KR20030093813A - Method for allocating multicast address - Google Patents

Abstract

PURPOSE: A method for assigning multicast addresses is provided to consider a transmission terminal identifier when forming an IPv6 multicast address, thereby preventing unnecessary packets from being transmitted in a link layer and applying SSM(Source Specific Multicast) technology to an IPv6 network. CONSTITUTION: A multicast address identifier(21) consists of 8 bits, and uses an 'ff'. A flag(22) consists of 4 bits, and sets a permanent SSM multicast address region to 2, then sets a non-permanent SSM multicast address region to 3. A scope value(23) consists of 4 bits as a multicast range value, and is used for showing a range of a multicast group. Group ID values(24) consist of 112 bits, and are configured in combination with an SLA ID(15), an interface ID(16), and a random 32-bit value(25).

Description

Method for allocating multicast address {Method for allocating multicast address}

The present invention relates to a multicast address allocation method, and more particularly, to a multicast address allocation method using a multicast address generation method for applying a source specific multicast (SSM) technique in IPv6.

The conventional multicast address allocation method in the source specific multicast (SSM) uses a method of arbitrarily generating a multicast address within a predetermined range (232.0.0.0 to 232.255.255.255).

SSM combines any group identifier with the source terminal IP address to create a channel and identifies a multicast group. That is, the multicast packet transmitted through a multicast address arbitrarily formed within a certain range is filtered through the IP module of each host joined to the multicast group so that only packets from the desired transmitting terminal are delivered to the host.

1 is a conceptual diagram illustrating a transmission process of a multicast packet through SSM technology in IPv4 according to the prior art.

Since the transmitting terminals 4 and 5 belong to the same multicast group by the router 1, they generate multicast addresses 232.7.8.1 of the same multicast group, and multicast addresses 2323.8.1 of the multicast group. ) And the channels A (147.6.0.1, 232.7.8.1) and () of each of the transmitting terminals 4 and 5 by combining the unicast addresses 147.6.0.1 and 147.6.0.2 of the transmitting terminals 4 and 5, respectively. B) (147.6.0.2, 232.7.8.1).

The host 6 registers with the router 2 information 147.6.0.1, 232.7.8.1 about the channel A, which contains the source 4 information source. Therefore, the host 6 subscribed to the channel A can receive the multicast packet of the transmitting terminal 4 through the router 2. However, due to the addition of the transmitting terminal 4 information, the group management protocol between the router 2 and the host 6 must be modified.

Similarly, the hosts 7 and 8 are informed about the channels A and B including the sources of the transmitting terminals 4 and 5 (147.6.0.1, 232.7.8.1), (147.6.0.2, 232.7.8.1) to the router (3). Therefore, the hosts 7 and 8 subscribed to the channels A and B can receive the multicast packets of the transmitting terminals 4 and 5 through the router 3. At this time, since the transmission is performed only by the multicast group address at the link layer, the hosts 7 and 8 may receive multicast packets from channels not subscribed to, so that IPs may be transmitted from the desired channel. Filtering through the source terminal address in the module is required.

As described above, since the multicast group identification method through the channel in the conventional SSM technology distinguishes the transmitting terminal IP address, the transmitting terminal IP address can be distinguished by allowing a plurality of channels using the same multicast address. There is a problem that a modification of a group management protocol between a router and a host is required to transmit unnecessary packets in a link layer that is not present and to distinguish an IP address of a transmitting terminal.

An object of the present invention for solving the above problems is to prevent unnecessary packet transmission in the link layer in consideration of the transmitting terminal identifier when forming a multicast address, and to apply the SSM technology to the IPv6 network without modifying the group management protocol. It is to be.

1 is a conceptual diagram illustrating a transmission process of a multicast packet through SSM technology in IPv4 according to the prior art.

2 is a conceptual diagram illustrating a multicast address generation format for applying SSM technology in IPv6 according to the present invention.

3 is a conceptual diagram illustrating a SSM multicast packet transmission process through a multicast address using the SSM multicast address generation method shown in FIG. 2;

<Description of Symbols for Major Parts of Drawings>

10: unicast address of the transmitting terminal

11: FP12: TLA ID

13: RES14: NLA ID

15: SLA ID16: Interface

ID20: Multicast address of the transmitting terminal

21: multicast address identifier 22: flag

23: scope value 24: group ID

25: 32-bit random value 31 to 33: Router

34, 35: transmitting terminal 36 to 38: host

In the multicast allocation method of the present invention for achieving the above object, in the Internet environment for transmitting a multicast packet of the transmitting terminal from the transmitting terminal to the host through the router using the multicast address of the transmitting terminal,

The multicast address area of the transmitting terminal includes a group ID,

The group ID is,

And a random value and an identifier for identifying the transmitting terminal in the global unicast address area of the transmitting terminal.

The above and other objects and features and advantages of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a conceptual diagram illustrating a method for generating an SSM multicast address according to the present invention. Here, the global unicast address 10 of the transmitting terminal is composed of FP 11, TLA ID 12, RES 13, NLA ID 14, SLA ID 15 and interface ID 16, The multicast address 20 consists of a multicast address identifier 21, a flag 22, a scope value 23, and a group ID 24.

The multicast address identifier 21 consists of 8 bits and uses ff.

The flag 22 is composed of four bits, and the permanent SSM multicast address area is set to two, and the non-permanent SSM multicast address area is set to three. Since the non-permanent SSM multicast address area is shown here, 3 is used for the flag 22 value.

Scope value 23 is a multicast category value consisting of 4 bits and is used to indicate the category of a multicast group.

The group ID value 24 is composed of 112 bits. The group ID value 24 is composed of a combination of the SLA ID 15 and the interface ID 16 and a random 32-bit value (Y) 25 of the transmitting terminal unicast address area. .

In this way, since the group ID 24 of the multicast address area is generated using the SLA ID 15 and the interface ID 16 of the transmitting terminal unicast address area, the duplication of the multicast address is minimized in the link layer. Unnecessary packet transmission can be prevented, and the group can be identified only by the multicast address of the group. Thus, there is no need to modify the existing group management protocol.

3 is a conceptual diagram illustrating a SSM multicast packet transmission process through a multicast address generated through the SSM multicast address generation method illustrated in FIG. 2.

The global unicast address (2001: 220: 80a: 2: a00: 20ff: fecf: 18a2, 2001: 220: 80a: 2: 2e0) of the transmitting terminals 34 and 35 belonging to the same multicast group by the router 31. : 14ff: fe55: c249) through the SSM multicast address generation method shown in FIG. 2e0: 14ff: fe55: c249: xxxx: xxxx).

The host 36 then receives information about the group of the transmitting terminals 34 subscribed to the channel A (the multicast address ff3e: 2: a00: 20ff: fecf: 18a2: xxxx: xxxx of the transmitting terminal 34). ) Is registered in the router 32 to receive the multicast packet transmitted from the transmitting terminal 34 through the router 32. Therefore, the host 36 filters only packets from the desired transmitting terminal through the transmitting terminal identifier included in the multicast address in the group to which the transmitting terminal 34 subscribed to the channel A belongs.

Similarly, the other hosts 37 and 38 are informed about the group of transmitting terminals 34 and 35 subscribed to the channels A and B (multicast address ff3e: 2 of the transmitting terminals 34 and 35). a00: 20ff: fecf: 18a2: xxxx: xxxx, ff3e: 2: 2e0: 14ff: fe55: c249: xxxx: xxxx)) The cast packet is transmitted through the router 33.

As described above, the present invention combines the information obtained from the sender's unicast address (SLA ID 15, interface ID 16) with arbitrary information (32-bit arbitrary value 25) when forming the SSM multicast address. Since the group ID of the multicast address is generated, the possibility of duplication of the multicast address can be minimized.

In addition, since the group can be identified using only the multicast address of the group, modification of the existing group management protocol is unnecessary.

In addition, since only the multicast packets from the desired transmitting terminal in the multicast host in the group need to be filtered through the transmitting terminal identifier in the group address, any transmitting terminal can be prevented from transmitting the multicast packets to the same multicast address. Can be.

As described above, the multicast address allocation method according to the present invention considers a transmitting terminal identifier when forming an IPv6 multicast address, thereby preventing unnecessary packet transmission at the link layer, and without modifying the group management protocol. The technology can be applied to IPv6 networks.

In addition, a preferred embodiment of the present invention is for the purpose of illustration, those skilled in the art will be able to various modifications, changes, substitutions and additions through the spirit and scope of the appended claims, such modifications and changes are the following claims It should be seen as belonging to a range.

Claims (3)

In an Internet environment in which a multicast packet of a transmitting terminal is transmitted from a transmitting terminal to a host through a router using a multicast address of a transmitting terminal, The multicast address area of the transmitting terminal includes a group ID, The group ID is, And a random value and an identifier for identifying the transmitting terminal in the global unicast address area of the transmitting terminal. The method of claim 1, And the identifier for identifying the transmitting terminal in the global unicast address area of the transmitting terminal is an SLA ID and an interface ID. The method of claim 1, And said random value is a 32-bit random value in IPv6.