JP2013201731A - Communication system, portable terminal, relay device, and communication control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To relay communication from an external network to an internal network while suppressing an increase in a memory size of a relay device.SOLUTION: A portable terminal comprises an acquisition unit and a transmission unit. The acquisition unit acquires second portable terminal identification information for identifying the portable terminal in a second network, and electronic apparatus identification information for identifying an electronic apparatus in the second network. The transmission unit sets first portable terminal identification information for identifying the portable terminal in a first network as a transmission source, and also transmits first packets including the second portable terminal identification information and the electronic apparatus identification information to a relay device via the first network. The relay device comprises a storage unit and a transfer unit. When the first packet transmitted from the portable terminal is received, the storage unit stores the first portable terminal identification information which is set as the transmission source of the first packets and the second portable terminal identification information included in the packets in association in a conversion table.

Description

  The present invention relates to a communication system, a portable terminal, a relay device, and a communication control method.

  Conventionally, a relay device for communication between a portable terminal such as a mobile phone connected to an external network such as a WAN (Wide Area Network) and an electronic device such as a home appliance connected to an internal network such as a LAN (Local Area Network) There is a communication system that relays. The relay device is also called a gateway (GW). In such a communication system, an IPv4 (Internet Protocol version 4) address is used as identification information for identifying a communication partner on the network. However, with the recent increase in the scale of networks, the IPv4 address is depleted. Was a problem.

  On the other hand, in recent communication systems, networks using IPv6 (Internet Protocol version 6) addresses developed as next-generation identification information instead of IPv4 addresses are becoming widespread. However, it is difficult to immediately migrate a network using an IPv4 address to one using an IPv6 address, and it is assumed that a network environment in which the IPv4 address and the IPv6 address coexist will occur. For example, a network environment in which an external network such as a WAN using an IPv6 address (hereinafter referred to as “IPv6 network”) and an internal network such as a LAN using an IPv4 address (hereinafter referred to as “IPv4 network”) is assumed. . In a network environment in which an IPv6 network and an IPv4 network coexist, it is desirable to enable connection from the IPv6 network to the IPv4 network.

  As a connection method from the IPv6 network to the IPv4 network, a technique called a port transfer method is known. In this port forwarding method, a static IP masquerade setting table representing the correspondence between port numbers and forwarding destination IPv4 addresses is held in the memory of the GW serving as a relay device. In the port forwarding method, a GW that receives a packet whose destination is an IPv6 address on the IPv6 network side and whose port number matches an entry in the static IP masquerade setting table sends a packet to the corresponding IPv4 address of the entry. Forward. Thereby, the GW can relay communication from the IPv6 network to the IPv4 network.

JP 2004-254203 A

  However, although the port transfer method described above can relay communication from the external network to the internal network, there is a problem that the memory scale of the GW increases.

  Specifically, in the port forwarding method, the correspondence between the port number and the IPv4 address of the forwarding destination is registered in advance in the static IP masquerade setting table of the GW. Scale increases. Further, as the number of transfer destination electronic devices having IPv4 addresses increases, the number of correspondences between port numbers and transfer destination IPv4 addresses, that is, the number of entries in the static IP masquerade setting table increases. This further increases the memory size.

  The disclosed technology has been made in view of the above, and is capable of relaying communication from an external network to an internal network while suppressing an increase in the memory size of the relay device, a mobile terminal, a relay device, and An object is to provide a communication control method.

  In one aspect, the communication system disclosed in the present application is a communication system in which a relay device relays communication between a mobile terminal connected to a first network and an electronic device connected to a second network. The portable terminal includes an acquisition unit and a transmission unit. The acquisition unit acquires second mobile terminal identification information for identifying the mobile terminal in the second network and electronic device identification information for identifying the electronic device in the second network. The transmission unit sets first portable terminal identification information for identifying the portable terminal in the first network as a transmission source, and includes the second portable terminal identification information and the electronic device identification information. The packet is transmitted to the relay device via the first network. The relay device includes a storage unit and a transfer unit. When the storage unit receives the first packet transmitted from the mobile terminal, the storage unit includes the first mobile terminal identification information set as the transmission source of the first packet and the first packet. The second mobile terminal identification information included is associated and stored in the conversion table. The transfer unit sets the second mobile terminal identification information stored in the conversion table as a transmission source, and sets a second packet in which the electronic device identification information included in the packet is set as a destination. To the electronic device via the network.

  According to one aspect of the communication system disclosed in the present application, it is possible to relay communication from the external network to the internal network while suppressing an increase in the memory size of the relay device.

FIG. 1 is a diagram illustrating the configuration of the communication system according to the first embodiment. FIG. 2 is a functional block diagram illustrating the configuration of the mobile phone according to the first embodiment. FIG. 3 is a diagram illustrating an example of the data structure of the IPv4 address management table. FIG. 4 is a diagram illustrating an example of the data structure of the IPv6 address management table. FIG. 5 is a diagram illustrating an example of a data structure of the GW information management table. FIG. 6 is a diagram illustrating an example of the contents of a code. FIG. 7 is a functional block diagram illustrating the configuration of the GW according to the first embodiment. FIG. 8 is a diagram illustrating an example of a data structure of the IPv6-IPv4 address conversion table. FIG. 9 is a diagram illustrating an example of a hardware configuration of the mobile phone according to the first embodiment. FIG. 10 is a diagram illustrating an example of a hardware configuration of the GW according to the first embodiment. FIG. 11 is a sequence diagram illustrating an example of a processing procedure of a process in which the mobile phone of the communication system according to the first embodiment communicates with the LAN TV via the GW. FIG. 12 is a flowchart illustrating a processing procedure of WAN address notification processing executed by the GW according to the first embodiment. FIG. 13 is a flowchart illustrating a processing procedure of IPv4 / IPv6 packet transmission processing executed by the mobile phone according to the first embodiment. FIG. 14 is a sequence diagram illustrating an example of a processing procedure of processing in which the mobile phone of the communication system according to the first embodiment communicates with the LAN TV via the WAN and the GW. FIG. 15 is a diagram (part 1) illustrating an example of a data structure of an IPv6 packet. FIG. 16 is a flowchart illustrating a processing procedure of IPv4 packet transfer processing executed by the GW according to the first embodiment. FIG. 17 is a diagram illustrating an example (part 1) of the data structure of the IPv4 packet. FIG. 18 is a diagram illustrating an example (part 2) of the data structure of the IPv4 packet. FIG. 19 is a flowchart of the IPv6 packet transfer process performed by the GW according to the first embodiment. FIG. 20 is a second diagram illustrating an exemplary data structure of an IPv6 packet. FIG. 21 is a flowchart illustrating the processing procedure of IPv4-IPv6 address deletion processing executed by the GW according to the first embodiment. FIG. 22 is a sequence diagram illustrating an example of a processing procedure of processing in which the mobile phone of the communication system according to the second embodiment communicates with the LAN TV via the WAN and the GW. FIG. 23 is a sequence diagram illustrating an example of a processing procedure of a process in which the mobile phone of the communication system according to the third embodiment communicates with the LAN TV via the GW. FIG. 24 is a sequence diagram illustrating an example of a processing procedure of a process in which the mobile phone of the communication system according to the third embodiment communicates with the LAN TV via the WAN and the GW. FIG. 25 is a third diagram illustrating an exemplary data structure of an IPv6 packet. FIG. 26 is a diagram illustrating another example of the data structure of the IPv6-IPv4 address conversion table. FIG. 27 is a fourth diagram illustrating an exemplary data structure of an IPv6 packet. FIG. 28 is a diagram illustrating the configuration of the communication system according to the fourth embodiment. FIG. 29 is a sequence diagram illustrating an example of a processing procedure of processing in which the mobile phone of the communication system according to the fourth embodiment communicates with the LAN TV via the WAN and the GW.

  Hereinafter, embodiments of a communication system, a mobile terminal, a relay device, and a communication control method disclosed in the present application will be described in detail with reference to the drawings. The disclosed technology is not limited by this embodiment.

  First, the configuration of the communication system according to the first embodiment will be described. FIG. 1 is a diagram illustrating the configuration of the communication system according to the first embodiment. As shown in FIG. 1, the communication system includes an IPv6 network 1, a carrier network 2, an area network 3, a home network 4, a television (TV) 5, a mobile phone 100, and a GW 200.

  The IPv6 network 1 is a network that uses an IPv6 address as identification information for identifying a communication partner. The carrier network 2 is a network operated by a telecommunications carrier that provides various communication services to the mobile phone 100 and uses an IPv6 address in the same manner as the IPv6 network 1. The area network 3 is a base station group that belongs to the carrier network 2 and uses an IPv6 address in the same manner as the IPv6 network 1 and the carrier network 2. The IPv6 network 1, the carrier network 2, and the area network 3 form a WAN 10 that is a kind of external network. The WAN 10 is an example of a first network.

  The home network 4 is a home network that mediates between the GW 200 and the TV 5. The TV 5 is an electronic device equipped with an IPv4 protocol stack that uses an IPv4 address, and is connected to the home network 4. The home network 4 and the TV 5 form a LAN 20 that is a kind of internal network. The LAN 20 is an example of a second network. Although illustration is omitted in FIG. 1 for simplification of explanation, it is assumed that an electronic device other than the TV 5 is also connected to the home network 4.

  The cellular phone 100 is wirelessly connected to the area network 3 of the WAN 10 and operates the TV 5 of the LAN 20 via the WAN 10 and a GW 200 described later. The mobile phone 100 can also be connected to the GW 200 wirelessly and operate the TV 5 of the LAN 20 via the GW 200. The mobile phone 100 is an example of a mobile terminal.

  The GW 200 is connected to the WAN 10 and to the LAN 20. The GW 200 relays communication between the mobile phone 100 connected to the WAN 10 and the TV 5 of the LAN 20. The GW 200 is an example of a relay device.

  In the communication system of the present embodiment, when the mobile phone 100 wirelessly connected to the GW 200 communicates with the LAN 20 via the GW 200, the IPv4 address that identifies the mobile phone 100 on the LAN 20 and the IPv4 address that identifies the TV 5 on the LAN 20 And get. Hereinafter, the IPv4 address that identifies the mobile phone 100 on the LAN 20 is referred to as the IPv4 address of the mobile phone 100, and the IPv4 address that identifies the TV 5 on the LAN 20 is referred to as the IPv4 address of the TV 5. The IPv4 address of the mobile phone 100 is an example of second mobile terminal identification information, and the IPv4 address of the TV 5 is an example of electronic device identification information.

  Then, the mobile phone 100 ends the connection with the GW 200 and connects to the area network 3 of the WAN 10 by radio. The cellular phone 100 acquires an IPv6 address that identifies the cellular phone 100 from the WAN 10 to the WAN 10. Hereinafter, the IPv6 address that identifies the mobile phone 100 in the WAN 10 is referred to as the IPv6 address of the mobile phone 100. The IPv6 address of the mobile phone 100 is an example of first mobile terminal identification information.

  Then, the mobile phone 100 sets the IPv6 address of the mobile phone 100 as a transmission source, and transmits an IPv6 packet including the IPv4 address of the mobile phone 100 and the IPv4 address of the TV 5 to the GW 200 via the WAN 10.

  Upon receiving the IPv6 packet transmitted from the mobile phone 100, the GW 200 associates the IPv6 address of the mobile phone 100 set as the source of the IPv6 packet with the IPv4 address of the mobile phone 100 included in the IPv6 packet. To store.

  Then, the GW 200 sets the IPv4 address of the mobile phone 100 stored in the conversion table as a transmission source, generates an IPv4 packet in which the IPv4 address of the TV5 included in the IPv6 packet is set as a destination, and transmits the TV5 via the LAN 20 Forward to.

  As described above, in the communication system according to the present embodiment, the mobile phone 100 connected to the WAN 10 sets the IPv6 address of the mobile phone 100 as a transmission source, and includes an IPv6 packet including the IPv4 address of the mobile phone 100 and the IPv4 address of the TV 5. Is transmitted to GW200. The GW 200 associates the IPv6 address of the mobile phone 100 that is the transmission source of the received IPv6 packet with the IPv4 address of the mobile phone 100 included in the IPv6 packet, and stores them in the conversion table. The GW 200 sets the IPv6 address of the mobile phone 100 in the conversion table as a transmission source, generates an IPv4 packet in which the IPv4 address of the TV 5 included in the IPv6 packet is set as a destination, and transfers the IPv4 packet to the TV 5 via the LAN 20. Therefore, in the communication system of the present embodiment, it is possible to transfer the IPv4 packet to the TV 5 via the LAN 20 without pre-registering the correspondence relationship between the port number and the IPv4 address of the transfer destination in the GW 200. As a result, communication from the WAN 10 to the LAN 20 can be relayed while suppressing an increase in the memory size of the GW 200.

  Next, the configuration of the mobile phone 100 shown in FIG. 1 will be described. FIG. 2 is a functional block diagram illustrating the configuration of the mobile phone according to the first embodiment. As illustrated in FIG. 2, the mobile phone 100 includes a storage unit 101, an IPv4 address acquisition unit 102, a communication request reception unit 103, a packet processing unit 104, a packet transmission unit 105, and a wireless interface unit 106.

  The storage unit 101 includes, for example, an IPv4 address management table 111, an IPv6 address management table 112, and a GW information management table 113.

  The IPv4 address management table 111 is a table that stores an IPv4 address for identifying a communication partner on the LAN 20. FIG. 3 is a diagram illustrating an example of the data structure of the IPv4 address management table. As shown in FIG. 3, this IPv4 address management table 111 stores devices and IPv4 addresses in association with each other. Among these, the device indicates the type of device connected to the LAN 20. The IPv4 address indicates an IPv4 address for identifying a device on the LAN 20. For example, the first line in FIG. 3 indicates that the IPv4 address of the TV 5 that identifies the TV 5 on the LAN 20 is “192.168.0.100”. The second line in FIG. 3 indicates that the IPv4 address of the mobile phone 100 that identifies the mobile phone 100 on the LAN 20 is “192.168.100.200”.

  The IPv6 address management table 112 is a table that stores an IPv6 address to which the mobile phone 100 connected to the WAN 10 is assigned from the WAN 10. FIG. 4 is a diagram illustrating an example of the data structure of the IPv6 address management table. As shown in FIG. 4, this IPv6 address management table 112 stores an IPv6 prefix. The IPv6 prefix indicates an IPv6 prefix that is the first half of an IPv6 address that identifies the mobile phone 100 in the WAN 20. The example of FIG. 4 indicates that the first half of the IPv6 address assigned from the WAN 20 is “2400: xxxx: xxxx: 11 :: / 64”.

  The GW information management table 113 is a table for storing a WAN address for identifying the GW 200 in the WAN 10. FIG. 5 is a diagram illustrating an example of a data structure of the GW information management table. As illustrated in FIG. 5, the GW information management table 113 stores a GW-IPv6 prefix, a GW-LAN side MAC address, and a code in association with each other as a WAN side address. Among these, the GW-IPv6 prefix indicates the IPv6 prefix of the GW 200 that is the first half of the IPv6 address that identifies the GW 200 in the WAN 20. Note that there are 48-bit and 64-bit IPv6 prefixes of GW200. The GW-LAN side MAC address indicates the MAC address on the LAN 20 side of the GW 200.

  The code is a flag indicating whether or not the GW 200 is relaying communication between the mobile phone 100 connected to the WAN 10 and the TV 5 of the LAN 20. When the code is “0x0000”, the code means that the GW 200 is relaying communication between the mobile phone 100 connected to the WAN 10 and the TV 5 of the LAN 20, as shown in FIG. To do. When the code is “0xFFFF”, the code means that the GW 200 has finished relaying communication between the mobile phone 100 connected to the WAN 10 and the TV 5 of the LAN 20. FIG. 6 is a diagram illustrating an example of the contents of the code.

  In the example of FIG. 5, the IPv6 prefix on the WAN 20 side of the GW 200 is 48 bits “2001: fe00: abcd :: / 48”, and the MAC address on the LAN 20 side of the GW 200 is “1CDF-0F0A-ABCD”. Indicates that there is. In the example of FIG. 5, since the code is “0x0000”, the GW 200 relays communication between the mobile phone 100 connected to the WAN 10 and the TV 5 of the LAN 20.

  Returning to FIG. 2, the IPv4 address acquisition unit 102 acquires the IPv4 address of the mobile phone 100 and the IPv4 address of the TV 5. For example, the IPv4 address acquisition unit 102 acquires the IPv4 address of the mobile phone 100 and the IPv4 address of the TV 5 by receiving a user input operation from an input device such as a touch panel. The IPv4 address acquisition unit 102 stores the acquired IPv4 address of the mobile phone 100 and the IPv4 address of the TV 5 in the IPv4 address management table 111. The IPv4 address acquisition unit 102 is an example of an acquisition unit.

  The communication request receiving unit 103 receives a communication request for requesting the GW 200 to relay communication between the mobile phone 100 and the TV 5 of the LAN 20 from the user. The communication request accepting unit 103 notifies the packet processing unit 104 of the accepted communication request.

  Further, the communication request accepting unit 103 accepts a communication end request for requesting the GW 200 to end the relay of communication between the mobile phone 100 and the TV 5 of the LAN 20 from the user. The communication request accepting unit 103 notifies the packet processing unit 104 of the accepted communication end request.

  When connecting to the GW 200, the packet processing unit 104 transmits a WAN address request for requesting the WAN address to the GW 200. The packet processing unit 104 receives the WAN address of the GW 200 returned from the GW 200 that has received the WAN address request, and stores it in the GW information management table 113. In this embodiment, the packet processing unit 104 receives the IPv6 prefix of the GW 200 notified from the GW 200, the MAC address and code on the LAN 20 side, and stores them in the GW information management table 113.

  In addition, when receiving a communication request from the communication request receiving unit 103, the packet processing unit 104 generates an IPv4 packet or an IPv6 packet based on the IPv4 address management table 111, the IPv6 address management table 112, and the GW information management table 113. To do.

  An example of processing in which the packet processing unit 104 generates an IPv4 packet or an IPv6 packet will be described. First, an example of processing in which the packet processing unit 104 generates an IPv4 packet will be described. When receiving the communication request, the packet processing unit 104 generates an IPv4 packet for confirming connectivity, transmits the packet to the GW 200, and waits for a reply from the GW 200. The packet processing unit 104 that has received a reply from the GW 200 recognizes that the mobile phone 100 is directly connected to the GW 200. Then, the packet processing unit 104 refers to the IPv4 address management table 111, sets the IPv4 address of the TV 5 that is the target of the communication request as the destination, and generates an IPv4 packet in which the IPv4 address of the mobile phone 100 is set as the transmission source. .

  Next, an example of processing in which the packet processing unit 104 generates an IPv6 packet will be described. When receiving the communication request, the packet processing unit 104 generates an IPv4 packet for confirming connectivity, transmits the packet to the GW 200, and waits for a reply from the GW 200. The packet processing unit 104 that has not received a reply from the GW 200 recognizes that the mobile phone 100 is connected to the WAN 10. The packet processing unit 104 refers to the IPv4 address management table 111 and the IPv6 address management table 112, sets the IPv6 prefix of the mobile phone 100 as a transmission source, and generates an IPv6 packet including the IPv4 addresses of the mobile phone 100 and the TV 5 . The data structure of the IPv6 packet generated by the packet processing unit 104 will be described later.

  Further, when the packet processing unit 104 receives a communication end request from the communication request receiving unit 103, the IPv6 packet including a code indicating that communication between the mobile phone 100 connected to the WAN 10 and the TV 5 of the LAN 20 is ended. Is generated.

  The packet transmission unit 105 receives the IPv4 packet generated by the packet processing unit 104, and transmits the received IPv4 packet to the GW 200. In addition, the packet transmission unit 105 receives the IPv6 packet generated by the packet processing unit 104 and transmits the received IPv6 packet to the GW 200 via the WAN 10. The packet transmission unit 105 is an example of a transmission unit.

  The wireless interface unit 106 is a processing unit that wirelessly performs data communication with the area network 3 of the GW 200 and the WAN 10. For example, the packet processing unit 104 receives the WAN address of the GW 200 notified from the GW 200 via the wireless interface unit 106. For example, the packet transmission unit 105 transmits an IPv4 packet to the GW 200 via the wireless interface unit 106. For example, the packet transmission unit 105 transmits an IPv6 packet to the GW 200 via the wireless interface unit 106.

  Next, the configuration of the GW 200 shown in FIG. 1 will be described. FIG. 7 is a functional block diagram illustrating the configuration of the GW according to the first embodiment. As illustrated in FIG. 7, the GW 200 includes a WAN-side interface unit 201, a LAN-side interface unit 202, an IPv6-IPv4 address conversion table 203, and an IPv6-IPv4 address storage unit 204. The GW 200 includes an IPv4 routing table 205, an IPv6 routing table 206, and a routing management unit 207. The GW 200 includes a MAC address storage unit 208, a code storage unit 209, an IPv6 address storage unit 210, an IPv6 address processing unit 211, and a packet transfer unit 212.

  The WAN side interface unit 201 is a processing unit that is connected to the IPv6 network 1 of the WAN 10 and performs data communication with the WAN 10. For example, the IPv6-IPv4 address storage unit 204 and the packet transfer unit 212 transmit / receive IPv6 packets and the like to / from the IPv6 network 1 of the WAN 10 via the WAN-side interface unit 201. For example, the IPv6 address processing unit 211 receives an IPv6 prefix or the like from the IPv6 network 1 of the WAN 10 via the WAN side interface unit 201.

  The LAN-side interface unit 202 is a processing unit that is connected to the LAN 20 and the mobile phone 100 and performs data communication with the LAN 20 and the mobile phone 100. For example, the packet transfer unit 212 transmits / receives an IPv4 packet or the like with the LAN 20 via the LAN side interface unit 202. For example, the IPv6 address processing unit 211 transmits the IPv6 prefix of the GW 200 to the mobile phone 100 via the LAN side interface unit 202.

  The IPv6-IPv4 address conversion table 203 is a table that is referred to when the packet transfer unit 212 converts a destination address or a source address when transferring an IPv6 packet and an IPv4 packet. FIG. 8 is a diagram illustrating an example of a data structure of the IPv6-IPv4 address conversion table. As shown in FIG. 8, this IPv6-IPv4 address conversion table 203 stores an IPv6 address, an IPv4 address, a code, and a timer value in association with each other. Among these, the IPv6 address stores the IPv6 address of the mobile phone 100 set as the source of the IPv6 packet. The IPv4 address stores the IPv4 address of the mobile phone 100 included in the IPv6 packet. The code stores a code included in the IPv6 packet. The timer value stores the holding period of the entry of the correspondence relationship between the IPv6 address of the mobile phone 100 and the IPv4 address of the mobile phone 100. When the timer value becomes “0”, the corresponding entry is deleted. The timer value is an example of retention period information.

  The example of FIG. 8 indicates that the IPv6 address of the mobile phone 100 set as the transmission source of the IPv6 packet is “2400: 1234: 5678: 1”. Further, the example of FIG. 8 indicates that the IPv4 address of the mobile phone 100 included in the IPv6 packet is “192.168.100.200”. In the example of FIG. 8, the code included in the IPv6 packet is “0x0000”. In the example of FIG. 8, the retention period of the correspondence relationship between the IPv6 address “2400: 1234: 5678 :: 1” of the mobile phone 100 and the IPv4 address “192.168.100.200” of the mobile phone 100 is “2000”. ".

  The IPv6-IPv4 address storage unit 204 receives the IPv6 packet transmitted from the mobile phone 100 connected to the WAN 10 via the WAN-side interface unit 201. The IPv6-IPv4 address storage unit 204 associates the IPv6 address of the mobile phone 100 set as the source of the IPv6 packet with the IPv4 address of the mobile phone 100 included in the IPv6 packet and stores it in the IPv6-IPv4 address conversion table 203. To do. Note that when the IPv6 packet includes a code, the IPv6-IPv4 address storage unit 204 further stores the code included in the IPv6 packet in the IPv6-IPv4 address conversion table 203.

  Further, the IPv6-IPv4 address storage unit 204 further stores a timer value indicating a holding period of the correspondence relationship between the IPv6 address of the mobile phone 100 and the IPv4 address of the mobile phone 100 in the IPv6-IPv4 address conversion table 203. The IPv6-IPv4 address storage unit 204 decrements the timer value of the IPv6-IPv4 address conversion table 203 every time a clock event occurs, for example. Then, when the holding period indicated by the timer value expires, in other words, when the timer value becomes “0”, the IPv6-IPv4 address storage unit 204 sets the entry corresponding to the timer value to the IPv6-IPv4 address. Delete from the conversion table 203.

  Also, the IPv6-IPv4 address storage unit 204 performs the following processing when a code indicating the end of communication is included in the IPv6 packet. That is, the IPv6-IPv4 address storage unit 204 deletes the entry corresponding to the IPv6 address of the mobile phone 100 set as the source of the IPv6 packet from the IPv6-IPv4 address conversion table 203.

  The IPv4 routing table 205 is a table that stores information on communication routes destined for an electronic device (hereinafter referred to as “IPv4 electronic device”) in which an IPv4 protocol stack is implemented in the LAN 20. The IPv6 routing table 206 is a table that stores information on communication routes destined for an electronic device (hereinafter, referred to as “IPv6 electronic device”) that implements the IPv6 protocol stack in the LAN 20. The routing management unit 207 manages the IPv4 routing table 205 and the IPv6 routing table 206, and mediates exchanges between the IPv4 routing table 205 and the IPv6 routing table 206 and the packet forwarding unit 212.

  The MAC address storage unit 208 stores the MAC address on the LAN 20 side of the GW 200 that is notified to the mobile phone 100 as a part of the WAN side address. The code storage unit 209 stores a code notified to the mobile phone 100 as a part of the WAN address. The IPv6 address storage unit 210 stores the IPv6 prefix of the GW 200 that is notified to the mobile phone 100 as part of the WAN address.

  The IPv6 address processing unit 211 receives an IPv6 prefix assigned from the IPv6 network 1 of the WAN 10. There are 48-bit and 64-bit IPv6 prefixes assigned from the IPv10 network 1 of the WAN 10. In this embodiment, it is assumed that the IPv6 prefix allocated from the IPv6 network 1 of the WAN 10 is 48 bits. The IPv6 address processing unit 211 stores the received IPv6 prefix in the IPv6 address storage unit 210.

  Further, when the IPv6 address processing unit 211 receives a WAN address request from the mobile phone 100, the IPv6 address processing unit 211 checks whether the IPv6 prefix of the IPv6 address storage unit 210 is 48 bits or 64 bits. The IPv6 address processing unit 211 performs the following processing when the IPv6 prefix of the IPv6 address storage unit 210 is 48 bits. The IPv6 address processing unit 211 notifies the cellular phone 100 of the MAC address on the LAN 20 side of the MAC address storage unit 208, the code on the code storage unit 209, and the IPv6 prefix on the IPv6 address storage unit 210 as the WAN side address of the GW 200. On the other hand, the IPv6 address processing unit 211 performs the following processing when the IPv6 prefix of the IPv6 address storage unit 210 is 64 bits. The IPv6 address processing unit 211 generates a WAN-side IPv6 address by adding an arbitrary 64-bit value to the IPv6 prefix in the IPv6 address storage unit 210. The IPv6 address processing unit 211 notifies the mobile phone 100 of the generated WAN side IPv6 address as the WAN side address of the GW 200. Note that the IPv6 address processing unit 211 holds the generated WAN-side IPv6 address in its own storage area.

  When receiving an IPv6 packet from the WAN 10, the packet transfer unit 212 generates an IPv4 packet based on the IPv6-IPv4 address conversion table 203, and transfers the generated IPv4 packet to the TV 5 of the LAN 20. Further, when receiving an IPv4 packet from the LAN 10, the packet transfer unit 212 generates an IPv6 packet based on the IPv6-IPv4 address conversion table 203, and transfers the generated IPv6 packet to the mobile phone 100 connected to the WAN 10. To do.

  An example of processing in which the packet transfer unit 212 generates an IPv4 packet will be described. When receiving the IPv6 packet from the WAN 10, the packet transfer unit 212 refers to the IPv6-IPv4 address conversion table 203 and searches for an entry with the same “IPv6 address” as the source of the IPv6 packet. The packet transfer unit 212 performs the following process when an entry with the same “IPv6 address” as the source of the IPv6 packet exists. That is, the packet transfer unit 212 resets the timer value of the entry, sets the IPv4 address of the mobile phone 100 corresponding to the entry as the transmission source, and sets the IPv4 address of the TV 5 included in the IPv6 packet as the destination. Generate a packet.

  An example of processing in which the packet transfer unit 212 generates an IPv6 packet will be described. When receiving the IPv4 packet from the LAN 20, the packet transfer unit 212 refers to the IPv6-IPv4 address conversion table 203 and searches for an entry with the same “IPv4 address” as the destination of the IPv4 packet. The packet transfer unit 212 performs the following process when an entry with the same “IPv4 address” as the destination of the IPv4 packet exists. That is, the packet transfer unit 212 generates an IPv6 packet in which the IPv6 address of the corresponding mobile phone 100 of the entry is set as the destination.

  Next, the hardware configuration of the mobile phone 100 according to the present embodiment will be described. FIG. 9 is a diagram illustrating an example of a hardware configuration of the mobile phone according to the first embodiment. A mobile phone 100 shown in FIG. 9 includes a CPU (Central Processing Unit) 301, a packet transfer engine 302, a RAM (Random Access Memory) 303, and a hard disk device 304. In addition, the mobile phone 100 includes a wireless interface device 305, an input device 306, and a display device 307. Each device 301 to 307 is connected to a bus 308.

  The RAM 303 implements the functions of the IPv4 address management table 111, the IPv6 address management table 112, and the GW information management table 113 in FIG. Further, the packet transfer engine 302 and the wireless interface device 305 realize the function of the wireless interface unit 106 in FIG.

  The hard disk device 304 stores various programs that realize processing by the IPv4 address acquisition unit 102, the communication request reception unit 103, the packet processing unit 104, the packet transmission unit 105, and the like illustrated in FIG.

  The CPU 301 and the RAM 303 read out and execute various programs stored in the hard disk device 304, thereby generating a process that realizes each function described above.

  Next, a hardware configuration of the GW 200 according to the present embodiment will be described. FIG. 10 is a diagram illustrating an example of a hardware configuration of the GW according to the first embodiment. A GW 200 illustrated in FIG. 10 includes a CPU 401, a packet transfer engine 402, a RAM 403, a hard disk device 404, a wireless interface device 405, and an input device 406. The GW 200 includes a WAN side interface device 407, a LAN side interface device 408, and a display device 409. Each device 401 to 409 is connected to the bus 410.

  The RAM 403 realizes the functions of the IPv6-IPv4 address conversion table 203, the IPv4 routing table 205, and the IPv6 routing table 206 in FIG. The RAM 403 implements the functions of the MAC address storage unit 208, the code storage unit 209, and the IPv6 address storage unit 210 in FIG. Further, the packet transfer engine 402 and the WAN side interface device 407 realize the function of the WAN side interface unit 201 in FIG. Further, the packet transfer engine 402, the wireless interface device 405, and the LAN side interface device 408 realize the function of the LAN side interface unit 202 in FIG.

  The hard disk device 404 stores various programs that realize processing by the IPv6-IPv4 address storage unit 204, the routing management unit 207, the IPv6 address processing unit 211, the packet transfer unit 212, and the like illustrated in FIG.

  The CPU 401 and the RAM 403 read out and execute various programs stored in the hard disk device 404, thereby generating processes for realizing the functions described above.

  Next, a processing procedure of the communication system according to the first embodiment will be described. First, a processing procedure of a series of processes in which the mobile phone 100 of the communication system according to the first embodiment is wirelessly connected to the GW 200 and communicates with the TV 5 of the LAN 10 via the GW 200 will be described. FIG. 11 is a sequence diagram illustrating an example of a processing procedure of a process in which the mobile phone of the communication system according to the first embodiment communicates with the LAN TV via the GW. In the example of FIG. 11, it is assumed that the mobile phone 100 exists in a range that can be connected to the GW 200. In the example of FIG. 11, it is assumed that the IPv6 prefix notified from the IPv6 network 1 of the WAN 10 to the GW 200 is 48 bits.

  As shown in FIG. 11, the mobile phone 100 acquires the IPv4 address of the mobile phone 100 and the IPv4 address of the TV 5 (step S101). The mobile phone 100 stores the acquired IPv4 address of the mobile phone 100 and the IPv4 address of the TV 5 in the IPv4 address management table 111.

  The GW 200 receives the 48-bit IPv6 prefix notified from the IPv6 network 1 of the WAN 10 (step S102). The GW 200 stores the received 48-bit IPv6 prefix in the IPv6 address storage unit 210.

  When connecting to the GW 200, the mobile phone 100 transmits a WAN address request to the GW 200 (step S103).

  When the GW 200 receives the WAN address request from the mobile phone 100, the GW 200 executes a WAN address notification process (step S104).

  Here, the WAN address notification processing in step S104 will be described. FIG. 12 is a flowchart illustrating a processing procedure of WAN address notification processing executed by the GW according to the first embodiment. As shown in FIG. 12, when the GW 200 receives a WAN address request from the mobile phone 100 (step S121), the GW 200 confirms whether the IPv6 prefix in the IPv6 address storage unit 210 is 64 bits (step S122). When the IPv6 prefix of the IPv6 address storage unit 210 is 48 bits (step S122; No), the GW 200 performs the following processing. The GW 200 notifies the mobile phone 100 of the MAC address on the LAN 20 side of the MAC address storage unit 208, the code of the code storage unit 209, and the IPv6 prefix of the IPv6 address storage unit 210 as the WAN side address of the GW 200 (step S123).

  On the other hand, when the IPv6 prefix of the IPv6 address storage unit 210 is 64 bits (step S122; Yes), the GW 200 performs the following processing. The GW 200 generates a WAN-side IPv6 address by adding an arbitrary 64-bit value to the IPv6 prefix in the IPv6 address storage unit 210, and notifies the WAN-side IPv6 address to the mobile phone 100 (step S124). The GW 200 holds the generated WAN side IPv6 address.

  In this embodiment, the IPv6 prefix of the IPv6 address storage unit 210 is 48 bits. Therefore, the GW 200 notifies the mobile phone 100 of the MAC address, code, and IPv6 prefix on the LAN 20 side in the example of FIG. 12 (steps S122; No, S123).

  Returning to FIG. 11, the mobile phone 100 receives the IPv6 prefix, the code, and the MAC address on the LAN 20 side notified from the GW 200 (step S105). The cellular phone 100 executes an IPv4 / IPv6 packet transmission process (step S106).

  Here, the IPv4 / IPv6 packet transmission processing in step S106 will be described. FIG. 13 is a flowchart illustrating a processing procedure of IPv4 / IPv6 packet transmission processing executed by the mobile phone according to the first embodiment.

  As illustrated in FIG. 13, the mobile phone 100 determines whether or not a communication request for requesting the GW 200 to relay communication with the TV 5 of the LAN 20 is received from the user (step S131). If the mobile phone 100 has not received a communication request (step S131; No), the process returns to step S131.

  On the other hand, when the mobile phone 100 receives a communication request (step S131; Yes), the mobile phone 100 generates an IPv4 packet for confirming connectivity and transmits the packet to the GW 200 (step S132), and waits for a reply from the GW 200. (Step S133). When there is a reply from the GW 200 (step S133; Yes), the mobile phone 100 performs the following processing. The mobile phone 100 refers to the IPv4 address management table 111, and generates an IPv4 packet in which the IPv4 address of the TV 5 is set as the destination and the IPv4 address of the mobile phone 100 is set as the transmission source (step S134). Then, the mobile phone 100 transmits the generated IPv4 packet to the GW 200 (step S135).

  When there is no reply from the GW 200 (step S133; No), the mobile phone 100 performs the following processing. The mobile phone 100 refers to the IPv4 address management table 111 and the IPv6 address management table 112. Then, the mobile phone 100 sets the IPv6 prefix of the mobile phone 100 as a transmission source, and generates an IPv6 packet including the IPv4 addresses of the mobile phone 100 and the TV 5 (step S136). Then, the cellular phone 100 transmits the generated IPv6 packet to the GW 200 via the WAN 10 (step S137).

  In the example of FIG. 11, the mobile phone 100 exists in a range that can be connected to the GW 200. Therefore, the mobile phone 100 generates an IPv4 packet in which the IPv4 address of the TV 5 is set as the destination in the example of FIG. 13 and transmits it to the GW 200 (step S133; Yes, S134, S135).

  Returning to FIG. 11, the GW 200 receives the IPv4 packet transmitted from the mobile phone 100 (step S107). The GW 200 transfers the received IPv4 packet to the TV 5 of the LAN 20 (step S108). The TV 5 receives the IPv4 packet and performs a predetermined process based on the data stored in the IPv4 packet. Thereafter, the TV 5 sets its own IPv4 address as a transmission source, generates an IPv4 packet in which the IPv4 address of the mobile phone 100 is set as a destination, and transmits it to the GW 200 (step S109). The GW 200 receives the IPv4 packet transmitted from the TV 5 and transfers it to the mobile phone 100 (step S110).

  Next, a processing procedure of a series of processes in which the mobile phone 100 of the communication system according to the first embodiment is wirelessly connected to the area network 3 of the WAN 10 and communicates with the TV 5 of the LAN 20 via the WAN 10 and the GW 200 will be described. FIG. 14 is a sequence diagram illustrating an example of a processing procedure of processing in which the mobile phone of the communication system according to the first embodiment communicates with the LAN TV via the WAN and the GW. In the example of FIG. 14, it is assumed that the mobile phone 100 exists in a range that can be connected to the area network 3 of the WAN 10.

  As shown in FIG. 14, the mobile phone 100 receives the IPv6 prefix notified from the area network 3 of the WAN 10 (step S141). The cellular phone 100 executes an IPv4 / IPv6 packet transmission process (step S142).

  Here, the IPv4 / IPv6 packet transmission processing in step S142 will be described. The IPv4 / IPv6 packet transmission process in step S142 corresponds to the IPv4 / IPv6 packet transmission process shown in FIG.

  In the example of FIG. 14, the mobile phone 100 does not exist in a range that can be connected to the GW 200, but exists in a range that can be connected to the area network 3 of the WAN 10. Therefore, in the example of FIG. 13, the mobile phone 100 sets the IPv6 prefix of the mobile phone 100 as a transmission source, and generates an IPv6 packet including the IPv4 addresses of the mobile phone 100 and the TV 5 (step S133; No, S136). . Then, the cellular phone 100 transmits the generated IPv6 packet to the GW 200 via the WAN 10 (step S137). The IPv6 packet generated in step S136 is, for example, as shown in FIG. FIG. 15 is a diagram (part 1) illustrating an example of a data structure of an IPv6 packet.

  The IPv6 packet shown in FIG. 15 has a v6 destination, a v6 transmission source, and a payload. Among these, the v6 destination is a destination address of the IPv6 packet, and includes a destination IPv6 prefix, a code, a v4 destination, and a v4 transmission source. The destination IPv6 prefix stores the IPv6 prefix of the GW 200 notified from the GW 200 by the mobile phone 100. The code stores the code notified from the GW 200 by the mobile phone 100. The v4 destination stores the IPv4 address of the TV 5 acquired by the mobile phone 100. The v4 transmission source stores the IPv4 address of the mobile phone 100 acquired by the mobile phone 100. The v6 transmission source is a transmission source address of an IPv6 packet, and includes a transmission source IPv6 prefix, a code, and a LAN side MAC address. The source IPv6 prefix stores the IPv6 prefix of the mobile phone 100 notified from the area network 3 of the WAN 10 by the mobile phone 100. The code stores the code notified from the GW 200 by the mobile phone 100. The LAN side MAC address stores the MAC address on the LAN 20 side, which is notified from the GW 200 by the mobile phone 100. The payload stores data for operating the TV 5.

  A process in which the mobile phone 100 generates an IPv6 packet will be described using the example of FIG. The cellular phone 100 sets the IPv6 prefix of the GW 200 included in the GW information management table 113 as the destination IPv6 prefix of the IPv6 packet. The cellular phone 100 stores the code of the GW information management table 113 in the code of the IPv6 packet. The cellular phone 100 stores the IPv4 address of the cellular phone 100 and the IPv4 address of the TV 5 included in the IPv4 address management table 111 in the v4 transmission source and the v4 destination of the IPv6 packet, respectively. The mobile phone 100 sets the IPv6 prefix of the mobile phone 100 included in the IPv6 address management table 112 as the source IPv6 prefix of the IPv6 packet. The mobile phone 100 stores the MAC address on the LAN 20 side of the GW 200 included in the GW information management table 113 in the LAN side MAC address of the IPv6 packet. The cellular phone 100 stores data for operating the TV 5 in the payload of the IPv6 packet. Thereby, an IPv6 packet is generated.

  Returning to FIG. 14, the GW 200 receives the IPv6 packet transmitted from the mobile phone 100 via the WAN 10 (step S143). A code is included in the v6 destination of the IPv6 packet transmitted from the mobile phone 100. The GW 200 executes an IPv4 packet transfer process (step S144).

  Here, the IPv4 packet transfer processing in step S144 will be described. FIG. 16 is a flowchart illustrating a processing procedure of IPv4 packet transfer processing executed by the GW according to the first embodiment.

  As shown in FIG. 16, the GW 200 receives an IPv6 packet from the WAN 10 (step S151). The GW 200 determines whether a code is included in the v6 destination of the IPv6 packet (step S152). When the code is not included in the v6 destination of the IPv6 packet (step S152; No), the GW 200 determines whether or not the v6 destination matches the WAN-side IPv6 address held by the GW 200 (step S153). When the GW 200 matches (step S153; Yes), the process proceeds to step S159. On the other hand, when they do not match (step S153; No), the GW 200 transfers the IPv6 packet to the IPv6 electronic device in the LAN 20 based on the IPv6 routing table 206 (step S154).

  On the other hand, when the code is included in the v6 destination of the IPv6 packet (step S152; Yes), the GW 200 terminates the communication between the mobile phone 100 connected to the WAN 10 and the TV 5 of the LAN 20. Whether to show or not is determined (step S155). When the code does not indicate the end of communication (step S155; No), the GW 200 extracts the LAN side MAC address from the v6 transmission source of the IPv6 packet (step S156). The GW 200 determines whether or not the LAN side MAC address of the IPv6 packet matches the LAN side MAC address of the MAC address storage unit 208 (step S157).

  When the LAN side MAC address of the IPv6 packet does not match the LAN side MAC address of the MAC address storage unit 208 (step S157; No), the GW 200 determines that the authentication has failed and discards the IPv6 packet (step S158).

  When the LAN side MAC address of the IPv6 packet matches the LAN side MAC address of the MAC address storage unit 208 (step S157; Yes), the GW 200 determines that the authentication is successful and performs the following processing. That is, the GW 200 refers to the IPv6-IPv4 address conversion table 203 (step S159), and determines whether there is an entry with the same “IPv6 address” as the v6 transmission source of the IPv6 packet (step S160). When there is no entry of “IPv6 address” that is the same as the v6 transmission source of the IPv6 packet (step S160; No), the GW 200 performs the following processing. That is, the GW 200 determines whether there is an entry with the same “IPv4 address” as the v4 transmission source of the IPv6 packet (step S161).

  When there is no entry of “IPv4 address” that is the same as the v4 transmission source of the IPv6 packet (step S161; No), the GW 200 performs the following processing. That is, the GW 200 associates the v6 transmission source and the v4 transmission source of the IPv6 packet and stores them as a new entry in the IPv6-IPv4 address translation table 203, and further sets the timer value of the new entry (step S162). Note that the GW 200 further stores the code included in the IPv6 packet in the IPv6-IPv4 address conversion table 203 when the code is included in the IPv6 packet. Then, when there is no entry in the IPv4 routing table 205 having the same destination IPv4 address as the v4 transmission source of the IPv6 packet (step S163; No), the GW 200 advances the process to step S170. When an entry with the same destination IPv4 address as the v4 transmission source of the IPv6 packet exists in the IPv4 routing table 205 (step S163; Yes), the GW 200 performs the following processing. That is, the GW 200 deletes the entry from the IPv4 routing table 205 (step S164), and the process proceeds to step S170.

  On the other hand, when there is an entry with the same “IPv4 address” as the v4 transmission source of the IPv6 packet (step S161; Yes), the GW 200 performs the following processing. That is, since the IPv6 prefix of the mobile phone 100 has been changed, the GW 200 deletes the same “IPv4 address” entry as the v4 transmission source of the IPv6 packet from the IPv6-IPv4 address conversion table 203 (step S165). Then, the GW 200 associates the v6 transmission source and the v4 transmission source of the IPv6 packet and stores them as a new entry in the IPv6-IPv4 address conversion table 203, and further sets a timer value for the new entry (step S166). Note that the GW 200 further stores the code included in the IPv6 packet in the IPv6-IPv4 address conversion table 203 when the code is included in the IPv6 packet.

  On the other hand, when the entry of “IPv6 address” identical to the v6 transmission source of the IPv6 packet exists in the IPv6-IPv4 address conversion table 203 (step S160; Yes), the GW 200 performs the following processing. That is, since the IPv6 address of the mobile phone 100 has already been registered, the GW 200 resets the timer value of the “IPv6 address” entry that is the same as the v6 transmission source of the IPv6 packet to the initial value (step S167), and performs the processing. Proceed to step S170.

  When the code of the IPv6 packet indicates the end of communication (step S155; Yes), the GW 200 refers to the IPv6-IPv4 address conversion table 203 (step S168). The GW 200 deletes the same “IPv6 address” entry as the v6 transmission source of the IPv6 packet (step S169).

  In step S170, the GW 200 sets the IPv4 address of the mobile phone 100 as the transmission source based on the IPv6-IPv4 address conversion table 203, and generates an IPv4 packet in which the IPv4 address of the TV 5 included in the IPv6 packet is set as the destination. . Then, the GW 200 transfers the generated IPv4 packet to the TV 5 of the LAN 20 (step S171). The IPv4 packet generated in step S170 is, for example, as shown in FIG. FIG. 17 is a diagram illustrating an example (part 1) of the data structure of the IPv4 packet.

  The IPv4 packet shown in FIG. 17 has a v4 destination, a v4 transmission source, and a payload. Among these, the v4 destination is the destination address of the IPv4 packet, and stores the IPv4 address of the TV 5 that is the transfer destination of the IPv4 packet. The v4 transmission source is a transmission source address of the IPv4 packet, and stores the IPv4 address of the mobile phone 100 that is a temporary transmission source of the IPv4 packet.

  A process in which the GW 200 generates an IPv4 packet will be described using the example of FIG. The GW 200 acquires the IPv4 address of the mobile phone 100 corresponding to the v6 transmission source of the IPv6 packet from the IPv6-IPv4 address conversion table 203. The GW 200 sets the acquired IPv4 address of the mobile phone 100 as the v4 transmission source of the IPv4 packet. The GW 200 sets the IPv4 address of the TV 5 stored in the v4 destination of the IPv6 packet as the v4 destination of the IPv4 packet. The GW 200 stores the data stored in the payload of the IPv6 packet in the payload of the IPv4 packet. Thereby, an IPv4 packet is generated.

  In the example of FIG. 14, the code is included in the v6 destination of the IPv6 packet transmitted from the mobile phone 100. Therefore, the GW 200 that has received the IPv6 packet from the WAN 10 determines that the code is included in the v6 destination of the IPv6 packet in the example of FIG. 16, and determines that the code does not indicate the end of communication (step S151, S152; Yes, S155; Yes). Thereafter, the GW 200 determines that the LAN side MAC address of the IPv6 packet matches the LAN side MAC address of the MAC address storage unit 208, generates an IPv4 packet, and transfers the packet to the TV 5 of the LAN 20 (step S157; Yes, S160 to S171). ).

  Returning to FIG. 14, the TV 5 receives the IPv4 packet transferred from the GW 200 (step S145). The TV 5 performs a predetermined process based on the data stored in the IPv4 packet. Thereafter, the TV 5 sets its own IPv4 address as a transmission source, generates an IPv4 packet in which the IPv4 address of the mobile phone 100 is set as a destination, and sends it back to the GW 200 (step S146). The IPv4 packet returned in step S146 is, for example, as shown in FIG. FIG. 18 is a diagram illustrating an example (part 2) of the data structure of the IPv4 packet.

  The IPv4 packet shown in FIG. 18 has a v4 destination, a v4 transmission source, and a payload. Among these, the v4 destination is the destination address of the IPv4 packet, and stores the IPv4 address of the mobile phone 100 that is a temporary return destination of the IPv4 packet. The v4 transmission source is the transmission source address of the IPv4 packet, and stores the IPv4 address of the TV 5 that is the transmission source of the IPv4 packet.

  Returning to FIG. 14, the GW 200 receives the IPv4 packet returned from the TV 5 from the LAN 20, and executes the IPv6 packet transfer process (step S 147). The IPv4 packet returned from the TV 5 is an example of a third packet.

  Here, the IPv6 packet transfer processing in step S147 will be described. FIG. 19 is a flowchart of the IPv6 packet transfer process performed by the GW according to the first embodiment.

  As shown in FIG. 19, the GW 200 receives a packet from the LAN 20 (step S181). When the destination address of the received packet is an IPv6 address (step S182; Yes), the GW 200 performs the following processing because the received packet is an IPv6 packet transmitted from an IPv6 electronic device in the LAN 20. In other words, the GW 200 transfers the IPv6 packet to another IPv6 electronic device in the LAN 20 based on the IPv6 routing table 206 (step S183).

  On the other hand, when the destination address of the received packet is an IPv4 address (step S182; No), the GW 200 performs the following process because the received packet is an IPv4 packet. That is, the GW 200 searches the IPv6-IPv4 address conversion table 203 for an entry of “IPv4 address” that is the same as the destination address of the IPv4 packet (step S184). When there is no entry of “IPv4 address” that is the same as the destination address of the IPv4 packet (step S185; No), the GW 200 performs the following processing. That is, the GW 200 transfers the IPv4 packet to the IPv4 electronic device in the LAN 20 based on the IPv4 routing table 205 (step S186).

  On the other hand, when the entry of “IPv4 address” that is the same as the destination address of the IPv4 packet exists in the IPv6-IPv4 address conversion table 203 (step S185; Yes), the GW 200 performs the following processing. That is, the GW 200 generates an IPv6 packet in which “IPv6 address” corresponding to the same “IPv4 address” as the destination address of the IPv4 packet is set as a destination (step S187). Then, the GW 200 transfers the generated IPv6 packet to the mobile phone 100 via the WAN 10 (step S188). The IPv6 packet generated in step S187 is, for example, as shown in FIG. FIG. 20 is a second diagram illustrating an exemplary data structure of an IPv6 packet.

  The IPv6 packet shown in FIG. 20 has a v6 destination, a v6 transmission source, and a payload. Among these, the v6 destination is a destination address of the IPv6 packet, and includes a destination IPv6 prefix, a code, and a LAN side MAC address. The destination IPv6 prefix stores the IPv6 prefix of the mobile phone 100. The code stores a code held by the GW 200. The LAN side MAC address stores the MAC address on the LAN 20 side of the GW 200. The v6 transmission source is a transmission source address of the IPv6 packet, and includes a transmission source IPv6 prefix, a code, a v4 transmission source, and a v4 destination. The source IPv6 prefix stores the IPv6 prefix of the GW 200. The code stores a code held by the GW 200. The v4 transmission source stores the IPv4 address of TV5. The v4 destination stores the IPv4 address of the mobile phone 100. The payload stores predetermined data.

  A process in which the GW 200 generates an IPv6 packet will be described using the example of FIG. The GW 200 refers to the IPv6-IPv4 address conversion table 203 and sets the IPv6 address of the mobile phone 100 corresponding to the same IPv4 address as the destination address of the IPv4 packet as the v6 destination of the IPv6 packet. The GW 200 stores the IPv6 prefix in the IPv6 address storage unit 210 in the source IPv6 prefix of the IPv6 packet. The GW 200 refers to the IPv6-IPv4 address conversion table 203 and stores a code corresponding to the same IPv4 address as the destination address of the IPv4 packet in the code of the IPv6 packet. The GW 200 stores the v4 destination and the v4 transmission source of the IPv4 packet in the v4 destination and the v4 transmission source of the IPv6 packet, respectively. Thereby, an IPv6 packet is generated.

  In the example of FIG. 14, the IPv4 address of the mobile phone 100 is included in the v4 destination of the IPv4 packet returned from the TV 5. Therefore, the GW 200 that has received the IPv4 packet from the LAN 20 confirms that the destination address of the IPv4 packet is an IPv4 address in the example of FIG. 19 (steps S181 and S182; No). Thereafter, the GW 200 determines that an entry with the same “IPv4 address” as the destination address of the IPv4 packet exists in the IPv6-IPv4 address conversion table 203 (steps S184 and S185; Yes). Then, the GW 200 generates an IPv6 packet in which the corresponding IPv6 address of the entry is set as a destination, and transfers it to the mobile phone 100 (steps S187 and S188).

  Returning to FIG. 14, the mobile phone 100 receives the IPv6 packet transferred from the GW 200 (step S148). Note that the mobile phone 100 performs predetermined processing using data included in the IPv6 packet. The GW 200 performs an IPv4-IPv6 address deletion process at a predetermined timing (step S149).

  Here, the IPv4-IPv6 address deletion processing in step S149 will be described. FIG. 21 is a flowchart illustrating the processing procedure of IPv4-IPv6 address deletion processing executed by the GW according to the first embodiment. The process illustrated in FIG. 21 is executed, for example, when a clock event occurs.

  As illustrated in FIG. 21, when there is no clock event (step S191; No), the GW 200 ends the process. On the other hand, when there is a clock event (step S191; Yes), the GW 200 decrements the timer values of all entries in the IPv6-IPv4 address conversion table 203 (step S192).

  When there is no entry for which the timer value = 0, the GW 200 ends the process (Step S193; No). On the other hand, when there is an entry with the timer value = 0 (step S193; Yes), the GW 200 deletes the entry from the IPv6-IPv4 address conversion table 203 (step S194).

  Next, effects of the communication system according to the first embodiment will be described. When the mobile phone 100 included in the communication system is connected to the WAN 10, the IPv6 address of the mobile phone 100 is set as a transmission source, and an IPv6 packet including the IPv4 address of the TV 5 of the mobile phone 100 and the LAN 20 is sent to the WAN 10. Via GW200. The GW 200 associates the IPv6 address of the mobile phone 100 set as the transmission source of the IPv6 packet received from the WAN 10 with the IPv4 address of the mobile phone 100 included in the IPv6 packet, and stores them in the IPv6-IPv4 address conversion table 203. The GW 200 sets the IPv6 address of the mobile phone 100 in the IPv6-IPv4 address conversion table 203 as a transmission source, generates an IPv4 packet in which the IPv4 address of the TV5 included in the IPv6 packet is set as a destination, and transfers the IPv4 packet to the TV5 of the LAN 20 . For this reason, in the communication system of the present embodiment, the IPv4 packet can be transferred to the TV 5 of the LAN 20 without pre-registering the correspondence relationship between the port number and the IPv4 address of the transfer destination in the GW 200. As a result, communication from the WAN 10 to the LAN 20 can be relayed while suppressing an increase in the memory size of the GW 200.

  Further, the GW 200 in the present embodiment searches the IPv6-IPv4 address conversion table 203 for the IPv6 address of the mobile phone 100 corresponding to the IPv4 address of the mobile phone 100 set as the destination of the IPv4 packet returned from the TV 5. The GW 200 transfers the IPv6 packet in which the searched IPv6 address of the mobile phone 100 is set as the destination to the mobile phone 100 via the WAN 10. Therefore, in the communication system of the present embodiment, it is possible to transfer the IPv6 packet to the mobile phone 100 via the WAN 10 without pre-registering the correspondence relationship between the port number and the IPv6 address of the transfer destination in the GW 200. As a result, communication from the LAN 20 to the WAN 10 can be relayed while suppressing an increase in the memory size of the GW 200.

  In addition, when the timer value indicating the retention period of the correspondence relationship between the IPv6 address and the IPv4 address of the mobile phone 100 has expired, the GW 200 in the present embodiment displays an entry corresponding to the expired timer value in the IPv6-IPv4 address conversion table. Delete from 203. For this reason, in the communication system of the present embodiment, the correspondence relationship between the IPv6 address and the IPv4 address of the mobile phone 100 that has not been used for a predetermined period can be deleted, and the memory of the GW 200 can be used efficiently. .

  In the first embodiment, the example has been described in which the GW deletes the entry corresponding to the expired timer value from the entry of the IPv6-IPv4 address translation table. However, when the communication end information indicating the communication end is included in the received IPv6 packet, the GW may delete the entry including the source of the IPv6 packet from the entry of the IPv6-IPv4 address conversion table. In the second embodiment, an example in which an entry including an IPv6 packet transmission source is deleted from an entry of an IPv6-IPv4 address translation table when communication end information indicating communication end is included in an IPv6 packet received by the GW will be described.

  In the mobile phone 100 of the present embodiment, when the packet transmission unit 105 receives a communication end request from the communication request reception unit 103, a code indicating the end of communication between the mobile phone 100 connected to the WAN 10 and the TV 5 of the LAN 20 An IPv6 packet including is generated. For example, the packet transmission unit 105 generates an IPv6 packet including “0xFFFF” illustrated in FIG. 6 as a code indicating the end of communication. The code indicating the end of communication is an example of communication end information. The packet transmission unit 105 transmits the generated IPv6 packet to the GW 200 via the WAN 10.

  In the GW 200 of the present embodiment, the IPv6-IPv4 address storage unit 204 performs the following processing when a code indicating the end of communication is included in the IPv6 packet. That is, the IPv6-IPv4 address storage unit 204 deletes the entry corresponding to the IPv6 address of the mobile phone 100 set as the source of the IPv6 packet from the IPv6-IPv4 address conversion table 203.

  FIG. 22 is a sequence diagram illustrating an example of a processing procedure of processing in which the mobile phone of the communication system according to the second embodiment communicates with the LAN TV via the WAN and the GW. In the example of FIG. 22, it is assumed that the mobile phone 100 exists in a range that can be connected to the area network 3 of the WAN 10. Note that steps S201 to S208 illustrated in FIG. 22 correspond to steps S141 to S148 illustrated in FIG. 14, and thus detailed description thereof is omitted here.

  As illustrated in FIG. 22, for example, when receiving an operation for a communication end request from a user, the mobile phone 100 transmits an IPv6 packet including a code indicating the end of communication to the GW 200 via the WAN 10 (step S209).

  The GW 200 receives the IPv6 packet transmitted from the mobile phone 100 via the WAN 10 and executes an IPv4 packet transfer process (step S210).

  Here, the IPv4 packet transfer processing in step S210 will be described. The IPv4 packet transfer process in step S210 corresponds to the IPv4 packet transfer process shown in FIG.

  In the example of FIG. 22, the code indicating the end of communication is included in the code of the IPv6 packet transmitted from the mobile phone 100. Therefore, the GW 200 that has received the IPv6 packet from the WAN 10 determines that the code is included in the v6 destination of the IPv6 packet in the example of FIG. 16, and determines that the code indicates the end of communication (step S151, S152; Yes, S155; Yes). After that, the GW 200 refers to the IPv6-IPv4 address conversion table 203 and deletes the “IPv6 address” entry that is the same as the v6 transmission source of the IPv6 packet (steps S168 and S169).

  Next, effects of the communication system according to the second embodiment will be described. The mobile phone 100 included in the communication system transmits an IPv6 packet including a code indicating the end of communication between the mobile phone 100 connected to the WAN 10 and the TV 5 of the LAN 20 to the GW 200 via the WAN 10. When the received IPv6 packet includes a code indicating the end of communication, the GW 200 deletes the IPv6 address entry that is the same as the source of the IPv6 packet from the IPv6-IPv4 address conversion table 203. For this reason, in the communication system of the present embodiment, the correspondence relationship between the IPv6 address and the IPv4 address of the mobile phone 100 can be deleted at any timing without depending on the expiration of the timer value, and the memory of the GW 200 can be further saved. It can be used efficiently.

  In the first and second embodiments, the example in which the IPv6 prefix notified from the WAN IPv6 network to the GW is 48 bits has been described. However, it is also assumed that the IPv6 prefix notified from the WAN IPv6 network to the GW is 64 bits. Therefore, in the third embodiment, an example in which the IPv6 prefix notified from the WAN IPv6 network to the GW is 64 bits will be described.

  In the GW 200 of this embodiment, the IPv6 address processing unit 211 receives a 64-bit IPv6 prefix from the IPv6 network 1 of the WAN 10 and stores the received IPv6 prefix in the IPv6 address storage unit 210.

  When the IPv6 address processing unit 211 receives a WAN address request from the mobile phone 100, the IPv6 address processing unit 211 adds an arbitrary 64-bit value to the 64-bit IPv6 prefix in the IPv6 address storage unit 210, and the 128-bit WAN-side IPv6. Generate an address. The IPv6 address processing unit 211 notifies the mobile phone 100 of the generated WAN side IPv6 address as the WAN side address of the GW 200. The IPv6 address processing unit 211 holds the WAN-side IPv6 address in its own storage area.

  The IPv6-IPv4 address storage unit 204 receives the IPv6 packet transmitted from the mobile phone 100 connected to the WAN 10 via the WAN-side interface unit 201. The IPv6-IPv4 address storage unit 204 associates the IPv6 address of the mobile phone 100 set as the source of the IPv6 packet with the IPv4 address of the mobile phone 100 included in the IPv6 packet and stores it in the IPv6-IPv4 address conversion table 203. To do. Note that the IPv6-IPv4 address storage unit 204 of the present embodiment does not include a code in the IPv6 packet, so the code of the IPv6-IPv4 address conversion table 203 is set as an empty area.

  Further, the IPv6-IPv4 address storage unit 204 further stores a timer value indicating a holding period of the correspondence relationship between the IPv6 address of the mobile phone 100 and the IPv4 address of the mobile phone 100 in the IPv6-IPv4 address conversion table 203. The IPv6-IPv4 address storage unit 204 decrements the timer value of the IPv6-IPv4 address conversion table 203 every time a clock event occurs, for example. Then, when the holding period indicated by the timer value expires, in other words, when the timer value becomes “0”, the IPv6-IPv4 address storage unit 204 sets the entry corresponding to the timer value to the IPv6-IPv4 address. Delete from the conversion table 203.

  When receiving an IPv6 packet from the WAN 10, the packet transfer unit 212 generates an IPv4 packet based on the IPv6-IPv4 address conversion table 203, and transfers the generated IPv4 packet to the TV 5 of the LAN 20. Note that the packet transfer unit 212 generates IPv4 packets in the same manner as in the first embodiment. Further, when receiving an IPv4 packet from the LAN 10, the packet transfer unit 212 generates an IPv6 packet based on the IPv6-IPv4 address conversion table 203, and transfers the generated IPv6 packet to the mobile phone 100 connected to the WAN 10. To do.

  An example of processing in which the packet transfer unit 212 generates an IPv6 packet will be described. When receiving the IPv4 packet from the LAN 20, the packet transfer unit 212 refers to the IPv6-IPv4 address conversion table 203 and searches for an entry with the same “IPv4 address” as the destination of the IPv4 packet. The packet transfer unit 212 performs the following process when an entry with the same “IPv4 address” as the destination of the IPv4 packet exists. That is, the packet transfer unit 212 generates an IPv6 packet in which the IPv6 address of the corresponding mobile phone 100 of the entry is set as the destination. Note that the packet transfer unit 212 of this embodiment sets the WAN-side IPv6 address held by the IPv6 address processing unit 211 as the source of the IPv6 packet.

  In the mobile phone 100 according to the present embodiment, the packet processing unit 104 receives a 128-bit WAN-side IPv6 address notified from the GW 200 and stores it in the GW information management table 113.

  In addition, when receiving a communication request from the communication request receiving unit 103, the packet processing unit 104 generates an IPv4 packet or an IPv6 packet based on the IPv4 address management table 111, the IPv6 address management table 112, and the GW information management table 113. To do. The process in which the packet processing unit 104 generates an IPv4 packet is the same as in the first embodiment.

  An example of processing in which the packet processing unit 104 generates an IPv6 packet will be described. When receiving the communication request, the packet processing unit 104 generates an IPv4 packet for confirming connectivity, transmits the packet to the GW 200, and waits for a reply from the GW 200. The packet processing unit 104 that has not received a reply from the GW 200 recognizes that the mobile phone 100 is connected to the WAN 10. The packet processing unit 104 refers to the IPv4 address management table 111 and the IPv6 address management table 112, sets the IPv6 prefix of the mobile phone 100 as a transmission source, and generates an IPv6 packet including the IPv4 addresses of the mobile phone 100 and the TV 5 . Further, the packet processing unit 104 sets the WAN side IPv6 address of the GW information management table 113 as the destination of the IPv6 packet. The data structure of the IPv6 packet generated by the packet processing unit 104 will be described later.

  Next, a processing procedure of a series of processes in which the mobile phone 100 of the communication system according to the third embodiment is wirelessly connected to the GW 200 and communicates with the TV 5 of the LAN 10 via the GW 200 will be described. FIG. 23 is a sequence diagram illustrating an example of a processing procedure of a process in which the mobile phone of the communication system according to the third embodiment communicates with the LAN TV via the GW. In the example of FIG. 23, it is assumed that the mobile phone 100 exists in a range that can be connected to the GW 200. In the example of FIG. 23, it is assumed that the IPv6 prefix notified from the IPv6 network 1 of the WAN 10 to the GW 200 is 64 bits.

  As shown in FIG. 23, the mobile phone 100 acquires the IPv4 address of the mobile phone 100 and the IPv4 address of the TV 5 (step S301). The mobile phone 100 stores the acquired IPv4 address of the mobile phone 100 and the IPv4 address of the TV 5 in the IPv4 address management table 111.

  The GW 200 receives the 64-bit IPv6 prefix notified from the IPv6 network 1 of the WAN 10 (step S302). The GW 200 stores the received 64-bit IPv6 prefix in the IPv6 address storage unit 210.

  When connecting to the GW 200, the mobile phone 100 transmits a WAN address request to the GW 200 (step S303).

  When receiving the WAN address request from the mobile phone 100, the GW 200 executes WAN address notification processing (step S304).

  Here, the WAN address notification processing in step S304 will be described. The WAN address notification process in step S304 corresponds to the WAN address notification process shown in FIG. In this embodiment, the IPv6 prefix of the IPv6 address storage unit 210 is 64 bits. For this reason, in the example of FIG. 12, the GW 200 generates a WAN-side IPv6 address and notifies the mobile phone 100 (step S122; Yes, S124).

  Returning to FIG. 23, the mobile phone 100 receives the WAN-side IPv6 address notified from the GW 200 (step S305). The cellular phone 100 executes an IPv4 / IPv6 packet transmission process (step S306).

  Here, the IPv4 / IPv6 packet transmission processing in step S306 will be described. The IPv4 / IPv6 packet transmission process in step S306 corresponds to the IPv4 / IPv6 packet transmission process shown in FIG. In the example of FIG. 23, the mobile phone 100 exists in a range that can be connected to the GW 200. Therefore, the mobile phone 100 generates an IPv4 packet in which the IPv4 address of the TV 5 is set as the destination in the example of FIG. 13 and transmits it to the GW 200 (step S133; Yes, S134, S135).

  Returning to FIG. 23, the GW 200 receives the IPv4 packet transmitted from the mobile phone 100 (step S307). The GW 200 transfers the received IPv4 packet to the TV 5 of the LAN 20 (step S308). The TV 5 receives the IPv4 packet and performs a predetermined process based on the data stored in the IPv4 packet. Thereafter, the TV 5 sets its own IPv4 address as a transmission source, generates an IPv4 packet in which the IPv4 address of the mobile phone 100 is set as a destination, and transmits it to the GW 200 (step S309). The GW 200 receives the IPv4 packet transmitted from the TV 5 and transfers it to the mobile phone 100 (step S310).

  Next, a processing procedure of a series of processes in which the mobile phone 100 of the communication system according to the third embodiment is wirelessly connected to the area network 3 of the WAN 10 and communicates with the TV 5 of the LAN 20 via the WAN 10 and the GW 200 will be described. FIG. 24 is a sequence diagram illustrating an example of a processing procedure of a process in which the mobile phone of the communication system according to the third embodiment communicates with the LAN TV via the WAN and the GW. In the example of FIG. 24, it is assumed that the mobile phone 100 exists in a range that can be connected to the area network 3 of the WAN 10.

  As shown in FIG. 24, the mobile phone 100 receives the IPv6 prefix notified from the area network 3 of the WAN 10 (step S311). The cellular phone 100 executes an IPv4 / IPv6 packet transmission process (step S312).

  Here, the IPv4 / IPv6 packet transmission processing in step S312 will be described. The IPv4 / IPv6 packet transmission process in step S312 corresponds to the IPv4 / IPv6 packet transmission process shown in FIG.

  In the example of FIG. 24, the mobile phone 100 does not exist in a range that can be connected to the GW 200, but exists in a range that can be connected to the area network 3 of the WAN 10. Therefore, in the example of FIG. 13, the mobile phone 100 sets the IPv6 prefix of the mobile phone 100 as a transmission source, and generates an IPv6 packet including the IPv4 addresses of the mobile phone 100 and the TV 5 (step S133; No, S136). . Then, the cellular phone 100 transmits the generated IPv6 packet to the GW 200 via the WAN 10 (step S137). The IPv6 packet generated in step S136 is, for example, as shown in FIG. FIG. 25 is a third diagram illustrating an exemplary data structure of an IPv6 packet.

  The IPv6 packet shown in FIG. 25 has a v6 destination, a v6 transmission source, a v4 destination, a v4 transmission source, and a payload. Among these, the v6 destination is the destination address of the IPv6 packet, and stores the WAN-side IPv6 address of the GW 200 notified from the GW 200 by the mobile phone 100. The v6 source is a source address of the IPv6 packet, and stores the IPv6 prefix of the mobile phone 100 notified from the area network 3 of the WAN 10 by the mobile phone 100. The v4 destination stores the IPv4 address of the TV 5 acquired by the mobile phone 100. The v4 transmission source stores the IPv4 address of the mobile phone 100 acquired by the mobile phone 100. The payload stores data for operating the TV 5.

  A process in which the mobile phone 100 generates an IPv6 packet will be described using the example of FIG. The cellular phone 100 sets the WAN side IPv6 address of the GW 200 included in the GW information management table 113 as the v6 destination of the IPv6 packet. The mobile phone 100 sets the IPv6 prefix of the mobile phone 100 included in the IPv6 address management table 112 as the v6 source of the IPv6 packet. The cellular phone 100 stores the IPv4 address of the cellular phone 100 and the IPv4 address of the TV 5 included in the IPv4 address management table 111 in the v4 transmission source and the v4 destination of the IPv6 packet, respectively. The cellular phone 100 stores data for operating the TV 5 in the payload of the IPv6 packet. Thereby, an IPv6 packet is generated.

  Returning to FIG. 24, the GW 200 receives the IPv6 packet transmitted from the mobile phone 100 via the WAN 10 (step S313). Note that the v6 destination of the IPv6 packet transmitted from the mobile phone 100 does not include a code. The GW 200 executes an IPv4 packet transfer process (step S314).

  Here, the IPv4 packet transfer processing in step S314 will be described. The IPv4 packet transfer process in step S314 corresponds to the IPv4 packet transfer process shown in FIG.

  In the example of FIG. 24, the code is not included in the v6 destination of the IPv6 packet transmitted from the mobile phone 100. For this reason, the GW 200 that has received the IPv6 packet from the WAN 10 determines that the code is not included in the v6 destination of the IPv6 packet in the example of FIG. 16 (steps S151 and S152; No). Then, the GW 200 determines that the v6 destination of the IPv6 packet matches the WAN-side IPv6 address held by the GW 200 (step S153; Yes). After that, the GW 200 associates the v6 transmission source and the v4 transmission source of the IPv6 packet and stores them as a new entry in the IPv6-IPv4 address translation table 203, and further sets the timer value of the new entry (steps S159 to S162). Note that the GW 200 sets the code of the IPv6-IPv4 address conversion table 203 in an empty area because the code is not included in the IPv6 packet. The IPv6-IPv4 address conversion table 203 in which the code is set to an empty area is, for example, as shown in FIG. FIG. 26 is a diagram illustrating another example of the data structure of the IPv6-IPv4 address conversion table. Thereafter, the GW 200 generates an IPv4 packet and transfers it to the TV 5 of the LAN 20 (steps S170 and 171).

  Returning to FIG. 24, the TV 5 receives the IPv4 packet transferred from the GW 200 (step S315). The TV 5 performs a predetermined process based on the data stored in the IPv4 packet. Thereafter, the TV 5 sets its own IPv4 address as the transmission source, generates an IPv4 packet in which the IPv4 address of the mobile phone 100 is set as the destination, and sends it back to the GW 200 (step S316).

  The GW 200 receives the IPv4 packet returned from the TV 5 from the LAN 20, and executes an IPv6 packet transfer process (step S317). The IPv4 packet returned from the TV 5 is an example of a third packet.

  Here, the IPv6 packet transfer processing in step S317 will be described. The IPv6 packet transfer process in step S317 corresponds to the IPv6 packet transfer process shown in FIG.

  In the example of FIG. 24, the IPv4 address of the mobile phone 100 is included in the v4 destination of the IPv4 packet returned from the TV 5. Therefore, the GW 200 that has received the IPv4 packet from the LAN 20 confirms that the destination address of the IPv4 packet is an IPv4 address in the example of FIG. 19 (steps S181 and S182; No). Thereafter, the GW 200 determines that an entry with the same “IPv4 address” as the destination address of the IPv4 packet exists in the IPv6-IPv4 address conversion table 203 (steps S184 and S185; Yes). Then, the GW 200 generates an IPv6 packet in which the corresponding IPv6 address of the entry is set as a destination, and transfers it to the mobile phone 100 (steps S187 and S188). The IPv6 packet generated in step S187 is, for example, as shown in FIG. FIG. 27 is a fourth diagram illustrating an exemplary data structure of an IPv6 packet.

  The IPv6 packet shown in FIG. 27 has a v6 transmission source, a v6 destination, and a payload. Among these, the v6 destination is the destination address of the IPv6 packet, and stores the IPv6 address of the mobile phone 100. The v6 transmission source is the transmission source address of the IPv6 packet, and stores the WAN side IPv6 address of the GW 200. The payload stores predetermined data.

  The process in which the GW 200 generates an IPv6 packet will be described using the example of FIG. The GW 200 refers to the IPv6-IPv4 address conversion table 203 and sets the IPv6 address of the mobile phone 100 corresponding to the same IPv4 address as the destination address of the IPv4 packet as the v6 destination of the IPv6 packet. The GW 200 stores the WAN-side IPv6 address held by the GW 200 in the v6 transmission source of the IPv6 packet. Thereby, an IPv6 packet is generated.

  Returning to FIG. 24, the mobile phone 100 receives the IPv6 packet transferred from the GW 200 (step S318). Note that the mobile phone 100 performs predetermined processing using data included in the IPv6 packet. The GW 200 performs an IPv4-IPv6 address deletion process at a predetermined timing (step S319). Note that the IPv4-IPv6 address deletion process in step S319 corresponds to the IPv4-IPv6 address deletion process shown in FIG.

  Next, effects of the communication system according to the third embodiment will be described. In the communication system of the present embodiment, even when the IPv6 prefix notified from the WAN 10 side to the GW 200 is 64 bits, the correspondence between the port number and the IPv4 address of the transfer destination is pre-registered in the GW 200 as in the first embodiment. This can be eliminated. As a result, communication from the WAN 10 to the LAN 20 can be relayed while suppressing an increase in the memory size of the GW 200.

  In the first to third embodiments, the example in which the mobile phone 100 is connected to the area network 3 of the WAN 10 by radio has been described. However, a situation in which the mobile phone 100 moves in the WAN 10 and is wirelessly connected to another area network different from the area network 3 is also assumed. In such a situation, the IPv6 prefix notified from the area network 3 of the WAN 10 to the mobile phone 100 is changed to the IPv6 prefix notified from the other area network of the WAN 10 to the mobile phone 100. In the fourth embodiment, an example in which the IPv6 prefix notified from the WAN 10 side is changed will be described.

  FIG. 28 is a diagram illustrating the configuration of the communication system according to the fourth embodiment. As shown in FIG. 28, this communication system includes an IPv6 network 1, a carrier network 2, an area network 3, an area network 3a, a home network 4, a TV 5, a mobile phone 100, and a GW 200.

  Among these, the IPv6 network 1, the carrier network 2, and the area network 3 correspond to the IPv6 network 1, the carrier network 2, and the area network 3 shown in FIG. The home network 4, TV 5 and GW 200 correspond to the home network 4, TV 5 and GW 200 shown in FIG. 1, respectively.

  The area network 3a notifies the mobile phone 100 of an IPv6 prefix different from that of the area network 3. The IPv6 network 1, the carrier network 2, the area network 3, and the area network 3a form a WAN 10 that is a kind of external network. The WAN 10 is an example of a first network.

  The cellular phone 100 is wirelessly connected to the area network 3 of the WAN 10 and operates the TV 5 of the LAN 20 via the WAN 10 and the GW 200. Furthermore, the mobile phone 100 can move in the WAN 10 and connect to the area network 3a of the WAN 10 by radio, and operate the TV 5 of the LAN 20 via the WAN 10 and the GW 200. The mobile phone 100 can also be connected to the GW 200 wirelessly and operate the TV 5 of the LAN 20 via the GW 200.

  Next, a processing procedure of a series of processes in which the mobile phone 100 of the communication system according to the fourth embodiment is wirelessly connected to the area networks 3 and 3a of the WAN 10 and communicates with the TV 5 of the LAN 20 via the WAN 10 and the GW 200 will be described. FIG. 29 is a sequence diagram illustrating an example of a processing procedure of processing in which the mobile phone of the communication system according to the fourth embodiment communicates with the LAN TV via the WAN and the GW. In the example of FIG. 29, it is assumed that the mobile phone 100 has moved to a range connectable to the area network 3a of the WAN 10 after being present in a range connectable to the area network 3 of the WAN 10.

  As shown in FIG. 29, the mobile phone 100 receives the IPv6 prefix notified from the area network 3 of the WAN 10 (step S401). In step S401, the IPv6 prefix notified from the area network 3 of the WAN 10 to the mobile phone 100 is denoted as IPv6 prefix P1. The cellular phone 100 executes an IPv4 / IPv6 packet transmission process (step S402).

  Here, the IPv4 / IPv6 packet transmission processing in step S402 will be described. The IPv4 / IPv6 packet transmission process in step S402 corresponds to the IPv4 / IPv6 packet transmission process shown in FIG.

  In the example of FIG. 29, the mobile phone 100 does not exist in a range that can be connected to the GW 200, but exists in a range that can be connected to the area network 3 of the WAN 10. Therefore, in the example of FIG. 13, the mobile phone 100 sets the IPv6 prefix P1 of the mobile phone 100 as a transmission source, and generates an IPv6 packet including the IPv4 addresses of the mobile phone 100 and the TV 5 (step S133; No, S136). ). Then, the cellular phone 100 transmits the generated IPv6 packet to the GW 200 via the WAN 10 (step S137).

  Returning to FIG. 29, the GW 200 receives the IPv6 packet transmitted from the mobile phone 100 via the WAN 10 (step S403). A code is included in the v6 destination of the IPv6 packet transmitted from the mobile phone 100. The GW 200 executes an IPv4 packet transfer process (step S404).

  Here, the IPv4 packet transfer processing in step S404 will be described. The IPv4 packet transfer process in step S404 corresponds to the IPv4 packet transfer process shown in FIG.

  In the example of FIG. 29, the v6 destination of the IPv6 packet transmitted from the mobile phone 100 includes a code. Therefore, the GW 200 that has received the IPv6 packet from the WAN 10 determines that the code is included in the v6 destination of the IPv6 packet in the example of FIG. 16, and determines that the code does not indicate the end of communication (step S151, S152; Yes, S155; Yes). Thereafter, the GW 200 determines that the LAN side MAC address of the IPv6 packet matches the LAN side MAC address of the MAC address storage unit 208, generates an IPv4 packet, and transfers the packet to the TV 5 of the LAN 20 (step S157; Yes, S160 to S171). ).

  Returning to FIG. 29, the TV 5 receives the IPv4 packet transferred from the GW 200 (step S405). The TV 5 performs a predetermined process based on the data stored in the IPv4 packet. Thereafter, the TV 5 sets its own IPv4 address as the transmission source, generates an IPv4 packet in which the IPv4 address of the mobile phone 100 is set as the destination, and sends it back to the GW 200 (step S406).

  The GW 200 receives the IPv4 packet returned from the TV 5 from the LAN 20, and executes an IPv6 packet transfer process (step S407). The IPv4 packet returned from the TV 5 is an example of a third packet.

  Here, the IPv6 packet transfer processing in step S407 will be described. The IPv6 packet transfer process in step S407 corresponds to the IPv6 packet transfer process shown in FIG.

  In the example of FIG. 29, the IPv4 address of the mobile phone 100 is included in the v4 destination of the IPv4 packet returned from the TV 5. Therefore, the GW 200 that has received the IPv4 packet from the LAN 20 confirms that the destination address of the IPv4 packet is an IPv4 address in the example of FIG. 19 (steps S181 and S182; No). Thereafter, the GW 200 determines that an entry with the same “IPv4 address” as the destination address of the IPv4 packet exists in the IPv6-IPv4 address conversion table 203 (steps S184 and S185; Yes). Then, the GW 200 generates an IPv6 packet in which the corresponding IPv6 address of the entry is set as a destination, and transfers it to the mobile phone 100 (steps S187 and S188).

  Returning to FIG. 29, the mobile phone 100 receives the IPv6 packet transferred from the GW 200 (step S408). Note that the mobile phone 100 performs predetermined processing using data included in the IPv6 packet.

  Thereafter, the mobile phone 100 moves to a range that can be connected to the area network 3a of the WAN 10, and receives the IPv6 prefix notified from the area network 3a of the WAN 10 (step S409). In step S409, the IPv6 prefix notified from the area network 3a of the WAN 10 to the mobile phone 100 is denoted as IPv6 prefix P2. The cellular phone 100 executes an IPv4 / IPv6 packet transmission process (step S410).

  Here, the IPv4 / IPv6 packet transmission processing in step S410 will be described. The IPv4 / IPv6 packet transmission process in step S410 corresponds to the IPv4 / IPv6 packet transmission process shown in FIG.

  In the example of FIG. 29, the mobile phone 100 does not exist in a range that can be connected to the GW 200, but exists in a range that can be connected to the area network 3 a of the WAN 10. Therefore, in the example of FIG. 13, the mobile phone 100 sets the IPv6 prefix P2 of the mobile phone 100 as a transmission source, and generates an IPv6 packet including the IPv4 addresses of the mobile phone 100 and the TV 5 (step S133; No, S136). ). At this time, an IPv6 prefix P2 different from the IPv6 prefix P1 is set as the source of the IPv6 packet. Then, the cellular phone 100 transmits the generated IPv6 packet to the GW 200 via the WAN 10 (step S137).

  Returning to FIG. 29, the GW 200 receives the IPv6 packet transmitted from the mobile phone 100 via the WAN 10 (step S411). A code is included in the v6 destination of the IPv6 packet transmitted from the mobile phone 100. The GW 200 executes an IPv4 packet transfer process (step S412).

  Here, the IPv4 packet transfer processing in step S412 will be described. The IPv4 packet transfer process in step S412 corresponds to the IPv4 packet transfer process shown in FIG.

  In the example of FIG. 29, the v6 destination of the IPv6 packet transmitted from the mobile phone 100 includes a code. Therefore, the GW 200 that has received the IPv6 packet from the WAN 10 determines that the code is included in the v6 destination of the IPv6 packet in the example of FIG. 16, and determines that the code does not indicate the end of communication (step S151, S152; Yes, S155; No). Thereafter, the GW 200 determines that the LAN side MAC address of the IPv6 packet matches the LAN side MAC address of the MAC address storage unit 208 (step S157; Yes). The GW 200 refers to the IPv6-IPv4 address conversion table 203 (step S159). The GW 200 determines that there is no entry with the same “IPv6 address” as the v6 source of the IPv6 packet and there is an entry with the same “IPv4 address” as the v4 source of the IPv6 packet (step S160; No, S161). ; Yes). Then, the GW 200 determines that the IPv6 prefix of the mobile phone 100 has been changed, and deletes the same “IPv4 address” entry as the v4 transmission source of the IPv6 packet from the IPv6-IPv4 address conversion table 203 (step S165). Then, the GW 200 associates the v6 transmission source and the v4 transmission source of the IPv6 packet and stores them as a new entry in the IPv6-IPv4 address conversion table 203, and further sets a timer value for the new entry (step S166). Note that the GW 200 further stores the code included in the IPv6 packet in the IPv6-IPv4 address conversion table 203 when the code is included in the IPv6 packet. Thereafter, the GW 200 generates an IPv4 packet and transfers it to the TV 5 of the LAN 20 (steps S170 and S171).

  Returning to FIG. 29, the TV 5 receives the IPv4 packet transferred from the GW 200 (step S413). The TV 5 performs a predetermined process based on the data stored in the IPv4 packet. Thereafter, the TV 5 sets its own IPv4 address as the transmission source, generates an IPv4 packet in which the IPv4 address of the mobile phone 100 is set as the destination, and sends it back to the GW 200 (step S414).

  The GW 200 receives the IPv4 packet returned from the TV 5 from the LAN 20, and executes an IPv6 packet transfer process (step S415). The IPv4 packet returned from the TV 5 is an example of a third packet.

  Here, the IPv6 packet transfer processing in step S415 will be described. The IPv6 packet transfer process in step S415 corresponds to the IPv6 packet transfer process shown in FIG.

  In the example of FIG. 29, the IPv4 address of the mobile phone 100 is included in the v4 destination of the IPv4 packet returned from the TV 5. Therefore, the GW 200 that has received the IPv4 packet from the LAN 20 confirms that the destination address of the IPv4 packet is an IPv4 address in the example of FIG. 19 (steps S181 and S182; No). Thereafter, the GW 200 determines that an entry with the same “IPv4 address” as the destination address of the IPv4 packet exists in the IPv6-IPv4 address conversion table 203 (steps S184 and S185; Yes). Then, the GW 200 generates an IPv6 packet in which the corresponding IPv6 address of the entry is set as a destination, and transfers it to the mobile phone 100 (steps S187 and S188).

  Returning to FIG. 29, the mobile phone 100 receives the IPv6 packet transferred from the GW 200 (step S416). Note that the mobile phone 100 performs predetermined processing using data included in the IPv6 packet. The GW 200 performs an IPv4-IPv6 address deletion process at a predetermined timing (step S417). The IPv4-IPv6 address deletion process in step S417 corresponds to the IPv4-IPv6 address deletion process shown in FIG.

  Next, effects of the communication system according to the fourth embodiment will be described. When the v6 transmission source of the IPv6 packet received from the WAN 10 does not exist in the IPv6-IPv4 address translation table 203 and the v4 transmission source of the IPv6 packet exists, the GW 200 adds an entry in the IPv6-IPv4 address translation table 203. Update. Therefore, in the communication system of the present embodiment, even when the IPv6 prefix notified from the WAN side to the mobile phone 100 is changed and the IPv6 address of the mobile phone 100 stored in the v6 source of the IPv6 packet is changed, The same operation as in the first embodiment can be realized. As a result, communication from the WAN 10 to the LAN 20 can be relayed while suppressing an increase in the memory size of the GW 200.

1 IPv6 network 2 Carrier network 3, 3a Area network 4 Home network 5 TV
10 WAN
20 LAN
DESCRIPTION OF SYMBOLS 100 Cellular phone 101 Memory | storage part 102 IPv4 address acquisition part 103 Communication request reception part 104 Packet processing part 105 Packet transmission part 106 Wireless interface part 111 IPv4 address management table 112 IPv6 address management table 113 GW information management table 200 GW
201 WAN side interface unit 202 LAN side interface unit 203 IPv6-IPv4 address conversion table 204 IPv6-IPv4 address storage unit 205 IPv4 routing table 206 IPv6 routing table 207 Routing management unit 208 MAC address storage unit 209 Code storage unit 210 IPv6 address storage unit 211 IPv6 address processing unit 212 Packet transfer unit

Claims (8)

A communication system in which a relay device relays communication between a mobile terminal connected to a first network and an electronic device connected to a second network,
The portable terminal is
An acquisition unit for acquiring second mobile terminal identification information for identifying the mobile terminal in the second network, and electronic device identification information for identifying the electronic device in the second network;
While setting the first portable terminal identification information for identifying the portable terminal in the first network as a transmission source, the first packet including the second portable terminal identification information and the electronic device identification information, A transmission unit for transmitting to the relay device via a first network,
The relay device is
When the first packet transmitted from the mobile terminal is received, the first mobile terminal identification information set as the transmission source of the first packet and the first packet included in the first packet A storage unit that associates the second mobile terminal identification information with each other and stores it in the conversion table;
The second mobile terminal identification information stored in the conversion table is set as a transmission source, and the second packet in which the electronic device identification information included in the first packet is set as a destination is set as the second packet. A communication system comprising: a transfer unit configured to transfer to the electronic device via a network.   The transfer unit further identifies the second portable terminal set as the destination of the third packet when receiving the third packet returned from the electronic device that has received the second packet. The first portable terminal identification information corresponding to the information is retrieved from the conversion table, and the fourth packet in which the retrieved first portable terminal identification information is set as the destination is transmitted via the first network. The communication system according to claim 1, wherein the communication system is transferred to a mobile terminal.   The storage unit stores retention period information indicating a retention period of a correspondence relationship between the first portable terminal identification information and the second portable terminal identification information, and the first portable terminal identification information and the second portable terminal. The first portable terminal identification information and the second portable terminal corresponding to the holding period information when the holding period indicated by the holding period information has expired, further stored in the conversion table in association with the identification information The communication system according to claim 1 or 2, wherein identification information is deleted from the conversion table. The transmission unit transmits the first packet further including communication end information indicating the end of the communication to the relay device via the first network;
When the communication end information is included in the received first packet, the storage unit includes the first portable terminal identification information and the first portable terminal set as a transmission source of the first packet. The communication system according to any one of claims 1 to 3, wherein the second portable terminal identification information corresponding to the terminal identification information is deleted from the conversion table.   The storage unit does not match the first portable terminal identification information set as the transmission source of the received first packet with the first portable terminal identification information stored in the conversion table; and When the second mobile terminal information included in the first packet matches the first mobile terminal identification information stored in the conversion table, the first mobile terminal stored in the conversion table The communication system according to claim 1, wherein the correspondence relationship between the terminal information and the second mobile terminal identification information is updated. The mobile terminal in a communication system in which a relay device relays communication between a mobile terminal connected to a first network and an electronic device connected to a second network,
An acquisition unit for acquiring second mobile terminal identification information for identifying the mobile terminal in the second network, and electronic device identification information for identifying the electronic device in the second network;
While setting the first portable terminal identification information for identifying the portable terminal in the first network as a transmission source, the first packet including the second portable terminal identification information and the electronic device identification information, A mobile terminal comprising: a transmission unit configured to transmit to the relay device via a first network. The relay device in a communication system in which a relay device relays communication between a mobile terminal connected to a first network and an electronic device connected to a second network,
The first portable terminal identification information for identifying the portable terminal in the first network is set as a transmission source, the second portable terminal identification information for identifying the portable terminal in the second network, and the second The first portable terminal identification information set as the transmission source of the first packet when the first packet including the electronic apparatus identification information for identifying the electronic apparatus in the network is received from the portable terminal A storage unit that associates and stores the second mobile terminal identification information included in the first packet in a conversion table;
The second mobile terminal identification information stored in the conversion table is set as a transmission source, and the second packet in which the electronic device identification information included in the first packet is set as a destination is set as the second packet. A relay device comprising: a transfer unit configured to transfer to the electronic device via a network. A communication control method executed by a communication system in which a relay device relays communication between a mobile terminal connected to a first network and an electronic device connected to a second network,
The mobile terminal acquires second mobile terminal identification information for identifying the mobile terminal in the second network, and electronic device identification information for identifying the electronic device in the second network;
The mobile terminal sets first mobile terminal identification information for identifying the mobile terminal in the first network as a transmission source, and includes the second mobile terminal identification information and the electronic device identification information. Of the packet to the relay device via the first network,
When the relay device receives the first packet transmitted from the mobile terminal, the first mobile terminal identification information set as the transmission source of the first packet and included in the packet The second mobile terminal identification information is associated with and stored in the conversion table,
The second mobile terminal identification information stored in the conversion table is set as a transmission source, and the second packet in which the electronic device identification information included in the packet is set as a destination is sent via the second network. And transferring it to the electronic device.

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