KR20090027973A - Method for providing multicast service in next generation network and system thereof - Google Patents

Abstract

A method for providing a multicast service in the next generation network and a system thereof are provided to secure a QoS(Quality of Service) through centralized resource control. In the first multicast router(40a) of a transmission side network terminal of a broadcasting program, the first routing route is calculated to a rendezvous point multicast router. A resource control server receives a resource request from the routers on the first routing route and assigns necessary resources. A terminal which receives authentication to use resources about a broadcasting channel that a user wants to watch requests subscription to a multicast group(S230). In the second multicast router of the terminal side network terminal, the second routing route is calculated to the rendezvous point multicast router(S232). A resource control server receives a resource request from the routers on the second routing route and assigns the necessary resources(S238,S240). A broadcast control server(20) receives a resource allocation result from the resource control server(S248). The broadcast control server notifies channel setup completion to the terminal(S254).

Description

Method for providing multicast service in next generation network and system thereof

The present invention divides a routing path calculation function and a resource allocation function of a corresponding path when a multimedia broadcasting channel is set up in a next generation network, and provides a multicast service that can guarantee the quality of service (QoS) of the broadcast service through centralized resource control. The present invention relates to a method and a system thereof.

The present invention is derived from the research conducted as part of the IT new growth engine core technology development project of the Ministry of Information and Communication [Task management number: 2006-S-058-02, Title: Development of integrated network service control technology based on ALL-IP] .

Next Generation Network (NGN) integrates all communication networks such as general telephone networks, dedicated networks, and wireless networks into a packet-based common network, reducing network construction costs and operating costs, and providing flexible and open network solutions. It is a voice and data integrated network to provide various applications.

In order to watch a multimedia broadcast in such a next-generation network, a terminal such as a set-top box is provided with an EPG (Electronic Program Guide) from a broadcast control server, and a user selects a desired channel by inquiring an EPG. When the user selects a channel, the terminal requests to join the multicast group with the multicast group ID assigned to the channel. In a general multicast protocol, when a user receives a multicast group join request message, a routing protocol is operated in a multicast router to calculate a routing path, and at the same time, the multicast traffic is transmitted by establishing a route.

However, since multicast routers cannot know the resource status of the entire network, they have no choice but to calculate routing paths based on the status of each router resource, and there is no network equipment that is responsible for resource allocation. none.

Accordingly, an object of the present invention is to provide a method and system for providing a multicast service capable of guaranteeing Quality of Service (QoS) of a broadcast service through centralized resource control.

In accordance with one aspect of the present invention, there is provided a method for providing a multicast service. The method includes: calculating a first routing path from a first multicast router at a transmission-side network end of a broadcast program to a rendezvous point multicast router; Receiving a resource request from the routers on the first routing path and allocating necessary resources, the terminal is authorized to use the resource for the broadcast channel that you want to watch the request to join the multicast group, Calculating a second routing path from a second multicast router to the rendezvous point multicast router, the resource control server receiving a resource request from routers on the second routing path, and allocating necessary resources; Resource allocation result from the control server To receive, and a step for notifying the channel setting completion to the mobile station.

On the other hand, the multicast service providing system according to the present invention, at least one transmitting side multicaster router located at the transmitting network end of the broadcast program, requesting the first routing path calculation to the rendezvous point multicast router, Requesting setting for a broadcast channel, and when the channel setting is completed, a terminal for reproducing a broadcast program received through the broadcast channel, and located at the terminal-side network end, and routing to the rendezvous point multicast router. At least one terminal-side multicast router for starting a route calculation, a resource control server for receiving resource requests from routers on the first and second routing paths, and allocating necessary resources, and receiving a broadcast channel from the terminal; Request authorization of resource use to resource control server And a broadcast control server to notify the terminal.

According to the present invention, the routing path calculation function and the resource allocation function of the corresponding path are separated into a multicast router and a resource control server, respectively, and the quality of service (QoS) of the broadcast service is controlled through centralized resource control of the resource control server. Service) can be guaranteed. In addition, since the present invention does not define the interface between the terminal and the broadcast control server as a specific protocol, it is applicable to both a next generation network based on SIP (Session Initiation Protocol) or a next generation network not based on SIP.

Hereinafter, with reference to the drawings will be described the present invention in more detail.

The method and system for providing a multicast service according to the present invention are basically applied to a Next Generation Network (NGN) environment based on a Session Initiation Protocol (SIP), but are not necessarily limited thereto, and other networks satisfying the conditions according to the present invention. Applicable in the environment.

1 is a diagram illustrating an example of a system configuration to which a multicast service providing method according to an embodiment of the present invention is applied. Referring to FIG. 1, the system includes a terminal 10, a broadcast control server 20, a resource control server 30, a first multicast router 40a, a rendezvous point multicast router 40b, and a second multicast. Router 40c, and broadcast server 50 are included.

The terminal 10 is a device that requests a multimedia broadcasting service channel setting, such as a set-top box, and watches the multimedia broadcasting when the channel setting is completed. The broadcast control server 20 is a server for controlling a multimedia broadcast service and transmits an EPG (Electronic Program Guide) to the terminal 10. When the terminal 10 requests a broadcast channel, the broadcast control server 20 requests authorization of resource use from the resource control server 30 and reports the result. The broadcast control server 20 and the resource control server 30 may communicate using the Rx or Gq protocols discussed in next generation networks (NGNs).

The resource control server 30 responds to an authorization request for resource use from the broadcast control server 20, receives a resource request from routers on the routing path calculated by the multicast routers 40a, 40b, and 40c, and is required. Allocate resources. The result of resource allocation is reported to the broadcast control server 50. The multicast routers 40a, 40b, and 40c may communicate using a common open policy service (COPS) protocol.

Here, COPS is a TCP-based query-and-response protocol used for exchanging policy information between PDP (Policy Decision Point) and PEP (Policy Enforcement Point). PEPs are devices that handle routers or IP traffic, and are implemented to enforce policies determined by the PDP. The PDP may be a controller for granting network access to a specific client or providing an appropriate service. In other words, the PEP sends a request, update, and delete command to the PDP, and the PDP is a client / server model for making a decision to the PEP.

The multicast routers 40a, 40b, and 40c are equipped with a multicast routing protocol for multicast path calculation. In this case, PIM-SM (Protocol Independent Multicast-Sparse Mode) may be used as the loaded multicast routing protocol. PIM-SM is a protocol for constructing a multicast forwarding tree using unicast routing information. Due to the characteristics of the PIM-SM, a program transmitted from the broadcast server 50 is delivered to the rendezvous point multicast router 40b, and the multicast tree is transmitted to the second multicast router 40c at the terminal side network end. It is composed.

The second multicast router 40c located at the terminal side network end is equipped with a multicast group management protocol for multicast group management. In this case, IGMP (Internet Group Management Protocol) may be used as the multicast group management protocol to be mounted. IGMP manages groups between subscriber station and subscriber end network equipment. That is, as shown in FIG. 2, the PIM-SM method is used between the multicast routers 40a, 40b, and 40c, and IGMP is applied between the second multicast router 40c and the terminal 10 of the terminal side network end. IP multicast can be used.

The broadcast server 50 then transmits a multimedia broadcast program. If it is assumed that the PIM-SM protocol is used, all programs are transmitted to the rendezvous pointer multicast router 40b even if the terminal 10 does not request a broadcast channel.

In FIG. 1, only three multicast routers 40a, 40b, and 40c are illustrated for convenience of description, but there may be more multicast routers present on a path for transmitting the actual multicast packet.

3 and 4 are signal flow diagrams provided for explaining a multicast service providing method according to an embodiment of the present invention. First, referring to FIG. 3, the broadcast server 50 transmits a broadcast program to be transmitted to the first multicast router 40a (S200), and the first multicast router 40a is a rendezvous point multicast router ( 40B) transmits a REGISTER message (S202). The rendezvous point multicast router 40b calculates a routing path to the multicast router 40c using the PIM-SM routing protocol (S204).

The rendezvous point multicast router 40b and the first multicast router 40a located on the calculated path each transmit a COPS REQ message to the resource control server 30 to request resources for the calculated path ( S206, S208). The resource control server 30 checks whether the resources are available and allocates resources by transmitting a COPS DEC (Decision) message to the rendezvous point multicast router 40b and the first multicast router 40a, respectively (S210,). S212). The rendezvous point multicast router 40b and the first multicast router 40a respond with a COPS RPT (Report State) message to the result of resource allocation (S214 and 216).

When such a procedure is completed, the program of the broadcast server 50 is transmitted through the path set from the first multicast router 40a to the rendezvous point multicast router 40b (S218).

Referring to FIG. 4, the broadcast control server 20 sends an EPG, which is information about a program transmitted by the broadcast server 50, to the terminal 10 (S220), and the terminal 10 refers to the transmitted EPG. A broadcast channel for a channel to be watched is requested (S222). The broadcast control server 20 requests authorization for resource use to the resource control server 30 using an Rx / Gq´AAR (AA-Request) message (S224), and the resource control server 30 authenticates AAA (Authentication). , Authorization, Account) message to inform the result of the authorization to use the resource (S226). The broadcast control server 20 notifies the terminal 10 of the result of the resource use authorization (S228).

Upon receiving the authorization for resource use, the terminal 10 transmits the multicast group address of the broadcast channel to be watched to the second multicast router 40c in an IGMP JOIN message (S230). All multicast routers including the second multicast router 40c calculate a routing path to the rendezvous point multicast router 40b using the PIM-SM routing protocol (S232).

All multicast routers located on the calculated paths transmit COPS REQ messages to the resource control server 30, respectively (S234 and S236), and request resources for the calculated paths. If there is an existing multicast routing tree, routers on the path calculated from the multicast router corresponding to the branch of the newly created tree may request resources from the resource control server 30. The resource control server 30 checks whether the resources are available and allocates resources by sending a COPS DEC message to all the multicast routers located on the path (S238 and S240). The multicast routers respond with COPS RPT (Report State) messages to the result of resource allocation, respectively (S242 and S244).

When such a procedure is completed, the program of the broadcast server is transmitted through the path set from the rendezvous point multicast router 40b to the second multicast router 40c (S246), and the second multicast router 40c is a terminal. The program is transmitted to (10) (S252).

The resource control server 30 simultaneously sends an Rx / Gq´RAR (Re-Auth-Request) message to the broadcast control server 20 (S248), and reports the result of resource allocation, and the broadcast control server 20 In response to the Rea-Auth-Answer (RAA) message (S250), the terminal 10 notifies that channel setting is completed (S254).

By such a process, it is possible to ensure the quality of service (QoS) of the broadcast service through the calculation of the respective paths in the multicast router and centralized resource control by the resource control server 30.

On the other hand, in the above embodiment has been described a case where there are three multicast routers 40a, 40b, 40c as an example, in general, there are more multicast routers exist on the path for transmitting the actual multicast packet. In this case, the calculation of the routing path is calculated at each of the multicast routers existing on the path, and each multicaster router is requested and assigned to each resource for the calculated path from the resource control server 30, respectively.

In addition, although the preferred embodiment of the present invention has been shown and described above, the present invention is not limited to the specific embodiments described above, but the technical field to which the invention belongs without departing from the spirit of the invention claimed in the claims. Of course, various modifications can be made by those skilled in the art, and these modifications should not be individually understood from the technical spirit or the prospect of the present invention.

1 is a diagram illustrating an example of a system configuration to which a multicast service providing method according to an embodiment of the present invention is applied;

FIG. 2 is a diagram schematically illustrating a method for transmitting a multicast packet in the system shown in FIG. 1; and

3 and 4 are signal flow diagrams provided for explaining a multicast service providing method according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

10: terminal 20: broadcast control server

30: resource control server 40a: first multicast router

40b: rendezvous point multicast router

40c: second multicast router 50: broadcast server

Claims (10)

Calculating a first routing path from the first multicast router at the transmitting end network end of the broadcast program to the rendezvous point multicast router; A resource control server receiving a resource request from routers on the first routing path and allocating necessary resources; Calculating a second routing path from a second multicast router of the terminal-side network end to the rendezvous point multicast router by requesting a subscription to a multicast group from a terminal authorized to use a resource for a broadcasting channel to be watched; ; The resource control server receiving a resource request from routers on the second routing path and allocating necessary resources; And And receiving, by the broadcast control server, the resource allocation result from the resource control server, and notifying the terminal of the completion of channel setting. The method of claim 1, And receiving a multimedia broadcast program through the set broadcast channel. The method of claim 1, The first and second routing paths are calculated using a multicast routing protocol. The method of claim 1, In the calculation of the second routing path, if there is an existing multicast routing tree, routers on the path calculated from the multicast router corresponding to the branch point of the newly created tree request resources to the resource control server to provide necessary resources. Multicast service providing method characterized in that the assignment. The method of claim 1, Requesting, by the terminal, the broadcast channel from the broadcast control server by querying an EPG (Electronic Program Guide) received from the broadcast control server; And And transmitting the resource usage authorization for the broadcast channel to the terminal according to the response received by the broadcast control server requesting authorization for resource usage to the resource control server. How to Provide Services. At least one transmitting multicaster router located at the transmitting network end of the broadcast program and requesting a first routing path calculation to a rendezvous point multicast router; A terminal for requesting setting of a broadcast channel to be watched and playing back a broadcast program received through the broadcast channel when the channel setting is completed; At least one terminal-side multicast router located at the terminal-side network end to initiate calculation of a second routing path to the rendezvous point multicast router; A resource control server that receives a resource request from routers on the first and second routing paths and allocates necessary resources; And And a broadcast control server for receiving a broadcast channel from the terminal and requesting resource use authorization to the resource control server and notifying the terminal of the result of the broadcast control server. The method of claim 6, And a broadcast server transmitting the broadcast program. The method of claim 6, The transmitting-side multicast router and the terminal-side multicaster router calculate a first and a second routing path using a multicast routing protocol, respectively. The method of claim 6, The broadcast control server requests the resource control server for permission to use a resource for the broadcast channel requested from the terminal, and notifies the terminal of permission for resource use for the broadcast channel according to a response received from the resource control server. Multicast service providing system, characterized in that. The method of claim 6, The second multicast router is configured to manage a multicast group using a multicast group management protocol.

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