KR20030086195A - Apparatus and method for assigning channel for a mbms in a mobile communication system - Google Patents

Abstract

PURPOSE: A system and method for setting channels for MBMSs(Multimedia Broadcast/Multicast Services) in a mobile system is provided to efficiently allocate channels for a plurality of mobile terminals that makes requests for an identical MBMS. CONSTITUTION: A UE(User Equipment) that belongs to RNC(Radio Network Controller)1 selects a specific MBMS and transmits an activate MBMS context request message to SGSN(Serving GPRS Support Node)1 together with an identifier associated with the selected MBMS and its own identifier(1801). Receiving the activate MBMS context request message, SGSN1 verifies whether the UE can receive the selected MBMS(1802). If the verification process is successfully executed, SGSN1 transfers a request MBMS join message to RNC1, including information, such as the selected MBMS associated identifier, etc(1803). Based on the received information, RNC1 checks whether a default SGSN for the MBMS corresponding to the MBMS associated identifier is set. In case that the default SGSN is set, RNC1 transmits the UE identifier and the selected MBMS identifier to the default SGSN through an MBMS join notification message(1804). The default SGSN transmits the selected MBMS identifier to all the RNCs belonging to the same PS pool-area as RNC1 and informs them that it has been set as the default SGSN of the MBMS(1805).

Description

Channel setting apparatus and method for multicast multimedia broadcasting service in mobile communication system {APPARATUS AND METHOD FOR ASSIGNING CHANNEL FOR A MBMS IN A MOBILE COMMUNICATION SYSTEM}

The present invention relates to a method for establishing a channel for a multicast multimedia broadcasting service in a mobile communication system, and more particularly, to a channel setting method by request of a multicast multimedia broadcasting service.

Today, due to the development of the telecommunications industry, the services provided by the code division multiple access (CDMA) mobile communication system are used to transmit not only voice services but also large data such as packet data and circuit data. Evolving into multicasting multimedia communications. Accordingly, in order to support the multicasting multimedia communication, there is a broadcast / multicast service that provides a service from a single data source to a plurality of mobile terminals (hereinafter referred to as UE). . The broadcast / multicast service is a cell broadcast service (hereinafter referred to as "CBS"), which is a message-oriented service, and a multicast multimedia broadcast service supporting multimedia forms such as real-time video, voice, still image, and text. Broadcast / Multicast Service, hereinafter referred to as "MBMS").

The CBS is a service that broadcasts a plurality of messages to all UEs located in a specific service area. In this case, the specific service area for providing the CBS may be the entire area where the CBS is provided in one cell. The MBMS is a service for simultaneously providing audio data and video data, and requires a large amount of transmission resources. Therefore, the MBMS is serviced through a broadcast channel in that there is a possibility that a large number of services can be simultaneously deployed in one cell.

As described above, in the conventional mobile communication system, when the same MBMS is requested from a plurality of mobile terminals controlled by the same cell or a wireless network controller, channels for providing the same MBMS are allocated to each of the plurality of mobile terminals. shall.

For this reason, the conventional mobile communication system is urgently required a signaling procedure for serving the same MBMS for a plurality of mobile terminals. However, when a plurality of channels are allocated to provide the same MBMS to different mobile terminals, channels may be unnecessarily wasted and the processing signaling procedure may be complicated.

Accordingly, an object of the present invention for solving the above problems is to provide a method for efficiently allocating channels for a plurality of mobile terminals that require the same multicast multimedia broadcasting service in a mobile communication system.

Another object of the present invention is to provide a method for allocating a minimum channel to mobile terminals requiring the same multicast multimedia broadcasting service.

Another object of the present invention is to provide a method for simplifying a signaling procedure for channel allocation by managing mobile terminals provided with a specific multicast multimedia broadcasting service for each channel.

Another object of the present invention is to provide a method for managing information according to provision of a specific multicast multimedia broadcasting service by one wireless network base station.

Another object of the present invention is to provide a method for managing information according to provision of a specific multicast multimedia broadcasting service by one SGSN.

In a first aspect for achieving the above object, the present invention designates at least two radio network controllers as a group in the mobile communication system, and separate SGSNs corresponding to the radio network controllers designated as the group. In the method for setting a channel for receiving the data for at least one mobile terminal receiving data by the wireless network controllers assigned to the group, a new multicast multimedia broadcasting service from any mobile terminal Determining a default SGSN corresponding to the mobile station among the SGSNs designated as the group when required, and managing information for the new multicast multimedia broadcasting service by the default SGSN; and from the other mobile station When the multicast multimedia broadcasting service is required For multicast broadcast multimedia service by the other to the managed information to a mobile terminal it characterized in that it comprises the step of setting the same channel as the arbitrary mobile terminal.

In a second aspect for achieving the above object, the present invention specifies at least two radio network controllers as a group in the mobile communication system, and SGSNs corresponding to the radio network controllers designated as the group to a separate group A method for setting a channel for receiving data for at least one mobile terminal for receiving data by wireless network controllers assigned to the group, wherein a new multicast multimedia broadcasting service is requested from any mobile terminal. The default SGSN corresponding to the mobile terminal among the SGSNs designated as the group, and the new multicast multimedia broadcasting service by the wireless network controller corresponding to the basic SGSN among the wireless network controllers designated as the group. To manage information for the When the multicast multimedia broadcasting service is requested from the mobile station, setting the same channel as the mobile terminal for the other mobile terminal based on information managed for the multicast multimedia broadcasting service. .

According to a third aspect for achieving the above object, the present invention designates at least two radio network controllers as a group in a mobile communication system, and assigns SGSNs corresponding to the radio network controllers designated as the group to a separate group. A method for establishing a channel for receiving the data for at least one mobile terminal receiving data by the wireless network controllers assigned to the group, wherein the mobile terminal is configured to select any one of the SGSNs. When the multicast multimedia broadcasting service is requested to the SGSN, the SGSN transmits an identifier of the multicast multimedia broadcasting service to a wireless network controller to which the mobile terminal belongs, and the wireless network controller controls the multicast multimedia broadcasting service. To the multicast multimedia broadcasting service by an identifier of Checking whether there is a corresponding reference SGSN; and if the reference SGSN does not exist, any SGSN among the SGSNs is set as a default SGSN, and the identifier of the mobile terminal and the identifier of the multicast multimedia broadcasting service are set to the reference SGSN. Transmitting the identifier of the mobile station and the identifier of the multicast multimedia broadcasting service to the reference SGSN if the reference SGSN exists, and the reference SGSN is assigned to the same group as the wireless network controller. And notifying to the wireless network controllers that the identifier of the multicast multimedia broadcasting service is set to the reference SGSN.

1 is a diagram conceptually illustrating a configuration of a code division multiple access mobile communication system for a multicast multimedia broadcasting service according to an exemplary embodiment of the present invention.

2 is a diagram illustrating a control flow for setting a channel according to a multicast multimedia broadcasting service.

3 is a diagram illustrating signaling for allocating a channel according to a multicast multimedia broadcasting service currently in service.

4 is a diagram illustrating signaling for allocating a channel according to a multicast multimedia broadcasting service, which is to be serviced later.

5 is a diagram conceptually illustrating a configuration of a mobile communication system having a full structure according to an embodiment of the present invention.

6 is a diagram conceptually illustrating a channel allocation signaling procedure that may be proposed in a mobile communication system having a full structure according to an embodiment of the present invention.

7 is a diagram illustrating a signaling procedure for allocating a channel in an initial multicast multimedia broadcasting service in a mobile communication system having a full structure according to an embodiment of the present invention.

8 is a diagram illustrating an example of a signaling procedure for allocating a new channel in a multicast multimedia broadcasting service in service in a mobile communication system having a full structure according to an embodiment of the present invention.

FIG. 9 illustrates another example of a signaling procedure for allocating a new channel in a multicast multimedia broadcasting service in service in a mobile communication system having a full structure according to an embodiment of the present invention.

FIG. 10 is a diagram illustrating a signaling procedure for notifying a target mobile terminal of the start of a multicast multimedia broadcasting service scheduled for future service in a mobile communication system having a full structure according to an embodiment of the present invention.

11 is a diagram illustrating a signaling procedure performed when a mobile terminal selects a multicast multimedia broadcasting service provided in a mobile communication system according to an embodiment of the present invention.

12 is a diagram illustrating a signaling procedure for terminating a multicast multimedia broadcasting service in service in a mobile communication system having a full structure according to an embodiment of the present invention.

13 is a diagram illustrating a signaling procedure for allocating a channel in an initial multicast multimedia broadcasting service in a mobile communication system having a full structure according to another embodiment of the present invention.

14 is a diagram illustrating an example of a signaling procedure for allocating a new channel in a multicast multimedia broadcasting service in service in a mobile communication system having a full structure according to another embodiment of the present invention.

15 is a diagram illustrating another example of a signaling procedure for allocating a new channel in a multicast multimedia broadcasting service in service in a mobile communication system having a full structure according to another embodiment of the present invention.

16 is a diagram illustrating a signaling procedure performed when a mobile station selects a multicast multimedia broadcasting service provided in a mobile communication system according to another embodiment of the present invention.

17 is a diagram illustrating a signaling procedure for terminating a multicast multimedia broadcasting service in service in a mobile communication system having a full structure according to another embodiment of the present invention.

18 illustrates signaling when a non-access stratum (NAS) message is used to allocate a channel in an initial multicast multimedia broadcasting service in a mobile communication system having a full structure according to an embodiment of the present invention. Drawing showing the procedure.

19 illustrates an example of a signaling procedure for setting and releasing a data transmission channel from when a service is terminated after actual multicast multimedia broadcasting service data starts to be transmitted in a mobile communication system having a full structure according to two embodiments of the present invention. Corresponding drawing.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

DETAILED DESCRIPTION In the following detailed description, one representative embodiment of the present invention is set forth in order to achieve the above technical problem. And other embodiments that can be presented with the present invention are replaced by the description in the configuration of the present invention.

First, terms used in embodiments of the present invention are defined as follows.

MBMS data refers to data provided to mobile terminals from a service provider by MBMS, and basic SGSN refers to SGSN which manages information for a specific multicast multimedia broadcasting service among SGSNs designated as one group.

1 is a diagram showing the basic structure of a mobile communication system for applying the embodiments of the present invention. That is, FIG. 1 illustrates basic entities for providing MBMS in a code division multiple access mobile communication system and mutual relationships therebetween.

Referring to FIG. 1, a mobile terminal (hereinafter referred to as "UE") 101 is a subscriber device capable of receiving MBMS data provided by an MBMS. A base station apparatus (UTRAN) 102 is a device for transmitting related data according to the MBMS to the UE, and is composed of a radio network controller (hereinafter referred to as "RNC") and a base station (Node B). The Serving GPRS Supporting Node (SGSN) 103 serves to control services related to MBMS of respective UEs. Representative examples include a role of managing service charging related data of each UE, and selectively transmitting multimedia data to a specific UTRAN. The GGSN 104 selectively transmits multimedia data received from the MB-SC 105 to a specific SGSN, and manages billing related data of all UEs receiving the multimedia data. The MB-SC 105 indicates a source of MBMS data according to the MBMS, and is responsible for scheduling each MBMS data. The MB-SC 105 also authenticates a provider of multimedia data for providing MBMS to the UEs. The Cell Broadcast Center (hereinafter referred to as "CBC") 107 informs the UEs of the MBMS-related menu currently being serviced or information related to MBMS data that will be serviced later. The MBMS to be serviced later refers to an MBMS to be provided at a point in time when service is not available and resources can be allocated later due to reasons such as a service or resource not provided by the mobile communication system. The home location register (hereinafter referred to as "HLR") 108 basically stores secret data of registered UEs, and serves to authenticate a UE that wants to communicate or a UE that wants to receive MBMS data. .

2 is a diagram illustrating a control flow of allocating a channel for each UE to receive a multicast multimedia broadcasting service from a mobile communication system. That is, the procedure for configuring a channel for receiving MBMS data after the UE powers on a specific cell based on the role and correlation of the entities in FIG. 1 is the same as that of FIG. As shown in FIG. 2, a procedure for establishing a channel for MBMS data transmission is largely divided into two types according to the characteristics of the MBMS selected by the UE. Here, the nature of MBMS means a service that is currently being provided or a service that will be provided later.

First, when the MBMS selected by the UE is currently being provided by the mobile communication system, a procedure of receiving a parameter for receiving MBMS data according to the selected MBMS will be described. Signaling for the UE 101 to receive MBMS data currently provided by the mobile communication system is shown in FIG. 3. Here, the parameter for receiving the MBMS data may include physical channel related information, transport channel related information, and the like. If the MBMS is encrypted and transmitted, information necessary to decrypt the MBMS data may also be transmitted.

If the UE 101 is powered on by the user in step 201, the process proceeds to step 202 to perform a registration (initial registration) procedure for a specific cell. The procedure performed by the UE 101 to register with the specific cell may use an existing procedure as it is. That is, the UE 101 establishes an RRC connection with the UTRAN 102 and transmits its IMSI (International Mobile Subscriber Identifier) value to the SGSN 103 using a Non Access Stratum (NAS) message. . In response, the SGSN 103 requests the HLR 108 to authenticate whether the UE performing the initial procedure is a registered UE.

In step 203, the UE 101 acquires information on the type of MBMS that is currently serving or to be serviced in the current cell. In this case, the CBC 107 may be used to broadcast the information about the MBMS service. Examples of the signal flow for broadcasting the information about the MBMS service using the CBC 107 may be steps 302 and 303 of FIG. 3. In step 204, the UE 101 selects its desired MBMS service from the received information about the MBMS service. It also identifies whether the selected MBMS is currently in service or scheduled for future service. If the selected MBMS is currently in service, the UE 101 may receive desired MBMS service data through steps 211 to 213. In step 211, the UE 101 presents to the UTRAN 102 the type of MBMS service it desires and information necessary for authentication. The UTRAN 102 determines whether the UE 101 can receive the MBMS selected by the information received from the UE 101. Examples of the entities participating in this step and the signal transmission between the entities are steps 304 and 305 of FIG. 3. First, in step 304, the UE 101 transmits the identifier of the MBMS selected by the UE 101 and its identifier (eg, "IMSI") to the SGNS 103. In response, the SGSN 103 asks the HLR 108 for authentication of the UE 101 and whether the selected MBMS service can be received in step 305. The UE 101 determines whether step 211 according to the above-described steps is performed successfully in step 212. If it is determined in step 212 that the UE 101 has a reception right for the selected MBMS, the process proceeds to step 213. In response, the UTRAN 102 transmits information for transmitting the selected MBMS data to the UE 101. In this case, examples of the signal flow between the UTRAN 102 and the UE 101 are 306, 307, 308, 309, and 310 of FIG. 3. In step 306 of FIG. 3, the SGSN 103 notifies the UTRAN 102 that authentication of the UE 101 has been successfully completed. In step 307, the UTRAN 102 provides information for receiving the selected MBMS data. The UE 101 notifies the UE 101 to receive it. Meanwhile, in step 308, the UE 101 successfully establishes a channel by using the information for receiving the selected MBMS data, and notifies the UTRAN 102 thereof. The UTRAN 102 informs the SGSN 103 again in step 309, and the SGSN 103 notifies the GGSN 104 that a specific UE has started receiving corresponding MBMS data in step 310. Step 310 is for transmitting basic data for charging corresponding to the reception of MBMS data and may be omitted depending on the charging system. As described above, the billing-related data for each UE is managed by the SGSN 103. Also, depending on the situation, step 310 may be performed after the service is terminated. However, in step 212, if the UE 101 determines that reception of the selected MBMS data is impossible and the MBMS service request fails, the UTRAN 102 may refuse to provide the selected MBMS service.

Next, when the MBMS service selected by the UE is provided later, a procedure of configuring a channel for the MBMS service will be described. In this case, the expected signal flow between MBMS service-related entities and entities is shown in FIG. 4.

If the UE 101 recognizes that the MBMS service selected by the UE is provided later, the UE 101 proceeds to step 205. When proceeding to step 205, the UE 101 may register the reception of the service in advance. At this time, the expected signal flows are the steps 404, 405 and 406 of FIG. In step 404, the UE 101 transmits the MBMS identifier and UE identifier selected by the UE 101 to the UTRAN 102. In this case, IMSI, P-TMSI, or RNTI may be used as the UE identifier. In response, the SGSN 103 checks whether the UE 101 can receive the MBMS data selected by the UE 101 in step 405. If the UE 101 can receive the selected MBMS data, in step 406, the SGSN 103 notifies the UE 101 that service registration has been successfully performed. In this case, the SGSN 103 may allocate a Temporary Multicast Group Identity (TMGI) which is a UE identifier commonly assigned to the selected MBMS service. In response, the SGSN 103 notifies the GGSN 104 of the request for the MBMS service selected by the UTRAN 102 managed by the SGSN 103 in step 407. The GGSN 104 notifies the MB-SC 105 of the notification from the SGSN 102 again. In the above-described step, a path for the MBMS service may be established between the MB-SC 105 and the SGSN 102.

In step 206 of FIG. 2, the UE 101 notifies related entities in advance that the selected MBMS data is soon to be provided. In this case, how much time the actual MBMS data is provided to each entity is notified depending on the implementation. An example of signal flow that may be used in step 206 may be step 408 of FIG. 4. In step 408, the MB-SC 105 determines the provision of the selected MBMS data through scheduling and informs the corresponding SGSN 103 of the MB-SC. In response, the SGSN 103 notifies relevant UEs via the UTRAN 102. The SGSN 103 may notify related UEs of the start of the MBMS service by using a predefined paging procedure in a code division multiple access mobile communication system using an existing asynchronous scheme.

In step 206, when the UE 101 recognizes the start of the pre-selected MBMS service, the UE 101 proceeds to step 207 to confirm receipt of the MBMS data. This is a procedure for confirming the reception of MBMS data, even if the UE has previously applied for MBMS service, depending on the situation. The UTRAN 102 may re-identify the UE 101 requesting reception of the MBMS data. Steps 409 and 410 of FIG. 4 correspond to this. In step 409, the UE 101 can transmit its identifier and TMGI or MBMS identifier.

The UE 101 determines whether the UE identification was successful in step 208. If it is determined in step 209 that the UE identification is successful, the UE 101 proceeds to step 209 and performs a procedure for establishing a channel for providing MBMS service between the UTRAN 102 and the UE 101. Steps 411, 412, 413 and 414 of FIG. 4 show an example of generating a related channel using a predefined procedure in a code division multiple access mobile communication system using an existing asynchronous method.

Meanwhile, the SGSN 102 notifies the GGSN 104 that the UE 101 receives MBMS data in step 415. As in step 310 of FIG. 3, the step 415 is for transmitting basic data for charging corresponding to the reception of the MBMS, and may be omitted depending on the charging system. In some cases, the service may be performed after the service is terminated.

In the above description, channel allocation according to MBMS has been described on the assumption that only one RAN and SGSN exist in the mobile communication system. However, it will be apparent that the mobile communication system is composed of a plurality of RANs and a plurality of SGSNs. In the following description, the transmission path setting in the case of applying the MBMS service to a plurality of RANs and a plurality of SGSNs will be described. Meanwhile, in the following description, Iu-Flex is introduced to divide a plurality of RANs into predetermined groups, and the predetermined groups are defined using the term CS pool-area or PS pool area.

5 illustrates a connection relationship between the RNC and the fixed network when the Iu-Flex is introduced. The path between the RNCs and the MSCs shown in FIG. 5 is for circuit-based services, and the path between the RNCs and SGSNs is for packet-based services. Considering the present invention relates to the transmission of multimedia data using the MBMS service, the following description focuses on the signaling transmission between the RNCs and the SGSNs.

Referring to FIG. 5, when the Iu-Flex concept is introduced, a plurality of RNCs may be connected to a fixed network through a plurality of SGSNs (or MSCs). A plurality of RNCs commonly managed by the plurality of SGSNs are called "PS pool-area", and a set of a plurality of RNCs commonly managed by the plurality of MSCs is called "CS pool-area". The devices in the same hierarchical position as the MSC and SGSN are referred to as CN (Core Network) nodes. Each SGSN (or MSCs) has a Network Resource Identifier (NRI), which is a unique identifier assigned to it, which becomes part of P-TMSI (or TMSI), which is a temporary identifier assigned to the UE. That is, when the RNCs need to establish a connection with the fixed network in order to provide any packet-based (or circuit-based) service to the UE, the RNCs are based on the NRI included in the P-TMSI (or TMSI) allocated to the UE. The connection between the RNCs and a specific SGSN (or between MSCs) is established. If the UE is not assigned a P-TMSI (or TMSI) as in the initial registration process, the RNC establishes a connection with any SGSN (or MSC) in consideration of the load of the SGSN (or MSC). The SGSN (or MSC) assigns the UE a P-TMSI (or TMSI) in the form of its NRI.

In the situation in which the Iu-Flex concept is introduced, when the channel setting scenario for MBMS data transmission in FIG. 3 and FIG. 4 described above is applied as it is, a path through which MBMS data is transmitted is duplicated in the same PS pool-area. That is, if any UEs belonging to the PS pool-area 2 in FIG. 5 select the same MBMS service and inform the corresponding SGSN, FIG. 6 according to the RNC to which the UE belongs and the type of the corresponding SGSN. 12 different transmission paths are possible.

As shown in FIG. 6, each of the RANs has a plurality of different paths corresponding to each of the plurality of SGSNs. For example, RAN node Area 2 is connected to each of SGSN 3, SGSN 4, and SGSN 5 by three different paths 601, 602, 603, and RAN node Area 3 is connected by three different paths 604, 605, 606. It is connected with each of SGSN 3, SGSN 4, and SGSN 5. In addition, the RAN node Area 6 is connected to each of the SGSN 3, the SGSN 4, and the SGSN 5 by three different paths 607, 608, 609, and the RAN node Area 7 has three different paths 610, 611, and 612. It is connected to each of the SGSN 3, SGSN 4, SGSN 5. Three different transmission paths 613, 614, 615 are connected between each of the SGSN 3, the SGSN 4, the SGSN 5, and the GGSN.

However, considering that the SGSN 3, the SGSN 4 and the SGSN 5 manage the same PS pool-area (RAN node Area2, RAN node Area3, RAN node Area 6, RAN node Area 7), the GGSN actually has only one SGSN. It can be seen that it is sufficient to create an MBMS data transmission path and the SGSN transmits the MBMS data to corresponding RNCs (RAN node Areas). In this example, the number of MBMS data paths actually required only needs to be four between the RAN node area and the SGSN and only one between the SGSN and the GGSN.

The present invention proposes a method for effectively creating a channel for providing an MBMS service even when the Iu-Flex concept is introduced in the MBMS service.

Embodiments for this purpose are divided into two types as follows.

(1) How RNC manages basic SGSN information

(2) How SGSN manages basic SGSN information

The default SGSN information (hereinafter, using the Def_SGSN_MBMS_sel variable) has a value corresponding to the identifier of the SGSN set as the default SGSN.

1. How RNC manages basic SGSN information

First, a method of effectively generating a transmission path for providing an MBMS service based on basic SGSN information will be described.

The following are items to be additionally defined compared to the case where Iu-Flex is not introduced in order for the RNC to manage basic SGSN information related to the MBMS service.

(1) The RNC shall store and manage the corresponding basic SGSN information for each MBMS service identifier and inform other SGSNs of the relevant information.

(2) The basic SGSN information is set when the UE selects the corresponding MBMS service and informs the RNC or other SGSNs inform the basic SGSN about the basic SGSN.

(3) The RNC manages the value corresponding to the identifier of the SGSN calculated from the P-TMSI of the UE as the default SGSN when the default SGSN related to the MBMS service selected by the UE is not set.

(4) The RNC stores the default SGSN value of MBMS received from other SGSNs.

(5) The SGSN set as the default SGSN for any MBMS shall be assigned to all RNCs belonging to the PS pool-area to the MBMS Service Identifier if it does not have information (TMGI, UE information, ...) about the MBMS Service. Report your identifier.

(6) When any MBMS service is terminated, the basic SGSN shall notify all RNCs in the PS pool-area of the termination of the service, and the RNCs that receive it delete the relevant information.

An example in which the signaling flow defined as shown in FIGS. 3 and 4 is redefined based on the added rule.

For convenience of description, a process of registering a specific MBMS service for the first time among UEs belonging to a certain PS pool-area, and after this process is successfully performed, other UEs belonging to the same PS pool-area may use the same MBMS service. The description will be divided into the case where it is selected.

FIG. 7 illustrates a process in which a first UE selects a specific MBMS service among UEs belonging to a certain PS pool-area. This is a procedure corresponding to steps 404 to 406 of FIG. 4. In FIG. 7, it is assumed that UE 1 is located in a region managed by RNC 1 (RAN node Area 1) and has P-TMSI allocated by SGSN 1 through an initial registration process. In addition, it is assumed that RNC 1, RNC 2 and RNC n belong to the same PS pool-area 701 and that SGSN 1, SGNS 2 and SGSN n 702 manage the PS pool-area jointly.

Referring to FIG. 7, UE 1 selects any MBMS that can be serviced after obtaining information on an MBMS service that can be serviced from a cell in which the current destination is located through a service acquisition step. When the random MBMS service is selected, the UE 1 notifies the RNC 1 to which it belongs in step 703 that the random MBMS is selected. At this time, UE 1 transmits its identifier (eg, P-TMSI) and the identifier of the selected MBMS to RNC 1. This corresponds to the procedure performed between the UE and the UTRAN in step 404 of FIG. 4 described above.

In response, the RNC 1 checks and changes basic SGSN information related to the selected MBMS service based on the information received from the UE 1 in step 704. As shown in FIG. 7, the signaling procedure assumes that the MBMS service is first selected from UE 1 in any PS pool-area, so that the Def_SGSN_MBMS_sel variable associated with the MBMS is not generated. Accordingly, the RNC 1 recognizing that there is no variable related to the MBMS selected by the UE 1 indicates an identifier of the SGSN corresponding to the NRI value obtained from the identifier (P-TMSI) value of the UE 1, and the value of the variable Def_SGSN_MBMS_sel. Set to. That is, in the case of Def_SGSN_MBMS_sel, a value for identifying the corresponding SGSN may be set to the same value as the ID_NNS (Intra Domain- NAS Node Selector) previously provided, or another constant value may be arbitrarily expressed in order to identify the basic SGSN. It can also be set by. In this example, the value of Def_SGSN_MBMS_sel is set to a value corresponding to the identifier of SGSN 1. If the value of Def_SGSN_MBMS_sel is successfully set, the RNC 1 may manage information as shown in Table 1 below for the MBMS service selected by the UE 1.

parameter value MBMS Service Identifier MBMS service identifier selected by UE ₁ Def_SGSN_MBMS_sel Identifier of SGSN ₁

The RNC 1 must manage the information shown in Table 1 for each MBMS.

When the setting of the desired information is completed by the above-described procedure, the RNC 1 transmits the MBMS service identifier selected by the UE 1 and the value 706 of the variable to the SGSN 1 in step 705. Of course, the identifier of the UE 1 should also be transmitted in consideration of authentication. This corresponds to a procedure in which UTRAN transmits a signal related to service registration to SGSN in step 404 of FIG. 4.

In step 707, the SGSN 1 authenticates the UE 1 based on information managed by the HLR. This is the same as step 405 of FIG. The SGSN 1 recognizes that the default SGSN for the MBMS service selected by the UE 1 is itself when the authentication for the UE 1 is successfully completed by the authentication process. When SGSN 1 recognizes that it is a basic SGSN corresponding to the selected MBMS, it confirms that it does not have the selected MBMS service related information, allocates a TMGI related to the selected MBMS service, and then requests the corresponding UE. Add the identifier of the UE 1 to the list of. In addition, the SGSN 1 notifies all RNCs (RNC 2 to RNC n) belonging to the same PS pool-area as the RNC 1 to the fact that it is set as the default SGSN for the MBMS service in step 708. In this case, the transmitted information includes an MBMS identifier selected by the UE 1. The SGSN 1 may also transmit Def_SGSN_MBMS_sel information received from the RNC 1 (reference numeral 709).

In response, the RNC 2 to the RNC n set a specific MBMS-related Def_SGSN_MBMS_sel variable in the same manner as the RNC 1 performs in step 704. In step 710, the RNC 2 to the RNC n inform the SGSN 1 of the specific MBMS-related Def_SGSN_MBMS_sel variable (reference number 711). This indicates a process of confirming that the SGSN 1 has been successfully registered as the default SGSN. When the above-described steps 708 and 710 are successfully performed, the RNCs 2 to RNC n may manage the same information as the <Table 1> managed by the RNC 1.

The SGSN 1 notifies that the MBMS selected by the UE 1 is successfully registered by transmitting the Def_SGSN_MBMS_sel to the RNC 1 in step 712, and the RNC 1 informs the UE 1 that the selected MBMS has been successfully registered in step 714. Notify. This is the procedure corresponding to step 406 of FIG. 4. As described above with reference to FIG. 4, a TMGI value may also be transmitted at this time.

Through the above process, the UE 1 completes the registration process for the selected specific MBMS service through the RNC 1 and the SGSN 1. Operations of the remaining steps, such as after step 408 of FIG. 4, will be described later. On the other hand, when comparing the signaling procedure shown in FIG. 4 and the signaling procedure implemented by introducing the Iu-Flex, it can be seen that a variable managed by the RNC is newly introduced. In addition, it can be seen that the process of creating and changing values of each variable (step 704) has been added to the RNC. Of course, an additional signaling transmission process (steps 708 to 711) has been introduced for this purpose, and in the same procedure as that of FIG. 4, information (reference numerals 706 and 711) to be additionally transmitted is also required.

Next, after UE 1 successfully completes the initial registration procedure for a specific MBMS, the process of the case that other UEs belonging to the same PS pool-area as UE 1 require registration of the same MBMS. For convenience of explanation, the following description will be divided into a process of registering an MBMS through SGSN 1 already set as the default SGSN and a process of registering the same MBMS through another SGSN.

First, if any UE belonging to the same PS pool-area as the UE 1 registers for the same MBMS as the MBMS provided to the UE 1 through another SGSN than the SGSN 1 as the default SGSN, An example is shown in FIG. 8. In the example of FIG. 8, it is assumed that UE 2 has P-TMSI allocated by SGSN 2.

Referring to FIG. 8, in step 803, the UE 2 selects the same MBMS as the UE 1, and requests the service of the selected MBMS to the RNC 2. At this time, the UE 2 transmits its identifier and the selected MBMS service identifier to the RNC 2. The RNC 2 determines in step 804 that the default SGSN corresponding to the selected MBMS service is set to SGSN 1 from the corresponding Def_SGSN_MBMS_sel variable managed by the initial registration procedure with respect to the MBMS selected by the UE 2. The RNC 2 confirming the basic SGSN confirms that a signaling connection should be set to SGSN 2 from the P-TMSI value of the UE 2. In addition, the RNC 2 transmits the selected MBMS service identifier and values of the State_MBMS_sel and Def_SGSN_MBMS_sel variables to the SGSN 2 together. The values of the transmitted variables are the same as in <Table 1>.

The SGSN 2 performs an authentication procedure of the UE 2 based on information managed by the HLR in step 807. In step 807, SGSN2 transmits the identifier of UE2 to SGSN1, which is the default SGSN, together with the identifier of the MBMS service selected by UE2. If authentication is performed for the UE 2 by the authentication procedure, the SGSN 2 determines that the SGNS 1, which is the default SGSN of the selected MBMS, includes the UE 2 in the UE list to receive the MBMS in step 808. TMGI (reference number 809) is informed to SGSN 2. The SGSN 1 newly registers the UE 2 in the UE list for which the selected MBMS is to be received, and then informs the SGSN 2 that the UE 2 has been registered in step 810. At this time, the identifier of the selected MBMS, the identifier of UE 2 and the TGMI (reference number 811) are transmitted together. The SGSN 2 notifies the RNC 2 that the registration of the selected MBMS service has been successfully performed in step 812, and the RNC 2 notifies the UE 2 that the selected MBMS service has been successfully registered in step 813.

When comparing the procedure described with reference to FIG. 8 with the case of FIG. 7, the SGSN 1 selected as the default SGSN is related to the MBMS service selected for all RNCs belonging to the PS pool-area. Instead of transmitting information (steps 708 to 711), it can be seen that a new step (steps 808 to 811) of transmitting UE information to SGSN 1, which is a basic SGSN, is added for charging.

Next, an example of a signaling procedure expected when any UE belonging to the same PS pool-area as the UE 1 registers for the same MBMS service as the MBMS service provided to the UE 1 through SGSN 1 which is a basic SGSN Is shown in FIG. 9. It can be seen that the signaling procedure shown in FIG. 9 is composed of some of the procedures described in FIG. That is, the signaling procedure shown in FIG. 9 corresponds to steps 703, 704, 705, 707, 712, and 714 of FIG. 7, and steps 708 and 710 are already performed by UE 1. Since this is a process performed in the registration process, it may be omitted. Meanwhile, in the case of FIG. 9, it is assumed that UE 3 belongs to RNC 1 and UE 4 belongs to RNC n, and UE 3 and UE 4 both have P-TMSI allocated by SGSN 1. If the procedure shown in the example shown in FIG. 9 is successfully performed, SGSN 1 selected as the default SGSN can know information about all UEs that want to receive the MBMS among the UEs belonging to the PS pool-area. A transmission path for specific MBMS data transmission may be set only between SGSN 1 and GGSN, which are SGSNs.

Referring to FIG. 9, UE 3 selects any MBMS service that can be serviced after obtaining information on an MBMS service that can be serviced from a cell in which the current receiver is located through a service acquisition step. If the selection of the arbitrary MBMS service is made, the UE 3 informs its RNC 1 that the random MBMS service is selected in step 901. At this time, UE 3 transmits its identifier (eg, P-TMSI) and the identifier of the selected MBMS to RNC 1.

In response, the RNC 1 checks and changes basic SGSN information related to the MBMS service selected in step 902 based on the information received from the UE 3. Recognizing that there is a variable associated with the MBMS service selected by the UE 3, the RNC 1 sets an NRI value obtained from the identifier (P-TMSI) value of the UE 3 to the value of the variable Def_SGSN_MBMS_sel. In this example, the value of Def_SGSN_MBMS_sel is set to a value corresponding to the identifier of SGSN 1. If the value of Def_SGSN_MBMS_sel is successfully set, the RNC 1 may manage the MBMS selected by the UE 3 in addition to the <Table 1>.

When the setting of the desired information is completed by the above-described procedure, the RNC 1 transmits the MBMS identifier selected by the UE 3 and the value of the variable (reference number 904) to the SGSN 1 in step 903. The SGSN 1 authenticates the UE 3 based on information managed by the HLR in step 905. The SGSN 1 recognizes that the default SGSN for the MBMS selected by the UE 3 is itself when the recognition of the UE 3 is successfully completed. When SGSN 1 recognizes that it is a basic SGSN in response to the selected MBMS, it confirms that it has the selected MBMS-related information, allocates a TMGI related to the selected MBMS, and then adds the TMGI to the list of UEs requesting the corresponding service. The identifier of the UE 3 is added. Meanwhile, the SGSN 1 notifies that the MBMS service selected by the UE 3 is successfully registered by transmitting the Def_SGSN_MBMS_sel to the RNC 1 in step 906, and the RNC 1 indicates that the selected MBMS service is successfully registered in step 908. The UE 3 is notified.

On the other hand, steps 909 to 916 for registering the MBMS service selected by the UE 4 will not be described in detail, but it will be apparent that the same procedure as in the above steps 901 to 908 is performed.

FIG. 10 illustrates a method of notifying when an actual MBMS service is provided to UEs that have registered for a specific MBMS service through the procedures shown in FIGS. 7 to 9. This corresponds to the signaling procedure corresponding to steps 408 and 409 of FIG. 4, which shows a control flow for a later serviceable MBMS service.

Referring to FIG. 10, step 1001 notifies the start of the service to SGSN 1 in which the GGSN is set as the default SGSN before the MBMS service selected by the UEs in FIGS. 7, 8, and 9 starts. How long before the start of the service is announced may be defined in the implementation of the embodiment of the present invention.

When SGSN 1 is notified of the start of the selected MBMS service from the GGSN, in steps 1002 to 1004, among the RNCs (RNC 1 to RNC n) belonging to the PS pool-area, the UEs requesting the reception of the corresponding MBMS are managed. RNCs are notified of the start of the MBMS. In this case, a paging massage, which is an existing RANAP message, may be used as an available message. Considering the possibility that the UE, which has selected the corresponding MBMS, moves to another cell, the call message may be transmitted to all RNCs belonging to the PS pool-area.

The RNCs receiving the call message should inform the relevant UEs of the start of the registered service, and the procedure for this is performed by steps 1005, 1008, and 1012. Possible messages for this step include paging type 1 or paging type 2. The choice of message type depends on the RRC state of the UE. UEs receiving the paging type 1 or paging type 2 message inform the RNC that they will actually receive the MBMS selected by them, and steps 1006, 1009 and 1013 correspond to this. At this time, a usable message is a paging response message.

In the case of UE 1, UE 3, and UE 4, since the P-TMSI is allocated from the SGSN 1, which is the default SGSN, each of the RNCs informs that the SGSN 1 actually wants to receive a service. This corresponds to steps 1007 and 1014. In the case of UE 2, RNC 2 should inform SGSN 2 that UE2 is actually served, and SGSN 2 should inform SGSN 1 again. This corresponds to steps 1010 and 1011. At this time, in step 1011, an MBMS identifier or TMGI and a UE identifier should be transmitted.

A channel for providing MBMS service is provided between UEs, RNCs (UTRANs), and SGSN 1, which is a basic SGSN, having successfully completed all the above-described steps, through steps 411, 412, 413, and 414 of FIG. Can be set.

11 is an expected procedure when the UE selects an MBMS service that is already provided in a certain PS pool-area. In this case, it can be seen that all RNCs included in the PS pool-area already have information on the basic SGSN for the MBMS service as all the steps shown in FIG. 10 are performed in FIG. 7. In the case of FIG. 11, UE 1 belongs to RNC 1 and it is assumed that SGSN 1 allocates P-TMSI. In addition, it is assumed that the basic SGSN of MBMS requested by UE 1 is set to Def_SGSN_MBMS_sel.

Referring to FIG. 11, UE 1 selects a service already provided in step 1101 and informs RNC 1 of this. The RNC 1 checks the MBMS-related Def_SGSN_MBMS_sel value selected by the UE 1 in step 1102. In this example, the value of Def_SGSN_MBMS_sel is a value meaning Def_SGSN. The RNC 1 determines that MBMS information selected by the UE 1 should be transmitted to the SGSN 1 from the P-TMSI value of the UE 1 in step 1103 and informs the SGSN 1 of this. Steps 1101, 1102, and 1103 described above correspond to step 304 of FIG.

In step 1104, the SGSN 1 performs an authentication procedure for authenticating the UE 1 based on information managed by the HLR. The authentication procedure corresponds to step 305 of FIG. The SGSN 1 notifies the MBMS identifier selected by the UE 1 and the identifier of the UE 1 to Def_SGSN set as the default SGSN in step 1105. In step 1106, the Def_SGSN includes UE 1 in a list of UEs receiving the MBMS service data (Multicast Group) and then notifies the SGSN 1. The SGSN 1 informs the RNC 1 that registration of the UE 1 has been completed successfully in step 1107. This is the procedure corresponding to step 306 of FIG.

If the RNC 1 is already providing the MBMS selected by the UE 1, that is, if other UEs belonging to the RNC 1 are already receiving the MBMS data, the RNC 1 receives the MBMS data. The necessary parameter may be transmitted in step 1109. However, if other RNCs belonging to the same PS pool-area as the RNC 1 are providing corresponding MBMS data, and there are no UEs receiving the corresponding MBMS data among the UEs belonging to the RNC 1, the Def_SGSN as described in step 1108 and the A procedure for setting a path for MBMS data transmission between RNC 1s is required.

Compared with the above-described procedure of FIG. 3, it can be seen that steps 1102, 1104, 1105, 1106, and 1108 are added. In addition, even in the step already defined in FIG. 3 as in step 1103, the value of the transmitted parameter is changed.

12 shows that when a specific MBMS service is terminated, corresponding basic SGSN related information managed by each RNC should be deleted. To this end, the basic SGSN transmits the identifier of the MBMS to all RNCs belonging to the PS pool-area, and all the RNCs receiving the information delete the information as shown in Table 1 above for the MBMS managed by the basic SGSN.

18 has the same assumptions as in the case of FIG. That is, it shows a process in which any one UE among the UEs belonging to a certain 'PS pool-area' first selects a specific MBMS service. However, this is an example in which information related to the MBMS selected by the UE is included in a non access stratum (NAS) message. The NAS message means that the RNC cannot know the contents included in the message. Meanwhile, for convenience of description, it is assumed that RNC1 and RNC2 belong to the same 'PS pool-area', and SGSN1 and SGSN2 manage RNCs belonging to the 'PS pool-area' together.

Referring to FIG. 18, the UE belonging to the RNC1 selects a specific MBMS service in step 1801 and informs the SGSN1 with its identifier. In this case, it is assumed that the UE has a P-TMSI allocated by the SGSN1. The MBMS service-related identifier and the own identifier for identifying the specific MBMS service selected by the UE may be delivered to the SGSN1 through an Activate MBMS Context Request message.

When SGSN1 receives the Activate MBMS Context Request message, it proceeds to step 1802 to verify whether the UE can receive the corresponding service. If the verification process is successfully performed, the SGSN1 transmits information such as an MBMS service-related identifier selected by the UE to the RNC1 in step 1803. In this case, information such as the selected MBMS service-related identifier may be delivered through a Request MBMS Join message. The RNC1 checks whether the basic SGSN for the MBMS service corresponding to the MBMS service related identifier is set based on the received information such as the MBMS service related identifier. If the default SGSN is not set, the RNC1 sets any SGSN as the default SGSN. In operation 1804, the UE identifier, the selected MBMS identifier, and the like are transmitted to the configured default SGSN through an MBMS Join Notification message. However, if a basic SGSN related to the already selected MBMS service is set, the UE and the selected MBMS identifier are notified to the corresponding basic SGSN. In FIG. 18, it is assumed that the set default SGSN is SGSN2. Herein, if the RNC does not set a default SGSN for a specific MBMS service, the method of configuring the RNC is related to the implementation. As the simplest method, as in the existing Iu Flex, a method of setting considering the load of SGSN may be used.

The basic SGSN sets up the selected MBMS service related information to all RNCs belonging to the same 'PS pool-area' as the RNC1 in step 1805 together with the selected MBMS service identifier as the default SGSN of the corresponding MBMS service. Notify However, if SGSN2 has already stored the MBMS service-related information, the UE proceeds to step 1809 after adding the UE identifier received in step 1804 to the MBMS service-related information.

Steps 1806 and 1808 indicate a process of establishing a channel for MBMS data transmission between SGSN2 and GGSN, which are basic SGSNs. This process is performed when the UE first selects the MBMS service in the PS pool-area managed by the SGSN2 in step 1801. On the other hand, when the channel setting request for transmission of the MBMS data is received from the SGSN2, the GGSN proceeds to step 1807 and transmits a Join IP Multicast message indicating that the relevant MBMS data should be transmitted to the MB-SC.

In step 1804, in step 1809, the SGSN2 allocates a TMGI related to the selected MBMS service and delivers the TMGI to the SGSN1 through an MBMS Context Create Notification message. SGSN1 delivers the TMGI received from SGSN2 to the UE in step 1810.

As described above, when another UE belonging to the same PS pool-area as the UE selects the same MBMS service, steps 1806, 1807, and 1808 may be omitted. On the other hand, in step 1804, the RNC (in this case, RNC1 or RNC2) informs the SGSN2 of the corresponding UE and the MBMS service identifier to the SGSN2 that is already set as the default SGSN.

2. How SGSN Manages Basic SGSN Information

Next, the SGSN manages the information as shown in Table 1 above. Similar to the case where the RNC manages the same information, the following should be additionally defined compared to the case where Iu-Flex is not introduced.

(1) SGSN shall additionally store and manage the corresponding basic SGSN information for each MBMS service identifier. For reference, even when Iu-Flex was not introduced, SGSN had to manage the list of UEs that want to receive data of TMGI and corresponding service for each MBMS service.

(2) The basic SGSN information may be set when the UE receives the MBMS service identifier selected by the UE from the RNC or receives information on the basic SGSN from another SGSN.

(3) The SGSN sets its identifier to the value of the default SGSN when the default SGSN associated with the MBMS service selected by any UE is not set. It also informs other SGSNs of their identifiers and corresponding MBMS service identifiers.

(4) The SGSN stores the information as shown in Table 1 by using the default SGSN value of MBMS data received from another SGSN.

(5) If any MBMS is terminated, the default SGSN transmits the identifier of the service to another SGSN co-managing the PS pool-area, and all SGSNs that receive it receive the <Table 1> above. Delete the same information.

An example in which the blurring of the signaling defined by FIGS. 3 and 4 is redefined based on the added rule. For convenience of description, a process of registering a specific MBMS service for the first time among UEs belonging to an arbitrary PS pool-area, and after the process is successfully performed, other UEs belonging to the same PS pool-area select the same MBMS. The explanation will be divided into cases.

FIG. 13 illustrates a process in which a first UE selects a specific MBMS service among UEs belonging to a certain PS pool-area. This is a procedure corresponding to step 406 in step 404 of FIG. 4, and is another example in the same situation as in the case of FIG. 7 described above. Meanwhile, in FIG. 12, it is assumed that UE 1 is in a region managed by RNC 1 (RAN node Area 1) and has P-TMSI allocated by SGSN 1 through an initial registration process. In addition, it is assumed that RNC 1, RNC 2 and RNC n belong to the same PS pool-area 1301, and SGSN 1, SGNS 2 and SGSN n 1302 jointly manage the PS pool-area 1301.

Referring to FIG. 13, UE 1 selects any MBMS service that can be serviced after obtaining information on an MBMS service that can be serviced from a cell in which the current receiver is located through a service acquisition step. When the selection of the random MBMS service is made, the UE 1 notifies the RNC 1 to which it belongs in step 1303 that the random MBMS service is selected, and the RNC 1 sends the corresponding message from the identifier of the UE 1 to the SGSN 1. Determine that it should be sent. The RNC 1 notifies the SGSN 1 of the message by the determination as described above. At this time, UE 1 transmits its identifier (eg, P-TMSI) and the identifier of the selected MBMS to SGSN 1. This corresponds to step 404 of FIG.

In response, the SGSN 1 authenticates the UE 1 based on information managed by the HLR in step 1304. This is the same as step 405 of FIG. The SGSN 1 recognizes that the default SGSN for the MBMS service selected by the UE 1 is itself when the authentication of the UE 1 is successfully completed by the authentication process. When SGSN 1 recognizes that it is a basic SGSN corresponding to the selected MBMS service, it confirms that it does not have the selected MBMS service related information, allocates a TMGI related to the selected MBMS service, and requests the corresponding service. Add the identifier of the UE 1 to the list of UEs. On the other hand, if the SGSN 1 is successfully completed by the above-described authentication process, in step 1305, the SGSN 1 checks and changes the basic SGSN information related to the selected MBMS service based on the information received from the UE 1. As the signaling procedure shown in FIG. 7 assumes an MBMS service selected first from UE 1 in an arbitrary PS pool-area, it can be seen that the Def_SGSN_MBMS_sel variable related to the MBMS service is not generated. Herein, the generation of the Def_SGSN_MBMS_sel variable may be generated in the same manner as in the first embodiment. That is, the information previously provided may be used as an identifier for identifying the basic SGSN, or a unique identifier for identifying the SGSN may be set using an arbitrary equation. Accordingly, when the MBMS Def_SGSN_MBMS_sel variable selected by the UE 1 recognizes that a variable related to generation is not present, the RNC 1 selects an identifier of an SGSN corresponding to an NRI value obtained from an identifier (P-TMSI) value of the UE 1. Set to the value of the variable Def_SGSN_MBMS_sel. In this example, the value of Def_SGSN_MBMS_sel is set to a value corresponding to the identifier of SGSN 1. If the value of Def_SGSN_MBMS_sel is successfully set, the SGSN 1 may manage information as shown in Table 2 below for the MBMS service selected by the UE 1.

parameter value MBMS Service Identifier MBMS service identifier selected by UE1 Def_SGSN_MBMS_sel Identifier of SGSN1 TMGI Assigned TMGI UE list UE identifier to receive service ... ...

Basic SGSNs set up corresponding to arbitrary MBMS services must manage the information shown in Table 2 for each MBMS service.

When the setting of the desired information is completed by the above-described procedure, the SGSN 1 transmits the MBMS service identifier selected by the UE 1 and the value 1307 of the variable to all SGSNs belonging to the same PS pool area in step 1306. . That is, the SGSN 1 notifies the remaining SGSNs (SGSN 2 to SGSN n) that it is set as the default SGSN in response to the corresponding MBMS service. In this case, the transmitted information may be not only the MBMS identifier but also an identifier of a basic SGSN (reference numeral 1307).

In response, SGSN 2 to SGSN n set a specific MBMS-related Def_SGSN_MBMS_sel variable in the same manner as that performed by SGSN 1 in step 1305. The SGSN 2 to the SGSN n inform the SGSN 1 of the specific MBMS service-related Def_SGSN_MBMS_sel variable (reference number 1309) set in step 1308. This indicates a process of confirming that the SGSN 1 has been successfully registered as the default SGSN. When the above steps 1306 and 1308 are successfully performed, the SGSN 2 to SGSN n may manage the same information as the <Table 2> managed by the SGSN 1.

The SGSN 1 notifies that the MBMS service selected by the UE 1 is successfully registered by transmitting Def_SGSN_MBMS_sel to the RNC 1 in step 1310. In response, the RNC 1 indicates that the selected MBMS service has been successfully registered. Notify 1 This is the procedure corresponding to step 406 of FIG. 4. As described above with reference to FIG. 4, a TMGI value may also be transmitted at this time.

Through the above process, the UE 1 completes the registration process for the selected specific MBMS service through the RNC 1 and the SGSN 1. On the other hand, when comparing the signaling procedure shown in FIG. 4 with the signaling procedure implemented by introducing the Iu-Flex, it can be seen that a variable managed by SGSN is newly introduced. Also, it can be seen that processes (steps 1305 and 1308) of generating and changing values of each variable have been added to the RNC. Of course, it can be seen that an additional signaling transmission process (steps 1306 to 1309) has also been introduced.

Next, after UE 1 successfully completes the initial registration procedure for a particular MBMS service, a process in which other UEs belonging to the same PS pool-area as UE 1 requests registration of the same MBMS service will be described. For convenience of explanation, the following description will be divided into a process of registering an MBMS service through SGSN 1 set as the default SGSN and a process of registering the same MBMS through another SGSN.

First, a signaling expected when any UE belonging to the same PS pool-area as the UE 1 registers for the same MBMS service as the MBMS service provided to the UE 1 through another SGSN other than the SGSN 1 which is the default SGSN. An example of the procedure is shown in FIG. 8. In the example of FIG. 8, it is assumed that UE 2 has P-TMSI allocated by SGSN 2.

Referring to FIG. 14, in step 1403, the UE 2 selects the same MBMS service as the UE 1 and informs the RNC 2 of the request, and the RNC 2 notifies the SGSN 2 again. In this case, the UE 2 transmits its identifier and the selected MBMS service identifier together. The SGSN 2 performs an authentication procedure for authentication of the UE 2 based on information managed by the HLR in step 1404. When authentication is performed for the UE 2 by the authentication procedure, the SGSN 2 may determine that the value of the Def_SGSN_MBMS_sel variable is set to SGSN 1 in relation to the MBMS service selected by the UE 2 in step 1405. The SGSN 2 transmits the identifier of the UE 2 to SGSN 1, which is the default SGSN, together with the service identifier of the MBMS selected by the UE 2 in step 1406. In step 1408, the SGSN 1 includes the UE 2 in a list of UEs to which the MBMS service data is to be received, and informs the SGSN 2 of the corresponding TMGI. The SGSN 2 notifies the UE 2 of successful registration for the selected MBMS service through step 1410.

FIG. 15 is a signaling procedure that is expected when another UEs belonging to the same PS pool-area as UE 1 continue to request registration for the same MBMS service through SGSN 1 which is a basic SGSN. In the case of FIG. 9, it is assumed that UE 3 belongs to RNC 1 and UE 4 belongs to RNC n. In addition, it is assumed that the UE 3 and the UE 4 both have a P-TMSI allocated in SGSN 1. The signaling procedure shown in FIG. 15 is the same as the signaling procedure in FIG. 4 described above except for steps 1503 and 1505 and 1510.

Referring to FIG. 15, SGSN 1 confirms that it has already been set as the default SGSN in relation to the MBMS service selected by UE 3 (UE 4) in step 1503 (step 1508). Then, the UE3 (UE4) is added to the list of UEs to which the MBMS service data is to be received. Meanwhile, SGSN 1 means that Def_SGSN_MBMS_sel value is transmitted to RNC 1 (RNC n) in step 1505 (step 1510), but this may be omitted.

13, 14, and 15 when the procedure shown in the example of FIG. 15 is successfully performed, SGSN 1 selected as the default SGSN for all UEs that want to receive corresponding MBMS service data among UEs belonging to the PS pool-area Since the information can be known, a channel for specific MBMS data transmission can be set only between SGSN1 and GGSN, which are basic SGSNs.

The method of notifying the actual MBMS service is provided to UEs that have registered for a specific MBMS service through the procedures shown in FIGS. 13, 14, and 15 follows the signaling procedure of FIG. 10 as it is.

FIG. 16 illustrates a channel generation procedure expected when the UE selects an MBMS that is already provided in a certain PS pool-area. In this case, it can be seen that all SGSNs jointly managing the same PS pool-area already have information on the basic SGSN for the MBMS while performing the processes of FIG. 13 to FIG. 15. On the other hand, if the Iu-Flex is not applied when applying for the service already provided the procedure is given in FIG. In the case of FIG. 16, it is assumed that UE 1 belongs to RNC 1 and SGSN 1 allocates P-TMSI. In addition, it is assumed that the basic SGSN of the MBMS service requested by UE 1 is set to Def_SGSN.

Referring to FIG. 16, the UE 1 selects an MBMS that is already in service in step 1601 and informs RNC 1 of this. The RNC 1 determines that MBMS service related information selected by the UE 1 should be transmitted to the SGSN 1 from the P-TMSI value of the UE 1, and informs the SGSN 1 of this. The SGSN 1 performs an authentication procedure for authenticating the UE 1 based on information managed by the HLR in step 1602. The authentication procedure corresponds to step 305 of FIG. The SGSN 1 checks the Def_SGSN_MBMS_sel value related to the MBMS service selected by the UE 1 in step 1603. In this example, the value of Def_SGSN_MBMS_sel is a value meaning Def_SGSN. In step 1604, the SGSN 1 informs the MBMS service identifier selected by the UE 1 and the identifier of the UE 1 to Def_SGSN set as the default SGSN. The Def_SGSN includes the UE 1 in the list of UEs receiving the MBMS service data in step 1605 and informs the SGSN 1 of this. The SGSN 1 informs the RNC 1 that registration of the UE 1 has been completed successfully in step 1606. This is the procedure corresponding to step 306 of FIG.

If the RNC 1 is already providing the MBMS service selected by the UE 1, that is, if other UEs belonging to the RNC 1 are already receiving the MBMS service, the RNC 1 transmits the MBMS service data. The parameter required for receiving may be transmitted in step 1608 (step 1607 may be omitted). However, if other RNCs belonging to the same PS pool-area as the RNC 1 are providing the MBMS service, and there are no UEs receiving the MBMS service among the UEs belonging to the RNC 1, the Def_SGSN and the RNC 1 as in step 1607. A procedure for preparing a channel for MBMS data transmission is needed.

FIG. 17 shows that corresponding SGSN related information such as <Table 2> managed by each SGSN should be deleted when a specific MBMS service is terminated. For this purpose, the basic SGSN transmits the service identifier of the MBMS to all SGSNs that jointly manage the same PS pool-area, and all SGSNs receiving the same are shown in Table 2 above for the MBMS they are managing. Delete all the information.

Therefore, the above embodiments are equally applicable to the CS-Pool, and accordingly, even if it is not an MBMS service, the RNC according to a data reception request from a UE belonging to the same pool may set the SGSN or the MSC in the default SGSN or MSC. It is of course possible to set the transmission path through the basic MSC to transmit and receive the data. In addition, the above embodiment describes only the embodiments of the management method in the RNC and SGSN, it is a matter of course that the transmission path management between the RNC and SGSN of the MBMS service can also be implemented through the HLR. Even in the case of a service in a fixed network, the data transmission path can be managed for each service.

FIG. 19 illustrates a flow of services that may occur when UEs select a specific MBMS service while the corresponding SGSN is set and the MBMS data starts to be transmitted after the UE selects a specific MBMS service. This is another example.

The MB-SC transmits the relevant MBMS data to the GGSN after scheduling in step 1901. Meanwhile, the GGSN transmits the MBMS data back to SGSN2, which is the corresponding default SGSN.

When SGSN2 receives the MBMS data, the SGSN2 proceeds to step 1902 to notify relevant RNCs that the MBMS service is actually started. Each RNC responding to the UE informs each UE that the MBMS service is actually started in step 1903. In this case, the related RNC may be an RNC including UEs that select a corresponding MBMS service or all RNCs included in a service area.

The RNCs inform SGSN2 through an MBMS Service Request message that it will actually receive MBMS data in step 1904. On the other hand, the RNCs and SGSN2 establish a channel for MBMS data transmission in steps 1905 and 1906.

If the channel for MBMS data transmission is established through the above steps, UEs notified of the start of the MBMS service selected by the UE in step 1903 will proceed to step 1907 so that they will actually receive the MBMS service. The RNCs will be informed of the need. The step 1907 may be implemented to be performed before the step 1904. Each of the RNCs informs the channel related information for actually delivering the MBMS data to the UE in step 1908.

Meanwhile, the SGSN2 delivers the corresponding MBMS data to the RNC1 in step 1909, and the RNC1 delivers the corresponding MBMS data received from the SGSN2 to the UE in step 1910. If there is no MBMS data to be transmitted anymore, the RNC1 releases the channel by requesting release of a channel currently configured to the UE through step 1911.

As described above, the present invention provides one path between RNC and SGSN, and one SGSN and GGSN per PS pool-area for the same MBMS data transmission even when the MBMS data transmission path is set in the situation in which the Iu-Flex concept is introduced. Since only one path is generated between them, it is effective to efficiently use wired / wireless resources for supporting the MBMS service.

Claims (16)

In the mobile communication system, at least two radio network controllers are designated as a group, SGSNs corresponding to the radio network controllers designated as the group are designated as a separate group, and data is received by the radio network controllers designated as the group. In the method for setting a channel for receiving the data for at least one mobile terminal, When a new multicast multimedia broadcasting service is requested from a mobile terminal, a basic SGSN corresponding to the mobile terminal is determined among the SGSNs assigned to the group, and the basic SGSN is used for the new multicast multimedia broadcasting service. To manage the information, When the multicast multimedia broadcasting service is requested from another mobile terminal, setting the same channel as the arbitrary mobile terminal for the other mobile terminal based on information managed for the multicast multimedia broadcasting service. Characterized in that the method. The method as claimed in claim 1, wherein the basic SGSN is determined corresponding to a radio resource identifier obtained by an identifier of the mobile terminal and an identifier of the new multicast multimedia broadcasting service. 2. The method of claim 1, wherein the default SGSN sets itself as the reference SGSN for the new multicast multimedia broadcast service by transmitting its identifier and the new multicast multimedia broadcast service identifier to all SGSNs assigned to the same group. The method of claim 1 further comprising the step of notifying. The method of claim 1, wherein the information for the new multicast multimedia broadcasting service comprises: an identifier of the new multicast multimedia broadcasting service, an identifier of the basic SGSN, and an identifier of at least one mobile terminal to provide the new multicast multimedia broadcasting service. The method characterized in that. The method as claimed in claim 1, further comprising: registering an identifier of the other mobile terminal as information for the new multicast multimedia broadcasting service. The method of claim 1, wherein the basic SGSN registers the identifier of the other mobile terminal corresponding to the identifier of the multicast multimedia broadcasting service if the identifier of the multicast multimedia broadcasting service requested from the other mobile terminal is already managed. Characterized in that the method. The method as claimed in claim 1, wherein the basic SGSN includes transmitting data of the registered multicast multimedia broadcasting service to the registered at least one mobile terminal through the set channel. 8. The method of claim 7, wherein, when data of a specific multicast multimedia broadcasting service is provided from a data source, the basic SGSN is connected to the specific multicast multimedia broadcasting service through at least one related wireless network controller to provide the specific multicast multimedia broadcasting service. And informing the corresponding mobile stations that the specific multicast multimedia broadcasting service has actually started. The method as claimed in claim 8, wherein the registered mobile stations include the step of notifying the reference SGSN that the specific multicast multimedia broadcasting service is actually received. In the mobile communication system, at least two radio network controllers are designated as a group, SGSNs corresponding to the radio network controllers designated as the group are designated as a separate group, and data is received by the radio network controllers designated as the group. In the method for setting a channel for receiving the data for at least one mobile terminal, When a new multicast multimedia broadcasting service is requested from a mobile station, a base SGSN corresponding to the mobile station is determined among the SGSNs assigned to the group, and corresponding to the base SGSN among the wireless network controllers assigned to the group. Managing information for the new multicast multimedia broadcasting service by a wireless network controller; When the multicast multimedia broadcasting service is requested from another mobile terminal, setting the same channel as the arbitrary mobile terminal for the other mobile terminal based on information managed for the multicast multimedia broadcasting service. Characterized in that the method. The method as claimed in claim 10, wherein the basic SGSN is determined in correspondence with a radio resource identifier obtained by an identifier of the mobile terminal and an identifier of the new multicast multimedia broadcasting service. The reference SGSN of claim 10, wherein the basic SGSN transmits the new multicast multimedia broadcasting service identifier to wireless network controllers belonging to the same group as the corresponding wireless network controller. The method further comprises the step of notifying that the set. The method as claimed in claim 10, wherein the information for the new multicast multimedia broadcasting service is an identifier of the mobile terminal and an identifier of the basic SGSN. The method as claimed in claim 10, further comprising registering the identifier of the other mobile terminal as information for the new multicast multimedia broadcasting service. 11. The method of claim 10, wherein the wireless network controller corresponding to the basic SGSN, if the identifier of the multicast multimedia broadcasting service requested from the other mobile terminal is already managed, the identifier of the other mobile terminal of the multicast multimedia broadcasting service; And registering in correspondence with an identifier. In the mobile communication system, at least two radio network controllers are designated as a group, SGSNs corresponding to the radio network controllers designated as the group are designated as a separate group, and data is received by the radio network controllers designated as the group. In the method for setting a channel for receiving the data for at least one mobile terminal, When a mobile station requests a multicast multimedia broadcasting service to any one of the SGSNs, the SGSN transmits an identifier of the multicast multimedia broadcasting service to a wireless network controller to which the mobile terminal belongs. and, The wireless network controller checking whether a reference SGSN corresponding to the multicast multimedia broadcasting service exists by an identifier of the multicast multimedia broadcasting service; If the reference SGSN does not exist, setting any of the SGSNs as a default SGSN and transmitting the identifier of the mobile terminal and the identifier of the multicast multimedia broadcasting service to the reference SGSN; Transmitting the identifier of the mobile station and the identifier of the multicast multimedia broadcasting service to the reference SGSN when the reference SGSN exists; The reference SGSN includes the step of notifying all wireless network controllers assigned to the same group as the wireless network controller and the identifier of the multicast multimedia broadcasting service and that the reference SGSN is set as the reference SGSN.