JP4809855B2 - IP multicast communication monitoring method and system - Google Patents

Description

  The present invention relates to a multicast communication monitoring method and system in a network composed of a plurality of nodes connecting a plurality of distribution servers and a plurality of viewer terminals, and in particular, IP multicast adjacency confirmation between a plurality of nodes is completed, Source information indicating that an IP multicast transfer request has been sent from a specific distribution server among a plurality of nodes performing IP multicast communication via an accepted route (hereinafter referred to as an accepted route). The present invention relates to a multicast communication monitoring method and system for confirming communication from a specific distribution server to a plurality of viewer terminals that IP multicast communication having (S) and specific group information (G) should reach.

  A conventional IP multicast communication monitoring method will be described (for example, see Non-Patent Documents 1 and 2). The first conventional method example based on the technology disclosed in Non-Patent Document 1 is a block diagram of an example of a conventional IP multicast arrival monitoring method using PING addressed to IP multicast (part 1). As shown in FIG. In addition, the second conventional method example based on the technique disclosed in Non-Patent Document 2 is a “block diagram (part 2) of a conventional IP multicast arrival monitoring method embodiment” using ssmping. 12 shows.

11 and 12,
101-1, 101-2 are distribution servers MS1, MS2,
110-1 and 110-2 are viewer terminals h1 and h2,
115 is its own network area,
116 is a distribution server side,
117 is a user side (that is, viewer terminal side),
118 and 119 are network boundary points,
120 is a source node A;
121 and 122 are relay nodes B, C,
123 and 124 are edge nodes D, E,
Reference numerals 140-1 to 140-6 denote multicast routes addressed to the same group (G) whose transmission source information (S) is MS1 (101-1).

Here as a prerequisite
In this example, the multicast control protocol between nodes is described using PIM-SSM, and the terminal viewing management protocol is described using MLDv2. Further, in the multicast route of 140-1 to 140-6, Neighber is established in the PIM-Hello between adjacent nodes of the source node A (120) to the edge node E (124) (establishment of adjacency confirmation), Further, it is assumed that the confirmation of PIM-join is completed and the request procedure from the viewer terminal by MLDv2 is completed (establishment of consent route).

Referring to the sequence shown in FIG.
The distribution server MS1 (101-1) transmits the IP multicast group-addressed PING addressed to the group (G). The PING addressed to the IP multicast group is copied by the relay node C (122) via the originating node A (120) and arrives at the edge node D (123) and the edge node E (124), respectively. The edge node D (123) transmits the PING addressed to the IP multicast group to the viewer terminal h2 (110-2) requesting viewing by MLDv2, and the viewer terminal h2 (110-2) is the distribution server of the transmission source Report the reply of the PING address to the IP multicast group to MS1 (101-1). Also, the edge node E (124) transmits the PING addressed to the IP multicast group to the viewer terminal h1 (110-1) requesting viewing by MLDv2, and the viewer terminal h1 (110-1) is the transmission source. A reply of the PING addressed to the IP multicast group is reported to the distribution server MS1 (101-1).

  Note that the reply to the IP multicast group-addressed PING returned from the viewer terminal h1 (110-1) is sent to the viewer via the edge node E (124), the relay node C (122), and the source node A (120). Arrives at terminal MS1. In parallel, the reply to the IP multicast group-addressed PING returned from the viewer terminal h2 (110-2) passes through the edge node D (123), the relay node C (122), and the originating node A (120). And arrives at the distribution server MS1. By this procedure, the distribution server MS1 confirms the IP multicast communication (see, for example, Non-Patent Document 1).

On the other hand, in the case of confirming communication by the viewer terminal h1 using ssmping, refer to the sequence shown in FIG.
The viewer terminal h1 (110-1) transmits ssmping to the edge node E (124). Ssmping arrives at the distribution server MS1 via the edge node E (124), the relay node C (122), and the originating node A (120). The distribution server MS1 (101-1) distributes the IP multicast packet to the group (G) to the viewer terminal h1 (110-1) upon receipt of the ssmping. The IP multicast packet distributed from the distribution server MS1 (101-1) is sent to the viewer terminal h1 (110-1) via the originating node A (120), the relay node C (122), and the edge node E (124). To arrive. Through this procedure, the viewer terminal h1 confirms the IP multicast communication (see, for example, Non-Patent Document 2).

Kamil Sarac and one other, "draft-sarac-mping-00.txt. MPING Protocol Operation", [online], June 2004, IETF, [Search on December 21, 2007], Internet <URL: http /// ietfreport.isoc.org/all-ids/draft-sarac-mping-00.txt> Pavan Namburi and 2 others, “433-059 SSM-PING: A PING UTILITY FOR SOURCE SPECIFIC MULTICAST 4 SSM-Ping”, [online], November 22, 2004, CIIT 2004, [December 21, 2007 Search], Internet <URL: http://www.actapress.com/Content_Of_Proceeding.aspx? ProceedingID = 266 # pages>, <URL: http://imj.gate.edu/papers/CIIT-04b.pdf.gz>

  However, in the above-described conventional technology, when confirming IP multicast communication, a route for passing an IP multicast packet (hereinafter referred to as multicast tree) is set by a user request, and the network boundary point (118, 119) is exceeded. Therefore, there is a problem that it is not possible to confirm the communication closed in the own network area (115). In addition, since it is difficult to check the communication in units of source information (S) and specific group information (G), it is not possible to grasp a timely route for passing an IP multicast packet (that is, multicast tree). There is also a problem that route monitoring is difficult. Furthermore, there is a problem that the IP multicast bandwidth usage status cannot be confirmed in a timely manner.

  Therefore, an object of the present invention is to confirm the current multicast tree state by checking the communication in units of the transmission source information (S) and specific group information (G), and monitor the IP multicast bandwidth usage status. It is another object of the present invention to provide an IP multicast communication monitoring method and system that can also be used.

  In order to solve the above problems, the IP multicast communication monitoring method of the present invention provides IP multicast communication in a network composed of a plurality of nodes connecting a plurality of distribution servers and a plurality of viewer terminals. The source node that communicates with a specific distribution server grasps the IP multicast packet for each source information and specific group information in communication, and monitors each combination of the source information and the specific group information. In addition, an IP multicast maintenance packet having a storage area for the sequence number and passing route number in the payload of the packet is generated, and a predetermined sequence number and the passing route number of the own node are inserted into the storing area, together with the IP multicast packet. To each downstream node, and each downstream node transmits its own forwarding node. A maintenance OpS that can be passed to one or more viewer terminals and forwarded together with the IP multicast packet to connect to each node in the network. Is characterized in that information on the communication of a route is acquired from each node.

  Furthermore, the IP multicast communication monitoring method of the present invention is an IP multicast communication monitoring method in a network composed of a plurality of nodes connecting a plurality of distribution servers and a plurality of viewer terminals. Transmission indicating that IP multicast adjacency confirmation has been completed, and that the IP multicast transfer request has been sent from a specific distribution server among a plurality of nodes performing IP multicast communication via an accepted route An IP multicast communication monitoring method for confirming whether IP multicast communication having original information and specific group information is communicated to the plurality of viewer terminals to be reached from the specific distribution server, wherein the network includes: A plurality of distribution servers, a plurality of viewer terminals, a single originating node, and a plurality of relays A plurality of edge nodes and one maintenance OpS, and each processing of the plurality of distribution servers sends an IP multicast packet to an adjacent source after completion of IP multicast transfer and arbitration. A process of transferring to a node, each process of the plurality of viewer terminals includes a process of receiving an IP multicast packet transferred from an adjacent edge node, and the process of the originating node A process of referring to the IP multicast packet received from any of the distribution servers, and grasping the IP multicast packet of the source information and the specific group information, and for each of the grasped source information and the specific group information One IP multicast maintenance packet is generated, and the referenced IP multicast packet is transferred. A process for transmitting to an adjacent relay node of the accepted route, a test mode for identifying the test mode when generating the IP multicast maintenance packet, a sequence number for determining the order of the IP multicast maintenance packet to be transmitted, and an IP A process of inserting information on the route number through which the route through which the multicast maintenance packet passes is inserted into a predetermined storage area, and after completing the transfer of the IP multicast maintenance packet to the accepted route, the IP multicast maintenance packet corresponding to the accepted route PIM-Join and PIM-Prune, which are routing control protocols for each combination of source information and specific group information, and a process for reporting the source information, specific group information, test mode, and sequence number to the maintenance OpS , Downstream By confirming whether or not the packet is received from the adjacent relay node of the acceptance route, when the inquiry is received from the maintenance OpS, it is possible to grasp the IP multicast transfer request from the downstream adjacent relay node. A process of reporting an IP multicast transfer request from an adjacent relay node of each of the plurality of relay nodes, wherein each of the plurality of relay nodes transmits an IP multicast packet and an IP multicast maintenance packet transferred from the adjacent node to an adjacent node of the acceptance route. When the IP multicast maintenance packet is forwarded to an adjacent node of the acceptance route, a passing route number of the own node that can identify the passing of the own forwarding node is assigned to the predetermined storage area in the IP multicast maintenance packet. And PIM-h based on the routing protocol By confirming llo, PIM-Join and PIM-Prun for each combination of the source information and the specific group information for the process of grasping the IP multicast adjacency status with the adjacent node from the adjacent node of the downstream acceptance route By confirming whether or not it is received, processing for grasping an IP multicast transfer request from a downstream adjacent node, and PIM-Join and PIM-Prune for each combination of source information and specific group information are By confirming whether or not the transmission is made to the adjacent node, it is possible to grasp the IP multicast transfer request to the upstream adjacent node, and when there is an inquiry from the maintenance OpS, the IP multicast adjacent status and the downstream adjacent IP multicast forwarding request from the node and upstream A process of reporting an IP multicast transfer request to a node, and each of the plurality of edge nodes includes a process of extracting only an IP multicast maintenance packet from IP multicast packets arriving from adjacent relay nodes, and an extracted IP Processing for confirming transmission source information, specific group information, test mode, sequence number, passage route number in multicast maintenance packet and reporting to maintenance OpS, and terminal viewing for each combination of transmission source information and specific group information By confirming whether or not the query of the management protocol has been transmitted to the viewer terminal corresponding to the acceptance route, the process of grasping the viewing permission status to the viewer terminal, the transmission source information and the specific group information Accept report of terminal viewing management protocol for each combination The PIM for each combination of transmission source information and specific group information, by confirming whether or not the request is received from the corresponding viewer terminal of the mobile terminal. -When confirming whether or not Join and PIM-Prune are transmitted to the upstream adjacent relay node, to grasp the IP multicast transfer request to the upstream adjacent relay node, and when there is an inquiry from the maintenance OpS Includes a process of reporting a viewing permission status to a viewer terminal corresponding to the accepted route, a viewing request status from the viewer terminal, and an IP multicast transfer request to an upstream adjacent relay node, and the maintenance OpS Is a process of transmitting / receiving information to / from the source node, each of the plurality of relay nodes, and each of the plurality of edge nodes. , Source information that is reported from the source node, specific group information, test mode, sequence number, and source information that is information reported from the edge node, specific group information, test mode, sequence And confirming whether the IP multicast maintenance packet transmitted by the originating node has arrived at the edge node to arrive by confirming the number and the passing route number, and a plurality of distributions by the maintenance OpS The communication is confirmed in a network composed of a plurality of nodes connecting the server and a plurality of viewer terminals.

  In the IP multicast communication monitoring method of the present invention, the maintenance OpS processing further inquires according to the necessity of information acquisition at each node, and the source node is connected to an adjacent node downstream of the source node. An IP multicast transfer request from a relay node is confirmed, and for each of the plurality of relay nodes, the IP multicast adjacency status grasping request, an IP multicast transfer request from a downstream adjacent node, and an upstream adjacency Confirming the IP multicast transfer request to the node, and requesting each viewer terminal to grasp the viewing permission status and requesting the viewer terminal to grasp the viewing request status for each of the plurality of edge nodes. And a process of confirming an IP multicast transfer request to an upstream adjacent relay node.

  In the IP multicast communication monitoring method of the present invention, the test mode includes a transfer band mode as a test for confirming a transfer band as a data amount of an IP multicast maintenance packet transferred in a predetermined measurement period, and other tests. A mode type for discriminating the normal mode as packet mode information, packet status information for discriminating a leading packet, an intermediate packet, and a final packet to be transferred in the transfer band mode when the mode type is a band confirmation mode, and the constant measurement Information on the period, information on the IP multicast maintenance packet length, and information on the number of IP multicast maintenance packets sent within the time of the certain measurement period are held, and when the transfer bandwidth is confirmed by the maintenance OpS In the process of the originating node, the bandwidth confirmation mode is registered in the mode type. And setting a packet status, a fixed measurement period, an IP multicast maintenance packet length, the number of IP multicast maintenance packets, and transferring an IP multicast maintenance packet to an adjacent relay node of the accepted route, and each of the plurality of edge nodes Refers to the mode type of the IP multicast maintenance packet that has arrived and extracted from the adjacent relay node. In the bandwidth confirmation mode, information on the packet status, the fixed measurement period, the IP multicast maintenance packet length, and the number of IP multicast maintenance packets is displayed. The processing of the maintenance OpS includes an IP multicast maintenance of “mode type = bandwidth confirmation mode” and “packet status = first packet” in any of the plurality of edge nodes whose transfer bandwidth is to be confirmed. packet When it arrives, it is determined that the confirmation test of the bandwidth confirmation mode has been started, and the packet status for each IP multicast maintenance packet that has arrived from “packet status = intermediate packet” until the final packet, a certain measurement period, IP multicast maintenance A network composed of a plurality of nodes that connect a plurality of distribution servers and a plurality of viewer terminals by the maintenance OpS, including processing for calculating a transfer bandwidth from information on the packet length and the number of IP multicast maintenance packets It is characterized in that the transfer bandwidth in the network is confirmed.

  Further, the IP multicast communication monitoring system of the present invention is an IP multicast communication monitoring system for monitoring IP multicast communication in a network composed of a plurality of nodes connecting a plurality of distribution servers and a plurality of viewer terminals. The source node that communicates with a specific distribution server has a function of grasping IP multicast packets for each source information and specific group information in communication, and for each combination of source information and specific group information. A function for generating an IP multicast maintenance packet having a storage area for a sequence number and a passing route number in the payload of the packet, and inserting a predetermined sequence number and the passing route number of the own node into the storing area, to the downstream node Each of the downstream nodes has the capability to transmit. A maintenance OpS that has a function of forwarding the IP multicast packet to one or more viewer terminals with the passing route number of each node in the network, and is connectable to each node in the network. It has a function of dropping an IP multicast maintenance packet from a node and monitoring the communication of the route.

  Furthermore, the IP multicast communication monitoring system of the present invention is an IP multicast communication monitoring system in a network composed of a plurality of nodes connecting a plurality of distribution servers and a plurality of viewer terminals. Transmission indicating that IP multicast adjacency confirmation has been completed, and that the IP multicast transfer request has been sent from a specific distribution server among a plurality of nodes performing IP multicast communication via an accepted route An IP multicast communication monitoring system for confirming whether IP multicast communication having original information and specific group information is communicated to the plurality of viewer terminals to be reached from the specific distribution server, wherein the network includes: A plurality of distribution servers, a plurality of viewer terminals, and a source node It is composed of a plurality of relay nodes, a plurality of edge nodes, and one maintenance OpS. Each of the plurality of distribution servers sends an IP multicast packet to an adjacent source after completion of IP multicast transfer and arbitration. Each of the plurality of viewer terminals has a function of receiving an IP multicast packet transferred from the adjacent edge node, and the source node is connected to the plurality of adjacent distributions. A function for referring to the IP multicast packet received from any of the servers and grasping the IP multicast packet of the source information and the specific group information, one for each of the grasped source information and the specific group information The IP multicast maintenance packet is generated, and the IP multicast packet referred to above is transferred. A function for transmitting to a relay node adjacent to the route, a test mode for identifying the test mode when generating the IP multicast maintenance packet, a sequence number for determining the order of the IP multicast maintenance packet to be transmitted, and IP multicast maintenance The function of inserting the information of the route number through which the route through which the packet passes can be inserted into a predetermined storage area, and the transmission of the IP multicast maintenance packet corresponding to the accepted route after the completion of the transfer of the IP multicast maintenance packet to the accepted route Downstream of PIM-Join and PIM-Prune, which are path control protocols for each combination of source information and specific group information, a function for reporting original information, specific group information, test mode, sequence number to the maintenance OpS Consent By confirming whether or not it is received from the adjacent relay node, and when there is an inquiry from the maintenance OpS, it is possible to grasp the IP multicast transfer request from the downstream adjacent relay node. A function of reporting an IP multicast transfer request from an adjacent relay node, wherein the plurality of relay nodes transfer an IP multicast packet and an IP multicast maintenance packet transferred from the adjacent node to an adjacent node of the acceptance route; A function of assigning a passing route number of the own node that can identify passing of the own forwarding node to the predetermined storage area in the IP multicast maintenance packet when transferring the IP multicast maintenance packet to an adjacent node of the acceptance route; Confirm PIM-hello based on the routing protocol Whether the PIM-Join and PIM-Prune for each combination of the source information and specific group information are received from the adjacent node of the downstream acceptance route by grasping the IP multicast adjacency status with the adjacent node By confirming whether or not, a function for grasping an IP multicast transfer request from a downstream adjacent node and a PIM-Join and a PIM-Prune for each combination of transmission source information and specific group information are transmitted to the upstream adjacent node. To confirm the IP multicast transfer request to the upstream adjacent node, and when there is an inquiry from the maintenance OpS, the IP multicast adjacent status and the IP from the downstream adjacent node Multicast transfer request and IP header to upstream neighboring node Each of the plurality of edge nodes has a function of extracting only an IP multicast maintenance packet out of IP multicast packets arriving from an adjacent relay node, and an inside of the extracted IP multicast maintenance packet. Source information, specific group information, test mode, sequence number, passing route number, and processing to report to the maintenance OpS, and terminal viewing management protocol Query for each combination of the source information and specific group information And a terminal for each combination of transmission source information and specific group information by confirming whether or not to transmit to the corresponding viewer terminal of the acceptance route Viewer terminal corresponding to the consent route of the report of the viewing management protocol By confirming whether or not it has been received from the viewer terminal, the function for grasping the viewing request status from the viewer terminal, and the PIM-Join and PIM-Prune for each combination of source information and specific group information are upstream The function to grasp the IP multicast transfer request to the upstream adjacent relay node by confirming whether or not it is transmitted to the adjacent relay node, and the corresponding viewing of the accepted route when there is an inquiry from the maintenance OpS A viewing permission status to the viewer terminal, a viewing request status from the viewer terminal, and an IP multicast transfer request to the upstream adjacent relay node, and the maintenance OpS includes the originating node, Each of the plurality of relay nodes and each of the plurality of edge nodes, a function of transmitting and receiving information, and reported from the source node Confirm source information, specific group information, test mode, sequence number, and information reported from the edge node, specific group information, test mode, sequence number, transit route number A function of confirming whether or not the IP multicast maintenance packet transmitted by the originating node has arrived at the edge node to arrive, and a plurality of distribution servers and a plurality of viewer terminals are provided by the maintenance OpS. The communication is confirmed in a network composed of a plurality of nodes connected to each other.

  In the IP multicast communication monitoring system of the present invention, the maintenance OpS further inquires according to the necessity of information acquisition at each node, and the source node is connected to an adjacent node downstream of the source node. An IP multicast transfer request from a relay node is confirmed, and for each of the plurality of relay nodes, the IP multicast adjacency status grasping request, an IP multicast transfer request from a downstream adjacent node, and an upstream adjacency Confirming the IP multicast transfer request to the node, and requesting each viewer terminal to grasp the viewing permission status and requesting the viewer terminal to grasp the viewing request status for each of the plurality of edge nodes. And a function of confirming an IP multicast transfer request to an upstream adjacent relay node.

  Further, in the IP multicast communication monitoring system of the present invention, the test mode includes a transfer band mode as a test for confirming a transfer band as a data amount of an IP multicast maintenance packet transferred in a certain measurement period, and other than that A mode type for determining the normal mode as a test of the packet, and when the mode type is the bandwidth confirmation mode, packet status information for determining the first packet, the intermediate packet, and the last packet transferred in the transfer bandwidth mode, and the constant Measurement period information, IP multicast maintenance packet length information, and information on the number of IP multicast maintenance packets sent within the predetermined measurement period, and the transfer bandwidth is confirmed by the maintenance OpS. In this case, the source node sets a bandwidth confirmation mode to the mode type. Registering, setting a packet status, a fixed measurement period, an IP multicast maintenance packet length, the number of IP multicast maintenance packets, and transferring an IP multicast maintenance packet to an adjacent relay node of the accepted route; and a plurality of edge nodes Each refers to the mode type of the IP multicast maintenance packet that arrives and is extracted from the adjacent relay node. In the bandwidth confirmation mode, information on the packet status, a fixed measurement period, the IP multicast maintenance packet length, and the number of IP multicast maintenance packets The maintenance OpS has an IP multicast maintenance of “mode type = bandwidth confirmation mode” and “packet status = first packet” in any of the plurality of edge nodes whose transfer bandwidth is to be confirmed. Packet When it arrives, it is judged that the confirmation test of the bandwidth confirmation mode has been started, the packet status for each IP multicast maintenance packet that has arrived from “packet status = intermediate packet” until the final packet, a certain measurement period, IP multicast maintenance It has a function to calculate the transfer bandwidth from the information of the packet length and the number of IP multicast maintenance packets, and is composed of a plurality of nodes connecting a plurality of distribution servers and a plurality of viewer terminals by the maintenance OpS. It is characterized in that the transfer bandwidth in the network is confirmed.

  According to the IP multicast communication monitoring method and system of the present invention, IP multicast communication closed in its own network area becomes possible. In addition, it is possible to check whether IP multicast has reached all terminals that should be reached in units of specific source information (S) and specific group information (G) in a timely manner, and to understand multicast trees in a timely manner. The route can be confirmed. This facilitates fault monitoring and fault isolation in the multicast communication path.

  In addition, since the test mode has a function of the bandwidth confirmation mode, it is possible to confirm the bandwidth usage status of the IP multicast in a timely manner on the premise of bandwidth guarantee.

  In addition, in the steady state, only notification to the maintenance OpS from the originating node and the edge node is required, and each node does not need to store a large amount of information as a database, so the IP multicast communication monitoring method and system of the present invention are realized. The effect on the node performance when incorporating the function for the purpose into each node can be reduced.

  Hereinafter, the IP multicast arrival monitoring method and system of each embodiment according to the present invention will be described in detail with reference to the drawings. 1 to 10 are block diagrams of embodiments of an IP multicast communication monitoring system showing the principle of the present invention. In addition, the same reference number is attached | subjected to the same component in each figure.

  In the following description, PIM-SSM is used as a multicast control protocol between nodes, and MLDv2 is used as a terminal viewing management protocol so as to facilitate comparison with the prior art. Further, in the multicast route of 140-1 to 140-6, Neighber is established in the PIM-Hello between adjacent nodes of the source node A (120) to the edge node E (124) (establishment of adjacency confirmation), Further, it is assumed that the confirmation of PIM-join is completed and the request procedure from the viewer terminal by MLDv2 is completed (establishment of consent route).

1 to 10,
101-1, 101-2 are distribution servers MS1, MS2,
110-1 and 110-2 are viewer terminals h1 and h2,
115 is its own network area,
116 is a distribution server side,
117 is a user side (that is, viewer terminal side),
118 and 119 are network boundary points,
120 is a source node A;
121 and 122 are relay nodes B, C,
123 and 124 are edge nodes D, E,
140-1 to 140-6 are multicast routes addressed to the same group (G) whose source information (S) is MS1 (101-1),
150 is a maintenance OpS (route information of each node can be confirmed as indicated by a symbol (A)),
160 is a breakdown of IP multicast maintenance packet information,
161 is detailed information in the test mode (TM),
Reference numerals 200 to 211 denote external devices a to l.

  The IP multicast communication monitoring method of each embodiment described below monitors IP multicast communication in a network composed of a plurality of nodes connecting a plurality of distribution servers and a plurality of viewer terminals. The originating node A (120) communicating with a specific distribution server grasps the IP multicast packet for each source information (hereinafter referred to as S) and specific group information (hereinafter referred to as G) during the communication, For each combination of source information and specific group information, an IP multicast maintenance packet (160) having a storage area for a sequence number (hereinafter referred to as SN) and a transit route number (hereinafter referred to as RN) in the payload is generated. Then, a predetermined sequence number (SN) and a passing route number (RN) of the own node are inserted into the storage area and transmitted to the downstream node together with the IP multicast packet. Each downstream node assigns the packet's own route route number of the packet and forwards it along with the IP multicast packet to one or more viewer terminals. Note that it is preferable to assign a test packet identifier (TPM) for identifying an IP multicast maintenance packet to an empty area of the header to the IP multicast maintenance packet (160) generated by the originating node. By referring to this TPM, the relay node or the edge node can easily identify whether the packet is an IP multicast packet or an IP multicast maintenance packet. This TPM may be in any form. For example, in the case of an IPv4 IP header, an Option field or the like is used to give it to a storage area that does not affect the normal transfer operation. A maintenance OpS (Operating System) (150) acquires information on the path communication from each node.

  That is, the IP multicast communication monitoring system of each embodiment described below includes a plurality of distribution servers MS1, MS2 (101-1, 101-2) and a plurality of viewer terminals h1, h2 (110-1, 110-2). In the IP multicast communication monitoring system in a network composed of a plurality of nodes connected to each other, the IP multicast adjacency confirmation between the plurality of nodes is completed and the IP multicast transfer request has been accepted (hereinafter referred to as the IP multicast transfer request). Source information (S) and specific group information (G) indicating that the data is transmitted from a specific distribution server MS1 among a plurality of nodes performing IP multicast communication via a consent route). A plurality of viewer terminals h1 and h2 (110-1) that the IP multicast communication to have should reach from the specific distribution server MS1 110-2) is an IP multicast communication monitoring system to check whether or not the communication to. Here, the present invention is not limited to the configuration of each embodiment with respect to a specific source node, a plurality of distribution servers, a plurality of relay nodes, a plurality of edge nodes, and a plurality of viewer terminals. Needless to say.

  The network in each embodiment includes a plurality of distribution servers MS1, MS2 (101-1, 101-2), a plurality of viewer terminals (h1, h2), one source node A (120), and a plurality of It is composed of relay nodes B and C (121 and 122), a plurality of edge nodes D and E (123 and 124), and one maintenance OpS (150).

  Each of the plurality of distribution servers MS1 and MS2 (101-1, 101-2) has a function of transferring an IP multicast packet to an adjacent originating node A (120) after completion of IP multicast transfer and arbitration. .

  Each of the plurality of viewer terminals h1 and h2 has a function of receiving an IP multicast packet transferred from an adjacent edge node.

  The source node A (120) refers to the IP multicast packet received from any of the plurality of adjacent delivery servers MS1, MS2 (101-1, 101-2), and transmits the source information (S) and specific group information. (G) A function for grasping an IP multicast packet, one IP multicast maintenance packet is generated for each grasped source information (S) and specific group information (G), and the referenced IP multicast packet is transferred. A function to transmit to an adjacent relay node of the accepted route, a test mode in which the test mode can be identified when generating an IP multicast maintenance packet (hereinafter referred to as TM), and the order of the IP multicast maintenance packet to be transmitted is determined. Sequence number (SN) and IP multicast maintenance packet pass through A function of inserting the information of the passing route number (RN) that can be grasped by the user into a predetermined storage area, and the transmission source of the IP multicast maintenance packet corresponding to the accepted route after completing the transfer of the IP multicast maintenance packet to the accepted route Information (S), specific group information (G), test mode (TM), function to report sequence number (SN) to maintenance OpS (150), source information (S) and specific group information (G) IP multicast transfer from the downstream adjacent relay node by confirming whether or not the PIM-Join and PIM-Prun, which are the routing control protocols for each combination, are received from the adjacent relay node of the downstream acceptance route When there is an inquiry from the maintenance OpS (150) and the function to grasp the request, the adjacent relay node downstream And a function to report IP multicast forwarding requests from.

  Each of the plurality of relay nodes B and C (121, 122) has a function of forwarding an IP multicast packet and an IP multicast maintenance packet transferred from an adjacent node to an adjacent node of the acceptance route, and an IP multicast maintenance packet adjacent to the acceptance route. When forwarding to a node, a function of assigning a passing route number (RN) of the own node that can identify passing of the own forwarding node to the predetermined storage area in the IP multicast maintenance packet, and a PIM-hello based on a routing protocol Confirming the IP multicast adjacency status with neighboring nodes, and downstream consent for PIM-Join and PIM-Prune for each combination of source information (S) and specific group information (G) Whether it is received from the adjacent node of the route By recognizing the IP multicast transfer request from the downstream adjacent node, and the upstream PIM-Join and PIM-Prun for each combination of the source information (S) and the specific group information (G) By checking whether or not it is transmitting to the node, it is possible to grasp the IP multicast transfer request to the upstream adjacent node, and when there is an inquiry from the maintenance OpS (150), the IP multicast adjacent status and the downstream adjacent It has a function of reporting an IP multicast transfer request from a node and an IP multicast transfer request to an upstream adjacent node.

  Each of the plurality of edge nodes D and E (123, 124) has a function of extracting only an IP multicast maintenance packet from IP multicast packets arriving from adjacent relay nodes, and transmission source information (S in the extracted IP multicast maintenance packet). ), A specific group information (G), a test mode (TM), a sequence number (SN), a passing route number (RN), and a function for reporting to the maintenance OpS (150), source information (S) and By checking whether the query of the terminal viewing management protocol for each combination of specific group information (G) is transmitted to the viewer terminal corresponding to the consent route, the viewing permission status to the viewer terminal is grasped. R of the terminal viewing management protocol for each combination of source function (S) and specific group information (G) By confirming whether or not the port is received from the viewer terminal corresponding to the acceptance route, the function for grasping the viewing request status from the viewer terminal, the transmission source information (S), and the specific group information ( G) a function for grasping an IP multicast transfer request to an upstream adjacent relay node by confirming whether or not PIM-Join and PIM-Prun for each combination are transmitted to the upstream adjacent relay node, and maintenance OpS When inquired from (150), reports the viewing permission status to the viewer terminal corresponding to the accepted route, the viewing request status from the viewer terminal, and the IP multicast transfer request to the upstream adjacent relay node It has the function to do.

  The maintenance OpS (150) transmits / receives information to / from the originating node A (120), each of the plurality of relay nodes B and C (121, 122), and each of the plurality of edge nodes D and E (123, 124). , Transmission source information (S), specific group information (G), test mode (TM), sequence number (SN), and information reported from the source node A (120), reported from the edge node By confirming the source information (S), the specific group information (G), the test mode (TM), the sequence number (SN), and the passing route number (RN), which are the transmitted information, the source node A (120 And a function for confirming whether or not the IP multicast maintenance packet transmitted by (1) has arrived at the edge node to arrive.

  The maintenance OpS (150) inquires according to the necessity of information acquisition at each node, and sends an IP address from an adjacent relay node downstream of the source node A (120) to the source node A (120). The multicast transfer request is confirmed, and for each of the plurality of relay nodes B and C (121, 122), an IP multicast adjacency status grasping request, an IP multicast transfer request from a downstream adjacent node, and an upstream The IP multicast transfer request to the adjacent node is confirmed, and for each of the plurality of edge nodes D and E (123, 124), a request for grasping the viewing permission status to each viewer terminal, and the viewer terminal A request for grasping the viewing request status and a request for forwarding an IP multicast to an upstream adjacent relay node.

  First, an IP multicast arrival monitoring method and system according to a first embodiment of the present invention will be described with reference to FIGS.

(Example 1)
Hereinafter, in the description, the processing for the multicast route (140-1 to 140-6) from MS1 is taken as an example. The IP multicast packet distributed from the distribution server MS1 (101-1) passes through the source node A (120) according to the multicast route (140-1 to 140-6) of the MS1, and then passes through the relay node C (122). It is assumed that, after being copied, it is transmitted to the edge node D (123) and the edge node E (124) and distributed to the viewer terminals h1 and h2. Therefore, the multicast route in the case of passing through the relay node B (121) will not be described, but the operation of the relay node B (121) in this case is the same as that of the relay node C (122).

  First, with reference to FIG. 1, the processing of the originating node A (120) will be described as “processing 1”.

[Process 1]
As processing of the originating node A (120), the following [Processing 1-a] to [Processing 1-c] are performed in a steady state, and [Processing 1-d] is performed when there is an inquiry from the maintenance OpS. .

[Process 1-a]
The originating node A (120) confirms the source information (S) and group number (G) of the passing IP multicast packet (hereinafter referred to as (S, G)).

[Process 1-b]
The originating node A (120) generates an IP multicast maintenance packet of the corresponding (S, G) and inserts it into the multicast route (140-2). At the time of generation, when the packet is inserted, the test mode (TM), sequence A number (SN) and a passing route number (RN) are assigned to the intra-packet payload (details will be described later in FIG. 9). In addition, the originating node A (120) gives a test packet identifier (TPM) for identifying an IP multicast maintenance packet to an empty area of the header in the IP multicast maintenance packet (160). The test packet identifier (TPM) is used to identify whether the packet is an IP multicast packet or an IP multicast maintenance packet in a downstream node (relay node or edge node).

[Process 1-c]
The calling node A (120) reports (S, G), test mode (TM), and sequence number (SN) of the inserted IP multicast maintenance packet to the maintenance OpS.

[Process 1-d]
In addition, when there is an inquiry from the maintenance OpS, the calling node A (120) determines the multicast route (140) for (S, G) corresponding to the IP multicast maintenance packet transmitted to the multicast route (140-2). -2) Confirm the PIM-join / prun transmission status from 2) and report it to the maintenance OpS.

  Next, with reference to FIG. 2, the processing of the relay node C (122) will be described as “processing 2”.

[Process 2]
As processing of the relay node C (122), the following [Processing 2-a] is performed in a steady state, and [Processing 2-b] to [Processing 2-d] are performed when there is an inquiry from the maintenance OpS. To do.

[Process 2-a]
The relay node C (122) refers to the test packet identifier (TPM) to identify it as an IP multicast maintenance packet, and assigns a transit route number (RN) to the multicast routes (140-3) and (140−). 5) Copy and transfer.

[Process 2-b]
When there is an inquiry from the maintenance OpS, the relay node C (122) confirms the PIM-he1lo between the originating node A (120), between the edge nodes E (124), and the edge node D (123). And report to the maintenance OpS.

[Process 2-c]
When there is an inquiry from the maintenance OpS, the relay node C (122) determines the multicast route for (S, G) corresponding to the IP multicast maintenance packet received via the multicast route (140-2). The reception status of PIM-join / prune from (140-3) and (140-4) is confirmed and reported to the maintenance OpS.

[Process 2-d]
In addition, when there is an inquiry from the maintenance OpS, the relay node C (122) determines the multicast for (S, G) corresponding to the IP multicast maintenance packet received via the multicast route (140-2). The PIM-join / prun transmission status to the route (140-2) is confirmed and reported to the maintenance OpS.

  Next, the processing of the edge node processing (10-3) will be described as “processing 3” with reference to FIG.

[Process 3]
As processing of the edge node D (123), the following [Processing 3-a] is performed in a steady state, and [Processing 3-b] to [Processing 3-d] are performed when there is an inquiry from the maintenance OpS. .

[Process 3-a]
The edge node D (123) identifies only the IP multicast maintenance packet received via the multicast route (140-5) by referring to the test packet identifier (TPM) and extracts it, and extracts it. The sequence number (SN) and transit route number (RN) are confirmed and reported to the maintenance OpS.

[Process 3-b]
In addition, when there is an inquiry from the maintenance OpS, the edge node D (123) determines MLDv2 for (S, G) corresponding to the IP multicast maintenance packet received via the multicast route (140-5). : Check the transmission status of the Query to the viewer terminal h2 (110-2) and report it to the maintenance OpS.

[Process 3-c]
In addition, when there is an inquiry from the maintenance OpS, the edge node D (123) determines MLDv2 for (S, G) corresponding to the IP multicast maintenance packet received via the multicast route (140-5). : ReportGoin / 1ave) to the viewer terminal h2 (110-2) is confirmed and reported to the maintenance OpS.

[Process 3-d]
In addition, when there is an inquiry from the maintenance OpS, the edge node D (123) performs multicast for (S, G) corresponding to the IP multicast maintenance packet received via the multicast route (140-5). The PIM-join / Prun transmission status to the route (140-5) is confirmed and reported to the maintenance OpS.

  Similarly, in the edge node E (124), as will be described below, [Process 3-a] is performed in a steady state, and [Process 3-b] to [Process 3-d] are inquiries from the maintenance OpS. It is carried out when there is.

[Process 3-a]
The edge node E (124) identifies only the IP multicast maintenance packet received via the multicast route (140-3) by referring to the test packet identifier (TPM) and extracts it, and extracts it. The sequence number (SN) and transit route number (RN) are confirmed and reported to the maintenance OpS.

[Process 3-b]
When there is an inquiry from the maintenance OpS, the edge node E (124) determines the MLDv2 for (S, G) corresponding to the IP multicast maintenance packet received via the multicast route (140-3). : Check the transmission status of the Query to the viewer terminal h1 (110-1) and report it to the maintenance OpS.

[Process 3-c]
When there is an inquiry from the maintenance OpS, the edge node E (124) determines the MLDv2 for (S, G) corresponding to the IP multicast maintenance packet received via the multicast route (140-3). : Confirm the reception status of Report (join / leave) to the viewer terminal h1 (110-1) and report it to the maintenance OpS.

[Process 3-d]
Further, when there is an inquiry from the maintenance OpS, the edge node E (124) performs multicasting for (S, G) corresponding to the IP multicast maintenance packet received via the multicast route (140-3). The PIM-join / prun transmission status to the route (140-3) is confirmed and reported to the maintenance OpS.

  Next, with reference to FIG. 4, the processing of the maintenance OpS (150) will be described as “processing 4”.

[Process 4]
As the processing of the maintenance OpS (150), the following [Process 4-a] and [Process 4-b] are performed.

[Process 4-a]
The maintenance OpS includes (S, G), test mode (TM), sequence number (SN) of the IP multicast maintenance packet acquired from the originating node A (120) in [Processing 1-a] described above, and the [[ In the process 3-a], the IP multicast maintenance packet acquired from the edge nodes D (123) and E (124) is collated with the test mode (TM), the sequence number (SN), and the transit route number (RN), and the IP Route monitoring is performed by grasping the arrival status of the multicast packet and the IP multicast tree.

[Process 4-b]
The maintenance OpS determines the viewer terminals h1, h2 (110-1, 110-2) from the information from the edge nodes D (123) and E (124) in [Processing 3-b] to [Processing 3-d] described above. ) Confirms whether the IP multicast packet has arrived as requested, and if it is determined that the IP multicast packet has arrived abnormally, if it is determined to be abnormal, [Processing 1-d] The information and the information of [Processing 2-b] to [Processing 2-d] are inquired with respect to the information and the relay node C (122), and fault isolation is performed.

  As described above, by using the method of the first embodiment, it is possible to confirm the IP multicast communication closed in the own network area. Further, in the method of the first embodiment, it is possible to confirm whether IP multicast has reached all terminals that should be reached in units of S and G in a timely manner, and it is possible to grasp the multicast tree, and to provide a timely route. Confirmation is possible.

  Next, an IP multicast arrival monitoring method and system according to a second embodiment of the present invention will be described with reference to FIGS.

(Example 2)
Hereinafter, in the description, the processing for the multicast route (140-1 to 140-6) from MS1 is taken as an example. The IP multicast packet distributed from the distribution server MS1 (101-1) passes through the source node A (120) according to the multicast route (140-1 to 140-6) of the MS1, and then passes through the relay node C (122). It is assumed that, after being copied, it is transmitted to the edge node D (123) and the edge node E (124) and distributed to the viewer terminals h1 and h2. Therefore, the multicast route in the case of passing through the relay node B (121) will not be described, but the operation of the relay node B (121) in this case is the same as that of the relay node C (122).

  First, with reference to FIG. 5, the processing of the external device a (200) will be described as “processing 1”.

[Process 1]
As processing of the external device a (200), the following [Processing 1-a] to [Processing 1-c] are performed in a steady state.

[Process 1-a]
The external device a (200) checks the source information (S) and group number (G) of the passing IP multicast packet (hereinafter referred to as (S, G)).

[Process 1-b]
The external device a (200) generates an IP multicast maintenance packet of the corresponding (S, G) and inserts it for the originating node A (120). At the time of generation, the test mode (TM) A sequence number (SN) and a passing route number (RN) are added to the payload in the packet (details will be described later in FIG. 9). Further, the external device a (200) gives a test packet identifier (TPM) for identifying the IP multicast maintenance packet to the empty area of the header in the IP multicast maintenance packet. This test packet identifier (TPM) is used to identify whether the packet is an IP multicast packet or an IP multicast maintenance packet in a downstream node (relay node or edge node, or downstream external device). .

[Process 1-c]
The external device a (200) reports the (S, G), test mode (TM), and sequence number (SN) of the inserted IP multicast maintenance packet to the maintenance OpS.

  Next, referring to FIG. 6, the processing of the external devices c, f, g (202, 207, 205) operates in the same manner as “Process 2”. First, the processing of the external device c (202) is performed. explain.

[Process 2]
As processing of the external device c (202), the following [Processing 2-a] is performed in a steady state, and [Processing 2-b] to [Processing 2-c] are performed when there is an inquiry from the maintenance OpS. To do.

[Process 2-a]
The external device c (202) refers to the test packet identifier (TPM), identifies it as an IP multicast maintenance packet, confirms the IP multicast maintenance packet, assigns a passing route number (RN), and sends a multicast route. Forward to relay node C (122) on (140-2).

[Process 2-b]
In addition, when there is an inquiry from the maintenance OpS, the external device c (202) confirms the PIM-he 11o between the originating node A (120) and the relay node C (122) to perform maintenance. Report to OpS.

[Process 2-c]
When there is an inquiry from the maintenance OpS, the external device c (202) transmits the relay node C ((S, G) corresponding to the IP multicast maintenance packet received from the originating node A (120). 122) The PIM-join / prun reception status from 122) is confirmed and reported to the maintenance OpS.

  Next, in the external device f (207), the following [Processing 2-a] is performed in a steady state, and [Processing 2-b] to [Processing 2-c] are performed when there is an inquiry from the maintenance OpS. carry out.

[Process 2-a]
The external device f (207) identifies the IP multicast maintenance packet by referring to the test packet identifier (TPM), confirms the IP multicast maintenance packet, assigns a passing route number (RN), and sends the multicast route. Transfer to the edge node E (124) on (140-2).

[Process 2-b]
In addition, when there is an inquiry from the maintenance OpS, the external device f (207) confirms the PIM-hello between the relay nodes C (122) and the edge node E (124), and performs maintenance. Report to OpS.

[Process 2-c]
When there is an inquiry from the maintenance OpS, the external device f (207) determines the edge node E (for the (S, G) corresponding to the IP multicast maintenance packet received from the relay node C (122). 124) The PIM-join / prun reception state from 124) is confirmed and reported to the maintenance OpS.

  At the same time, the following [Processing 2-a] was also carried out in a steady manner in the external device g (205), and [Processing 2-b] to [Processing 2-c] were inquired from the maintenance OpS. When to do.

[Process 2-a]
The external device g (205) refers to the test packet identifier (TPM), identifies it as an IP multicast maintenance packet, confirms the IP multicast maintenance packet, assigns a passing route number (RN), and sends a multicast route. Transfer to the edge node D (123) on (140-2).

[Process 2-b]
In addition, when there is an inquiry from the maintenance OpS, the external device g (205) checks the PIM-he 11o between the relay node C (122) and the edge node D (123) to perform maintenance. Report to OpS.

[Process 2-c]
When there is an inquiry from the maintenance OpS, the external device g (205) sends the edge node D ((S, G) corresponding to the IP multicast maintenance packet received from the relay node C (122). 123) The reception state of the PIM-join / prune from 123) is confirmed and reported to the maintenance OpS.

  Next, referring to FIG. 7, the processing of the external device k, l (210, 211) operates similarly as “processing 3”. First, the processing of the external device k (210) will be described.

[Process 3]
As processing of the external device k (210), the following [Processing 3-a] is performed in a steady state, and [Processing 3-b] to [Processing 3-c] are performed when there is an inquiry from the maintenance OpS. To do.

[Process 3-a]
The external device k (210) identifies only the IP multicast maintenance packet received from the edge node E (124) by referring to the test packet identifier (TPM), extracts it, and extracts the sequence number ( SN) and transit route number (RN) are confirmed and reported to the maintenance OpS.

[Process 3-b]
When there is an inquiry from the maintenance OpS, the external device k (210) determines the edge node E ((S, G) corresponding to the IP multicast maintenance packet received from the edge node E (124). 124) confirms the MLDv2: Query transmission status from the viewer terminal h2 (110-2) to the maintenance OpS.

[Process 3-c]
In addition, when there is an inquiry from the maintenance OpS, the external device k (210) sends MLDv2: Report () for (S, G) corresponding to the IP multicast maintenance packet received from the edge node E (124). The reception state from the viewer terminal h2 (110-2) of join / leave) to the edge node E (124) is confirmed and reported to the maintenance OpS.

  The external device 1 (211) also performs the following [Process 3-a] in a steady state, and performs [Process 3-b] to [Process 3-c] when there is an inquiry from the maintenance OpS. .

[Process 3-a]
The external device l (211) identifies only the IP multicast maintenance packet received from the edge node D (123) by referring to the test packet identifier (TPM) and extracts it, and extracts the sequence number ( SN) and weekly route number (RN) are confirmed and reported to the maintenance OpS.

[Process 3-b]
When there is an inquiry from the maintenance OpS, the external device l (211) sends the edge node D ((S, G) corresponding to the IP multicast maintenance packet received from the edge node D (123). 123) confirms the transmission status of the MLDv2: Query from the viewer terminal h1 (110-1) to the maintenance OpS.

[Process 3-c]
In addition, when there is an inquiry from the maintenance OpS, the external device l (211) performs MLDv2: Report () on (S, G) corresponding to the IP multicast maintenance packet received from the edge node d (123). The reception state from the viewer terminal h1 (110-1) of join / leave) to the edge node D (123) is confirmed and reported to the maintenance OpS.

  Next, with reference to FIG. 8, the processing of the maintenance OpS (150) will be described as “processing 4”.

[Process 4]
As the processing of the maintenance OpS (150), the following [Process 4-a] and [Process 4-b] are performed.

[Process 4-a]
The maintenance OpS (150) includes (S, G), test mode (TM), sequence number (SN) of the IP multicast maintenance packet acquired from the external device a (200) in [Process 1-a] described above, The test mode (TM), sequence number (SN), and transit route number (RN) of the IP multicast maintenance packet acquired from the external devices k (210) and l (211) in the above [Process 3-a] The route is checked by checking the arrival status of the IP multicast packet and the IP multicast tree.

[Process 4-b]
The maintenance OpS (150), as requested by the viewing host h (110), from the information from the external devices k (210) and l (211) in [Processing 3-b] to [Processing 3-d] described above. The arrival normality of whether the IP multicast packet has arrived at the destination is confirmed, and if it is determined that there is an abnormality, the external devices c (202), f (207) and g (205) on the multicast route 2-b] to [Processing 2-c] are inquired, and fault isolation is performed.

  As described above, according to the method of the second embodiment, even when an external device is used, it is possible to check the IP multicast communication closed in the own network area. Further, in the method of the second embodiment, it is possible to check whether IP multicast has reached all terminals that should be reached in units of S and G in a timely manner, and to understand the multicast tree, and to provide a timely route. Confirmation is possible.

  Further, according to the method of the second embodiment, it is possible to avoid the problems of “whether the function of each node can be changed” and “restriction of function inclusion depending on the functional performance condition of each node”.

  Next, an IP multicast arrival monitoring method and system according to a third embodiment of the present invention will be described with reference to FIGS. In the IP multicast arrival monitoring system of the first or second embodiment described above, this is an example of checking the band usage status, and further functions are provided for the IP multicast arrival monitoring system of the first or second embodiment.

(Example 3)
That is, the IP multicast arrival monitoring system according to the third embodiment is further compared with the IP multicast arrival monitoring system according to the first or second embodiment in a certain measurement period (hereinafter referred to as T) in the test mode (TM). Mode type (hereinafter, referred to as “forwarding band mode”) for confirming the data amount (hereinafter referred to as “forwarding band”) of the IP multicast maintenance packet to be transferred and other tests (hereinafter referred to as “normal mode”). Hereafter referred to as MD), and when the mode type (MD) is in the bandwidth confirmation mode, information on the packet status (hereinafter referred to as PST) that can distinguish the first packet, intermediate packet, and last packet transferred in the transfer bandwidth mode, , Information on the fixed measurement period (T), information on the IP multicast maintenance packet length (hereinafter referred to as M), and the fixed IP multicast service packet number sent within the time of measurement period (T) is configured to hold the information (hereinafter, referred to as N).

  Then, when confirming the transfer bandwidth by the maintenance OpS (150), the originating node A (120) registers the bandwidth confirmation mode in the mode type (MD), the packet status (PST), and a fixed measurement period (T ), IP multicast maintenance packet length (M), number of IP multicast maintenance packets (N), and a function of transferring the IP multicast maintenance packet to the adjacent relay node of the accepted route, and a plurality of edge nodes D and E (123, 124) ) Refer to the mode type (MD) of the IP multicast maintenance packet that arrives and is extracted from the adjacent relay node, and in the bandwidth confirmation mode, the packet status (PST), the fixed measurement period (T), the IP multicast Retrieve information on maintenance packet length (M) and number of IP multicast maintenance packets (N) It has a function.

  In addition, the maintenance OpS (150) sets “mode type (MD) = bandwidth confirmation mode” and “packet status (PST) to any one of the plurality of edge nodes D and E (123, 124) whose transfer bandwidth is to be confirmed. When the IP multicast maintenance packet of “) = first packet” arrives, it is determined that the confirmation test in the bandwidth confirmation mode has started, and the IP multicast maintenance arrived from “packet status (PST) = intermediate packet” until the final packet is reached. It has a function to calculate the transfer bandwidth from information of packet status (PST), constant measurement period (T), IP multicast maintenance packet length (M), and number of IP multicast maintenance packets (N) for each packet.

  FIG. 9 shows information in the IP multicast maintenance packet showing the principle of the present invention. When checking whether or not the IP multicast packet is using the required bandwidth (hereinafter referred to as bandwidth usage status confirmation), the test mode (TM) area is used for identification.

Details of the test mode (TM) (161) show the breakdown of parameters.
MD: Mode identification (normal mode / bandwidth confirmation mode),
PST: Packet status (first packet / intermediate packet / last packet),
T: Measurement interval (when sending from the first packet to the end of the last packet: sec),
M: packet length (bit),
N: Number of packets (number of packets sent within the measurement interval (T): number)
From this parameter, the transfer bandwidth is (1 to N) ΣM / T.

  Next, the operation will be described with reference to FIG. In the description, an example of processing in which an IP multicast packet is transferred through the IP multicast route (140) from the MS1 will be described.

  In the case of “confirmation of bandwidth usage”, the bandwidth confirmation mode is set in the mode identification (MD) in the test mode (TM) of the IP multicast maintenance packet to be inserted at the originating node A (120).

  In the band confirmation mode, the packet status (PST), measurement interval (T), packet length (M), and number of packets (N) are set. Note that M allows a variable value for each packet, and T and M must be set when PST = first packet.

  When the originating node A (120) starts sending an IP multicast maintenance packet in which MD = bandwidth confirmation mode and PST = first packet are set to the relay node C, “bandwidth usage confirmation” is started. The originating node A (120) sends out the packet set to the number of packets (N) within the measurement interval (T).

  In response to the inquiry from the maintenance OpS (150), the edge node E (124) and the edge node D (123) send the IP multicast maintenance packet in the band confirmation mode (MD) in which the transferred PST is from the first packet to the last packet. , Calculate the transfer bandwidth based on the extracted T, M, and N using Equation (1), check the bandwidth usage status, and report to the maintenance OpS (150).

  As described above, by using the method of the third embodiment, it is possible to confirm the IP multicast communication closed in the own network area. In addition, in this method, it is possible to confirm whether IP multicast has reached all terminals that should be reached in units of S and G in a timely manner, and it is possible to grasp the multicast tree and to confirm timely routes. is there.

  In addition, since the test mode has a function of a bandwidth confirmation mode, it is possible to confirm the bandwidth usage status of the IP multicast in a timely manner assuming bandwidth compensation.

  Further, in each of the above-described embodiments, the steady state is only a notification to the maintenance OpS from the source node and the edge node, and each node does not need to store a large amount of information as a database. The influence on the node performance when incorporating the above function into each node can be reduced.

  Although specific embodiments have been described in the above-described embodiments, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the invention. For example, it can also be realized by combining the first or second embodiment. Accordingly, the invention is not limited by the embodiments described above, but only by the claims.

  Since it becomes possible to confirm whether or not communication is possible from a specific server to a plurality of viewer terminals, it is useful for multicast communication.

It is a block diagram of the IP multicast arrival monitoring system of Example 1 by the present invention (the 1). FIG. 3 is a block diagram of the IP multicast arrival monitoring system according to the first embodiment of the present invention (No. 2). It is a block diagram of the IP multicast arrival monitoring system of Example 1 by the present invention (the 3). It is a block diagram of the IP multicast arrival monitoring system of Example 1 by this invention (the 4). It is a block diagram of the IP multicast arrival monitoring system of Example 2 by the present invention (the 1). It is a block diagram of the IP multicast arrival monitoring system of Example 2 by the present invention (the 2). It is a block diagram of the IP multicast arrival monitoring system of Example 2 by the present invention (the 3). It is the block diagram of the IP multicast arrival monitoring system of Example 2 by this invention (the 4). It is a figure which shows the information in an IP multicast maintenance packet of one Example by this invention. It is a block diagram of the IP multicast arrival monitoring system of Example 3 by this invention. It is a block diagram of the conventional IP multicast arrival monitoring system (the 1). It is a block diagram of the conventional IP multicast arrival monitoring system (the 2).

Explanation of symbols

101-1, 101-2 distribution server MS1, MS2
110-1, 110-2 Viewer terminals h1, h2
115 Local network area 116 Distribution server side 117 User side 118, 119 Network boundary point 120 is
121 and 122 are relay nodes B and C
123 and 124 are edge nodes D and E, respectively.
140-1 to 140-6 Multicast Route 150 Maintenance OpS
160 Breakdown of IP multicast maintenance packet information 161 Detailed information in test mode (TM),
200 to 211 External devices a to l

Claims (8)

A method for monitoring IP multicast communication in a network composed of a plurality of nodes connecting a plurality of distribution servers and a plurality of viewer terminals,
The originating node that communicates with the specific distribution server grasps the IP multicast packet for each of the transmission source information and the specific group information during the communication, and sequences the packet payload for each combination of the transmission source information and the specific group information. Generating an IP multicast maintenance packet having a storage area for the number and the passage route number, inserting a predetermined sequence number and the passage route number of the own node into the storage area, and transmitting to the downstream node together with the IP multicast packet;
Each of the downstream nodes gives the IP multicast maintenance packet a passage route number that can identify the passage of the self-forwarding node, and forwards it together with the IP multicast packet toward one or more viewer terminals.
A maintenance OpS that can be connected to each node in the network acquires route communication information from each node. In the IP multicast communication monitoring method in a network composed of a plurality of nodes connecting a plurality of distribution servers and a plurality of viewer terminals, the IP multicast adjacency confirmation is completed between the plurality of nodes, and the IP multicast IP multicast communication having source information and specific group information indicating that it has been transmitted from a specific distribution server among a plurality of nodes performing IP multicast communication via an approved route for which the transfer request is approved Is an IP multicast communication monitoring method for confirming whether communication is made to the plurality of viewer terminals to be reached from the specific distribution server,
The network is composed of a plurality of distribution servers, a plurality of viewer terminals, a single originating node, a plurality of relay nodes, a plurality of edge nodes, and a single maintenance OpS.
The processing of each of the plurality of distribution servers is as follows:
A process of forwarding an IP multicast packet to an adjacent originating node after completion of IP multicast forwarding and arbitration;
The processing of each of the plurality of viewer terminals is as follows:
Receiving IP multicast packets forwarded from adjacent edge nodes;
The processing of the originating node is as follows:
A process of referring to an IP multicast packet received from any of the plurality of adjacent delivery servers and grasping the IP multicast packet of the source information and the specific group information;
A process of generating one IP multicast maintenance packet for each of the grasped source information and the specific group information, and transmitting the generated IP multicast maintenance packet to an adjacent relay node of an accepted route to which the referred IP multicast packet is transferred;
When generating the IP multicast maintenance packet,
Insert the test mode that can identify the test mode, the sequence number that can determine the order of the IP multicast maintenance packet to be transmitted, and the information of the route number that can be used to know the route that the IP multicast maintenance packet passes through into the predetermined storage area. Processing to
A process of reporting the source information, specific group information, test mode, and sequence number of the IP multicast maintenance packet corresponding to the accepted route to the maintenance OpS after the transfer of the IP multicast maintenance packet to the accepted route is completed;
By confirming whether PIM-Join and PIM-Prun, which are path control protocols for each combination of the transmission source information and specific group information, are received from the adjacent relay node of the downstream acceptance route, A process of grasping an IP multicast transfer request from a relay node of
A process of reporting an IP multicast transfer request from the adjacent downstream relay node when inquired from the maintenance OpS,
The processing of each of the plurality of relay nodes is as follows:
A process of transferring the IP multicast packet and the IP multicast maintenance packet transferred from the adjacent node to the adjacent node of the acceptance route;
When transferring the IP multicast maintenance packet to an adjacent node of the acceptance route, a process of assigning a passing route number of the own node that can identify passing of the own forwarding node to the predetermined storage area in the IP multicast maintenance packet;
A process of grasping the IP multicast adjacency status with an adjacent node by confirming the PIM-hello based on the routing protocol;
IP multicast transfer from downstream neighboring nodes by checking whether or not PIM-Join and PIM-Prun for each combination of transmission source information and specific group information are received from neighboring nodes of downstream consent route Processing to understand the request,
A process of grasping an IP multicast transfer request to an upstream adjacent node by confirming whether or not PIM-Join and PIM-Prun for each combination of transmission source information and specific group information are transmitted to the upstream adjacent node; ,
When there is an inquiry from the maintenance OpS, the processing includes reporting the IP multicast adjacency status, an IP multicast transfer request from a downstream adjacent node, and an IP multicast transfer request to an upstream adjacent node,
The processing of each of the plurality of edge nodes is as follows:
A process of extracting only an IP multicast maintenance packet from IP multicast packets arriving from adjacent relay nodes;
Processing for confirming the source information, specific group information, test mode, sequence number, passage route number in the extracted IP multicast maintenance packet and reporting to the maintenance OpS;
By confirming whether or not the query of the terminal viewing management protocol for each combination of the transmission source information and the specific group information is transmitted to the viewer terminal corresponding to the consent route, the viewing permission status to the viewer terminal is determined. Process to understand,
By confirming whether or not the report of the terminal viewing management protocol for each combination of the transmission source information and the specific group information is received from the corresponding viewer terminal of the acceptance route, the viewing request status from the viewer terminal is determined. Process to understand,
By confirming whether or not the PIM-Join and PIM-Prun for each combination of the transmission source information and specific group information are transmitted to the upstream adjacent relay node, an IP multicast transfer request to the upstream adjacent relay node is made. Process to understand,
When inquired from the maintenance OpS, reports the viewing permission status to the viewer terminal corresponding to the accepted route, the viewing request status from the viewer terminal, and the IP multicast transfer request to the upstream adjacent relay node. Processing to include,
The maintenance OpS process is as follows:
A process of transmitting and receiving information to and from the source node, each of the plurality of relay nodes, and each of the plurality of edge nodes;
Source information which is information reported from the source node, specific group information, test mode and sequence number, and source information which is information reported from the edge node, specific group information, test mode and sequence number , And confirming whether or not the IP multicast maintenance packet transmitted by the originating node has arrived at the edge node to arrive by confirming the passing route number,
An IP multicast communication monitoring method characterized by confirming communication in a network composed of a plurality of nodes connecting a plurality of distribution servers and a plurality of viewer terminals by the maintenance OpS. . In the IP multicast arrival monitoring method according to claim 2,
The maintenance OpS process further inquires according to the necessity of information acquisition in each node,
For the originating node, confirm an IP multicast forwarding request from an adjacent relay node downstream of the originating node,
For each of the plurality of relay nodes, confirm the IP multicast adjacency status grasp request, the IP multicast transfer request from the downstream adjacent node, and the IP multicast transfer request to the upstream adjacent node,
For each of the plurality of edge nodes, a request for grasping the viewing permission status to each viewer terminal, a request for grasping the viewing request status from the viewer terminal, and IP multicast transfer to an upstream adjacent relay node An IP multicast communication monitoring method comprising a process of confirming a request. In the IP multicast arrival monitoring method according to claim 2 or 3,
In the test mode,
A mode type for determining a transfer bandwidth mode as a test for confirming a transfer bandwidth as a data amount of an IP multicast maintenance packet to be transferred in a certain measurement period, and a normal mode as another test;
When the mode type is a bandwidth confirmation mode,
Packet status information that can distinguish the first packet, intermediate packet, and last packet transferred in the transfer bandwidth mode,
Information on the fixed measurement period;
IP multicast maintenance packet length information,
Information of the number of IP multicast maintenance packets sent within the time of the predetermined measurement period is held,
When confirming the transfer bandwidth by the maintenance OpS,
The processing of the originating node is as follows:
Processing for registering the bandwidth confirmation mode in the mode type, setting the packet status, a fixed measurement period, the IP multicast maintenance packet length, the number of IP multicast maintenance packets, and transferring the IP multicast maintenance packet to the adjacent relay node of the accepted route When,
Each of the plurality of edge nodes refers to the mode type of an IP multicast maintenance packet that has arrived and extracted from an adjacent relay node. In the bandwidth confirmation mode, the packet status, a fixed measurement period, an IP multicast maintenance packet length, an IP And processing for retrieving information on the number of multicast maintenance packets,
The maintenance OpS process is as follows:
Bandwidth confirmation mode confirmation test when an IP multicast maintenance packet of “mode type = bandwidth confirmation mode” and “packet status = first packet” arrives at any of the plurality of edge nodes subject to transfer bandwidth confirmation From the information of the packet status for each IP multicast maintenance packet that has arrived from the “packet status = intermediate packet” to the final packet, a certain measurement period, the IP multicast maintenance packet length, and the number of IP multicast maintenance packets Including the process of calculating the transfer bandwidth,
An IP multicast communication monitoring method characterized in that the transfer bandwidth in a network composed of a plurality of nodes connecting a plurality of distribution servers and a plurality of viewer terminals is confirmed by the maintenance OpS. . An IP multicast communication monitoring system for monitoring IP multicast communication in a network composed of a plurality of nodes connecting a plurality of distribution servers and a plurality of viewer terminals,
The originating node that communicates with the specific distribution server has a function of grasping the IP multicast packet for each of the transmission source information and the specific group information in communication, and the packet payload for each combination of the transmission source information and the specific group information. A function of generating an IP multicast maintenance packet having a storage area for a sequence number and a passing route number, and a function for inserting a predetermined sequence number and a passing route number of the own node into the storing area and transmitting the packet to a downstream node Have
Each of the downstream nodes has a function of giving a route route number of the node of the packet and transferring the packet together with the IP multicast packet to one or more viewer terminals,
The maintenance OpS that can be connected to each node in the network has a function of dropping an IP multicast maintenance packet from each node and monitoring a path communication property. In an IP multicast communication monitoring system in a network composed of a plurality of nodes connecting a plurality of distribution servers and a plurality of viewer terminals, the IP multicast adjacency confirmation is completed between the plurality of nodes, and the IP multicast IP multicast communication having source information and specific group information indicating that it has been transmitted from a specific distribution server among a plurality of nodes performing IP multicast communication via an approved route for which the transfer request is approved Is an IP multicast communication monitoring system for confirming whether communication is made from the specific distribution server to the plurality of viewer terminals to be reached,
The network is composed of a plurality of distribution servers, a plurality of viewer terminals, a single originating node, a plurality of relay nodes, a plurality of edge nodes, and a single maintenance OpS.
Each of the plurality of distribution servers is
After completion of IP multicast transfer and arbitration, it has a function to transfer IP multicast packets to adjacent originating nodes;
Each of the plurality of viewer terminals is
A function of receiving an IP multicast packet transferred from the adjacent edge node;
The source node is
A function of referring to an IP multicast packet received from any of the plurality of adjacent delivery servers, and grasping the IP multicast packet of the source information and the specific group information;
A function of generating one IP multicast maintenance packet for each of the grasped source information and the specific group information, and transmitting the IP multicast maintenance packet to an adjacent relay node of an accepted route to which the referred IP multicast packet is transferred;
When generating the IP multicast maintenance packet,
Insert the test mode that can identify the test mode, the sequence number that can determine the order of the IP multicast maintenance packet to be transmitted, and the information of the route number that can be used to know the route that the IP multicast maintenance packet passes through into the predetermined storage area. Function to
A function of reporting transmission source information, specific group information, test mode, and sequence number of the IP multicast maintenance packet corresponding to the accepted route to the maintenance OpS after the transfer of the IP multicast maintenance packet to the accepted route is completed;
By confirming whether PIM-Join and PIM-Prun, which are path control protocols for each combination of the transmission source information and specific group information, are received from the adjacent relay node of the downstream acceptance route, A function of grasping an IP multicast transfer request from a relay node of
A function of reporting an IP multicast transfer request from the downstream adjacent relay node when inquired from the maintenance OpS;
The plurality of relay nodes are:
A function of transferring the IP multicast packet and the IP multicast maintenance packet transferred from the adjacent node to the adjacent node of the acceptance route;
A function of assigning, to the predetermined storage area in the IP multicast maintenance packet, a passing route number of the own node capable of identifying passing of the own forwarding node when transferring the IP multicast maintenance packet to an adjacent node of the acceptance route;
A function of grasping an IP multicast adjacency situation with an adjacent node by confirming a PIM-hello based on the routing protocol;
IP multicast transfer from downstream neighboring nodes by checking whether or not PIM-Join and PIM-Prun for each combination of transmission source information and specific group information are received from neighboring nodes of downstream consent route The ability to understand the requirements,
A function of grasping an IP multicast transfer request to an upstream adjacent node by confirming whether or not PIM-Join and PIM-Prun for each combination of transmission source information and specific group information are transmitted to the upstream adjacent node; ,
A function of reporting the IP multicast adjacency status, an IP multicast transfer request from a downstream adjacent node, and an IP multicast transfer request to an upstream adjacent node when inquired from the maintenance OpS;
Each of the plurality of edge nodes is
Among IP multicast packets arriving from adjacent relay nodes, a function of extracting only an IP multicast maintenance packet;
Processing for confirming the source information, specific group information, test mode, sequence number, passage route number in the extracted IP multicast maintenance packet and reporting to the maintenance OpS;
By confirming whether or not the query of the terminal viewing management protocol for each combination of the transmission source information and the specific group information is transmitted to the viewer terminal corresponding to the consent route, the viewing permission status to the viewer terminal is determined. The ability to understand,
By confirming whether or not the report of the terminal viewing management protocol for each combination of the transmission source information and the specific group information is received from the corresponding viewer terminal of the acceptance route, the viewing request status from the viewer terminal is determined. The ability to understand,
By confirming whether or not the PIM-Join and PIM-Prun for each combination of the transmission source information and specific group information are transmitted to the upstream adjacent relay node, an IP multicast transfer request to the upstream adjacent relay node is made. The ability to understand,
When inquired from the maintenance OpS, reports the viewing permission status to the viewer terminal corresponding to the accepted route, the viewing request status from the viewer terminal, and the IP multicast transfer request to the upstream adjacent relay node. And has a function to
The maintenance OpS is
A function of transmitting and receiving information to and from the source node, each of the plurality of relay nodes, and each of the plurality of edge nodes;
Source information which is information reported from the source node, specific group information, test mode and sequence number, and source information which is information reported from the edge node, specific group information, test mode and sequence number A function for confirming whether an IP multicast maintenance packet transmitted by the originating node has arrived at an edge node to arrive by confirming a passing route number;
An IP multicast communication monitoring system characterized in that the maintenance OpS confirms communication in a network composed of a plurality of nodes connecting a plurality of distribution servers and a plurality of viewer terminals. . In the IP multicast arrival monitoring system according to claim 6,
The maintenance OpS further inquires according to the necessity of information acquisition at each node,
For the originating node, confirm an IP multicast forwarding request from an adjacent relay node downstream of the originating node,
For each of the plurality of relay nodes, confirm the IP multicast adjacency status grasp request, the IP multicast transfer request from the downstream adjacent node, and the IP multicast transfer request to the upstream adjacent node,
For each of the plurality of edge nodes, a request for grasping the viewing permission status to each viewer terminal, a request for grasping the viewing request status from the viewer terminal, and IP multicast transfer to an upstream adjacent relay node An IP multicast communication monitoring system having a function of confirming a request. In the IP multicast arrival monitoring system according to claim 6 or 7,
In the test mode,
A mode type for determining a transfer bandwidth mode as a test for confirming a transfer bandwidth as a data amount of an IP multicast maintenance packet to be transferred in a certain measurement period, and a normal mode as another test;
When the mode type is a bandwidth confirmation mode,
Packet status information that can distinguish the first packet, intermediate packet, and last packet transferred in the transfer bandwidth mode,
Information on the fixed measurement period;
IP multicast maintenance packet length information,
Information of the number of IP multicast maintenance packets sent within the time of the predetermined measurement period is held,
When confirming the transfer bandwidth by the maintenance OpS,
The source node is
A function of registering a bandwidth confirmation mode in the mode type, setting a packet status, a fixed measurement period, an IP multicast maintenance packet length, and the number of IP multicast maintenance packets, and transferring the IP multicast maintenance packet to an adjacent relay node of the accepted route When,
Each of the plurality of edge nodes refers to the mode type of an IP multicast maintenance packet that has arrived and extracted from an adjacent relay node. In the bandwidth confirmation mode, the packet status, a fixed measurement period, an IP multicast maintenance packet length, an IP A function to extract information on the number of multicast maintenance packets,
The maintenance OpS is
Bandwidth confirmation mode confirmation test when an IP multicast maintenance packet of “mode type = bandwidth confirmation mode” and “packet status = first packet” arrives at any of the plurality of edge nodes subject to transfer bandwidth confirmation From the information of the packet status for each IP multicast maintenance packet that has arrived from the “packet status = intermediate packet” to the final packet, a certain measurement period, the IP multicast maintenance packet length, and the number of IP multicast maintenance packets Has the function to calculate the transfer bandwidth,
An IP multicast communication monitoring system characterized in that a transfer bandwidth in a network composed of a plurality of nodes connecting between a plurality of distribution servers and a plurality of viewer terminals is confirmed by the maintenance OpS. .

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