10 and the GGSN 35, IP allocation information, and bandwidth allocation information. SGSN 34 sends a PDP context creation request message to GGSN 35. The GGSN 35 sends a PDP Create Packet Data Protocol Context Response message to the SGSN 34. As a result, a radio access bearer is established between the MS 10 and the SGSN 34. At this time, when the bandwidth negotiated in the radio access bearer between the RNC 22 and the SGSN 34 is different from the bandwidth between the SGSN 34 and the GGSN 35 performed in the previous step, the SGSN 34 is connected to the RNC 22. ) Can be transmitted to the GGSN 35 through a PDP Context Update Request (Update Packet Data Protocol Context Request) message. The GGSN 35 sends a PDP Update Packet Data Protocol Context Response message to the SGSN 34. If the result returned from the GGSN 35 is successful, the SGSN 34 returns a PDP Activation Packet Data Protocol Context Accept message to the MS 10.

The GGSN 35 performs radio resource allocation and serves as a gateway to an external packet network. The GTP processing unit 351 of the GGSN 35 converts the message transmitted from the SGSN 34 into digital data. The external network matching unit 352 performs an interface function with the Internet. The storage unit 353 stores MS location information for each mobile station of the MS 10.

The GGSN control unit 354 accesses the corresponding site through the external network matching unit 352 according to the Internet access request received through the GTP processing unit 351, receives data, and sends the data to the SGSN 34 through the GTP processing unit 351. send.

In addition, according to an exemplary embodiment, the GGSN control unit 354 extracts location information of the MS from the PDP context update request message received through the GTP processing unit 351 and stores the location information of the MS in the storage unit 353. 10) are stored for each mobile station. The GGSN controller 354 forms a PDP context response message and transmits it to the SGSN 34 through the GTP protocol processor.

Referring to FIG. 1, a network network monitoring apparatus 50 of a network operator may be connected to the GGSN 35. The network monitoring device 50 receives the location information of the MS stored in the GGSN 35, grasps the location change of the MS in real time, and analyzes the fluctuation state of the MS to adjust the cell size or add a cell. have.

Hereinafter, as the MS 10 periodically transmits a location information report message to the SGSN 34 through the RNC 22, the SGSN 34 transmits the location information of the MS 10 to the GGSN 35. Shows an example. Referring to FIG. 4, the MS 10 transmits a Routing Area Update Request message to the SGSN 34 for reporting location information at a predetermined period (S1), and according to the present embodiment, the SGSN ( 34) transmits a PDP context update request message (Update PDP Context Request) to the GGSN 35 (S2), and the GGSN 35 transmits a PDP context update request acceptance message (Update PDP Context Response) to the SGSN 34. (S3).

When the SGSN 34 receives the PDP context update request acceptance message, the SGSN 34 registers the location information indicating the movement state of the MS 1 so as to provide a communication service to the MS 1 after the location movement. In step S4, a location update request message is transmitted (S4). The second MSC / VLR 31 ′ transmits a location update message to the HLR 33 (S5). The HLR 33 transmits and receives a location information removal / response message (Cancel Location / Cancel Location Ack) with the first MSC / VLR 31 which provided the communication service to the MS 1 before moving the location (S6, S7). After transmitting and receiving (S9 and S10) the second MSC / VLR 31 'and the MS Subscriber Data Insertion / Accept message (S9 and S10), the second MSC / VLR 31' accepts the location update. The message (Update Location Ack) is transmitted (S8). Thereafter, the second MSC / VLR 31 ′ transmits a location information update acceptance message to the SGSN 34 (S11). SGSN 34 transmits a Routing Area Update Accept message to MS 10 (S12).

By such a configuration, the GGSN 35 may transfer the location information of the MS 10 to the network monitoring apparatus to grasp the location variation of the MSs and use the same in cell design.

While the invention and its various functional components have been described in particular embodiments, the invention may be implemented in hardware, software, firmware, middleware, or a combination thereof, and the system, subsystem, components or sub-configurations thereof. It should be understood that they can be used as elements. If implemented in software, the elements of the invention are instructions / code segments for performing the necessary tasks. The program or code segments may be stored in a machine readable medium, such as a processor readable medium, a computer program product, or via a transmission medium or communication link by a computer data signal embodied in a carrier wave or a signal modulated by a carrier. Can be sent. Machine readable media or processor readable media may include any medium that can store or transmit information in a form readable and executable by a machine (eg, processor, computer, etc.).

In addition, while the present invention has been described in connection with some embodiments, it should be understood that various modifications and changes can be made within the scope of the invention to those skilled in the art to which the invention pertains. Also, such modifications and variations are intended to fall within the scope of the claims appended hereto.

1 is a schematic diagram showing a configuration of a mobile communication system according to an embodiment;

Figure 2 is a schematic diagram showing the internal configuration of the SGSN and GGSN of Figure 1;

3 is a schematic diagram illustrating a process of generating a PDP context in a mobile communication system.

4 is a message flow diagram for transmitting, by the SGSN, location information of the mobile station to the GGSN.

Claims (8)

A mobile communication system comprising a packet switching support device connected to the Internet through a packet switching gateway device to provide a packet call service. The packet switching support apparatus extracts mobile station position information from the mobile station position information report message received from the mobile station, and transmits the mobile station position information to the packet switched gateway device; And the packet-switched gateway device accumulates and stores the location information for each mobile station. The method of claim 1, And the mobile station location information is transmitted to the packet switched gateway device as a parameter of a 3rd Generation Partnership Project (3GPP) standard Packet Data Protocol Context Update Request message (Update PDP Context Request). The method of claim 1, The mobile station location information is the packet exchange gateway as a location information parameter of a Create Packet Data Protocol Context Request message that the packet switching support device sends to the packet switching gateway device when a session establishment request for a packet service is requested. A mobile communication system transmitted to the device. The method according to claim 2 or 3, The packet exchange support device, And extracting location information of the mobile station from the message, and storing the location information of the mobile station by each identification number of the mobile station. The method of claim 1, And the packet-switching support device transmits the position information of the mobile station to the packet-switching gateway device at regular intervals. The method of claim 1, And a network monitoring device configured to receive mobile station location information from the packet-switching gateway device and accumulate the mobile station and analyze the positional change of the mobile station. A method of providing location information of a packet switching support apparatus connected to the Internet through a packet switching gateway device in a mobile communication system to provide a packet call service, And extracting, by the packet-switching support device, location information from the mobile station location information report message received from the mobile station, and transmitting the location information to the packet-switching gateway device. The method of claim 7, wherein And transmitting, by the packet switching gateway device, the location information to a network monitoring device.

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