JP4476844B2 - Mobile network communication method and mobile communication control device - Google Patents

Description

  In the case where a mobile network is composed of a plurality of independent sub mobile networks, the present invention continues the communication without interruption when a terminal in the mobile network moves across the sub mobile networks while performing communication. The present invention relates to a communication method for a mobile network that can perform communication and a mobile communication control apparatus that realizes the communication method.

  Conventionally, in a network in which a plurality of sub-networks are connected to each other, the provision of IP mobility has been made possible by "RFC3344," IP Mobility Support. for IPv4 (refer to Non-Patent Document 1, referred to as Mobile IP). IPv6 is defined in “RFC3775,“ Mobility Support in IPv6 ”(refer to Non-Patent Document 2, referred to as Mobile IPv6).

  For example, in the conventional IP mobility network shown in Non-Patent Document 2, there is a communication relay device that supports a mobile terminal called a home agent in a network system that supports the mobile terminal, and each sub-network There is a communication relay device called an access router that notifies the mobile terminal of the current location information and serves as an access point when the mobile terminal performs communication. Then, the mobile terminal registers the current location information with the home agent. The mobile terminal has an identifier (home IP address) that does not depend on the current location, and is managed by the home agent by this identifier.

  Here, the IP frame addressed to the mobile terminal is transferred to the mobile terminal via the home agent until an optimum route is set by the Route Optimization function between the mobile terminal and the communication partner terminal (normal terminal). On the other hand, after the optimum route is set, the IP frame is directly transferred from the communication counterpart terminal (normal terminal) to the mobile terminal. In order to set an optimum route by the Route Optimization function, the mobile terminal notifies the communication partner terminal (normal terminal) of the current position.

  Further, in Non-Patent Document 3, by expanding the above Mobile IPv6, a subnetwork (hereinafter referred to as a mobile network) that is a collection of a plurality of terminals changes a connection point with another network, that is, It allows mobile networks to move between sub-networks.

  For example, in the conventional system for realizing network mobility shown in Non-Patent Document 3, there is a communication relay device called a home agent that supports network mobility in a network system that supports a mobile network. The mobile network is composed of mobile routers and terminals constituting the mobile network, and the mobile router registers the current location information and mobile network information (Network Prefix) with the home agent.

  Here, in the home agent that supports network mobility, a bidirectional tunnel is established between the home agent and the mobile router based on the network prefix of the mobile network. For example, when receiving a packet addressed to a terminal located in the mobile network, the home agent searches only the Network Prefix part of the IPv6 address (here, Network Prefix + ID) indicating the address of the terminal. And tunnel the packet to the current location indicated by the mobile router.

  In the network mobility described above, a terminal in a mobile network can continue communication even when a mobile router moves between sub-networks regardless of the presence or absence of Mobility Support in the terminal.

  In addition, in providing IP mobility, a technique for reducing handover delay during movement of a mobile terminal by exchanging between two nodes providing mobility and establishing a tunnel is disclosed. (For example, refer to Patent Document 1).

JP 2003-209872 A C. Perkins, Ed "IP Mobility Support for IPv4" August 2002, [online], [retrieved on 2005-1-12], retrieved from the Internet: <URL: http://ietf.org/rfc/rfc3344.txt > D. Johnson, C. Perkins, J. Arkko, "Mobility Support in IPv6" June 2004, [online], [retrieved on 2005-1-12], retrieved from the Internet: <URL: http://ietf.org /rfc/rfc3775.txt> Vijay Devarapalli, Ryuji Wakikawa, Alexandru Petrescu, Pascal Thubert, "Network Mobility (NEMO) Basic Support Protocol" January 2005, [online], [retrieved on 2005-1-12], retrieved from the Internet: <URL: http: / /ietf.org/ rfc / rfc3963.txt>

  However, with conventional Mobile IP and Mobile IPv6, mobile terminals need to support Mobile IP and Mobile Ipv6, and terminals that do not support Mobile IP and Mobile Ipv6 can communicate when moving across networks. There was a problem that could not be continued.

  In addition, with Network Mobility (NEMO) Basic Support Protocol, even when a mobile network moves across different sub-networks, all of the mobile network's It is possible to continue communication with other terminals. However, when a terminal in the mobile network moves from the mobile network to another network, there is a problem that the terminal needs to support Mobile IP or Mobile Ipv6.

  In addition, when a terminal in a mobile network communicates with a terminal on another network, it is necessary to communicate via a mobile router. Therefore, when many terminals in a mobile network communicate simultaneously, a single mobile There was a problem that processing was concentrated on the router.

  Further, in the technique (Fast Handover) for reducing the handover delay according to Patent Document 1 described above, a bidirectional tunnel is established between the access routers before and after the movement, which becomes an access point when the mobile terminal performs communication. Thus, communication via the access router after movement is realized based on an instruction from the mobile terminal. However, there is a problem that the mobile terminal needs to support Fast Handover and cannot be used with a conventional terminal. In addition, there is a problem that it is necessary to cope with a technique for realizing Fast Handover in the access router to which the mobile terminal moves.

  The present invention has been made in order to solve the above-described problem, and in a mobile network composed of a plurality of independent sub mobile networks, the terminals in the mobile network do not support IP mobility. The object of the present invention is also to obtain a mobile network communication method capable of continuing communication when moving across sub-mobile networks of a terminal, and a mobile communication control apparatus for realizing the same.

In order to solve the above-described problems and achieve the object, a mobile network communication method according to the present invention includes a plurality of independent sub mobile networks each including a mobile router, and a terminal. a communication method for a mobile network, if the terminal is located on the one of the sub-mobile in the network to change the connection point between the mobile router moves to another sub-mobile network, the terminal, the mobile and transmitting the connection confirmation message to confirm connectivity with the router periodically changed after mobile router the other sub-mobile network after the change of the connection point is provided has received the connection acknowledgment message later, the terminal sub-movement network before the change of the connection point a movement notification to move that that made the change of the connection point to the own device to the own sub-mobile network And performing relative change before mobile router workpiece comprises the post-change mobile router transmits, after receiving the connection confirmation message, a response message to the terminal for the connection confirmation message to set the destination of the own router And after the mobile router before change receives a packet addressed to the terminal transmitted from outside the mobile network via a home agent provided outside the mobile network, to the mobile router after change a step of transferring packets of the addressed terminal, the post-change mobile router, the step of forwarding a packet addressed to the terminal which has been transferred from the pre-change mobile router to the terminal, the terminal, the response message the changed packet of its own mobile network outside addressed based on the set destination of the change after the mobile router to the transfer And transmitting to the router, the after-mobile router, the step of transferring packets of the own mobile network outside destined from the terminal to the pre-change mobile router, wherein the pre-change mobile router, wherein from the terminal Transmitting the packet addressed outside the mobile network to the home agent, and transmitting the packet forwarded from the mobile router before change to the home agent, the home agent transmitting to the outside of the mobile network. It is characterized by.

  According to the present invention, when a terminal located in one sub mobile network changes a connection point with a mobile router across another sub mobile network, the post-change provided in the sub mobile network after changing the connection point The mobile router sends a notification that the terminal has moved to its own sub mobile network to the pre-change mobile router included in the sub mobile network before the connection point change, and the pre-change mobile router sends it from outside the mobile network. After receiving the packet addressed to the terminal, the packet addressed to the terminal is forwarded to the mobile router after change, and the mobile router after change forwards the packet addressed to the terminal transferred from the mobile router before change to the terminal. The terminal sends a packet addressed outside the mobile network to the mobile router after the change, and the mobile router after the change sends the packet from the terminal to the mobile router before the change. Because it is to forward the data is continued without communications during movement across the sub-mobile network of the terminal is interrupted.

  According to the present invention, it is possible to continue communication when a terminal that does not support movement in a mobile network composed of a plurality of independent sub mobile networks moves across the sub mobile networks, and the degree of freedom of the terminals is improved. There is an effect that can be achieved. In addition, since one mobile network can be configured from a plurality of independent sub mobile networks, there is an effect that communication by a larger number of terminals can be executed in one mobile network. Furthermore, since the mobile network is composed of a plurality of independent sub mobile networks, it becomes easy to divide one mobile network into a plurality according to the situation at the time of communication, thereby improving the operability of the mobile network. There is an effect that it is possible.

  DESCRIPTION OF EMBODIMENTS Embodiments of a mobile network communication method and a mobile communication control apparatus that realizes the mobile network according to the present invention will be described below in detail with reference to the drawings. In addition, this invention is not limited by the following description, In the range which does not deviate from the summary of this invention, it can change suitably.

Embodiment 1 FIG.
FIG. 1 is a system configuration diagram showing a system configuration of a mobile network system according to an embodiment of the present invention, and is a system configuration diagram showing a configuration of a mobile network composed of a plurality of independent sub mobile networks. In this mobile network, each sub mobile network achieves the mobility (mobility) of the sub mobile network by “Internet-Draft,“ Network Mobility (NEMO) Basic Support Protocol ”(RFC3963.txt)”. .

  As shown in FIG. 1, the mobile network system includes a backbone IP network 100, sub-networks 201, 202, 203, and 204 connected to each other via the backbone IP network 100, and a mobile network 900. Configured. The sub-network 201 includes an access router (AR) 211. The subnetwork 202 includes an access router (AR) 212. The subnetwork 203 includes a normal terminal 701. The subnetwork 204 includes a home agent 401.

  The mobile network 900 includes an independent sub mobile network 901 and sub mobile network 902, and a terminal 801. The sub mobile network 901 includes a mobile router 311 that is a mobile communication control apparatus that relays between the terminal 801 and another network by connecting to the terminal 801 in the mobile network 900. Similarly, the sub mobile network 902 includes a mobile router 312 that is a mobile communication control device that connects between the terminal 801 and another network by connecting to the terminal 801 in the mobile network 900.

  As shown in FIG. 2, the mobile router 311 and the mobile router 312 include a detection unit 301, a movement notification transmission / reception unit 302, a packet transfer unit 303, and a control unit 304. The detection unit 301 detects a change in the connection point of the terminal 801 to the own device based on the arrival confirmation message transmitted from the terminal 801 in order to confirm the connectivity with the terminal 801.

  When the detection unit 301 detects the terminal 801 that changes the connection point for its own device, the movement notification transmission / reception unit 302 moves to the own sub mobile network and changes the connection point for its own device. Is sent to the mobile router before the connection point is changed. In addition, the movement notification transmission / reception unit 302 sends a movement notification indicating that the terminal 801 has moved to another sub mobile network and has changed the connection point to the mobile router constituting the other sub mobile network. Received from a mobile router (a mobile router after changing the connection point) constituting the sub mobile network (sub mobile network after changing the connection point).

  When the detection unit 301 detects a terminal that changes the connection point in its own device, the packet transfer unit 303 transfers the packet addressed to the terminal 801 transferred from the mobile router before the change of the connection point to the terminal 801. When the detecting unit 301 detects a terminal that changes the connection point in its own device, the packet addressed to another network transmitted from the terminal 801 is transferred to the mobile router before the change of the connection point.

  Further, when receiving the movement notification, the packet transfer unit 303 transfers the packet addressed to the terminal 801 received by the own device to another mobile router based on the movement notification. Further, the packet addressed to the other network transferred from the other mobile router is transferred outside the mobile network based on the movement notification.

  The home agent 401 is a server that supports network mobility, and provides mobility to the mobile networks (here, the sub mobile networks 901 and 902) accommodated by the mobile routers 311 and 312. Here, the mobile routers 311 and 312 have registered with the home agent 401 location information (IPv6 address) created based on information obtained from a network that is currently available or desired to be used. The mobile routers 311 and 312 belong to a single mobile network 900 and receive services from the same home agent 401. In addition, mobile routers (in this case, mobile routers 311 and 312) belonging to a single mobile network 900 exchange information with each other in advance.

  A terminal 801 on the sub mobile network 901 is an IPv6 terminal that does not support IP Mobility. This terminal 801 obtains a valid network prefix (in this case, Net-Prefix 311) in the sub mobile network from the mobile router 311 on the sub mobile network 901, and follows the IPv6 automatic address generation procedure defined in IPv6. Generate a global address. The terminal 801 communicates with the normal terminal 701 located on the subnetwork 203 using the IPv6 global address generated above.

  Here, even when the access router to which the sub mobile network 901 is connected is changed from the access router 211 to another access router (for example, the access router 212), the mobile router 311 uses the sub mobile network 901. Conceal movement. For this reason, even when the access router to which the sub mobile network 901 is connected changes from the access router 211 to another access router (for example, the access router 212), the terminal 801 in the sub mobile network 901 communicates. Can be continued.

  Next, an operation when the terminal 801 on the sub mobile network 901 belonging to the mobile network 900 performs communication with the normal terminal 701 will be described.

  First, a case where the terminal 801 performs communication in the network to which the terminal 801 belongs will be described with reference to FIG. When the terminal 801 communicates with a terminal belonging to another network with the network to which the terminal 801 belongs (here, the sub-mobile network 901), the terminal 801 passes through a router (here, the mobile router 311) on the network to which the terminal 801 belongs. Send and receive packets. The terminal 801 periodically transmits a packet called a Neighbor Solicitation message to the mobile router 311 as a reachability confirmation in order to confirm the connectivity with the mobile router 311 during communication. In response to the Neighbor Solicitation message received for the terminal 801, the mobile router 311 transmits a packet called a Neighbor Advertisement message for setting the destination of the own router to the terminal 801.

  That is, for example, when data transmission (communication) is performed from the terminal 801 to the normal terminal 701, the terminal 801 transmits an IPv6 packet addressed to the normal terminal 701 to the mobile router 311 as shown in FIG. 3 (step S101). The mobile router 311 receives the IPv6 packet transmitted from the terminal 801 and transfers it to the normal terminal 701 via the access router (AR) 211 of the subnetwork 201 (step S102).

  On the other hand, when data transmission (communication) is performed from the normal terminal 701 to the terminal 801, the normal terminal 701 transmits IPv6 addressed to the terminal 801 via the access router (AR) 211 of the subnetwork 201 as shown in FIG. The packet is transmitted to the mobile router 311 (step S103). The mobile router 311 receives the IPv6 packet transmitted from the normal terminal 701 and transfers it to the terminal 801 (step S104).

  Then, the terminal 801 periodically transmits a Neighbor Solicitation message to the mobile router 311 in order to confirm the connectivity with the mobile router 311 during communication (step S105). Then, the mobile router 311 transmits a Neighbor Advertisement message to the terminal 801 as a response to the Neighbor Solicitation message to the terminal 801 (step S106).

  Next, in a situation where the terminal 801 on the sub mobile network 901 belonging to the mobile network 900 is communicating with the normal terminal 701, another sub mobile network belonging to the mobile network 900 (here, the sub mobile network 902). ) Will be described with reference to FIG.

  First, in order to perform data transmission (communication) from the terminal 801 to the normal terminal 701, the terminal 801 transmits an IPv6 packet addressed to the normal terminal 701 to the mobile router 311 (step S201). The mobile router 311 receives the IPv6 packet transmitted from the terminal 801 and transfers it to the home agent 401 via the access router (AR) 211 of the subnetwork 201 (step S202). The home agent 401 receives the IPv6 packet transmitted from the mobile router 311 and forwards it to the normal terminal 701 (step S203). In FIG. 4, the access router (AR) 211 is omitted.

  On the other hand, when data transmission (communication) is performed from the normal terminal 701 to the terminal 801, the normal terminal 701 transmits an IPv6 packet addressed to the terminal 801 to the home agent 401 (step S204). The home agent 401 receives the IPv6 packet transmitted from the normal terminal 701 and transfers it to the mobile router 311 (step S205). The mobile router 311 receives the IPv6 packet transmitted from the home agent 401 and transfers it to the normal terminal 701 (step S206).

  Further, the terminal 801 periodically transmits a Neighbor Solicitation message to the mobile router 311 in order to confirm the connectivity with the mobile router 311 during communication (step S207). Then, the mobile router 311 transmits a Neighbor Advertisement message to the terminal 801 as a response to the Neighbor Solicitation message to the terminal 801 (step S208).

  Next, the terminal 801 moves from the sub mobile network 901 to another sub mobile network (here, the sub mobile network 902) belonging to the same mobile network 900 at a certain time (indicated by an arrow A in FIG. 4). At this time, the terminal 801 moves to the sub mobile network 902, changes the connection point with the mobile router, and changes the mobile router to be connected. When the terminal 801 moves from the sub mobile network 901 to the sub mobile network 902), the mobile router to be connected is changed from the mobile router 311 to the mobile router 312. Therefore, here, the mobile router 311 is a mobile router before the connection point is changed, and the mobile router 312 is a mobile router after the connection point is changed.

  When the terminal 801 moves from the sub-mobile network 901 to the sub-mobile network 902, the mobile router 312 on the sub-mobile network 902 that is the movement destination is Neighbor Solicitation for confirming the reachability of the mobile router existing in the same mobile network. Message is intercepted (step S209). The mobile router 312 then sends a terminal (here, terminal 801) that is the source of the Neighbor Solicitation message to the mobile router (here, mobile router 311) that is the original destination of the intercepted Neighbor Solicitation message. However, it moves to its own network (here, the sub moving network 902) and makes a movement notification that the connection point has been changed (step S210). In addition, the mobile router 312 transmits a Neighbor Advertisement message for setting the destination of the own router to the terminal 801 as a response to the received Neighbor Solicitation message (step S211).

  Here, when data transmission (communication) is performed from the normal terminal 701 to the terminal 801, the normal terminal 701 transmits an IPv6 packet addressed to the terminal 801 to the home agent 401 (step S212). The home agent 401 receives the IPv6 packet transmitted from the normal terminal 701 and transfers it to the mobile router 311 (step S213). When receiving the IPv6 packet addressed to the terminal 801, the mobile router 311 that has received the movement notification indicating that the terminal 801 has moved to the network belonging to the mobile router 312 receives the IPv6 packet addressed to the terminal 801. A tunnel header indicating this is added, and the packet is transferred to the mobile router 312 (step S214).

  When receiving the tunneled IPv6 packet transferred from the mobile router 311, the mobile router 312 removes (detunnels) the tunnel header added to the IPv6 packet and extracts the IPv6 packet. If the destination of the extracted IPv6 packet is the terminal 801 located under its own network, the mobile router 312 transfers the extracted IPv6 packet to the terminal 801 (step S215). Here, whether or not the destination is located under the own network is determined based on a Neighbor Solicitation message that is a reachability confirmation transmitted by the terminal.

  On the other hand, when data transmission (communication) is performed from the terminal 801 to the normal terminal 701, the terminal 801 is notified of the IPv6 packet addressed to the normal terminal 701 by the Neighbor Advertisement message in accordance with the notification of the Neighbor Advertisement message from the mobile router 312. It transmits to the mobile router 312 (step S216). When receiving the IPv6 packet addressed to the normal terminal 701 transmitted from the terminal 801, the mobile router 312 adds a tunnel header to the received IPv6 packet and forwards the packet to the mobile router 311 (step S217).

  When receiving the tunneled IPv6 packet transferred from the mobile router 312, the mobile router 311 removes the tunnel header added to the IPv6 packet (detunneling). Then, the mobile router 311 transfers the extracted IPv6 packet toward the home agent 401 (step S218). The home agent 401 receives the IPv6 packet transmitted from the mobile router 311 and transfers the IPv6 packet to the normal terminal 701 (step S219).

  When the IPv6 terminal 801 moves to the sub mobile network 902, the IPv6 global address automatically generated in the sub mobile network 902 is automatically generated from the mobile router 312 of the sub mobile network 902, and the IPv6 global address is set. It is also possible to newly start communication different from the communication performed before moving.

  As described above, in the network system according to the present embodiment, even when an IPv6 terminal that does not support IP Mobility moves around in one mobile network composed of a plurality of independent sub mobile networks, the IPv6 described above is used. Communication can be continued without changing the configuration of the terminal. In other words, it is possible to continue communication when a terminal that does not support movement in a mobile network composed of a plurality of independent sub mobile networks changes connection points across the sub mobile networks, improving the degree of freedom of the terminals There is an effect that can be achieved.

  In the network system according to the present embodiment, even when a plurality of independent sub mobile networks constituting one mobile network are separated as separate mobile networks, IPv6 terminals belonging to each sub mobile network communicate with each other. It is possible to continue communication regardless of whether or not it connects to a sub-mobile network in which the IPv6 global address used for is valid.

  And since it becomes possible to comprise one mobile network from several independent sub mobile networks, there exists an effect that communication by many terminals can be performed within one mobile network.

  Furthermore, in the network system according to the present embodiment, the mobile network can be easily divided by constructing one mobile network as an independent sub mobile network. Then, by collecting a plurality of sub mobile networks, it becomes easy to construct a larger scale mobile network. In other words, since one mobile network can be configured from a plurality of independent sub mobile networks, there is an effect that communication by a larger number of terminals can be executed in one mobile network. Since the mobile network is composed of a plurality of independent sub-mobile networks, it becomes easy to divide one mobile network into a plurality according to the situation during communication, thereby improving the operability of the mobile network. There is an effect that it is possible.

Embodiment 2. FIG.
In Embodiment 1 described above, a method for realizing continuation of communication when a conventional terminal moves across a sub mobile network by establishing a bidirectional tunnel between mobile routers that construct the sub mobile network However, the mobile router after moving that detects that the terminal has moved to its own sub mobile network may register the location information of the terminal not only with the mobile router before moving but also with the home agent. good. As a result, the home agent expands the function to realize network mobility, and the packet for the registered conventional terminal is forwarded to the mobile router after movement, thereby enabling continuous communication when crossing the sub mobile network. It is also possible to do. Hereinafter, the specific method will be described with reference to FIG.

  In the following, from a situation in which the terminal 801 on the sub mobile network 901 belonging to the mobile network 900 is communicating with the normal terminal 701, another sub mobile network belonging to the mobile network 900 (here, the sub mobile network 902) ) Will be described with reference to FIG.

  First, in order to perform data transmission (communication) from the terminal 801 to the normal terminal 701, the terminal 801 transmits an IPv6 packet addressed to the normal terminal 701 to the mobile router 311 (step S301). The mobile router 311 receives the IPv6 packet transmitted from the terminal 801 and transfers it to the home agent 401 via the access router (AR) 211 of the subnetwork 201 (step S302). The home agent 401 receives the IPv6 packet transmitted from the mobile router 311 and transfers it to the normal terminal 701 (step S303). In FIG. 5, the access router (AR) 211 is omitted.

  On the other hand, when data transmission (communication) is performed from the normal terminal 701 to the terminal 801, the normal terminal 701 transmits an IPv6 packet addressed to the terminal 801 to the home agent 401 (step S304). The home agent 401 receives the IPv6 packet transmitted from the normal terminal 701 and transfers it to the mobile router 311 (step S305). The mobile router 311 receives the IPv6 packet transmitted from the home agent 401 and transfers it to the normal terminal 701 (step S306).

  In addition, during communication, the terminal 801 periodically transmits a Neighbor Solicitation message to the mobile router 311 in order to confirm the connectivity with the mobile router 311 (step S307). Then, the mobile router 311 transmits a Neighbor Advertisement message to the terminal 801 as a response to the Neighbor Solicitation message to the terminal 801 (step S308).

  Next, when the terminal 801 moves from the sub mobile network 901 to another sub mobile network (in this case, the sub mobile network 902) belonging to the same mobile network 900 at a certain time (the time indicated by the arrow B in FIG. 5). The mobile router 312 on the destination sub mobile network 902 intercepts a Neighbor Solicitation message for confirming the reachability of the mobile router existing in the same mobile network (step S309).

  The mobile router 312 sends a terminal (here, the terminal 801) that is the source of the Neighbor Solicitation message to the mobile router (here, the mobile router 311) that is the original destination of the intercepted Neighbor Solicitation message. It moves to its own network (here, the sub-mobile network 902) and makes a movement notification that the connection point has been changed (step S310). Further, the mobile router 312 moves to the effect that the terminal (here, the terminal 801) that is the transmission source of the Neighbor Solicitation message has moved to its own network (here, the sub mobile network 902) and has changed the connection point. The notification is also sent to the home agent, and the home agent 401 is registered as a proxy for the location information of the terminal 801 and temporarily manages the location information of the terminal 801 (step S311).

  In addition, the mobile router 312 transmits a Neighbor Advertisement message for setting the destination of its own router to the terminal 801 as a response to the received Neighbor Solicitation message (step S312).

  Here, when data transmission (communication) is performed from the normal terminal 701 to the terminal 801, the normal terminal 701 transmits an IPv6 packet addressed to the terminal 801 to the home agent 401 (step S313). The home agent 401 receives the IPv6 packet transmitted from the normal terminal 701 and transfers it to the mobile router 312 (step S314).

  When receiving the IPv6 packet transferred from the home agent 401, the mobile router 312 transfers the IPv6 packet to the terminal 801 when the destination of the IPv6 packet is the terminal 801 located under the own network (step 801). S315). Here, whether or not the destination is located under the own network is determined based on a Neighbor Solicitation message that is a reachability confirmation transmitted by the terminal.

  On the other hand, when data transmission (communication) is performed from the terminal 801 to the normal terminal 701, the terminal 801 is notified of the IPv6 packet addressed to the normal terminal 701 by the Neighbor Advertisement message in accordance with the notification of the Neighbor Advertisement message from the mobile router 312. Transmit to the mobile router 312 (step S316). When receiving the IPv6 packet addressed to the normal terminal 701 transmitted from the terminal 801, the mobile router 312 transfers the received IPv6 packet toward the home agent 401 (step S317). The home agent 401 receives the IPv6 packet transmitted from the mobile router 312 and transfers the IPv6 packet to the normal terminal 701 (step S318).

  As described above, in this embodiment in which the mobile router after movement detecting that the terminal has moved to its own sub mobile network has registered information not only with the mobile router before movement but also with the home agent. Also by this method, the same effect as that of the first embodiment described above can be obtained.

  As described above, the mobile network communication method according to the present invention moves between sub mobile networks while a terminal in the mobile network performs communication in a mobile network composed of a plurality of independent sub mobile networks. This is useful when the communication is continuously performed without interruption, and is particularly suitable when the terminal does not support Mobile IP or Mobile Ipv6 or does not support Fast Handover.

It is a system configuration figure showing the system configuration of the mobile network system concerning an embodiment of the invention, and is a system configuration figure showing the composition of the mobile network which consists of a plurality of independent sub mobile networks. It is a block diagram which shows schematic structure of the mobile router concerning this Embodiment. FIG. 3 is a sequence diagram for explaining a communication operation in the network system according to the first exemplary embodiment; FIG. 3 is a sequence diagram for explaining a communication operation in the network system according to the first exemplary embodiment; FIG. 10 is a sequence diagram for explaining a communication operation in the network system according to the second exemplary embodiment;

Explanation of symbols

100 period IP network 201 subnetwork 202 subnetwork 203 subnetwork 204 subnetwork 211 access router (AR)
212 Access router (AR)
311 Mobile Router (MR)
312 Mobile Router (MR)
401 Home Agent (HA)
701 Normal terminal 801 Terminal 900 Mobile network 901 Sub mobile network 902 Sub mobile network

Claims (5)

A mobile network communication method comprising a plurality of independent sub-mobile networks each having a mobile router and a terminal,
When a terminal located in the one sub mobile network moves to another sub mobile network to change the connection point with the mobile router,
The terminal periodically transmits a connection confirmation message for confirming connectivity with the mobile router;
The other changes after mobile router sub mobile network comprises the changed of the connection point, after receiving the connection confirmation message, performing the terminal changes the connection point to the own device to move to its own sub-mobile network To the mobile router before change provided in the sub mobile network before the change of the connection point,
The changed mobile router, after receiving the connection confirmation message, sets a destination of its own router and transmits a response message to the connection confirmation message to the terminal;
The pre-change mobile router receives a packet addressed to the terminal transmitted from outside the mobile network via a home agent provided outside the mobile network, and then transmits the packet addressed to the terminal to the post-change mobile router. Forwarding the packet;
The post-change mobile router forwarding the packet addressed to the terminal transferred from the pre-change mobile router to the terminal;
The terminal transmits a packet addressed to the outside of the mobile network based on the destination of the changed mobile router set in the response message to the changed mobile router;
The post-change mobile router forwards packets addressed to the outside of the mobile network from the terminal to the pre-change mobile router;
The pre-change mobile router sending a packet addressed to the outside of the mobile network from the terminal to the home agent;
The home agent sending the packet forwarded from the pre-change mobile router to a destination outside the mobile network;
A communication method for a mobile network, comprising: Respectively provided in a plurality of independent sub mobile network constituting a mobile network, the home agent is provided between said terminal and other networks outside the mobile network by connecting the terminal in the mobile network A mobile communication control device relaying via
Based on a connection confirmation message transmitted from the terminal to confirm connectivity with the terminal, a detection unit that detects a terminal that has changed the connection point to its own device;
When the detection unit detects a terminal that has changed its connection point to its own device, a movement notification that the terminal has moved to its own sub-mobile network and has changed its connection point is sent to the connection point. A movement notification unit for the mobile communication control device before the change,
When detecting terminal said Tsu make changes at the connection point to the own device in the detection unit, from the own mobile network outside via the home agent to be transferred from the mobile communication control system before the change of the connection point A packet forwarding unit for forwarding the transmitted packet addressed to the terminal to the terminal, and forwarding the packet addressed to the other network transmitted from the terminal to the mobile communication control device before the change of the connection point;
A mobile communication control device comprising: A home agent provided outside the mobile network is provided between each of the plurality of independent sub mobile networks constituting the mobile network and connected to the terminal in the mobile network. A mobile communication control device relaying via
A notification of movement indicating that the terminal has moved to another sub-mobile network in the mobile network and changed the connection point to another mobile communication control device constituting the other sub-mobile network, A receiving unit for receiving from the communication control device;
When the movement notification is received, based on the reception of the movement notification , the packet addressed to the terminal transmitted from the outside of the own mobile network and received by the own device via the home agent is transmitted to the other mobile communication control. A packet forwarding unit that forwards the packet addressed to the other network transmitted from the terminal and forwarded from the other mobile communication control device based on the movement notification to the outside of the mobile network, ,
A mobile communication control device comprising: A mobile network communication method comprising a plurality of independent sub-mobile networks each having a mobile router and a terminal,
When a terminal located in the one sub mobile network moves to another sub mobile network to change the connection point with the mobile router,
The terminal periodically transmits a connection confirmation message for confirming connectivity with the mobile router;
After the change mobile router included in the other sub mobile network after the change of the connection point receives the connection confirmation message, the terminal moves to the own sub mobile network and changes the connection point to the own device. To the mobile router before change provided in the sub mobile network before the change of the connection point,
The post-change mobile router , after receiving the connection confirmation message , performing the movement notification to a home agent provided outside the mobile network and temporarily managing the location information of the terminal;
After receiving the movement notification , the home agent forwards the packet addressed to the terminal to the changed mobile router based on the movement notification after receiving the packet addressed to the terminal from outside the mobile network. Process,
The post-change mobile router forwarding the packet addressed to the terminal forwarded from the home agent to the terminal;
The terminal transmits a packet addressed to the outside of the mobile network based on the destination of the changed mobile router set in the response message to the changed mobile router;
The post-change mobile router forwarding a packet addressed to the outside of the mobile network from the terminal to the home agent ;
Sending the packet forwarded from the modified mobile router to the outside of the mobile network by the home agent;
The method of communication mobile network, characterized by comprising a. Provided in each of a plurality of independent sub mobile networks constituting the mobile network, connected to a terminal in the mobile network, provided outside the mobile network and the mobile network, and temporarily manages location information of the terminal A mobile communication control device that relays between home agents ,
Based on a connection confirmation message transmitted from the terminal to confirm the connectivity with the terminal, a detection unit that detects a terminal that has changed the connection point to its own device;
When the detection unit detects a terminal that has changed its connection point to its own device, a movement notification that the terminal has moved to its own sub-mobile network and has changed its connection point is sent to the connection point. A mobile notification controller before the change and a movement notification unit for the home agent ;
When the detection unit detects a terminal that has changed the connection point to its own device, the packet addressed to the terminal transferred from the home agent to the own device is transferred to the terminal based on the connection confirmation message. in addition, the packet transfer unit that transfers a packet addressed to another network to be transmitted from the terminal to the home agent,
A mobile communication control device comprising:

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