JP2014232909A - Multicast communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a multicast communication system capable of performing appropriate multicast service operation.SOLUTION: A multicast communication system 10 comprises a plurality of terminals 12, a base station 14 wirelessly connected to the terminal 12, an ASNGW 16, a multicast router 18 for performing multicast distribution to the terminal 12, and a Mcbcs server 24. The ASNGW 16 includes a Mcbcs Proxy 30 which performs joining processing (Join) for allowing the terminal 12 to join a multicast service for the multicast distribution and leaving processing (Leave) for allowing the terminal 12 to leave from the multicast service. The joining processing and the leaving processing have a plurality of transactions respectively.

Description

  The present invention relates to a multicast communication system that performs multicast distribution in a multicast service using WiMAX.

  As a next-generation high-speed mobile communication system, WiMAX (Worldwide Interoperability for Microwave Access) has attracted international attention, and a plurality of network service providers provide services using this WiMAX communication system.

  As a standard technology for providing a multicast service in WiMAX, Mcbcs (Multicast and Broadcast Services) is known. (Refer nonpatent literature 1).

WiMAX FORUM “WiMAX Forum Network Architecture” WMF-T33-112-R015v01 November 21, 2009

  However, the standard technique described in Non-Patent Document 1 does not fully consider the cooperation with the IP multicast protocol for Mcbcs, and cannot implement an appropriate multicast service.

  In the multicast service, a process for joining the multicast service (Join) and a process for leaving the multicast service (Leave) are performed. These joining / leaving processes need to be performed for many terminals and may be performed in a congested manner. If this congestion processing becomes enormous, the CPU load in the system will increase and processing delay will occur, Join and Leave processing may time out, and join / leave processing may not be performed properly. Further, a similar problem occurs when a plurality of multicast services are performed for a specific terminal.

  The present invention has been made in consideration of the above-described problems, and an object of the present invention is to provide a multicast communication system capable of appropriately distributing loads for joining and leaving processing and performing equal control on terminals. .

  A multicast communication system according to the present invention includes a plurality of terminals, a base station wirelessly connected to the terminals, an ASNGW (Access Service Network Gateway), a multicast router for multicast delivery to the terminals, and Mcbcs (Multicast and Broadcast). Service) server, wherein the ASNGW performs a join process in which the terminal participates in the multicast service for the multicast distribution and a leave process in which the terminal leaves the multicast service. The joining process and the leaving process each have a plurality of transactions. The McbcsProxy is a JOIN state that is a processing state for the terminal to participate in the multicast service, and the terminal In the JOIN state and the LEAVE state, there are a LEAVE state that is a processing state for leaving the service, and a READY state that is a standby state for the transaction for transitioning to the JOIN state or the LEAVE state. Each transaction is processed for another terminal after processing for one terminal.

  In the multicast communication system, the McbcsProxy determines whether the initiative source is the terminal, the ASNGW, or the Mcbcs server from the transmission source of the transaction message.

  According to the multicast communication system, in JOIN_ST and LEAVE_ST, each transaction is processed for one terminal after processing for one terminal, so that load distribution for joining and leaving processing can be appropriately performed. It is possible to control the terminals equally.

It is explanatory drawing of the multicast communication system which concerns on 1st Embodiment of this invention. It is explanatory drawing of the participation procedure of MS initiative IPv6 multicast. It is explanatory drawing of the leaving procedure of MS initiative IPv6 multicast. It is explanatory drawing of the participation procedure of BS and ASNGW initiative IPv6 multicast. It is explanatory drawing of the leaving procedure of BS and ASNGW initiative IPv6 multicast. It is explanatory drawing of the participation procedure of McbcsSvr initiative IPv6 multicast. It is explanatory drawing of the withdrawal procedure of McbcsSvr initiative IPv6 multicast. It is explanatory drawing of the multicast communication system which concerns on 2nd Embodiment of this invention. It is explanatory drawing of the participation procedure of MS initiative IPv4 multicast. It is explanatory drawing of the leaving procedure of MS initiative IPv4 multicast. It is explanatory drawing of the participation procedure of BS and ASNGW initiative IPv4 multicast. It is explanatory drawing of the leaving procedure of BS * ASNGW initiative IPv4 multicast. It is explanatory drawing of the participation procedure of McbcsSvr initiative IPv4 multicast. It is explanatory drawing of the withdrawal procedure of McbcsSvr initiative IPv4 multicast. It is explanatory drawing of the process sequence in case the version of IGMP differs. It is explanatory drawing of the state transition diagram for every terminal. It is explanatory drawing of the state transition diagram of JOIN_ST. It is explanatory drawing of the state transition diagram of LEAVE_ST.

<First Embodiment>
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings. FIG. 1 is an explanatory diagram of a multicast communication system according to the first embodiment.

  The multicast communication system 10 includes terminals (MS) 12a to 12d, such as computers and mobile phones having communication functions, a base station 14 to which the terminals 12a to 12d are wirelessly connected, an ASNGW (Access Service Network Gateway) 16, A multicast router 18, a Pdb 20, a Radius server (Radius Svr) 22, and an Mcbcs server (Mcbcs Svr) 24 are provided. The Pdb 20, the Radius server 22, and the Mcbcs server 24 are connected to the network 36 that is a public line, and are connected to the ASNGW 16 via the multicast router 18.

  The ASNGW 16 includes a Pf router (Pfmif) 26, an Mld (Multicast Listener Discovery) Proxy 28, an Mcbcs Proxy 30, an Mbs service flow control unit (SFA: Service Flow Agent) 32, and a Gdb 34. The MldProxy 28 relays control packets related to the Mld (Multicast Listener Discovery) protocol. McbcsProxy30 performs management, control, relay, etc. of the multicast service. The Mbs service flow control unit 32 is a control unit that performs processing related to a service flow. Also, the Mbs service flow control unit 32 includes a movement control unit 32a (not shown). The movement control unit 32a performs processing related to handover and paging control, and transmits MBS_JOIN and MBS_LEAVE which are control messages. The Gdb 34 is a database that manages registration, update, deletion, etc. of information related to multicast.

  The Radius server 22 is a server that performs terminal authentication and billing information collection / management.

<Description of Operation of Invention According to First Embodiment>
Next, the operation of the multicast communication system 10 will be described with reference to FIGS.

<Operation of Join led by IPv6 terminal>
The participation procedure (Join) to the IPv6 multicast service led by the terminal 12a will be described with reference to FIG. FIG. 2 is an explanatory diagram of the MS-initiated IPv6 multicast participation procedure. Hereinafter, each step means a transaction.

  First, as an initial setting, a multicast service availability process is performed between the Radius server 22 and the McbcsProxy 30. That is, the Radius server 22 transmits information (Access-Accept) about the availability of the multicast service of the terminal 12a to the McbcsProxy 30 (step MSJS1).

  Notification processing of a request for participation in the multicast service by the terminal 12a is performed. That is, the terminal 12a transmits a request for participation in the multicast service (MLD Report) to the MldProxy 28 by the MLD protocol via the base station 14 (step MSJS2). Based on the MLD Report, the MldProxy 28 transmits a request for participation of the terminal 12a (MBS_JOIN) to the McbcsProxy 30 (step MSJS3). When this MBS_JOIN is transmitted, the MAC address, multicast group address, source address information, etc. of the terminal 12a are also transmitted simultaneously.

  Participation registration processing for the multicast service of the terminal 12a is performed. That is, the McbcsProxy 30 transmits a request for participation of the terminal 12a (Access-Request) to the Mcbcs server 24 via the Radius server 22 (step MSJS4). In the Mcbcs server 24, participation registration processing for the multicast service of the terminal 12a is performed. When transmitting this Access-Request, the MAC address of the terminal 12a, the multicast group address, the source address, the IP address of the base station 14 and the like are also transmitted simultaneously. The Mcbcs server 24 collates and approves the request for participation of the terminal 12a, and, through the Radius server 22, includes the SF (Service Flow) ID in the Mcbcs Proxy 30 and indicates permission to participate in the multicast service (Access- Accept) is transmitted (step MSJS5). In this multicast service participation registration process, a timer is set, and if this process is not completed within a predetermined time, the processes of steps MSJS4 and MSJS5 are performed again.

  In order to perform multicast distribution to the terminal 12a, setting processing of a service flow generated for each content that is a target of the multicast service is performed. That is, the McbcsProxy 30 transmits a service flow generation request (SFA_MBS_JOIN) to the Mbs service flow control unit 32 (step MSJS6). This service flow is generated for each content subject to multicast service.

  The Mbs service flow control unit 32 requests an SF profile for generating a service flow from the Pdb 20 (step MSJS7). The Pdb 20 generates an SF profile corresponding to the SFID, and transmits it to the Mbs service flow control unit 32 (step MSJS8).

  The Mbs service flow control unit 32 transmits to the base station 14 that a service flow is generated based on the SF profile (RR_REQ) (step MSJS9). The base station 14 transmits a message (DSA_NOTI) to add a service flow to the Mbs service flow control unit 32 (step MSJS10). The Mbs service flow control unit 32 transmits to the base station 14 that the service flow is shared (BIND_MC_SF) (step MSJS11). Thereby, a plurality of service flows can be handled as a bundle (BIND).

  The base station 14 transmits a service flow generation request (DSA-Req) to the terminal 12a. (Step MSJS12). After the service flow is generated between the terminal 12a and the base station 14, the base station 14 transmits to the terminal 12a that the generation of the service flow has been completed (DSA-Rsp) (step MSJS13). The base station 14 transmits to the terminal 12a that the service flow generation procedure has been completed (DSA-Ack). (Step MSJS14).

  The base station 14 transmits to the Mbs service flow control unit 32 that the service flow has been generated (BIND_MC_SF_NOTI) (step MSJS15). The Mbs service flow control unit 32 transmits to the McbcsProxy 30 that the service flow for the terminal 12a has been generated (SFA_MBS_JOIN) (step MSJS16).

  If the service flow setting process for multicast delivery in steps MSJS6 to MSJS16 is not completed within a predetermined time, the process is stopped and the process is restarted from the service flow generation request process in step MSJS6. The

  Routing setting in the ASNGW 16 for multicast distribution to the terminal 12a is performed. That is, the McbcsProxy 30 performs routing setting with the Pf router 26 (step MSJS17).

  Processing related to the routing setting of the multicast router 18 for multicast distribution to the terminal 12a is performed. That is, McbcsProxy30 transmits a message (MldProxySndRpt) to MldProxy28 to request transmission of MLD Report (step MSJS18). The MldProxy 28 transmits an MLD Report to the multicast router 18 (step MSJS19). Further, the MldProxy 28 transmits a message (MldProxySndRpt (Success)) indicating that the MLD Report has been transmitted to the McbcsProxy 30 (step MSJS20).

  Information registration processing for multicast distribution to the terminal 12a is performed. In other words, McbcsProxy30 transmits a message indicating that multicast distribution information is registered in Gdb34 (step MSJS21). Further, after registering the multicast information, Gdb 34 transmits information indicating that the multicast information has been registered in McbcsProxy 30 (step MSJS22). The multicast information to be registered includes the MAC address, group address, source address, etc. of the terminal 12a.

  After the above processing, multicast is distributed to the terminal 12a. Steps MSJS7 and MSJS8 are performed only for the terminal 12a, which is the first receiving terminal of multicast, and when the terminal 12b, which is a terminal other than the terminal 12a, uses the multicast service by the same service flow. Not done. Further, step MSJS17 is not performed after the routing related to the terminal 12a is set. Further, steps MSJS18 to MSJS20 are not performed after the service flow for the terminal 12a is generated.

<Leave operation led by IPv6 terminal>
A procedure (Leave) for leaving the IPv6 multicast service led by the terminal 12a will be described with reference to FIG. FIG. 3 is an explanatory diagram of the procedure for leaving the MS-led IPv6 multicast.

  First, the terminal 12a is notified of a withdrawal request from the multicast service. That is, the terminal 12a transmits a request for leaving the multicast service (MLD Report) to the MldProxy 28 via the base station 14 by the MLD protocol (step MSLS1). Based on the MLD Report, the MldProxy 28 transmits a request for leaving the terminal 12a (MBS_LEAVE) to the McbcsProxy 30 (step MSLS2). When this MBS_LEAVE is transmitted, the MAC address, multicast group address, source address information, etc. of the terminal 12a are also transmitted simultaneously.

  A process for verifying and approving a withdrawal request from the multicast service of the terminal 12a is performed. That is, the McbcsProxy 30 transmits a request for leaving the terminal 12a (Access-Request) to the Mcbcs server 24 via the Radius server 22 (step MSLS3). When transmitting this Access-Request, the MAC address of the terminal 12a, the multicast group address, the source address, the IP address of the base station 14 and the like are also transmitted simultaneously. The Mcbcs server 24 collates and approves the request for leaving the terminal 12a, and transmits an acknowledgment (access-accept) of the multicast service to the Mcbcs Proxy 30 via the radius server 22 (step MSLS4).

  Routing setting in the ASNGW 16 for stopping the multicast distribution to the terminal 12a is performed. That is, the McbcsProxy 30 performs routing setting with the Pf router 26 (step MSLS5).

  Processing related to the routing setting of the multicast router 18 for canceling multicast distribution to the terminal 12a is performed. That is, McbcsProxy30 transmits a message (MldProxySndDone) requesting MldProxy28 to transmit an MLD Report (step MSLS6). The MldProxy 28 transmits a message (MLDv2Done) to request the multicast distribution stop to the multicast router 18 (step MSLS7). Further, the MldProxy 28 transmits a message (MldProxySndRpt (Success)) indicating that the MLD Report has been transmitted to the McbcsProxy 30 (step MSLS8).

  A service flow setting process for canceling multicast distribution to the terminal 12a is performed. That is, the McbcsProxy 30 transmits a message to delete the service flow (SFA_MBS_LEAVE) to the Mbs service flow control unit 32 (step MSLS9). The Mbs service flow control unit 32 transmits a message (UNBIND_MC_SF) to cancel sharing of the service flow to the base station 14 (step MSLS10).

  The base station 14 transmits to the terminal 12a a message to delete the service flow (DSD-Req) (step MSLS11). The terminal 12a transmits to the base station 14 that the service flow has been deleted (DSD-Rsp) (step MSLS12).

  After canceling the sharing of the service flow, the base station 14 transmits a message (UNBIND_MC_SF_NOTI) indicating that the sharing of the service flow has been canceled to the Mbs service flow control unit 32 (step MSLS13). The Mbs service flow control unit 32 transmits to the base station 14 a message to delete the service flow (SF_DELETE) (step MSLS14). The base station 14 transmits a message (DSD_NOTI) indicating that the service flow has been deleted to the Mbs service flow control unit 32 (step MSLS15). The Mbs service flow control unit 32 transmits to the McbcsProxy 30 that the service flow for the terminal 12a has been deleted (SFA_MBS_LEAVE_OK) (step MSJS16).

  Information registration processing for canceling multicast distribution to the terminal 12a is performed. That is, McbcsProxy30 transmits to Gdb34 that multicast distribution information is to be deleted (step MSLS17). The Gdb 34 deletes the multicast distribution information to the McbcsProxy 30, and then transmits a message to the effect that it has been deleted (step MSLS18). The multicast information to be deleted is the MAC address, group address, source address, etc. of the terminal 12a.

  With the above processing, the terminal 12a is completely disconnected from the multicast. Steps MSLS5 to MSLS8, MSLS14, and MSLS15 are performed only when the terminal 12a is the last one that leaves the multicast service.

<Operation of Join led by IPv6BS and ASNGW>
The participation procedure (Join) to the IPv6 multicast service led by the base station 14 and the ASNGW 16 will be described with reference to FIG. FIG. 4 is an explanatory diagram of a participation procedure of BS and ASNGW-led IPv6 multicast.

  First, as an initial setting, the Radius server 22 transmits information (Access-Accept) about availability of the multicast transmission / reception service of the terminal 12a to the McbcsProxy 30 (step BSJS1).

  Next, notification processing of a request to join the terminal 12a to the multicast service by the ASNGW 16 is performed. That is, the Mbs service flow control unit 32 transmits to the McbcsProxy 30 a message indicating that the terminal 12a participates in the multicast service under the initiative of the ASNGW 16 (MBS_JOIN) (step BSJS2). Step BSJS3 is a missing number.

  Steps BSJS4 and BSJS5, which are the registration process for joining the terminal 12a to the multicast service, are processed in the same manner as the steps BSJS4 and BSJS5 in the terminal-led participation process described above.

  Steps BSJS6 to BSJS16, which are service flow setting processes for multicast delivery to terminal 12a, are processed in the same manner as steps MSJS6 to MSJS16 described above.

  Step BSJS17, which is a routing setting in ASNGW 16 for multicast distribution to terminal 12a, is processed in the same manner as step MSJS17 described above.

  Steps BSJS18 to BSJS20, which are processing related to the routing setting of the multicast router 18 for multicast distribution to the terminal 12a, are processed in the same manner as the above-described steps MSJS18 to MSJS20.

  Steps BSJS21 and BSJS2, which are information registration processing for multicast distribution to the terminal 12a, are processed in the same manner as steps MSJS21 and MSJS22 described above.

  The McbcsProxy 30 transmits to the Mbs service flow control unit 32 that the terminal 12a participation processing for the multicast service is completed (MBS_JOIN_OK) (step BSJS23). After the above processing, multicast distribution is performed to the terminal 12a.

<Leave operation led by IPv6BS and ASNGW>
A procedure (Leave) for leaving the IPv6 multicast service led by the base station 14 and the ASNGW 16 will be described with reference to FIG. FIG. 5 is an explanatory diagram of a procedure for leaving the BS and ASNGW-led IPv6 multicast.

  The ASNGW 16 performs notification processing of a request to leave the terminal 12a from the multicast service. That is, the Mbs service flow control unit 32 transmits to the McbcsProxy 30 that the ASNGW 16 takes the initiative in leaving the terminal 12a from the multicast service (MBS_LEAVE) (step BSLS1). Note that step BSLS2 is a missing number.

  Steps BSLS3 and BSLS4, which are the registration process for leaving the terminal 12a from the multicast service, are processed in the same manner as the steps MSLS3 and MSLS4 in the terminal-initiated leaving process described above.

  Step BSLS5, which is a routing setting for canceling multicast distribution to terminal 12a, is processed in the same manner as step MSLS5 described above.

  Steps BSLS6 to BSLS8, which are routing settings of the multicast router 18 for canceling multicast distribution to the terminal 12a, are processed in the same manner as steps MSLS6 to MSLS8 described above.

  Steps BSLS9 to BSLS16, which are service flow setting processes for canceling multicast distribution to the terminal 12a, are processed in the same manner as steps MSLS9 to MSLS16 described above.

  Steps BSLS17 and BSLS18, which are information registration processes for canceling multicast distribution to the terminal 12a, are processed in the same manner as steps MSLS17 and MSLS18 described above. Further, McbcsProxy30 transmits to the Mbs service flow control unit 32 that the terminal 12a has been disconnected from the multicast service (MBS_LEAVE_OK) (step BSLS19).

  With the above processing, the withdrawal of the terminal 12a from the multicast service led by the ASNGW 16 is completed.

<Join operation led by IPv6Mcbcs server>
The participation procedure (Join) to the IPv6 multicast service led by the Mcbcs server 24 will be described with reference to FIG. FIG. 6 is an explanatory diagram of a participation procedure of McbcsSvr-led IPv6 multicast.

  First, the Mcbcs server 24 performs notification processing of a request for participation in the multicast service of the terminal 12a. That is, the Mcbcs server 24 transmits a message (CoARequest) indicating that the terminal 12a participates in the multicast service to the McbcsProxy 30 via the Radius server 22 (step McJS1).

  Steps McJS6 to McJS16, which are service flow setting processes for multicast delivery to the terminal 12a, are processed in the same manner as steps MSJS6 to MSJS16 described above. Steps McJS2 to McJS5 are missing numbers.

  Step McJS17, which is a routing setting in ASNGW 16 for multicast delivery to terminal 12a, is processed in the same manner as step MSJS17 described above.

  Steps McJS18 to McJS20, which are processing related to the routing setting of the Pf router 26 for multicast distribution to the terminal 12a, are processed in the same manner as steps MSJS18 to MSJS20 described above.

  Notification of the process of joining the terminal 12a to the multicast service by the MldProxy 28 is made. That is, the MldProxy 28 transmits a message (CoAAck) indicating that the terminal 12a has been joined to the multicast service to the Mcbcs server 24 via the Radius server 22 (step McJS21).

  Steps McJS22 and McJS23, which are information registration processing for multicast distribution to the terminal 12a, are processed in the same manner as steps MSJS21 and MSJS22 described above.

  Step McJS24, which is transmission processing to the effect that participation processing for the multicast service has been completed, is processed in the same manner as step MBJS23 described above.

  After the above processing, multicast is distributed to the terminal 12a.

<Leave operation led by IPv6 Mcbcs server>
A procedure (Leave) for leaving the IPv6 multicast service led by the Mcbcs server 24 will be described with reference to FIG. FIG. 7 is an explanatory diagram of the McbcsSvr-led IPv6 multicast leaving procedure.

  First, the Mcbcs server 24 performs a process of notifying a request to leave the terminal 12a from the multicast service. That is, the Mcbcs server 24 transmits a message (CoARequest) that causes the terminal 12a to leave the multicast service to the McbcsProxy 30 via the Radius server 22 (step McLS1).

  Step McLS5, which is a routing setting for canceling multicast distribution to terminal 12a, is processed in the same manner as step MSJL5 described above. Steps McLS2 to McJS4 are missing numbers.

  Steps McLS6 to McLS8, which are routing settings of the multicast router 18 for canceling multicast distribution to the terminal 12a, are processed in the same manner as the above-described steps MSLS6 to MSLS8.

  Steps McLS9 to McLS16, which are service flow setting processes for canceling multicast distribution to the terminal 12a, are processed in the same manner as steps MSLS9 to MSLS16 described above.

  Notification of the process of joining the terminal 12a to the multicast service by the MldProxy 28 is made. That is, the MldProxy 28 transmits a message (CoAAck) that the terminal 12a has been disconnected from the multicast service to the Mcbcs server 24 via the Radius server 22 (step McLS17).

  Steps McLS18 and McLS19, which are information registration processes for canceling multicast distribution to the terminal 12a, are processed in the same manner as steps MSLS17 and MSLS18 described above.

  With the above processing, the withdrawal of the terminal 12a from the multicast service led by the Mcbcs server 24 is completed.

  In a multicast communication system, when a terminal participates in an IPv6 multicast service, a service flow corresponding to unicast is generated for each content targeted for the multicast service. By processing the participation of the terminal 12 in the multicast service for each service flow and handling the generated service flow as a bundle (BIND), it is possible to provide a pseudo multicast service under the MLD protocol.

  Further, in the multicast communication system, when the terminal leaves the IPv6 multicast service, the withdrawal of the terminal from the multicast service is processed for each service flow, and the generated service flow is handled as a bundle (BIND). It becomes possible to provide a multicast service in a pseudo manner.

Second Embodiment
Next, a second embodiment of the present invention will be described with reference to the drawings. FIG. 8 is an explanatory diagram of the multicast communication system 40 according to the second embodiment.

  The multicast communication system 40 includes the IgmpProxy 44 instead of the MldProxy 28 in the multicast communication system 10 according to the first embodiment. The same components as those of the multicast communication system 10 shown in FIG. 1 are denoted by the same reference numerals, and detailed description thereof is omitted. The operation of the multicast communication system 40 will be described with reference to FIGS.

<Join operation led by IPv4 terminal>
The participation procedure (Join) to the IPv4 multicast service led by the terminal 12a will be described with reference to FIG. FIG. 9 is an explanatory diagram of the MS-initiated IPv4 multicast participation procedure.

  First, as an initial setting, the Radius server 22 transmits information (Access-Accept) on the availability of the multicast transmission / reception service of the terminal 12a to the McbcsProxy 30 (step MSJS31).

  Notification processing of a request for participation in the multicast service by the terminal 12a is performed. That is, the terminal 12a transmits a request for participation in the multicast service (IGMP Report) to the IgmpProxy 44 via the base station 14 by IGMP (Internet Group Management Protocol) (step MSJS32). Based on the IGMP Report, the IgmpProxy 44 transmits a request for participation of the terminal 12a (MBS_JOIN) to the McbcsProxy 30 (Step MSJS33). When this MBS_JOIN is transmitted, the MAC address, multicast group address, source address information, etc. of the terminal 12a are also transmitted simultaneously.

  Participation registration processing for the multicast service of the terminal 12a is performed. That is, the McbcsProxy 30 transmits a request for participation in the terminal 12a (Access-Request) to the Mcbcs server 24 via the Radius server 22 (step MSJS34). In the Mcbcs server 24, participation registration processing for the multicast service of the terminal 12a is performed. When transmitting this Access-Request, the MAC address of the terminal 12a, the multicast group address, the source address, the IP address of the base station 14 and the like are also transmitted simultaneously. The Mcbcs server 24 collates and approves the request for participation of the terminal 12a, and transmits to the McbcsProxy 30 permission to participate in the multicast service (Access-Accept) including the SFID via the Radius server 22. (Step MSJS35). In this multicast service participation registration process, when a timer is set and this process is not completed within a predetermined time, the processes of steps MSJS34 and MSJS35 are performed again.

  A service flow setting process for multicast distribution to the terminal 12a is performed. That is, the McbcsProxy 30 transmits a service flow generation request (MBSSFC_MBS_JOIN) to the Mbs service flow control unit 32 (step MSJS36).

  The Mbs service flow control unit 32 requests the SF profile for generating a service flow from the Pdb 20 (step MSJS37). The Pdb 20 generates an SF profile corresponding to the SFID and transmits it to the Mbs service flow control unit 32 (step MSJS38).

  The Mbs service flow control unit 32 transmits to the base station 14 a message indicating that a service flow is generated based on the SF profile (RR_REQ) (step MSJS39). The base station 14 transmits a message (DSA_NOTI) to add a service flow to the Mbs service flow control unit 32 (step MSJS40). The Mbs service flow control unit 32 transmits to the base station 14 that the service flow is shared (BIND_MC_SF) (step MSJS41).

  The base station 14 transmits a service flow generation request (DSA-Req) to the terminal 12a. (Step MSJS42). After the service flow is generated between the terminal 12a and the base station 14, the base station 14 transmits to the terminal 12a that the generation of the service flow is completed (DSA-Rsp) (step MSJS43). The base station 14 transmits to the terminal 12a that the service flow generation procedure has been completed (DSA-Ack). (Step MSJS44).

  The base station 14 transmits to the Mbs service flow control unit 32 that the service flow has been generated (BIND_MC_SF_NOTI) (step MSJS45). The Mbs service flow control unit 32 transmits to the McbcsProxy 30 that the service flow for the terminal 12a has been generated (MBSSFC_MBS_JOIN_OK) (step MSJS46).

  If the service flow setting process for multicast delivery in steps MSJS36 to MSJS46 is not completed within a predetermined time, the process is stopped and the process is restarted from the service flow generation request process in step MSJS36. The

  Routing setting in the ASNGW 16 for multicast distribution to the terminal 12a is performed. That is, the McbcsProxy 30 performs routing setting with the Pf router 26 (step MSJS47).

  Processing related to the routing setting of the multicast router 18 for multicast distribution to the terminal 12a is performed. That is, McbcsProxy30 transmits to the ASNGW 42 a request for transmission of IGMP Report (IgmpProxySndRpt) (step MSJS48). The IgmpProxy 44 transmits an IGMP Report to the multicast router 18 (step MSJS49). In addition, the IgmpProxy 44 transmits a message (IgmpProxySndRpt (Success)) indicating that the IGMP Report has been transmitted to the McbcsProxy 30 (Step MSJS50).

  Information registration processing for multicast distribution to the terminal 12a is performed. In other words, McbcsProxy30 transmits a message to register multicast distribution information in Gdb34 (step MSJS51). Further, after registering multicast information, Gdb 34 transmits information indicating that multicast information has been registered in McbcsProxy 30 (step MSJS52). The multicast information to be registered includes the MAC address, group address, source address, etc. of the terminal 12a.

  After the above processing, multicast is distributed to the terminal 12a. Steps MSJS37 and MSJS38 are performed only for the terminal 12a, which is the first multicast receiving terminal, and when the terminal 12b, which is a terminal other than the terminal 12a, uses the multicast service with the same service flow. Not done. Further, step MSJS47 is not performed after the routing related to the terminal 12a is set. Further, steps MSJS48 to MSJS50 are not performed after the service flow for the terminal 12a is generated.

<Leave operation led by IPv4 terminal>
A procedure (Leave) for leaving the IPv4 multicast service led by the terminal 12a will be described with reference to FIG. FIG. 10 is an explanatory diagram of the procedure for leaving the MS-led IPv4 multicast.

  First, the terminal 12a is notified of a withdrawal request from the multicast service. That is, the terminal 12a transmits a request to leave the multicast service (IGMP Report) to the MldProxy 28 by IGMP via the base station 14 (step MSLS31). Based on the IGMP Report, the MldProxy 28 transmits a request for leaving the terminal 12a (MBS_LEAVE) to the McbcsProxy 30 (step MSLS32). When this MBS_LEAVE is transmitted, the MAC address, multicast group address, source address information, etc. of the terminal 12a are also transmitted simultaneously.

  A process for verifying and approving a withdrawal request from the multicast service of the terminal 12a is performed. That is, the McbcsProxy 30 transmits a request for leaving the terminal 12a (Access-Request) to the Mcbcs server 24 via the Radius server 22 (step MSLS33). When transmitting this Access-Request, the MAC address of the terminal 12a, the multicast group address, the source address, the IP address of the base station 14 and the like are also transmitted simultaneously. The Mcbcs server 24 collates and approves the request for leaving the terminal 12a, and sends an acknowledgment (access-accept) of the multicast service to the Mcbcs Proxy 30 via the radius server 22 (step MSLS34).

  Processing related to IGMP for canceling multicast distribution to the terminal 12a is performed. That is, McbcsProxy30 transmits to ASNGW 42 a request for transmission of IGMP Query (IgmpSndSpecificQry (srcgrp)) (step MSLS35). The ASNGW 42 transmits an IGMP Query to the base station 14 (Step MSLS36). Further, the ASNGW 42 transmits a message (IgmpSndSpecificQry (srcgrp)) indicating that the IGMP Query has been transmitted to the McbcsProxy 30 (Step MSLS37).

  A service flow setting process for canceling multicast distribution to the terminal 12a is performed. That is, the McbcsProxy 30 transmits a message to delete the service flow (MBSSFC_MBS_LEAVE) to the Mbs service flow control unit 32 (step MSLS38). The Mbs service flow control unit 32 transmits to the base station 14 the cancellation of service flow sharing (UNBIND_MC_SF) (step MSLS39).

  The base station 14 transmits to the terminal 12a a message to delete the service flow (DSD-Req) (step MSLS40). The terminal 12a transmits to the base station 14 that the service flow has been deleted (DSD-Rsp) (step MSLS41).

  After canceling the sharing of the service flow, the base station 14 transmits a message (UNBIND_MC_SF_NOTI) indicating that the sharing of the service flow has been canceled to the Mbs service flow control unit 32 (step MSLS42). The Mbs service flow control unit 32 transmits to the base station 14 a message to delete the service flow (SF_DELETE) (step MSLS43). The base station 14 transmits a message (DSD_NOTI) indicating that the service flow has been deleted to the Mbs service flow control unit 32 (step MSLS44). The Mbs service flow control unit 32 transmits to the McbcsProxy 30 that the service flow for the terminal 12a has been deleted (MBSSFC_MBS_LEAVE_OK) (step MSJS45).

  Information registration processing for canceling multicast distribution to the terminal 12a is performed. That is, McbcsProxy30 transmits to Gdb34 that multicast distribution information is to be deleted (step MSLS46). The Gdb 34 deletes the multicast distribution information to the McbcsProxy 30, and then transmits information indicating that the deletion has been made (step MSLS47). The multicast information to be deleted is the MAC address, group address, source address, etc. of the terminal 12a. In addition, McbcsProxy30 transmits to the Mbs service flow control unit 32 that the terminal 12a has been disconnected from the multicast service (MBS_LEAVE_OK) (step BSLS48).

  Routing setting in the ASNGW 16 for stopping multicast distribution to the terminal 12a is performed. That is, the McbcsProxy 30 performs routing setting with the Pf router 26 (step MSLS49).

  Processing related to the routing setting of the multicast router 18 for stopping multicast distribution to the terminal 12a is performed. That is, McbcsProxy30 transmits to IgmpProxy 44 a request to transmit IGMP Report (IgmpProxySndDone) (step MSLS50). The IgmpProxy 44 transmits a message (IGMPv1 / v2GroupLeavev3Report) requesting the multicast router 18 to stop multicast distribution (step MSLS51). In addition, the IgmpProxy 44 transmits a message (IgmpProxySndDone (Success)) indicating that the IGMP Report has been transmitted to the McbcsProxy 30 (Step MSLS52).

  With the above processing, the terminal 12a is completely disconnected from the multicast. Steps MSLS35 to MSLS37, MSLS43, and MSLS44 are performed only when the terminal 12a is the last one that leaves the multicast service. Further, when a terminal other than the terminal 12a, for example, the terminal 12b receives the same multicast service, IGMP Querry is transmitted from the IgmpProxy 44 to the terminal 12b. The terminal 12b receives the IGMP Querry, and transmits an IGMP Report as a response to the McbcsProxy30 via the IgmpProxy44. However, when there is no terminal other than the terminal 12a, the IGMP Report to be transmitted to the IgmpProxy 44 is not transmitted as a response to the IGMP Querie transmitted from the IgmpProxy 44. Therefore, IgmpProxy 44 transmits a message (MBS_NO_GRP_MEMBER_NOTI) that there is no response to IGMP Report to McbcsProxy30 when it does not receive an IGMP Report for a predetermined time or more after transmitting IGMP Querry (step MSLS53). Thereafter, the processing is performed by the above-described MSLS 49 to MSLS 53.

<Operation of Join led by IPv4BS and ASNGW>
The participation procedure (Join) to the IPv4 multicast service led by the base station 14 and the ASNGW 16 will be described with reference to FIG. FIG. 11 is an explanatory diagram of the participation procedure of the BS and ASNGW-led IPv6 multicast.

  First, as an initial setting, the Radius server 22 transmits information (Access-Accept) about availability of the multicast transmission / reception service of the terminal 12a to the McbcsProxy 30 (step BSJS31).

  Next, notification processing of a request to join the terminal 12a to the multicast service by the ASNGW 16 is performed. That is, the Mbs service flow control unit 32 transmits to the McbcsProxy 30 a message indicating that the terminal 12a is to participate in the multicast service (MBS_JOIN) (step BSJS32). Step BSJS33 is a missing number.

  Steps BSJS34 and BSJS35, which are participation registration processing for the terminal 12a in the multicast service, are processed in the same manner as steps MSJS34 and MSJS35 in the terminal-led participation processing described above.

  Steps BSJS36 to BSJS46, which are service flow setting processes for multicast distribution, are processed in the same manner as steps MSJS36 to MSJS46 described above.

  Step BSJS47, which is a routing setting in ASNGW 16 for multicast delivery to terminal 12a, is processed in the same manner as step MSJS47 described above.

  Steps BSJS48 to BSJS50, which are processing related to the routing setting of the multicast router 18 for multicast distribution to the terminal 12a, are processed in the same manner as steps MSJS48 to MSJS50 described above.

  Steps BSJS51 and BSJS52, which are information registration processing for multicast distribution to the terminal 12a, are processed in the same manner as steps MSJS51 and MSJS52 described above.

  The McbcsProxy 30 transmits a message (MBS_JOIN_OK) indicating that the terminal 12a has joined the multicast service (MBS_JOIN_OK) to the Mbs service flow control unit 32 (step BSJS53). After the above processing, multicast distribution is performed to the terminal 12a.

<Leave operation led by IPv4BS and ASNGW>
A procedure (Leave) for leaving the IPv4 multicast service led by the base station 14 and the ASNGW 16 will be described with reference to FIG. FIG. 12 is an explanatory diagram of a procedure for leaving the BS and ASNGW-led IPv4 multicast.

  The ASNGW 16 performs notification processing of a request to leave the terminal 12a from the multicast service. That is, the Mbs service flow control unit 32 transmits to the McbcsProxy 30 that the terminal 12a is to be detached from the multicast service (MBS_LEAVE) under the initiative of the ASNGW 16 (step BSLS31). Note that step BSLS 32 is a missing number.

  Steps BSLS33 and BSLS34, which are verification approval processing of a request to leave the terminal 12a from the multicast service, are processed in the same manner as steps MSLS33 and MSLS34 in the above-described terminal-initiated leaving processing.

  Steps BSLS35 to BSLS37, which are processes related to IGMP for canceling multicast delivery to the terminal 12a, are processed in the same manner as steps MSLS35 to BSLS37 in the terminal-initiated leaving process described above.

  Steps BSLS38 to BSLS45, which are service flow setting processes for canceling multicast delivery to the terminal 12a, are processed in the same manner as steps MSLS38 to MSLS45 in the terminal-initiated leaving process described above.

  Steps BSLS46 to BSLS53, which are information registration processes for canceling multicast distribution to the terminal 12a, are processed in the same manner as steps MSLS46 to MSLS53 described above.

  With the above processing, the base station 14 and the ASNGW 42 take the initiative to leave the terminal 12a from the multicast service.

<Join operation led by IPv4 Mcbcs server>
The participation procedure (Join) to the IPv4 multicast service led by the Mcbcs server 24 will be described with reference to FIG. FIG. 13 is an explanatory diagram of a participation procedure of McbcsSvr-led IPv4 multicast.

  First, the Mcbcs server 24 performs notification processing of a request for participation in the multicast service of the terminal 12a. That is, the Mcbcs server 24 transmits a message (CoARequest) indicating that the terminal 12a participates in the multicast service to the McbcsProxy 30 via the Radius server 22 (step McJS31).

  Steps McJS36 to McJS46, which are service flow setting processes for multicast distribution to the terminal 12a, are processed in the same manner as steps MSJS36 to MSJS46 described above. Steps McJS32 to McJS5 are missing numbers.

  Step McJS47, which is a routing setting in ASNGW 16 for multicast delivery to terminal 12a, is processed in the same manner as step MSJS47 described above.

  Steps McJS48 to McJS50, which are processes related to the routing setting of the Pf router 26 for multicast distribution to the terminal 12a, are processed in the same manner as the above-described steps MSJS48 to MSJS50.

  Notification of the process of joining the terminal 12a to the multicast service by the MldProxy 28 is made. That is, the MldProxy 28 transmits a message (CoAAck) indicating that the terminal 12a has been joined to the multicast service to the Mcbcs server 24 via the Radius server 22 (step McJS51).

  Steps McJS52 and McJS53, which are information registration processing for multicast distribution to the terminal 12a, are processed in the same manner as steps MSJS51 and MSJS52 described above.

  The McbcsProxy 30 transmits a message (MBS_JOIN_OK) indicating that the process of joining the terminal 12a to the multicast service has been completed to the Mbs service flow control unit 32 (step McJS54). After the above processing, multicast is distributed to the terminal 12a.

<Leave operation led by IPv4 Mcbcs server>
A procedure (Leave) for leaving the IPv4 multicast service led by the Mcbcs server 24 will be described with reference to FIG. FIG. 14 is an explanatory diagram of the McbcsSvr-led IPv4 multicast leaving procedure.

  First, the Mcbcs server 24 performs a process of notifying a request to leave the terminal 12a from the multicast service. That is, the Mcbcs server 24 transmits a message (CoARequest) that causes the terminal 12a to leave the multicast service to the McbcsProxy 30 via the Radius server 22 (step McLS31).

  Steps McLS35 to BSLS37, which are processes related to IGMP for canceling multicast distribution to the terminal 12a, are processed in the same manner as steps MSLS35 to BSLS37 in the terminal-initiated leaving process described above. Steps McLS32 to McLS34 are missing numbers.

  Steps McLS38 to McLS45, which are service flow setting processes for canceling multicast distribution to the terminal 12a, are processed in the same manner as steps MSLS38 to MSLS45 described above.

  Notification of the process of joining the terminal 12a to the multicast service by the MldProxy 28 is made. In other words, the MldProxy 28 transmits a message (CoAAck) indicating that the terminal 12a has been disconnected from the multicast service to the Mcbcs server 24 via the Radius server 22 (step McLS46).

  Steps McLS47 to McLS54, which are information registration processes for canceling multicast distribution to the terminal 12a, are processed in the same manner as the above-described steps MSLS46 to MSLS53.

  With the above processing, the withdrawal of the terminal 12a from the multicast service led by the Mcbcs server 24 is completed.

  In a multicast communication system, when a terminal participates in an IPv4 multicast service, a service flow corresponding to unicast is generated for each content targeted for the multicast service. By processing the participation of the terminal in the multicast service for each service flow and handling the generated service flow as a bundle (BIND), it is possible to provide a pseudo multicast service under IGMP.

  In addition, in the multicast communication system, when the terminal leaves the IPv6 multicast service, the withdrawal of the terminal from the multicast service is processed for each service flow, and the generated service flow is handled as a bundle (BIND). The pseudo multicast service can be provided below.

<Processing procedure when IGMP version is different>
Next, a process of joining and leaving a terminal having a different IGMP version that can be used will be described with reference to FIG. FIG. 15 is an explanatory diagram of a processing procedure when the IGMP versions are different.

  The terminal 12c is a terminal that can use IGMPv3 that can designate a multicast group address and a multicast source address, and the terminal 12d can use IGMPv2 that can designate only a multicast group address, that is, IGMPv1 or IGMPv2. A description will be given of the joining / leaving process when the terminal can be used.

  First, the IgmpProxy 44 transmits to the terminal 12c an IGMPv3 Query for confirming the presence / absence of a terminal that desires a multicast service to the IGMPv3-compatible terminal 12c via the base station 14 (step S1). The terminal 12c receives the IGMPv3 Query, and transmits an IGMPv3 Report in which the multicast group address and the multicast source address are specified to the McbcsProxy 30 via the base station 14 and the IgmpProxy 44 (step S2). Also, step 1 may be missing and start from step 2. Based on this IGMPv3 Report, a process of joining the multicast service for designating the multicast group address and multicast source address of the terminal 12c is performed (step S3). Further, the timer 46 is set to a predetermined time T1 by the instruction of McbcsProxy30 and starts (step S4).

  The terminal 12d corresponding to IGMPv1 or IGMPv2 transmits to the McbcsProxy30 an IGMP Report in which only the multicast group address corresponding to IGMPv1 or IGMPv2 is specified via the base station 14 and IgmpProxy44 (step S5). Based on this IGMP Report, a process of joining the multicast service that designates only the multicast group address of the terminal 12d is performed (step S6). Further, the timer 46 is set to a predetermined time T2 by the instruction of McbcsProxy30 and starts (step S7).

  When the IgmpProxy 44 confirms that the terminal 12d corresponding to IGMPv1 or IGMPv2 has joined the multicast service, thereafter, instead of the IGMPv3 Query, the IGMP Query corresponding to IGMPv1 or IGMPv2 is sent via the base station 14 to the terminal 12c. And transmitted to the terminal 12d (step S8). The terminal 12c receives the IGMP Query, and transmits an IGMP Report in which only the multicast group address is designated to the McbcsProxy 30 via the base station 14 and the IgmpProxy 44 (Step S9).

  Since McbcsProxy30 receives the IGMP Report within a predetermined time T1, the terminal 12c newly joins (joins) a multicast service that specifies only the same multicast group address without specifying a multicast source address in IGMPv1 or IGMPv2. Processed (step S10). Not specifying a multicast source address means including any multicast source address. With this process, even when a terminal 12c not compatible with IGMPv3 participates in the multicast service while the terminal 12c compatible with IGMPv3 participates in the multicast service, distribution of the same multicast service to the terminal 12c is interrupted. Can continue without. As a result, even when terminals supporting IGMPv3 and not supporting IGMPv3 coexist, multicast distribution can be performed stably and continuously.

  The McbcsProxy 30 does not receive an IGMPv3 Report for notifying the continuation of the multicast service in which the multicast group address and the multicast source address of the terminal 12c are specified within the predetermined time T1, and this multicast is led by the base station 14 and the ASNGW 16 A multicast service leaving process (LEAVE) in which the group address and the multicast source address are designated is performed (step S11). Even if this processing is performed, since the participation in the same multicast service in which only the same multicast group address is specified in step S10 is performed in advance, the distribution is not stopped.

<Congestion processing for Join and Leave procedures>
Next, the congestion process for the Join / Leave procedure in McbcsProxy30 will be described. 16 is an explanatory diagram of a state transition diagram for each terminal 12, FIG. 17 is an explanatory diagram of a state transition diagram of JOIN_ST, and FIG. 18 is an explanatory diagram of a state transition diagram of LEAVE_ST.

  A Join procedure that is a joining process in which the terminal 12 participates in the multicast service and a Leave procedure that is a leaving process in which the terminal 12 leaves the multicast service each have a plurality of transactions.

  The state transition of the terminal 12 includes four statements, that is, READY_ST (READY state), JOIN_ST (JOIN state), LEAVE_ST (LEAVE state), and JOIN_ERR_LEAVE_ST. READY_ST is a message waiting state for transition to JOIN_ST and LEAVE_ST. JOIN_ST is a processing state for the terminal 12 to join the multicast service. LEAVE_ST is a processing state for the terminal 12 to leave the multicast service. JOIN_ERR_LEAVE_ST is a processing state for leaving after the join processing fails.

  The state transition of the terminal 12 is started in any of the following cases, and transitions to READY_ST. That is, the McbcsProxy 30 receives notification that the multicast service related information is notified from the Mbs service flow control unit 32 corresponding to the network entry (MBS_SFA_ACCESS_NOTI), or the McbcsProxy 30 responds to the handover of the terminal 12 from the mobility control unit 32a regarding the handover. Transition to READY_ST when information notification (MBS_MOB_MCBCS_INFO_NOTI) is received. This process is a process performed after steps MSJS1, BSJS1, McJS1, MSJS31, BSJS31, and McJS31.

  Next, the transition procedure of JOIN_ST will be described. First, McbcsProxy30 receives a request for participation in the multicast service of terminal 12 (MBS_JOIN) (step JS1). Step JS1 is the same process as steps MSJS3, BSJS2, MSJS33, and BSJS32.

  The McbcsProxy 30 determines the initiative source from the MBS_JOIN transmission source (step JS2). When MBS_JOIN is transmitted from MldProxy 28 or IgmpProxy 44, the initiative source is determined to be a terminal. When MBS_JOIN is transmitted from the movement control unit 32a, the initiative source is determined to be ASNGW. When MBS_JOIN is transmitted from McbcsProxy30, the initiative source is determined to be the Mcbcs server.

  When the McbcsProxy 30 determines that the terminal is driven or ASNGW is driven, the state transition is changed to EAP_JOIN_ST (step JS3). Step JS3 is a process performed before steps MSJS4, BSJS4, MSJS34, and BSJS34.

  The McbcsProxy 30 transmits a request to generate a service flow (SFA_MBS_JOIN) to the Mbs service flow control unit 32, and the state transition transitions to MCSF_JOIN_ST (step JS4). Step JS4 is processing performed after steps MSJS5, BSJS5, MSJS35, and BSJS35, and transmission of SFA_MBS_JOIN is the same processing as steps MSJS6, BSJS6, MSJS36, and BSJS36.

  If McbcsProxy30 determines that the Mcbcs server is led, McbcsProxy30 transmits SFA_MBS_JOIN to the Mbs service flow control unit 32, and the state transition transitions to MCSF_JOIN_ST (step JS5). Step JS5 is processing performed after steps McJS1 and McJS31, and transmission of SFA_MBS_JOIN is the same processing as steps McJS6 and McJS36.

  The McbcsProxy 30 receives the fact that the service flow has been generated from the Mbs service flow control unit 32 (SFA_MBS_JOIN_OK), and the state transition transits to READY_ST (step JS6). Step JS6 is processing performed after MSJS15, BSJS15, McJS15, MSJS45, BSJS45, McJS45, and reception of SFA_MBS_JOIN_OK is the same processing as MSJS16, BSJS16, McJS16, MSJS46, BSJS46, McJS46.

  Next, the transition procedure of LEAVE_ST will be described. First, the McbcsProxy 30 receives a request to leave the terminal 12 (MBS_LEAVE) (step LS1). Step LS1 is the same process as steps MSLS2, BSLS1, MSLS32, and BSLS31.

  The McbcsProxy30 determines the initiative source from the transmission source of MBS_LEAVE (step LS2). When MBS_LEAVE is transmitted from MldProxy 28 or IgmpProxy 44, the initiative source is determined to be a terminal. When MBS_LEAVE is transmitted from the movement control unit 32a, the initiative source is determined to be ASNGW. When MBS_LEAVE is transmitted from McbcsProxy30, the initiative source is determined to be the Mcbcs server.

  When McbcsProxy30 determines that it is terminal-driven or ASNGW-driven, the state transition transitions to EAP_LEAVE_ST (step LS3). Step LS3 is a process performed before steps MSLS3, BSLS2, MSLS33, and BSLS33.

  The McbcsProxy 30 transmits a request to delete the service flow (SFA_MBS_JOIN) to the Mbs service flow control unit 32, and the state transition transits to MCSF_LEAVE_ST (step LS4). Step LS4 is a process performed after steps MSLS4, BSLS4, MSJS34, and BSJS34.

  When McbcsProxy30 determines that the Mcbcs server is led, McbcsProxy30 transmits SFA_MBS_LEAVE to the Mbs service flow control unit 32, and the state transition transitions to MCSF_LEAVE_ST (step LS5). Step LS5 is a process performed after steps McLS1 and McLS31.

  The McbcsProxy 30 receives that the service flow has been deleted from the Mbs service flow control unit 32 (SFA_MBS_LEAVE_OK), and the state transition transitions to READY_ST (step LS6). Step LS6 is the same processing as MSJS16, BSJS16, McJS16, MSJS45, BSJS45, and McJS45.

  The multicast communication system 10 includes a plurality of terminals 12, a base station 14 that is wirelessly connected to the terminals 12, an ASNGW 16, a multicast router 18 for multicast distribution to the terminals 12, and an Mcbcs server 24. The ASNGW 16 includes an McbcsProxy 30 that performs a joining process (Join) in which the terminal 12 participates in the multicast service for the multicast distribution and a leaving process (Leave) in which the terminal 12 leaves the multicast service. Each of the leaving processes includes a plurality of transactions. McbcsProxy30 is a processing state for the terminal 12 to participate in the multicast service, a JOIN_ST that is a processing state for the terminal 12 to leave the multicast service, and a transaction for the transition to JOIN_ST or LEAVE_ST. Each transaction is processed for another terminal 12 after processing for one terminal 12 in JOIN_ST and LEAVE_ST. As described above, in the multicast communication system 10, by performing transaction processing, it is possible to appropriately perform load distribution for joining and leaving processing, and to perform control on the terminals 12 equally.

  Further, the McbcsProxy 30 determines whether the initiative source is the terminal 12, the ASNGW 16, or the Mcbcs server 24 from the transmission source of the message of the transaction.

  It should be noted that the present invention is not limited to the above-described embodiment, and various configurations can be adopted without departing from the gist of the present invention.

10 ... multicast communication system 12 ... terminal 14 ... base station 16 ... ASNGW
18 ... multicast router 20 ... Pdb
22 ... Radius server 24 ... Mbcs server 26 ... Pf router 28 ... MldProxy
30 ... McbcsProxy
32 ... Mbs Service Flow Control Unit (SFA)
32a ... Movement control unit 34 ... Gdb
36 ... Network 40 ... Multicast communication system 42 ... ASNGW
44 ... IgmpProxy
46 ... Timer

Claims (2)

A multicast communication system comprising a plurality of terminals, a base station wirelessly connected to the terminals, an ASNGW (Access Service Network Gateway), a multicast router for multicast distribution to the terminals, and an Mcbcs (Multicast and Broadcast Service) server Because
The ASNGW includes a McbcsProxy that performs a joining process in which the terminal participates in the multicast service for the multicast distribution and a leaving process in which the terminal leaves the multicast service.
Each of the joining process and the leaving process has a plurality of transactions,
The McbcsProxy includes a JOIN state that is a processing state for the terminal to participate in the multicast service, a LEAVE state that is a processing state for the terminal to leave the multicast service, and the JOIN state or the LEAVE state. A READY state that is a standby state of the transaction for transition;
In the JOIN state and the LEAVE state, each transaction is processed for another terminal after being processed for one terminal. The multicast communication system according to claim 1,
The McbcsProxy determines whether the initiative source is the terminal, the ASNGW, or the Mcbcs server from the transmission source of the message of the transaction.

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