JP5465328B2 - Wireless communication apparatus and wireless communication method - Google Patents

Description

  The present invention relates to a wireless communication apparatus and a wireless communication method.

  For example, Non-Patent Document 1 discloses the specification of an OLSR (Optimized Link State Routing) protocol that is one of ad hoc network routing protocols. This OLSR is a protocol for unicast transmission, but there is known a MOLSR (Multicast Optimized Link State Routing) protocol in which OLSR is extended for multicast transmission. The MOLSR performs multicast transmission by flooding various messages based on the relay node and route information acquired by the OLSR.

T. Clausen et al., "Optimized Link State Routing Protocol", October 2003, The Internet Society, [searched May 31, 2010], Internet URL http: // www. Ietf.org/rfc/rfc3626.txt

MOLSR is a protocol related to multicast transmission in a wireless network, and is not considered for cooperation with a wired network. That is, the MOLSR cannot transmit a multicast packet that flows through the wireless network to the wired network, or cannot transmit a multicast packet that flows through the wired network to the wireless network.
For example, PIM (Protocol-Independent Multicast) is known as a protocol for multicast transmission in a wired network. However, even if both PIM and MOLSR are implemented, they are completely independent protocols. And multicast transmission that supports both wired and wired networks cannot be realized.

  The present invention has been made from the above-described background, and an object thereof is to provide a wireless communication apparatus and a wireless communication method capable of multicast transmission compatible with both a wireless network and a wired network connected to each other.

  A wireless communication apparatus according to the present invention is a wireless communication apparatus connected to both a wireless network and a wired network, and participates in a multicast group existing in the wired network according to a multicast transmission protocol used in the wired network. Means for acquiring terminal information, means for constructing an information base indicating that the multicast packet transmitted from the terminal is relayed to a wireless network based on the acquired information of the multicast group participating terminal, and the constructed Based on the information base, it comprises a means for relaying a multicast packet transmitted from the wired network to the wireless network.

  The wireless communication method according to the present invention is a wireless communication method in a wireless communication device connected to both a wireless network and a wired network, according to a multicast transmission protocol used in the wired network, Acquire information on multicast group participating terminals existing in the wired network, and build an information base indicating that multicast packets transmitted from the terminals are relayed to the wireless network based on the acquired multicast group participating terminal information. The multicast packet transmitted from the wired network is relayed to the wireless network based on the constructed information base.

  According to the wireless communication apparatus and the wireless communication method according to the present invention, it is possible to realize multicast transmission corresponding to both a wireless network and a wired network connected to each other.

It is a figure which shows the communication system concerning embodiment of this invention. It is a figure which shows the hardware constitutions of the wireless router shown in FIG. It is a figure which shows the communication program which operate | moves in each wireless router shown in FIG. It is a sequence diagram which shows the group joining / leaving process performed by the wireless router and the wired network side. This is a format of a group member join / leave application message transmitted from the wired router to the wireless router. It is a sequence diagram which shows the process of the communication program when a group member participation application message is received. FIG. 10 is a sequence diagram illustrating multicast group join / leave processing performed based on information from a wired network in a wireless router. It is a figure which illustrates transmission / reception of the message between several communication apparatuses. It is a figure which illustrates transmission / reception of the message between several communication apparatuses. It is a figure which shows the format of the SourceClaim message and ConfirmParent message which concern on this invention. It is a sequence diagram which shows the joining / leaving process of the multicast group performed based on the information from a wireless network in a wireless router.

  Hereinafter, multicast transmission corresponding to both the wireless network and the wired network will be described. The present invention is an improvement of MOLSR, which is a protocol for multicast transmission in a wireless network.

FIG. 1 is a diagram showing a communication system 1 according to an embodiment of the present invention.
As shown in FIG. 1, the communication system 2 includes wireless routers (wireless communication devices) 20-1 to 20-3, wired routers 120-1 to 120-4, and terminals 140-1 to 140-4. You are building a wireless network and a wired network connected to.

As shown in FIG. 1, the wireless router 20-1 (wireless router # 1) and the wireless router 20-2 (wireless router # 2) establish a link with each other via a wireless communication line, A link is established with the wireless router 20-3 (wireless router # 3) via a wireless communication line.
That is, a wireless network is constructed by the wireless router 20-1, the wireless router 20-2, and the wireless router 20-3. When data is transmitted from the wireless router 20-1 to the wireless router 20-3, the wireless router 20-2 becomes a relay node that relays data.
In the following description, devices such as the wireless router 20 that can be the subject of information processing and communication in the communication system may be collectively referred to as nodes.

A wired network is connected to each of the wireless routers 20-1 to 20-3. Specifically, the wired router 120-1 is wired to the wireless router 20-1, and the terminal 140-1 is wired to the wired router 120-1 (this wireless router 20-1 and wired router 120-1 And a system of a wired network made up of the terminal 140-1 and system # 1).
Similarly, the wired router 120-2 is wired to the wireless router 20-2, and the terminal 140-2 is wired to the wired router 120-2 (this wireless router 20-2, wired router 120-2, and terminal The system of the wired network consisting of 140-2 is referred to as system # 2.)
Furthermore, the wired routers 120-3 and 120-4 are wired to the wireless router 20-3, and the terminals 140-3 and 140-4 are wired to the wired routers 120-3 and 120-4, respectively (this wireless A system of a wired network composed of the router 20-3, the wired routers 120-3 and 120-4, and the terminals 140-3 and 140-4 is referred to as a system # 3).
That is, the wired router 120 relays communication between the wireless router 20 and the terminal 140.

FIG. 2 is a diagram illustrating a hardware configuration of the wireless router 20 illustrated in FIG.
As shown in FIG. 2, the wireless router 20 includes a control unit 20a having a CPU and a memory, a transmission / reception circuit 20b that performs baseband processing such as modulation / demodulation, a wireless unit 20c that performs power amplification of transmission / reception signals, an antenna 20d, a wired network, and the like. An interface (I / F) 20e is provided.
The control unit 20a performs a routing process described later on data transmitted / received via the wireless transmission / reception system (transmission / reception circuit 20b, wireless unit 20c, antenna 20d) and data transmitted / received via the wired network interface.
The wireless router 20 performs the routing process, but may have a function as a general wireless terminal.
That is, the wireless router 20 simply transmits information received from the wired terminal 140 to the other wireless router 20 and transmits information received from the other wireless router 20 to the wired terminal 140. Alternatively, the wireless router 20 itself may create a multicast packet and transmit it to another wireless router 20, the wired router 120, and the terminal 140.
The wired router 120 shown in FIG. 1 has a general hardware configuration as a router, and the terminal 140 also has a hardware configuration as a general communication terminal such as a PC. Detailed description is omitted.

FIG. 3 is a diagram showing a communication program 30 that operates in each wireless router 20 shown in FIG.
The communication program 30 is stored in a memory in the control unit 20a, for example, and is executed by a CPU or the like.
That is, the communication program 30 is executed by specifically using the hardware resources of the wireless router 20.

As shown in FIG. 3, the communication program 30 includes a wireless network interface (I / F) 300, a wired network interface 302, a multicast routing management unit 304, a network filter unit 306, a multicast relay information base 308, a unicode unit. A cast routing processing unit 310, a wireless-side multicast processing unit 320, and a wired-side multicast processing unit 330 are configured.
In FIG. 3, the wireless network interface (I / F) 300 and the wired network interface 302 are processes in the physical layer, and the network filter unit 306 and the multicast relay information base 308 are processes in the MAC layer. In addition, other processes are processes performed in a layer higher than the MAC layer.

The unicast routing processing unit 310 includes a unicast routing management unit 312, a unicast tree construction processing unit 314, and a message transmission / reception processing unit 316, and implements a unicast routing protocol.
In this embodiment, a known OLSR is realized by the unicast routing processing unit 310. Specifically, the unicast routing processing unit 310 uses the unicast tree construction processing unit 314 based on the control message (HELLO message or TC message) received via the wireless network interface 300 and the message transmission / reception processing unit 316. Cast path construction and relay node (MPR (Multipoint Relay)) determination. The unicast routing management unit 312 performs control message transmission interval control and transfer control of data transmitted by unicast.

  Here, an outline of OLSR will be briefly described. OLSR is a proactive type ad hoc routing protocol that always exchanges routing information, and is characterized in that flooding is performed by collecting a minimum number of MPRs. In OLSR, path construction is performed mainly by exchanging HELLO messages and TC (Topology Control) messages.

  The HELLO message is transmitted from each node (wireless router 20) and includes link information of the own node and information such as MPR and MPR selector. MPR is a node in charge of relay, and each node is selected with reference to link information of one hop ahead of an adjacent node in order to perform efficient flooding. An MPR selector is a node that has selected its own node as an MPR.

  If only MPR is selected, a communication path is not yet established. Therefore, in OLSR, the topology of the entire network is constructed using TC messages. The TC message includes information of the MPR selector set and is transmitted from each node selected as the MPR. The TC message is flooded throughout the network by the MPR.

  With this TC message, all nodes in the network can acquire information on the MPR and its MPR selector set. Each node calculates a shortest route to the destination based on the information and creates a route table.

  Continuing the description of FIG. 3, the wireless-side multicast processing unit 320 includes a wireless-side message transmission / reception unit 324 and a wireless-side multicast routing tree construction unit 326.

  The wired-side multicast processing unit 330 includes a wired-side message transmission / reception unit 334 and a wired-side uni / multicast routing tree construction unit 336. Side multicast routing processing.

The radio side multicast routing tree construction unit 326 constructs a multicast routing tree based on the information received via the radio network interface 300 and the radio side message transmission / reception unit 324 and the routing information calculated by the unicast routing processing unit 310. . This tree construction operation is similar to that of MOLSR.
In addition, the wireless-side multicast routing tree construction unit 326 constructs a tree using the routing information of the wired-side uni / multicast routing tree construction unit 336 acquired via the multicast routing management unit 304.

The wired side uni / multicast routing tree construction unit 336 constructs a unicast and multicast routing tree based on the information received via the wired network interface 302 and the wired side message transmission / reception unit 334. This tree construction operation is performed according to PIM-SM.
In addition, the wired-side uni / multicast routing tree construction unit 336 uses the routing information of the wireless-side multicast routing tree construction unit 326 acquired through the multicast routing management unit 304 to construct a tree.

The multicast routing management unit 304 is registered in the multicast relay information base 308 and the net filter unit 306 based on the routing information acquired from the wireless side multicast routing tree construction unit 326 and the wired side uni / multicast routing tree construction unit 336. Update.
The network filter unit 306 extracts a MAC (Media Access Control) address corresponding to an IP address of a parent router (a wireless router that has transmitted the SourceClaim message to its own wireless router 20) from a SourceClaim message described later, and the SourceClaim message A multicast packet with a multicast group address added to is set to be transferred (for both wireless and wired networks) only when it is sent from the MAC address, and discarded otherwise. To do.
Thereby, it is possible to prevent the multicast packet from looping in the wireless network.

Information stored in the multicast relay information base 308 is based on information acquired from the wired-side uni / multicast routing tree construction unit 336 and information acquired from the wireless-side multicast routing tree construction unit 326 by the multicast routing management unit 304. Created.
When a multicast packet is input from the wired side or the wireless side, the multicast relay information base 308 refers to the information stored in the multicast relay information base 308 and flows the multicast packet from the wired side to the wireless side, or Decide whether to flow from the wireless side to the wired side.

Table 1 is a table showing the contents of information stored in the multicast relay information base 308.
As shown in Table 1, the multicast relay information base 308 includes the address of the terminal 140 (source IP address), the multicast group address in which the terminal 140 participates, the INPUT I / F, and the OUTPUT I / F. Remembered.

In Table 1, the first line shows a packet with “***. ***. *. 1” as the source IP address and “***. *. *. 1” as the multicast group address. When input from the wired network interface 302, this indicates that the packet is sent to the wireless network interface 300. In the second line, the packet with “***. ***. *. 2” as the source IP address and “***. *. *. 1” as the multicast group address is sent to the wireless network. When the packet is input from the interface 300, it indicates that the packet is transmitted (transferred) to the wired network interface 302. Similarly, in the third line, a packet with “***. ***. *. 3” as the source IP address and “***. *. *. 2” as the multicast group address is sent to the wireless network. When input from the interface 300, it indicates that the packet is transmitted (transferred) to the wireless network interface 300.
On the other hand, the multicast relay information base 308 discards packets that do not correspond to any of the stored information.

Next, the processing of the communication program 30 shown in FIG. 3 will be described in detail.
In the present invention, in order to enable multicast transmission corresponding to both the wired network and the wireless network, in multicast transmission from the wired network to the wireless network,
(1) According to the multicast transmission protocol used in the wired network, acquire information on the multicast group participating terminals existing in the wired network,
(2) Based on the acquired information of the multicast group participation terminal, construct an information base indicating that the multicast packet transmitted from the terminal is relayed to the wireless network;
(3) relaying a multicast packet transmitted from the wired network to the wireless network based on the constructed information base;
It was configured as follows.
In multicast transmission from a wireless network to a wired network,
(1) According to a multicast transmission protocol used in the wireless network, acquire information on multicast group participating terminals existing in the wireless network;
(2) Based on the information of the acquired multicast group participation terminal, construct an information base indicating that the multicast packet transmitted from the terminal is relayed to the wired network;
(3) relaying a multicast packet transmitted from the wireless network to the wired network based on the constructed information base;
It was configured as follows.
Hereinafter, the above process will be described in detail.

FIG. 4 is a sequence diagram (S10) showing group joining / leaving processing performed on the wireless router 20 and the wired network side. In the sequence shown in FIG. 4, the processing of the wireless router 20 is performed by the wired multicast processing unit 330.
In this embodiment, processing between the wired router 120 and the wireless router 20 is performed according to a known PIM-SM protocol, and processing between the terminal 140 and the wired router 120 is performed using a known IGMP (Internet Group Management Protocol). ), But the protocol used is not limited to them.

As shown in FIG. 4, in step 102 (S102) and step 104 (S104), a PIM-SM HELLO message is periodically transmitted and received between the wired router 120 and the wireless router 20. In the wireless router 20, the wired message transmission / reception unit 334 generates and transmits / receives a PIM-SM HELLO message.
On the other hand, in step 106 (S106), a group member confirmation message is periodically transmitted from the wired router 120 to the terminal 140.
If the terminal 140 wishes to participate in the multicast group, in step 108 (S108), the terminal 140 transmits a group member participation application message to the wired router 120 as a response to the group member confirmation message.
The wired router 120 that has received the group member participation application message transmits a PIM-SM Join message to the wireless router 20 in step 110 (S110).

If the terminal 140 wishes to leave the multicast group, in step 120 (S120), a group member leave application message is transmitted to the wired router 120 as a response to the group member confirmation message.
In step 122 (S122), the wired router that has received the group member leave application message transmits a PIM-SM Leave message to the wireless router.
The order of the processes shown in FIG. 4 may be changed as appropriate. The same applies to the sequences shown below.

FIG. 5 shows a format of a group member join / leave application message transmitted from the wired router to the wireless router.
As shown in FIG. 5, the group member join / leave application message includes a header part, a message generation source address, a multicast group address, the number of participating nodes, the number of leaving nodes, and a joining / leaving node address. If it is a participation application message, an integer of 1 or more is entered in the number of participating nodes, and if it is a withdrawal application message, an integer of 1 or more is entered in the number of leaving nodes.

  When the wired router message transmission / reception unit 334 receives the group member join / leave application message, the wireless router 20 constructs a tree in the wired uni / multicast routing tree construction unit 336 according to the received message. That is, the wireless router 20 updates the wired multicast routing information based on the group member join / leave application message. This multicast routing information includes at least the multicast group address and the address of the terminal 140 that participates in the multicast group address.

Next, processing of the wireless router 20 when a group member join / leave application message is received from the wired network will be described.
FIG. 6 is a sequence diagram (S20) showing processing of the communication program 30 when a group member participation application message is received.

As shown in FIG. 6, when the wire side message transmission / reception unit 334 receives the PIM-Join in step 202 (S202), the wire side message transmission / reception unit 334 constructs a wire side uni / multicast routing tree in step 204 (S204). A group participation notification is transmitted to the unit 336. This notification includes the address of the multicast transmission source terminal and the multicast group address.
When the wired side uni / multicast routing tree construction unit 336 receives the group participation notification, the wired side uni / multicast routing tree construction unit 336 updates the multicast routing information on the wired side, and in step 206 (S206), multicast routing management request for multicast routing setting from wired to wireless is performed. To the unit 304. This setting request includes the address of the multicast transmission source terminal and the multicast group address.

When receiving the above setting request, the multicast routing management unit 304 transmits a routing setting instruction from the wired network to the wireless network to the multicast relay information base 308 in step 207-1 (S207-1). This instruction includes the address of the multicast transmission source terminal and the multicast group address. Upon receiving this instruction, the multicast relay information base 308 adds the source address and multicast group address included in the instruction to the database shown in Table 1, and sets the wired network as the INPUT I / F corresponding to them. Then, the wireless network is set as the OUTPUT I / F, and a response is returned to the multicast routing management unit 304 in step 207-2 (S207-2).
In this way, when a join message to the multicast group (join in the case of PIM) is received from the wired protocol, an information base for relaying multicast packets from the wired network to the wireless network is constructed.

The multicast routing management unit 304 that has received the response from the multicast relay information base 308 returns a response to the wired-side uni / multicast routing tree construction unit 336 in step 208 (S208), and in step 210 (S210), the multicast transmission source The address (terminal address) and the group participation notification are transmitted to the wireless multicast routing tree construction unit 326.
When receiving the group participation notification, the wireless-side multicast routing tree construction unit 326 transmits a terminal address and group address registration request to the wireless-side message transmission / reception unit 324 in step 212 (S212).
In step 214 (S214), the wireless-side message transmission / reception unit 324 returns a response to the wireless-side multicast routing tree construction unit 326, and in step 216 (S216), the received terminal address and the terminal address included in the group address registration request and Based on the group address, a SourceClaim message, which will be described later, is generated and transmitted (flooded) to another wireless router 20 via the wireless network IF 300.

In step 220 (S220), when the wired message transmission / reception unit 334 receives the PIM-Leave, in step 222 (S222), from the wired message transmission / reception unit 334 to the wired uni / multicast routing tree construction unit 336. A group leaving notice is sent. This leave notification includes the address of the multicast transmission source terminal and the multicast group address.
When the wired side uni / multicast routing tree construction unit 336 receives the group leaving notification, the wired side uni / multicast routing tree construction unit 336 updates the multicast routing information on the wired side and, at step 224 (S224), multicast routing management cancels a request for canceling the multicast routing from the wired to the wireless side. To the unit 304. This release request includes the address of the multicast transmission source terminal and the multicast group address.

  When receiving the above cancellation request, the multicast routing management unit 304 transmits a routing cancellation instruction from the wired network to the wireless network to the multicast relay information base 308 in step 225-1 (S225-1). This instruction includes the address of the multicast transmission source terminal and the multicast group address. Upon receiving this instruction, the multicast relay information base 308 deletes the source address and multicast group address included in the instruction from the database shown in Table 1, and the corresponding INPUT I / F and OUTPUT I / F. In step 225-2 (S225-2), a response is returned to the multicast routing management unit 304.

The multicast routing management unit 304 that has received the response from the multicast relay information base 308 returns a response to the wired-side uni / multicast routing tree construction unit 336 in step 226 (S226), and wirelessly sends a group leave notification in step 228 (S228). To the side multicast routing tree construction unit 326.
When receiving the group leaving notification, the wireless-side multicast routing tree construction unit 326 transmits a terminal address and group address deletion request to the wireless-side message transmission / reception unit 324 in step 230 (S230).
Upon receiving the terminal address and group address deletion request, the wireless side message transmission / reception unit 324 returns a response signal to the wireless side multicast routing tree construction unit 326 and stops the transmission of the SourceClaim message in step 232 (S232).

  Next, multicast group join / leave processing in the wireless network will be described.

FIG. 7 is a sequence diagram (S30) illustrating a multicast group joining / leaving process performed based on information from the wired network in the wireless router 20, (A) showing the joining process, and (B) showing the leaving process. Indicates.
As shown in FIG. 7, in the process of joining / leaving a multicast group in a wireless network, a SourceClaim message and a ConfirmParent message are exchanged between the wireless nodes. Specific processing will be described later.
Here, a method of exchanging the SourceClaim message and the ConfirmParent message will be described. This exchange conforms to MOLSR.

8 and 9 are diagrams illustrating message transmission / reception between the plurality of communication devices 100. FIG. Here, the communication device 100 may have the same configuration as the wireless router 20, may have a configuration as a general wireless terminal, or may have both configurations.
8 and 9, the communication device 100-1 (communication device # 1) has a bidirectional link with the communication device 100-2 (communication device # 2) and the communication device 100-5 (communication device # 5). Has been built.
The communication device 100-2 has a bidirectional link established with the communication device 100-3 (communication device # 3) and the communication device 100-4 (communication device # 4). The communication device 100-2 is an MPR, and relays communication between the communication device 100-1 and the communication devices 100-3 and 100-4.
The communication device 100-5 has a bidirectional link with the communication device 100-6 (communication device # 6). The communication device 100-5 is an MPR, and relays communication between the communication device 100-1 and the communication device 100-6.
Further, the communication device 100-1 is a source of multicast packets in a certain multicast group (group # 1), and the communication devices 100-2 and 100-4 are not participating in the multicast group (group # 1). First, the communication devices 100-3, 100-5, and 100-6 participate in the multicast group (group # 1).
Here, “the communication device 100 is participating in a multicast group” means that the communication device 100 itself is participating in the multicast group when the communication device 100 has a function as a wireless terminal. This includes not only the case where the terminal 140 connected to the communication apparatus 100 via a wired network is participating in the multicast group.

As shown in FIG. 8A, the communication device 100-1 transmits a SourceClaim message to the communication devices 100-2 and 100-5 in which a bidirectional link is established with itself.
Here, the SourceClaim message is a message transmitted from a router that transmits a multicast packet to each wireless router in the ad hoc network, and is a message for confirming nodes participating in a multicast group that can receive the multicast packet. is there.

As illustrated in FIG. 8B, the communication device 100-2 receives the communication device 100-2 from the communication device 100-1 with respect to the communication devices 100-3 and 100-4 that have selected the communication device 100-2 as the MPR. Send (flood) a SourceClaim message.
Similarly, the communication device 100-5 transmits (floods) the SourceClaim message received from the communication device 100-1 to the communication device 100-6 that has selected the communication device 100-5 as an MPR.
Note that since the communication device 100-1 selects the communication devices 100-2 and 100-5 as MPRs, the communication devices 100-2 and 100-5 also communicate with the communication device 100-1. The SourceClaim message received from 1 is transmitted.
In this case, when the communication device 100-1 receives the SourceClaim message transmitted by itself, the communication device 100-1 may discard the message.

Further, as illustrated in FIG. 8B, since the communication device 100-5 participates in the group # 1, it transmits a ConfirmParent message to the communication device 100-1 that has transmitted the SourceClaim message.
Here, the ConfirmParent message means that when there is a terminal participating in the multicast group indicated by the SourceClaim message in the wired network connected to the wireless router that has received the SourceClaim message, the ConfirmParent message is transmitted by the router that has received the SourceClaim message. This message is sent to the router that sent the SourceClaim message.
That is, the ConfirmParent message is a message that can be a response to the SourceClaim message.

As shown in FIG. 9A, since the communication device 100-3 participates in the group # 1, it transmits a ConfirmParent message to the communication device 100-2 that has transmitted the SourceClaim message.
Similarly, since the communication device 100-6 participates in the group # 1, it transmits a ConfirmParent message to the communication device 100-5 that has transmitted the SourceClaim message.

As shown in FIG. 9B, the communication device 100-2 does not participate in the group # 1, but since it is an MPR, the communication device 100-3 is different from the communication device 100-1. The ConfirmParent message received from is transmitted (flooded).
Similarly, since the communication device 100-5 itself is an MPR, it transmits (floods) the ConfirmParent message received from the communication device 100-6 to the communication device 100-1.
Here, when the communication device 100-2 which is an MPR receives a multicast packet from the communication device 100-1, the communication device 100-2 transmits the multicast packet to the communication device 100-3 participating in the multicast group related to the multicast packet. Relay processing is performed so that it can be transferred.
Similarly, when the communication device 100-5 that is an MPR receives a multicast packet from the communication device 100-1, the communication device 100-5 transmits the multicast packet to the communication device 100-6 that participates in the multicast group related to the multicast packet. Relay processing is performed so that it can be transferred.

Communication device 100-2 also transmits a ConfirmParent message message to communication devices 100-3 and 100-4.
In this case, the communication device 100-3 may discard the message when receiving the ConfirmParent message transmitted by itself. Since the communication device 100-4 is not an MPR, the communication device 100-4 discards the received ConfirmParent message. In this case, the source router (communication device 100-1) that first transmitted the SourceClaim message or the communication of the source router The ConfirmParent message may be transmitted only to the MPR for this purpose.
In this case, the communication device 100-2 may transmit the ConfirmParent message only to the communication device 100-1.

FIG. 10 is a diagram showing a format of a SourceClaim message and a ConfirmParent message according to the present invention. Each message shown in FIG. 10 is different from that used in MOLSR.
FIG. 10A is a diagram showing the format of the SourceClaim message according to the present invention.
As shown in FIG. 10A, the SourceClaim message includes a header part, a message generation source address, a multicast group address, the number of participating nodes corresponding to the multicast group address, the number of leaving nodes, and the address of the participating node. (Participating node address) and a leaving node address (leaving node address).

The reason why the number of participating nodes and the number of leaving nodes is included is that a plurality of participating node addresses and leaving node addresses can be included in one SourceClaim message. Specifically, when a plurality of node addresses are described, it is possible to determine the number of addresses up to “participation” and the number of addresses from “leave”. Therefore, both the number of participating nodes and the number of leaving nodes are not necessarily required, and information on the number of nodes is not necessary when the SourceClaim message is divided into “participating” and “leaving”.
Further, the participating node address and the leaving node address may include both the address of the terminal 140 and the address of the wired router, or may include either one.
The same applies to the Confirm Parent message described later.

FIG. 10B is a diagram showing the format of the ConfirmParent message according to the present invention.
As shown in FIG. 10B, the ConfirmParent message includes a header part, a message generation source address, a multicast group address, the number of participating nodes corresponding to the multicast group address, the number of leaving nodes, and the participating parent router address. A participating child router address, a participating node address, a leaving parent router address, a leaving child router address, and a leaving node address.

The joining / leaving child router address is an address of the wireless router 20 that connects the wired network to which the joining node or the leaving node (the terminal 140 or the wired router 120) is connected to the wireless network.
The joining / leaving parent router address is the address of the wireless router 20 one hop before the joining / leaving child router (one hop before when viewed from the source of the SourceClaim message).
The joining / leaving parent router address, joining / leaving child router address, and joining / leaving child node address are described in the ConfirmParent message as many as the number of joining nodes and leaving nodes, with three as one set.

Based on the above, the sequence in FIG. 7 will be described.
As shown in FIG. 7A, in step 302 (S302), the wireless router # 1 (wireless router 20-1) receives the PIM-SM from the wired router # 1 connected to itself via a wired network. The Join message (PIM-Join) is received.
In step 304 (S304), the wireless router # 1 creates a SourceClaim message related to the system # 1 based on the PIM-SM Join message and transmits it to the wireless router # 2 (wireless router 20-2). As described above, by receiving the SourceClaim message after receiving the PIM-Join, useless traffic can be suppressed.

In step 306 (S306), the wireless router # 2 performs processing described later with reference to FIG. 11, and transmits a ConfirmParent message to the wireless router # 1 that is the parent router.
In Step 308 (S308), since the wireless router # 2 is MPR, the SourceClaim message received from the wireless router # 1 is transmitted to the wireless router # 3 (wireless router 20-3) which is a child router.
In step 310 (S310), the wireless router # 3 performs processing to be described later with reference to FIG. 11, and transmits a ConfirmParent message to the wireless router # 2 that is the parent router.
In Step 312 (S312), the wireless router # 2 that has received the ConfirmParent message from the wireless router # 3 has a participating node (terminal # 3) participating in the group wired to the wireless router # 3. The relay processing between the wireless router # 1 and the wireless router # 3 is performed.
In step 314 (S314), the wireless router # 2 performs processing to be described later with reference to FIG. 11, and transmits the ConfirmParent message from the wireless router # 3 to the wireless router # 1 that is the parent router.

As shown in FIG. 7B, in step 320 (S320), the wireless router # 1 transmits a SourceClaim message to the wireless router # 2.
In step 326 (S326), the wireless router # 3 receives the PIM-SM Leave message (PIM-Leave) from the wired router # 3 connected to the wireless router # 3 via the wired network.
In step 328 (S328), the wireless router # 3 performs processing to be described later with reference to FIG. 11, and transmits a ConfirmParent message to the wireless router # 2 that is the parent router.
In Step 330 (S330), the wireless router # 2 that has received the ConfirmParent message from the wireless router # 3 has no participating node (terminal # 3) participating in the group wired to the wireless router # 3. Therefore, a process of canceling the relay between the wireless router # 1 and the wireless router # 3 is performed.
In step 332 (S332), the wireless router # 2 performs processing to be described later with reference to FIG. 11, and transmits the ConfirmParent message from the wireless router # 3 to the wireless router # 1 that is the parent router.

FIG. 11 is a sequence diagram (S40) showing the multicast group joining / leaving processing performed based on information from the wireless network in the wireless router 20.
In the following description, the processing in the wireless router # 2 is given as an example, and the parent router is the wireless router # 1 and the child router is the wireless router # 3.
In step 402 (S402), the wireless-side message transmission / reception unit 324 (for example, the wireless router # 2) receives the SourceClaim message from the parent router (for example, the wireless router # 1).
In step 404 (S404), the wireless-side message transmission / reception unit 324 that has received the SourceClaim message notifies the wireless-side multicast routing tree construction unit 326 of the terminal address and group address included in the SourceClaim message, and the message source router (For example, wireless router # 1) is set as the parent router.
In step 406 (S406), the wireless-side multicast routing tree construction unit 326 transmits a group participation notification including a terminal address and a multicast group address in which the terminal participates to the multicast routing management unit 304, and wirelessly wired. Make a multicast routing setting request to.

When receiving the above setting request or the like, the multicast routing management unit 304 transmits a routing setting instruction from the wireless network to the wired network to the multicast relay information base 308 in step 407-1 (S407-1). This instruction includes the address of the multicast transmission source terminal and the multicast group address.
Upon receiving this instruction, the multicast relay information base 308 adds the source address and multicast group address included in the instruction to the database shown in Table 1, and sets the wireless network as the INPUT I / F corresponding to them. Then, the wired network is set as the OUTPUT I / F, and a response is returned to the multicast routing management unit 304 in step 407-2 (S407-2).
Thus, when a join message to the multicast group (SourceClaim in the case of MOLSR) is received from the wireless side protocol, an information base for relaying multicast packets from the wireless network to the wired network is constructed.

Upon receiving the response from the multicast relay information base 308, the multicast routing management unit 304 returns the response to the wireless side multicast routing tree construction unit 326 in step 408 (S408), and in step 410 (S410), the wired side uni / The terminal address and group address are notified to the multicast routing tree construction unit 326.
In step 412 (S 412), the wired side uni / multicast routing tree construction unit 336 transmits the terminal address and group address registration request to the wired side message transmission / reception unit 334.
In step 414 (S414), the multicast routing management unit 304 performs a multicast packet reception permission setting of the message transmission source router (for example, wireless router # 1) to the network filter unit 306.
In step 416 (S416), the wired-side message transmission / reception unit 334 sends PIM-Join to the wired router 120 (for example, wired router # 2) that is wired to the wireless router 20 (for example, wireless router # 2). Send. Thereby, the group participation notification is transmitted to the wired network side.

When the own wireless router 20 (for example, wireless router # 2) is MPR, in step 420 (S420), the wireless side multicast routing tree construction unit 326 sends a SourceClaim message to the wireless side message transmission / reception unit 324 as a child router. The wireless router 20 (for example, wireless router # 3) is instructed to flood.
In step 422 (S422), the wireless side message transmission / reception unit 324 receives an instruction from the wireless side multicast routing tree construction unit 326 and transmits the SourceClaim message to the wireless router 20 (eg, wireless router # 3) as a child router ( Flooding).

If the group participation notification has already been received from the wired router 120 (for example, wired router # 2) connected to its own wireless router 20 (for example, wireless router # 2), the multicast routing management unit 304 in step 430 (S430). Transmits the terminal address of the participating terminal 140 (for example, terminal # 2) and the group participation notification to the wireless-side multicast routing tree construction unit 326.
In step 432 (S432), when receiving the group participation notification, the wireless multicast routing tree construction unit 326 transmits a terminal address and group address registration request to the wireless message transmission / reception unit 324.
In step 434 (S434), the wireless-side message transmission / reception unit 324 returns a response to the wireless-side multicast routing tree construction unit 326, and in step 436 (S436), the received terminal address and the terminal address included in the group address registration request and Based on the group address, a ConfirmParent message is created and transmitted to the wireless router 20 (for example, wireless router # 1) which is the parent router.
If the terminal 140 has left the group, the ConfirmParent message is not transmitted.

In Step 440 (S440), the wireless-side message transmission / reception unit 324 receives the ConfirmParent message transmitted (flooded) from the wireless router 20 (for example, wireless router # 3) as a child router.
In step 444 (S444), if the parent router address included in the received ConfirmParent message is its own wireless router 20 (for example, wireless router # 2), the wireless-side message transmission / reception unit 324 determines that the message source router (for example, wireless router) # 3) is registered as a child router, and the terminal address and group address are notified to the radio side multicast routing tree construction unit 326.

In step 446 (S446), the wireless-side multicast routing tree construction unit 326 transmits a group participation notification including the terminal address and the multicast group address in which the terminal participates to the multicast routing management unit 304, from the wireless network. Make a multicast routing setting request to the wired network.
In addition, the wireless-side multicast routing tree construction unit 326 notifies the multicast routing management unit 304 of the terminal address included in the SourceClaim message that triggered the received ConfirmParent message and the multicast group address in which the terminal participates, Request routing configuration from wireless network to wireless network.

In step 447-1 (S447-1), the multicast routing management unit 304 that has received these requests instructs the multicast relay information base 308 to set the routing from the wireless network to the wired network, and from the wireless network to the wireless network. Send routing setting instructions. Each instruction includes a terminal address and a multicast group address notified from the radio side multicast routing tree construction unit 326.
Upon receiving the routing setting instruction from the wireless network to the wired network, the multicast relay information base 308 adds the source address and the multicast group address included in the instruction to the database shown in Table 1, and the INPUT corresponding to them. A wireless network is set as the I / F, and a wired network is set as the OUTPUT I / F.
Also, the multicast relay information base 308 that has received the routing setting instruction from the wireless network to the wireless network adds the source address and multicast group address included in the instruction to the database shown in Table 1 and supports them. A wireless network is set for the INPUT I / F and the OUTPUT I / F.
The multicast relay information base 308 that has made these settings returns a response to the multicast routing management unit 304 in step 447-2 (S447-2).
In this way, when a join message response to the multicast group (ConfirmParent in the case of MOLSR) is received from the wireless side protocol, an information base for relaying multicast packets from the wireless network to the wired network is constructed. At the same time, an information base for relaying multicast packets from the wireless network to the wireless network is constructed.

When the response from the multicast relay information base 308 is received, in step 448 (S448), the multicast routing management unit 304 notifies the wired uni / multicast routing tree construction unit 326 of the terminal address and group address.
In step 450 (S450), the wired side uni / multicast routing tree construction unit 336 transmits the terminal address and group address registration request to the wired side message transmission / reception unit 334.
In step 452 (S452), the wired-side message transmission / reception unit 334 sends PIM-Join to the wired router 120 (for example, wired router # 2) that is wired to the wireless router 20 (for example, wireless router # 2). Send.

If the device itself is an MPR, in step 462 (S462), the wireless-side message transmission / reception unit 324 transmits a ConfirmParent message to the wireless router 20 (for example, wireless router # 1) that is the parent router.
Note that, in the case of relay (it is an MPR itself), even if the terminal 140 is disconnected from the group, the ConfirmParent transmission process is not stopped.

By performing the above processing, when the wireless router 20 receives the ConfirmParent message, the wireless router 20 receives the multicast packet addressed to the multicast group corresponding to the ConfirmParent message from its own wired network. It can be transmitted to another wireless router 20.
As described above, according to the present invention, it is possible to perform multicast transmission corresponding to both a wireless network and a wired network connected to each other.
Further, in the known MOLSR, it is necessary to encapsulate multicast packets in UDP (User Datagram Protocol) broadcast data in combination with MDFP (Multicast Data Forwarding Protocol) when actually performing multicast. Therefore, the broadcast IP tunneling header must be added / deleted as appropriate in each wireless router.
Such addition / deletion of the broadcast IP tunneling header increases the processing time. However, since the present invention does not require encapsulation, the processing time can be shortened.

  In the above embodiment, as a trigger for constructing a multicast relay information base from a wired network to a wireless network, a case where a participation message is received from the wired protocol is shown. When received (in the case of MOLSR, when the source of SourceClaim receives ConfirmParent addressed to itself), a multicast relay information base from the wired network to the wireless network may be constructed.

  The present invention is applicable to a communication device.

DESCRIPTION OF SYMBOLS 1 ... Communication system, 20 ... Wireless router, 120 ... Wired router, 140 ... Terminal, 30 ... Communication program, 300 ... Wireless network IF, 302 ... Wired network IF, 310 ... unicast routing processing unit, 306 ... network filter unit, 308 ... multicast relay information base, 304 ... multicast routing management unit, 320 ... radio-side multicast processing unit, 322 ... Wireless side multicast routing management unit, 324... Wireless side message transmission / reception unit, 326... Wireless side multicast routing tree construction unit, 330... Wired side multicast processing unit, 334. ... Unique / multicast routings on the cable side Over construction unit

Claims (6)

A plurality of wired networks each including one or more terminals and a first communication device connected to the terminals;
A plurality of second communication devices, each connected to the first communication device of any one of the plurality of wired networks, and connecting between the wired network and another wired network via a wireless network. Wireless communication system,
Each of the first communication devices transmits a first message to the terminal connected to the first communication device according to a communication protocol in each of the wired networks,
In response to the first message from the first communication device, each of the terminals responds to the first communication device to join or leave the multicast group,
Each of the first communication devices can participate in a multicast group from the terminal or leave the multicast group with respect to the second communication device connected to the first communication device. Send a response,
Each of the second communication devices is
Based on the response of the terminal received from the first communication device of the connected wired network, to transmit the multicast packet transmitted from each terminal included in the multicast group in the wired network to the wireless network Update the information base used for
A wireless communication system, wherein a multicast packet transmitted from the wired network is relayed to the wireless network based on the updated information base. Each of the second communication devices is
Obtaining the information base from each of the other second communication devices via the wireless network according to a communication protocol in the wireless network;
The wireless communication system according to claim 1, wherein a multicast packet from the wireless network is relayed to the wired network based on the acquired information base. Each of the second communication devices further includes:
In response to a response of the terminal joining or leaving the multicast group of the connected first communication device, a second message including at least the address of the joining or leaving terminal and the multicast group address Transmitting to the second communication device via a wireless network,
Used for relaying the multicast packet based on the response of the terminal joining or leaving the multicast group of the connected first communication device and the second message from the other second communication device. The wireless communication system according to claim 1, wherein the multicast routing tree is managed. A plurality of wired networks each including one or more terminals and a first communication device connected to the terminals, and each wired network connected to the first communication device of any of the plurality of wired networks. A communication method in a wireless communication system comprising a plurality of second communication devices that connect a network and another wired network via a wireless network,
Each of the first communication devices transmits a message to the terminal connected to the first communication device according to a communication protocol in each of the wired networks,
In response to a message from the first communication device, each of the terminals responds to the first communication device to join or leave the multicast group,
Each of the first communication devices can participate in a multicast group from the terminal or leave the multicast group with respect to the second communication device connected to the first communication device. Send a response,
Each of the second communication devices is
Based on the response of the terminal received from the first communication device of the connected wired network, to transmit the multicast packet transmitted from each terminal included in the multicast group in the wired network to the wireless network Update the information base used for
A wireless communication method, comprising: relaying a multicast packet transmitted from the wired network to the wireless network based on the updated information base. Each of the second communication devices is
Obtaining the information base from each of the other second communication devices via the wireless network according to a communication protocol in the wireless network;
The wireless communication method according to claim 4 , wherein a multicast packet from the wireless network is relayed to the wired network based on the acquired information base and a communication protocol of the wired network. Each of the second communication devices further includes:
In response to a response of the terminal joining or leaving the multicast group of the connected first communication device, a second message including at least the address of the joining or leaving terminal and the multicast group address Transmitting to the second communication device via a wireless network,
Used for relaying the multicast packet based on the response of the terminal joining or leaving the multicast group of the connected first communication device and the second message from the other second communication device. The wireless communication system according to claim 4 or 5, wherein a managed multicast routing tree is managed.

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