JP5212282B2 - Relay communication system - Google Patents

Description

  The present invention relates to a relay communication system that enables client terminals connected to a LAN (Local Area Network) to communicate with each other over a WAN (Wide Area Network).

  By using a VPN (Virtual Private Network), a client terminal can communicate with a client terminal at a remote location beyond the WAN. However, it is difficult for VPN to build a scalable and flexible network.

  The relay communication system disclosed in Patent Document 1 can construct a network as if a remote LAN is directly connected, like VPN. This relay communication system is more scalable and flexible than a general VPN, such as being able to dynamically change the group relationship between LANs.

JP 2008-129991 A

  In the relay communication system of Patent Literature 1, each relay server enables communication between client terminals by sharing identification information of client terminals connected to each LAN. Specifically, the relay server can relay communication packets between the client terminals by sharing the association information between the identification information of the relay server and the identification information of the client terminal throughout the network.

  It is an object of the present invention to provide a communication method that is excellent in flexibility and expandability in constructing a communication system in which a client terminal communicates via a WAN.

  In order to solve the above-mentioned problem, the invention according to claim 1 is a relay communication system in which a first relay server and a second relay server are connected, and the first relay server is connected to the first relay server side. An acquisition unit that acquires first specifying information for specifying a first routing device that performs routing control of the first LAN based on a network address of the first LAN; and a second LAN on the second relay server side A request unit that requests the second relay server to transmit second specifying information that specifies a second routing device that executes routing control of the second LAN based on a network address of the second LAN, first specifying information, and first 2 based on the specific information, information associating the network address of the first LAN with the first routing device, and the network of the second LAN A routing setting information creating unit that creates routing setting information including information that associates an address with the second routing device, and the second relay server responds to a request from the requesting unit. A response unit that acquires specific information and transmits the specific information to the first relay server, wherein the first relay server and the second relay server include a sharing unit that shares the routing setting information, and the first relay server; A routing session for routing a communication packet between the first LAN and the second LAN via the second relay server is configured based on the routing setting information and the first routing device. A communication session connected to the first LAN, and a routing session establishment unit established between the two routing devices. When a communication packet whose destination address is an IP address belonging to the second LAN is sent from the first routing device, the first routing device routes the communication packet to the second LAN by referring to the routing setting information It is determined that it is possible, and the communication packet is transferred using the routing session.

  The invention according to claim 2 is the relay communication system according to claim 1, wherein the first relay server further searches for a LAN capable of routing control and creates a list of the LAN; And a selection unit that selects the network address of the first LAN and the network address of the second LAN using the list.

  According to a third aspect of the present invention, in the relay communication system according to the first or second aspect, the first routing device is connected to the first relay server, and the second routing server is connected to the second relay server via the first relay server. A client terminal capable of communicating with a relay server, wherein the client terminal shares the routing setting information with the first relay server and the second relay server.

  According to a fourth aspect of the present invention, in the relay communication system according to any one of the first to third aspects, the second routing device is the second relay server.

  In the relay communication system according to the present invention, a routing device establishes a routing session based on routing setting information, and executes routing control of communication packets transmitted from a communication terminal connected to the LAN, using the routing session. To do. The route information is created by specifying a routing device corresponding to the LAN routing and associating the LAN network address with the routing device.

  Thereby, it is possible to simplify the creation of the routing setting information necessary for enabling the routing function of the relay communication system. When the configuration of the relay communication system changes, the routing information can be easily updated, so that the routing function using the relay communication system can be easily managed. In addition, since the relay communication system can search for a LAN that can be routed and specify a LAN to be routed based on the search result, the creation of routing setting information can be further simplified.

It is the schematic of the whole structure of a relay communication system. It is a figure which shows the structure of a relay server. It is a figure which shows the structure of a client terminal. It is a figure which shows the flow of a registration process of a relay server and a client terminal. It is a figure which shows the information produced according to the process of step S9. It is a figure which shows the information produced according to the process of step S10. It is a figure which shows the information produced according to the process of step S12. It is a figure which shows the information produced according to the process of step S13. It is a figure which shows the information produced according to the process of step S14. It is a figure which shows the flow of the process in connection with construction of a relay group. It is a figure which shows the information produced according to the instruction | indication of the construction of a relay group. It is a figure which shows the information produced by the process of step S20. It is a figure which shows the flow of the process in connection with construction of a relay group. It is a figure which shows the information produced by the process of step S24. It is a figure which shows the information produced by the process of step S28. It is a figure which shows the detailed structure of each LAN. It is a figure which shows the flow of a network search process. It is a figure which shows network search information. It is a figure which shows network search information. It is a figure which shows network search information. It is a figure which shows the network search result displayed on the monitor of a client terminal. It is a figure which shows operation | movement of the client terminal instruct | indicated the network search. It is a figure which shows operation | movement of the relay server at the time of network search command reception. It is a figure which shows the flow of a route search process. It is a figure which shows route search information. It is a figure which shows operation | movement of the client terminal instruct | indicated the route search. It is a figure which shows operation | movement of the relay server which received the route search command. It is a figure which shows the flow of a routing start. It is a figure which shows routing group information. It is a figure which shows the flow of routing control of a communication packet.

<1. Overall Configuration of Relay Communication System>
Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a schematic diagram of the overall configuration of a relay communication system. The relay communication system includes LANs 1, 2, and 3 and a WAN (Wide Area Network) 100. The WAN 100 is a wide area network such as the Internet.

  Client terminals 11 and 12 and a relay server 13 are connected to the LAN 1. A client terminal 21 and a relay server 22 are connected to the LAN 2. Client terminals 31 and 32 and a relay server 33 are connected to the LAN 3. A SIP (Session Initiation Protocol) server 101 is connected to the WAN 100.

  The client terminal connected to each of the LANs 1 to 3 is a personal computer or the like. The relay servers 13, 22, and 33 relay communication between client terminals respectively connected to two different LANs. The SIP server 101 relays communication between the relay servers. In this embodiment, each relay server uses SIP when communicating with other relay servers, but a protocol other than SIP may be used.

<2. Configuration of relay server>
FIG. 2 is a block diagram illustrating a configuration of the relay server 13. The relay server 13 includes an interface unit 131, a control unit 132, and a database storage unit 133. The configuration of the relay servers 22 and 33 is the same as that of the relay server 13.

  The interface unit 131 communicates with the client terminals 11 and 12 using a private IP (Internet Protocol) address. The interface unit 131 communicates with the SIP server 101 using a global IP address.

  The control unit 132 manages various databases stored in the database storage unit 133. The database storage unit 133 includes a relay group information storage unit 134, a relay server information storage unit 135, a client terminal information storage unit 136, and a routing group information storage unit 137. The control unit 112 has the same configuration as the control unit 322 of the client terminal 32 described later.

<3. Configuration of client terminal>
FIG. 3 is a diagram illustrating the configuration of the client terminal 32. The client terminal 32 includes an interface unit 321, a control unit 322, an operation unit 323, a monitor 324, and a database storage unit 325. The configuration of the client terminals 11, 21, and 31 is the same as that of the client terminal 32, and the configuration of the client terminal 12 is the same as that of the client terminal 32 except for the routing control function of communication packets.

  The interface unit 321 communicates with the relay server 33 using a private IP address.

  The control unit 322 includes a LAN driver 391, a LAN side IP packet processing unit 392, a WAN side IP packet processing unit 393, a routing control unit 394, a routing session processing unit 395, and a routing session unit 396.

  The LAN driver 391 is driver software that controls the interface unit 321. The LAN side IP packet processing unit 392 processes the communication packet received from the client terminal 31 or the like and outputs it to the routing control unit 394. The routing control unit 394 determines the routing destination of the communication packet based on the information stored in the database storage unit 325. The routing session processing unit 395 determines a routing session to relay the communication packet based on the information stored in the database storage unit 325, and outputs the routing session to the routing session X unit 396. The routing session X is a media session established with a specific relay server or client terminal. The routing session X unit 396 outputs the communication packet to the WAN side IP packet processing unit 393. The WAN-side IP packet processing unit 393 transmits and receives communication packets via the routing session X.

  The operation unit 323 is a keyboard, a mouse, and the like, and receives an instruction for the client terminal 32. The monitor 324 is a liquid crystal display or the like.

  The database storage unit 325 includes a relay group information storage unit 327, a relay server information storage unit 328, and a routing group information storage unit 329.

  Hereinafter, the processing flow of the relay communication system shown in FIG. 1 will be described in the order of relay group construction and routing processing.

<4. Build Relay Group>
FIG. 4 is a diagram illustrating a flow of processing for registering a relay server and a client terminal that participate in a relay group. Each administrator of the relay servers 13, 22, and 33 has decided to construct a group of relay communication systems between the LANs 1, 2, and 3.

<4.1. Registration of relay server and client terminal>
First, the administrator of the relay server 13 registers the identification information and global IP address of the relay server 13 in the SIP server 101 (step S1). Similarly, each administrator of the relay servers 22 and 33 registers the identification information and global IP address of the relay servers 22 and 33 in the SIP server 101 (steps S2 and S3).

  The SIP server 101 manages the identification information of each relay server in association with the global IP address. As a result, the SIP server 101 can relay communication between relay servers using the global IP address of each relay server.

  Next, an account for each client terminal is created (steps S4 to S8). Specifically, the administrator of the relay server 13 creates an account for the user of the client terminal 11 (step S4), and creates an account for the user of the client terminal 12 (step S5). The relay server 13 creates relay server information 51-1 indicating details of the relay server 13 and client terminal information 61 indicating details of the client terminals 11 and 12. The relay server information 51-1 and the client terminal information 61 are stored in the relay server information storage unit 135 and the client terminal information storage unit 136, respectively.

  Similarly, the administrator of the relay server 22 creates an account for the user of the client terminal 21 (step S6). The relay server 22 creates relay server information 51-2 indicating details of the relay server 22 and client terminal information 71 indicating details of the client terminal 21.

  The administrator of the relay server 33 creates an account for the user of the client terminal 31 (step S7), and creates an account for the user of the client terminal 32 (step S8). The relay server 33 creates relay server information 51-3 indicating details of the relay server 33 and client terminal information 81 indicating details of the client terminals 31 and 32.

<4.2. Logon processing of client terminal>
After the client terminal user account is created, each client terminal logs on to the relay server (steps S9 to S15). The order in which each client terminal logs on may not be the order described below.

  First, logon (steps S9 to S11) of the client terminals 11 and 12 will be described. The user of the client terminal 11 inputs the identification information and password of the client terminal 11 and logs on to the relay server 13 (step S9). In response to logon of the client terminal 11, the relay server information 51-1 and the client terminal information 61 are updated. The client terminal 11 receives the relay server information 51-1 as a response to log on to the relay server 13.

  FIG. 5 is a diagram showing information held by the relay server 13 after the process shown in step S9. The relay server information 51-1 includes upper information 511-1 related to the relay server 13 and lower information 512-1 related to the client terminals 11 and 12.

  In the upper information 511-1, “id” and “name” indicate the identification information and name of the relay server information 13. In “id”, identification information “relay-server-1@abc.net” of the relay server 13 is set. In the activation information 513-1, “active” indicating that the relay server 13 is being activated is set.

  In the lower information 512-1, two node tags corresponding to the client terminals 11 and 12 are created. In each node tag, “div”, “id”, and “name” indicate the installation unit signature, identification information, and name of the client terminal. These pieces of information are set when the client terminal information 61 is created. “Group” indicates a relay group in which the client terminal participates. The site information 514-1 indicates identification information of the relay server that is the logon destination of the client terminal.

  “Group” of each node tag of the lower information 512-1 is blank because a relay group has not been constructed at this time. The upper node tag of the lower information 512-1 corresponds to the client terminal 11, and the identification information “client-11@relay-server-1.abc.net” of the client terminal 11 is set as “id”. In the site information 514-1, the identification information of the relay server 13 is set as the client terminal 11 logs on.

  The lower node tag of the lower information 512-1 corresponds to the client terminal 12, and identification information “client-12@relay-server-1.abc.net” of the client terminal 12 is set as “id”. . The site information 514-1 is blank because the client terminal 12 is not logged on.

  In the client terminal information 61, two node tags corresponding to the client terminals 11 and 12 are created. In each node tag of the client terminal information 61, “div”, “id”, “name”, and “pass” indicate the installation unit signature, identification information, name, and password of the client terminal. These pieces of information are set when the client terminal information 61 is created. “Group” indicates a relay group in which the client terminal participates. Address information 611, expiration date information 612, and port information 613 indicate the IP address, registration expiration date, and port number of the client terminal, and are set when each client terminal logs on.

  In the client terminal information 61, “group” of each node tag is blank because no relay group has been established. The node tag on the upper side of the client terminal information 61 corresponds to the client terminal 11, and the identification information of the client terminal 11 is set as “id”. When the client terminal 11 logs on (step S9), “192.168.1.11”, “1213”, and “5070” are set in the address information 611, the expiration date information 612, and the port information 613, respectively. The

  The node tag below the client terminal information 61 corresponds to the client terminal 12, and the identification information of the client terminal 12 is set as “id”. Since the client terminal 12 is not logged on to the relay server 13 at the time of step S9, the address information 611 is blank. Further, “0” is set in the expiration date information 612 and the port information 613.

  After the logon of the client terminal 11 (step S9), the user of the client terminal 12 inputs the identification information and password of the client terminal 12 and logs on to the relay server 13 (step S10).

  The relay server 13 updates the relay server information 51-1 and the client terminal information 61 to the relay server information 52-1 and the client terminal information 62, respectively, as the client terminal 12 logs on. The client terminal 12 receives the relay server information 52-1 as a response to logon to the relay server 13.

  FIG. 6 is a diagram showing information held by the relay server 13 after the process shown in step S10. The update part accompanying the logon of the client terminal 12 is underlined.

  When the client terminal 12 logs on, the identification information of the relay server 13 is set in the site information 524-1 of the lower node tag of the lower information 522-1. In the node tag below the client terminal information 62, “192.168.2.22”, “1213”, and “5070” are set in the address information 621, the expiration date information 622, and the site information 623, respectively. .

  After logging on the client terminal 12, the relay server 13 transmits the relay server information 52-1 to the client terminal 11 (step S11). Thereby, the relay server information 51-1 held by the client terminal 11 is updated to the relay server information 52-1.

  Next, the logon (step S12) of the client terminal 21 will be described. The user of the client terminal 21 inputs the identification information and password of the client terminal 21 and logs on to the relay server 22 (step S12). The relay server 22 updates the relay server information 51-2 and the client terminal information 71 as the client terminal 21 logs on. The client terminal 21 receives the relay server information 51-2 as a response to logon to the relay server 22.

  FIG. 7 is a diagram illustrating information held by the relay server 22 after the process of step S12. The relay server information 51-2 includes upper information 511-2 and lower information 512-2. Identification information “relay-server-2@abc.net” of the relay server 22 is registered in “id” of the upper information 511-2. In the activation information 513-2, “active” indicating that the relay server 22 is being activated is set.

  The “group” of each node tag of the lower information 512-2 and the client terminal information 71 is blank because no relay group is constructed.

  Information related to the client terminal 21 is registered in the node tag of the lower information 512-2. In “id”, the identification information “client-21@relay-server-2.abc.net” of the client terminal 21 is registered. As the client terminal 21 logs on, the identification information of the relay server 22 is set in the site information 514-2.

  In the client terminal information 71, the node tag corresponds to the client terminal 21, and the identification information of the client terminal 21 is set as “id”. As the client terminal 21 logs on, “172.16.1.21,” “1213,” and “5070” are registered in the address information 711, the expiration date information 712, and the port information 713, respectively.

  Next, the logon process (steps S13 to S15) of the client terminals 31 and 32 will be described. The user of the client terminal 31 inputs the identification information and password of the client terminal 31, and logs on to the relay server 33 (step S13). In response to logon of the client terminal 31, the relay server information 51-3 and the client terminal information 81 are updated. The client terminal 31 receives the relay server information 51-3 as a response of step S13 and stores it in the relay server information storage unit 318.

  FIG. 8 is a diagram illustrating information held by the relay server 33 after the process of step S13. The relay server information 51-3 includes upper information 511-3 and lower information 512-3. In the upper information 511-3, the identification information “relay-server-3@abc.net” of the relay server 33 is registered as “id”. In the activation information 513-3, “active” indicating that the relay server 33 is being activated is set.

  The “group” of each node tag of the lower information 512-3 and the client terminal information 81 is blank because no relay group is constructed.

  The node tag on the upper side of the lower information 512-3 corresponds to the client terminal 31, and the identification information “client-31@relay-server-3.abc.net” of the client terminal 31 is set as “id”. As the site information 514-3, the identification information of the relay server 33 is set when the client terminal 31 logs on.

  The lower node tag of the lower information 512-3 corresponds to the client terminal 32, and identification information “client-32@relay-server-3.abc.net” of the client terminal 32 is set as “id”. . The site information 514-3 is blank because the client terminal 32 is not logged on.

  The node tag on the upper side of the client terminal information 81 corresponds to the client terminal 31, and the identification information of the client terminal 31 is set in “id”. As the client terminal 31 logs on, “200.1.2.31”, “1213”, and “5070” are set in the address information 811, the expiration date information 812, and the port information 813, respectively.

  The node tag below the client terminal information 81 corresponds to the client terminal 32, and the identification information of the client terminal 32 is set as “id”. Since the client terminal 32 is not logged on, the address information 811 is blank. Also, “0” is set in the expiration date information 812 and the port information 813.

  After logging on the client terminal 31 (step S13), the user of the client terminal 32 inputs the identification information and password of the client terminal 32 and logs on to the relay server 33 (step S14).

  As the client terminal 32 logs on, the relay server 33 updates the relay server information 51-3 and the client terminal information 81 to the relay server information 52-3 and the client terminal information 82, respectively. The client terminal 32 receives the relay server information 52-3 as a response in step S14.

  FIG. 9 is a diagram illustrating information held by the relay server 33 after the process of step S14. The update location associated with the logon of the client terminal 32 is underlined.

  The identification information of the relay server 33 is set in the site information 524-3 of the lower node tag of the lower information 522-3. In the node tag below the client terminal information 82, “200.1.3.132”, “1213”, and “5070” are set in the address information 821, the expiration date information 822, and the site information 823, respectively. Is done.

  After logging on the client terminal 32, the relay server 33 transmits the relay server information 52-3 to the client terminal 31 (step S15). The client terminal 31 updates the relay server information 51-3 stored in the relay server information storage unit 318 to the relay server information 52-3.

<4.3. Creating relay group information>
FIG. 10 is a diagram showing a flow of processing relating to the construction of the relay group. In FIG. 10, the display of the client terminals 21 and 33 is omitted.

  After the processing shown in step S15, the administrator of the relay server 13 inputs the identification information of the relay servers 13, 22, and 33, and instructs the relay server 13 to construct a relay group. The relay server 13 newly creates the relay group information 41 and stores it in the relay group information storage unit 134.

  FIG. 11 is a diagram illustrating information held by the relay server 13 after an instruction to construct a relay group is given. The relay server information 52-1 and the client terminal information 62 are not changed from FIG.

  The relay group information 41 includes upper information 411 related to the relay group and lower information 412 related to the relay server participating in the relay group. In the upper information 411, relay group identification information “group-a@relay-server-1.abc.net” is set in “id”. “Lastmod” and “name” indicate the last update time of the relay group information 41 and the name of the relay group. In addition, identification information of the relay servers 13, 22, and 33 is set in each site tag of the lower information 412.

  The relay server 13 requests the relay server 22 to construct a relay group in which the relay servers 13, 22, and 33 participate via the SIP server 101 (steps S16 and S16.1). Similarly, the relay server 13 requests the relay server 33 to construct a relay group via the SIP server 101 (steps S17 and S17.1). When a relay group construction request is made, relay group information 41 is transmitted to the relay servers 22 and 33.

<4.4. Composition of relay server information>
Next, the relay server 13 requests the relay server 22 to transmit the relay server information 51-2 via the SIP server 101 (steps S18 and S18.1), and transmits the relay server information 52-3 to the relay server. 33 (steps S19 and S19.1). The relay server 13 combines the relay server information 52-1, 51-2, and 52-3 to create the relay server information 53. The client terminal information 62 is updated to the client terminal information 63. The relay server information storage unit 135 stores relay server information 52-1 and 53.

  FIG. 12 is a diagram illustrating information held by the relay server 13 after the process of step S19. The update location associated with the process shown in step S18 is underlined.

  In the relay server information 53, the upper information 531-1 and the lower information 532-1 correspond to the upper information 521-1 and the lower information 522-1 shown in FIG. Similarly, the upper information 531-2 and the lower information 532-2 correspond to the upper information 511-2 and the lower information 512-2 shown in FIG. The upper information 531-3 and the lower information 532-3 correspond to the upper information 521-3 and the lower information 522-3 shown in FIG.

  Accompanying the construction of the relay group, the relay group identification is made into “group” of each node tag of the lower information 532-1, 532-2, and 532-3 and “group” of each node tag of the client terminal information 63. Information is set.

  The relay server 13 refers to the client terminal information 63 and confirms that the client terminals 11 and 12 are logged on. The relay group information 41 and the relay server information 53 are transmitted to the client terminals 11 and 12 (steps S20 and S21).

  FIG. 13 is a diagram showing a flow of processing after step S22 in the construction of the relay group. In FIG. 13, the display of the client terminals 11 and 12 is omitted.

  The relay server 22 requests the relay server 13 to transmit the relay server information 52-1 via the SIP server 101 (steps S22 and S22.1), and requests the relay server 33 to transmit the relay server information 52-3. (Steps S23, S23.1). The relay server 22 combines the relay server information 52-1, 51-2, and 52-3 to create the relay server information 53. The client terminal information 71 is updated to the client terminal information 72. The relay server 22 continues to hold the relay server information 51-2.

  FIG. 14 is a diagram showing information held by the relay server 22 after the processing shown in step S23. The change part accompanying the process shown in step S23 is underlined. The relay group identification information is newly set in “group” of the client terminal information 72.

  The relay server 22 refers to the client terminal information 72 and confirms that the client terminal 21 is logged on. Relay group information 41 and relay server information 53 are transmitted to the client terminal 21 (step 24).

  Next, the relay server 33 requests the relay server 13 to transmit the relay server information 52-1 via the SIP server 101 (steps S25 and S25.1), and transmits the relay server information 51-2 to the relay server. 22 (steps S26 and S26.1). The relay server 33 combines the relay server information 52-1, 51-2, and 52-3 to create the relay server information 53. The client terminal information 82 is updated to the client terminal information 83.

  FIG. 15 is a diagram showing information held by the relay server 33 after the processing shown in step S26. The change part accompanying the process of step S26 is underlined. The relay group identification information is newly set in “group” of each node tag of the client terminal information 83.

  The relay server 33 refers to the client terminal information 83 and confirms that the client terminals 31 and 32 are logged on. Relay group information 41 and relay server information 53 are transmitted to client terminals 31 and 32, respectively (steps S27 and S28).

  By the processing so far, a relay group in which the client terminals 11, 12, 21, 31, and 32 and the relay servers 13, 22, and 33 participate is constructed. Computers participating in the relay group can refer to the relay group information 41 and the relay server information 53 to check the configuration of the relay group or the operating state of each computer.

<5. Routing process flow>
A flow of routing processing using the relay communication system shown in FIG. 1 will be described.

<5.1. Detailed configuration of LAN>
FIG. 16 is a diagram illustrating a detailed configuration of the LANs 1 to 3. In FIG. 16, the display of the SIP server 101 is omitted. LANs 1 to 3 are connected to general terminals that are personal computers that do not function as client terminals.

  The LAN 1 has a configuration in which a LAN 10-1 and a LAN 10-2 are connected via a general-purpose router 14. A client terminal 11, a relay server 13, and a general terminal 15 are connected to the LAN 10-1. A client terminal 12 and a general terminal 16 are connected to the LAN 10-2. The network addresses of the LANs 10-1 and 10-2 are “192.168.1.0/24” and “192.168.2.0/24” (the last 24 is a subnet mask).

  Similar to FIG. 1, a general terminal 23 is connected to the LAN 2 in addition to the client terminal 21 and the relay server 22. The network address of LAN2 is “192.168.1.0/24”.

  The LAN 3 has a configuration in which a LAN 30-1 and a LAN 30-2 are connected via a general-purpose router 34 and a LAN 30-1 and a LAN 30-3 are connected via a general-purpose router 35. A relay server 33 is connected to the LAN 30-1. A client terminal 31 and a general terminal 36 are connected to the LAN 30-2, and a client terminal 32 and a general terminal 37 are connected to the LAN 30-3. The network addresses of the LANs 30-2 and 30-3 are “200.1.2.0/24” and “200.1.3.0/24”.

<5.2. Network search processing flow>
FIG. 17 is a diagram showing a flow of search processing for a network capable of routing using the relay communication system. The user of the client terminal 11 inputs a search instruction for a network that can be routed using the relay communication system (step S31). Thereby, the client terminal 11 transmits a network search command to the relay server 13 (step S32).

  By referring to the relay group information 41, the relay server 13 identifies the relay servers 22 and 33 constituting the relay group as the transfer destination of the network search command. First, the relay server 13 transmits a network search command to the relay server 22 via the SIP server 101 (steps S33 and S33.1). The relay server 22 refers to the client terminal information 71 and transmits a network search command to the logged-on client terminal 21 (step S33.1.1).

  Since the client terminal 21 has a routing function and can route the LAN 2, the client terminal 21 transmits the network address of the LAN 2 to the relay server 22. The relay server 22 creates network search information 91 based on the response from the client terminal 21 and transmits it to the relay server 13 as a response to the network search command.

  FIG. 18 is a diagram showing the network search information 91. In the network search information 91, the main body information 911 is information related to the network search information 91 itself. In “name”, “IP routing map” indicating a response to the network search command is set, and in “owner”, identification information of the relay server 22 is set as a creation source of the network search information 91.

  The network search list information 912 is a list of responses from relay servers and client terminals having a routing function. In the routing device response information 912-1, the network address of the LAN 2 as a routable network is set in “addr”, and the identification information of the client terminal 21 is set in “router”. In the routing device response information 912-2, the network address of the LAN 2 and the identification information of the relay server 22 are set. This is because the relay server 22 can function as a LAN2 routing device.

  Next, the relay server 13 transmits a network search command to the relay server 33 via the SIP server 101 (steps S34 and S34.1). The relay server 33 transfers the network search command to the client terminals 31 and 32 (steps S34.1.1 and S34.1.2). The client terminals 31 and 32 having the routing function transmit the network addresses of the routable LANs 30-2 and 30-3 to the relay server 33, respectively. The relay server 33 creates network search information 92 based on the responses from the client terminals 31 and 32 and transmits it to the relay server 13.

  FIG. 19 is a diagram showing the network search information 92. Identification information of the relay server 33 is set in “owner” of the main body information 921. In the routing apparatus response information 922-1 of the network search list information 922, the network address of the LAN 30-2 and the identification information of the client terminal 31 are set. In the routing device response information 922-2, the network address of the LAN 30-3 and the identification information of the client terminal 32 are set. The relay server 33 that does not have a routing function is not registered in the network search information 92.

  Reference is again made to FIG. The relay server 13 transmits a network search command to the client terminal 12 (step S35). Since the client terminal 12 does not have a routing function, it does not transmit a routable LAN network address as a response to the network search command.

  The relay server 13 creates network search information 93 by combining the received network search information 91 and 92. Network search information 93 is transmitted to the client terminal 11 as a response to the network search command.

  Since the client terminal 11 has a routing function and can route the LAN 10-2, it updates the network search information 93 to the network search information 94. Then, the client terminal 11 displays the network search result on the monitor based on the network search information 94 (step S36).

  FIG. 20 is a diagram showing the network search information 94. Identification information of the client terminal 11 is set in “owner” of the main body information 941. The network search list information 942 is a list of LAN network addresses that can be routed in the relay communication system.

  The routing device response information 932-1 is information added when the network search information 91 and 92 are combined to create the network search information 93. In the routing device response information 932-1, the network address of the LAN 10-1 that can be routed by the relay server 13 and the identification information of the relay server 13 are set.

  The routing device response information 942-1 is added when the network search information 93 is updated to the network search information 94. In the routing device response information 942-1, the network address of the LAN 10-2 to which the client terminal 11 can route and the identification information of the client terminal 11 are set.

  FIG. 21 is a list of LANs displayed as a result of network search on the monitor of the client terminal 11 based on the network search information 94. As shown in FIG. 21, a network address of a routable LAN and a relay server or client terminal capable of routing control of each LAN are displayed in association with each other. The user of the client terminal 11 can confirm the LAN that can be routed in the relay communication system with reference to the list shown in FIG.

  In the network search process, it is only necessary to search for a network that can use the routing function of the relay communication system. Therefore, it is not necessary to set the identification information of the client terminal or the relay server in each routing device response information.

  FIG. 22 is a flowchart showing the operation of the client terminal 11 that executes network search. The process shown in FIG. 22 corresponds to steps S31 and S32 (see FIG. 17). When a network search is instructed (Yes in step S101), the client terminal 11 transmits a network search command to the logon destination relay server 13 based on the relay server information 53 (step S102). When the client terminal 11 receives the network search information 93 as a response to the network search command (Yes in step S103), the client terminal 11 updates the network search information 93 to the network search information 94. Then, the list shown in FIG. 21 is displayed on the monitor of the client terminal 11 based on the network search information 94 (step S104).

  FIG. 23 is a flowchart showing the operation of the relay server 13 that has received the network search command. When receiving the network search command from the client terminal 11 (Yes in Step S151), the relay server 13 reads the relay group information 41 (Step S152). When the network search command has not been transmitted to all the relay servers registered in the relay group information 41 (No in step S153), the network search command is transmitted to the relay server identified from the relay group information 41 (step S154). ). This processing corresponds to processing (see FIG. 17) such as steps S33 and S33.1. When the network search command response is received (Yes in step S155), the relay server 13 updates the network search information based on the received response (step S156), and returns to step S153.

  When the network search command is transmitted to all the relay servers (Yes in Step S153), the relay server 13 reads the client terminal information 63 (Step S157). When the network search command has not been transmitted to all the client terminals that are logged on (No in step S158), the relay server 13 identifies the client terminal that is logged on from the client terminal information 63. A network search command is transmitted from the relay server 13 to the identified client terminal (step S159). This process corresponds to the process of step S35 (see FIG. 17). When the response to the network search command is received (Yes in step S160), the relay server 13 updates the network search information based on the received response (step S161), and returns to step S158.

  When the network search command is transmitted to all client terminals that are logged on (Yes in step S158), the relay server 13 transmits the network search information to the client terminal 11 that is the transmission source of the network search command (step S162). . Thereby, the processing of the relay server 13 that has received the network search command ends.

<5.3. Flow of route search processing>
FIG. 24 is a diagram showing the flow of route search processing. The user of the client terminal 11 refers to the network search information 94 and instructs a route search of the LANs 10-1 and 30-3 as a target of routing control (step S37). The route search command is a command for instructing a search for a routing route for routing the LAN designated by the user. The client terminal 11 transmits a route search command in which the network addresses of the LANs 10-1 and 30-3 are set to the log-on destination relay server 13 (step S38).

  The relay server 13 newly creates response information for the route search command in response to receiving the route search command. The relay server 13 transmits a route search command to the relay servers 22 and 33 based on the relay group information 41, similarly to the transfer of the network search command. First, a route search command is transmitted from the relay server 13 to the client terminal 21 via the SIP server 101 and the relay server 22 (steps S39, S39.1, and S39.1.1). The client terminal 21 and the relay server 22 cannot cope with the routing of the LANs 10-1 and 30-3. For this reason, the client terminal 21 notifies the relay server 22 that routing is not possible (NO ROUTE), and the relay server 22 notifies the relay server 13 that routing is not possible.

  Next, a route search command is transmitted from the relay server 13 to the client terminals 31 and 32 via the SIP server 101 and the relay server 33 (steps S40, S40.1, S40.1.1 and S40.1). .2).

  Since the client terminal 31 cannot cope with the routing of the LANs 10-1 and 30-3, the client terminal 31 notifies that routing is impossible. The client terminal 32 is connected to the LAN 30-3 and has a routing function. For this reason, the client terminal 32 transmits its own terminal identification information and the network address of the LAN 30-3 to the relay server 33 to notify that routing is possible. Further, the relay server 33 does not support the routing function. As a result, the relay server 33 creates specific information for specifying the client terminal 32 that can operate as a routing point of the LAN 30-3, and transmits the specific information to the relay server 13. In the specific information, the identification information of the client terminal 32 is associated with the network address of the LAN 30-3. The relay server 13 adds the specific information to the response information 95 of the route search command.

  Next, the relay server 13 transmits a route search command to the client terminal 12 (step S41). Since the client terminal 12 does not support the routing function, the client terminal 12 notifies that routing is not possible.

  The relay server 13 has a routing function and can route the LAN 10-1. Therefore, the relay server 13 adds specific information in which the identification information of the relay server 13 is associated with the network address of the LAN 10-1 to the response information of the route search command. Then, response information of the route search command is transmitted from the relay server 13 to the client terminal 11. The client terminal 11 displays the route search information 95 created based on the response information of the route search command as a route search result (step S42).

  FIG. 25 is a diagram showing the route search information 95. In the body information 951, “name” is set with the name “IP routing group 1” given by the user at the time of the route search instruction, and “owner” is set with the identification information of the client terminal 11. .

  The routing target information 952 is route information used for routing control of the LANs 10-1 and 30-3. Network information 952-1 and 952-2 correspond to the specific information described above. The network information 952-1 indicates that the relay server 13 executes the routing control of the LAN 10-1, since the network address of the LAN 10-1 is set and the identification information of the relay server 13 is set. Similarly, the network information 952-2 indicates that the client terminal 32 executes the routing control of the LAN 30-3.

  The network search list information included in the network search information 91 to 94 has the same configuration as the routing target information 952. As described above, the routing target information 952 indicates that the routing control of the LANs 10-1 and 30-3 is performed by the relay server 13 and the client terminal 32. However, the network search list information is a list of LANs that can be routed. Therefore, there is no relationship between the routing target information 952 and the network search list information 912.

  As described above, the user of the client terminal 11 can acquire the route search information 95 by instructing the route search by specifying the network address to be subject to the routing control. For this reason, when the routing function of the relay communication system is validated, there is no need to confirm a relay server, a client terminal, or the like having the routing function.

  FIG. 26 is a flowchart showing the operation of the client terminal 11 instructed to search for a route. When a route search is instructed (Yes in step S201), the client terminal 11 confirms with the user whether or not to specify a network address to be a route search target (step S202). When designating a network address (Yes in step S202), the user of the client terminal 11 inputs the network address (step S203). When the start of route search is instructed (Yes in step S204), the client terminal 11 creates a route search command in which the input network address is set (step S205). When the network address is further designated (Yes in step S206), the client terminal 11 adds the designated network address to the argument of the route search command (step S207). If no network address is added (No in step S206), the client terminal 11 transmits a route search command to the relay server 13 (step S208).

  When the client terminal 11 receives the response to the route search command (Yes in step S209), the client terminal 11 confirms the response. When the specific information corresponding to the designated LAN is not included in the response, the client terminal 11 determines that there is no routing route (No in step S210). Then, the client terminal 11 notifies an error that the routing route of the designated LAN could not be searched (step S211). On the other hand, if it is determined that there is a routing route (Yes in step S210), the client terminal 11 creates route search information 95 based on the received response, and displays routing route candidates on the monitor (step S212).

  The user of the client terminal 11 selects a routing route from the route search result displayed on the monitor. When the client terminal 11 is instructed to start routing control on the route selected by the user (Yes in Step S213), the client terminal 11 transmits a routing start command to the relay server 13 (Step S214). The routing control start process will be described later.

  FIG. 27 is a flowchart showing the operation of the relay server 13 that has received the route search command. When receiving the route search command (Yes in Step S301), the relay server 13 reads the relay group information 41 (Step S302). If the route search command has not been transmitted to all the relay servers registered in the relay group information 41 (No in step S303), the route search command is transferred to the relay server identified from the relay group information 41 (step S304). ). This processing corresponds to processing (see FIG. 24) such as steps S39 and S39.1.

  When the response to the route search command is received (Yes in step S305), the relay server 13 confirms the response (step S306). When the specific information is not included in the response (No in step S306), the relay server 13 returns to step S303. When the specific information is included in the response (Yes in Step S306), the relay server 13 adds the specific information to the response information of the route search command (Step S307), and returns to Step S303. Further, when the LAN specified by the route search command can be routed, the relay server 13 adds specific information corresponding to the relay server 13 to the response information of the route search command.

  When the network search command is transmitted to all the relay servers (Yes in step S303), the relay server 13 reads the client terminal information 63 (step S308).

  When the route search command is not transmitted to all client terminals registered in the client terminal information 63 (except for the source of the route search command) (No in step S309), the route search command is transferred based on the client terminal information 63. The destination is specified. Then, the relay server 13 transmits a network search command to the specified transfer destination (step S310). This process corresponds to step S41 (see FIG. 24).

  The processes of steps S311, S312 and S313 are the same as the processes of steps S305 to S307. When the route search command is transmitted to all client terminals (Yes in step S309), the relay server 13 transmits response information of the route search command to the client terminal 11 (step S314).

<5.4. Routing start processing flow>
FIG. 28 is a diagram illustrating a flow of a routing control start process using the relay communication system.

  The user of the client terminal 11 designates the relay server 13 and the client terminal 32 as routing points based on the route search result displayed on the monitor, and instructs the start of routing control (step S43). The client terminal 11 transmits a routing start command to the relay server 13 together with the network information 951-1 and 952-2 (step S44). Steps S43 and S44 correspond to steps S213 and S214 shown in FIG.

  The relay server 13 creates routing group information 96 from the route search information 95 based on the received routing start command. The routing group information 96 is routing setting information for executing routing control using the relay communication system, and is stored in the routing group information storage unit 137.

  FIG. 29 is a diagram showing the routing group information 96. Routing loop information 96 is created by adding routing permission information 963 and session information 964 to route search information 95.

  The routing permission information 963 indicates a communication terminal that can use the routing function of the relay communication system, and includes permission terminal information 963-1 and 963-2. Here, in addition to the terms “client terminal” and “general terminal”, the term “communication terminal” is used. The “client terminal” is a terminal that can log on to the relay server, and the “general terminal” is a terminal that cannot log on to the relay server, whereas the “communication terminal” is “relay server”, All terminals including “client terminal” and “general terminal” are shown. This is not limited to the relay server and the client terminal logged on to the relay server, but the “communication terminal” connected to the LANs 1 to 3 and registered in the permitted terminal information has the routing function of the relay communication system. This is because routing is possible.

  In each permitted terminal information, “name” and “addr” indicate the name of the communication terminal or LAN that can use the routing function, and the IP address. In the permitted terminal information 963-1, “192.168.1. *” Indicating all communication terminals connected to the LAN 10-1 is set. In the permitted terminal information 963-2, “200.1.3. *” Indicating all communication terminals connected to the LAN 30-3 is set.

  Note that the user of the client terminal 11 may specify a client terminal, a relay server, a general terminal, and the like to be registered in the permitted terminal information when the routing start instruction (step S43). In this case, the route search information 95 with the routing permission information 963 added is transmitted to the relay server 13 (step S44).

  The session information 964 includes point information 964-1 regarding the routing session. The routing session is a media session that the relay server 13 and the client terminal 32 use for routing control of communication packets. “Start” of the point information 964-1 indicates the starting point of the routing session, and the identification information of the relay server 13 is set. “End” indicates an end point of the routing session, and identification information of the client terminal 32 is set.

  Reference is again made to FIG. The relay server 13 transmits the routing group information 96 to the client terminal 32 via the SIP server 101 and the relay server 33 (Steps S45, S45.1, and S45.1.1). Thereby, the relay server 13 and the client terminal 32 that function as a routing device share the routing group information 96.

  Next, a routing session is established between the relay server 13 and the client terminal 32. The relay server 13 refers to the point information 964-1 and confirms that its own device is set as the starting point of the routing session.

  The relay server 13 transmits a routing session establishment request to the relay server 33 via the SIP server 101 (steps S46 and S46.1). In response to the response from the relay server 33, the relay server 13 transmits ACK to the relay server 33 via the SIP server 101 (steps S47 and S47.1). The relay server 33 establishes a media session between the relay servers 13 and 33 in response to the ACK (step S48). In addition, a media session is established between the relay server 33 and the client terminal 32 (steps S49, S50, and S51). This process is the same as steps S46 to S48 except that a media session is established without going through the SIP server 101. A routing session is constituted by the two media sessions established in steps S48 and S51.

<5.5. Routing control of communication packets>
FIG. 30 is a diagram showing a flow of routing control using a routing session established between the relay server 13 and the client terminal 32.

  The general terminal 15 transmits a communication packet destined for the general terminal 37 (step S52). The relay server 13 determines whether the received communication packet can be routed based on the routing group information 96.

  First, the relay server 13 determines whether the communication packet can be routed using the routing target information 952. The IP address “200.1.3.250” of the destination (general terminal 37) of the communication packet corresponds to the network address of the LAN 30-3 set in the network information 952-2. The IP address “192.168.1.150” of the transmission source (general terminal 15) corresponds to the network address of the LAN 10-1 set in the network information 952-1. For this reason, the client terminal 11 determines that the received communication packet can be routed.

  Next, the relay server 13 refers to the routing permission information 963 and confirms whether the routing of the communication packet is permitted. The IP address of the destination (general terminal 37) of the communication packet corresponds to “200.1.3. *” Set in the permitted terminal information 963-2. Further, the IP address of the communication packet transmission source (general terminal 15) corresponds to “192.168.1. *” Set in the permitted terminal information 963-1. For this reason, the relay server 13 determines that routing of the communication packet is permitted.

  The relay server 13 sends out a communication packet that is permitted to be routed using a routing session (steps S53 and S53.1). The client terminal 32 transfers the communication packet received via the routing session to the general terminal 37 (step S54). Since the communication packet is encapsulated when transferred using a routing session, the general terminals 15 and 37 can communicate without being aware of the presence of the WAN 100. That is, the general terminals 15 and 37 can communicate with each other via the WAN 100 using the private IP address.

  As described above, the routing function according to the present embodiment is validated by sharing the routing group information 96 between the relay server 13 and the client terminal 32 that can communicate with each other. Then, the routing control of the IP packet is performed by the function of the relay communication system using the routing session established for routing. As described above, the routing validated in the present embodiment is routing executed in the application layer, and is different from normal IP routing.

  Next, the flow of routing end will be described. The client terminal 32 deletes the routing group information 96 in response to a routing end instruction based on the routing group information 96. An end instruction is transmitted to the relay server 13 via the relay server 33 and the SIP server 101 (steps S55, S55.1, and S55.1.1). The relay server 13 deletes the routing group information 96 based on the termination instruction.

  When the client terminal 32 receives the response to the termination instruction, the client terminal 32 transmits a routing session disconnection request to the relay server 33 (step S56). Based on the disconnection request, the media session between the client terminal 32 and the relay server 33 in the routing session is disconnected. Similarly, the media session between the relay servers 13 and 33 in the routing session is disconnected (steps S57 and S57.1). Thereby, the routing process based on the routing group information 96 is completed.

  As the routing process ends, communication between the general terminals 15 and 37 becomes impossible. Even if the general terminal 15 sends a communication packet addressed to the general terminal 37 (step S58), the relay server 13 does not hold the routing group information 96, and therefore cannot recognize the destination of the received communication packet. Therefore, the relay server 13 notifies the general terminal 15 that the destination is unreachable.

  As described above, the relay communication system according to the present embodiment automatically creates routing setting information in which a designated LAN network address is associated with a relay server or client terminal that functions as a routing device. For this reason, it is possible to simplify the creation of routing setting information used as route information in routing using a relay communication system. Further, even if the configuration of the relay communication system changes, it becomes easy to create routing setting information according to the configuration of the relay communication system.

1, 2, 3 LAN
11, 12, 21, 31, 32 Client terminals 15, 16, 23, 36, 37 General terminals 13, 22, 33 Relay server 100 WAN
101 SIP server 131 Interface unit 132, 322 Control unit 133, 325 Database storage unit 134, 327 Relay group information storage unit 135, 328 Relay server information storage unit 136 Client terminal information storage unit 137, 329 Routing group information storage unit

Claims (4)

A relay communication system in which a first relay server and a second relay server are connected,
The first relay server is
An acquisition unit for acquiring first specifying information for specifying a first routing device that performs routing control of the first LAN based on a network address of the first LAN on the first relay server side;
Requesting the second relay server to transmit second specifying information for specifying a second routing device that executes routing control of the second LAN based on a network address of the second LAN on the second relay server side A requesting section to
Based on the first specific information and the second specific information, information associating the network address of the first LAN with the first routing device, the network address of the second LAN, and the second routing device, A routing setting information creating unit for creating routing setting information including information associated with
With
The second relay server is
A response unit that acquires the second specific information in response to a request from the request unit and transmits the second specific information to the first relay server;
With
The first relay server and the second relay server are:
A sharing unit for sharing the routing setting information;
A routing session for routing a communication packet between the first LAN and the second LAN via the first relay server and the second relay server based on the routing setting information. A routing session establishment unit established between one routing device and the second routing device;
With
When a communication packet whose destination address is an IP address belonging to the second LAN is transmitted from a communication terminal connected to the first LAN, the first routing device refers to the routing setting information And determining that the communication packet can be routed to the second LAN, and transferring the communication packet using the routing session. The relay communication system according to claim 1,
The first relay server further includes:
A list creation unit that searches for a LAN capable of routing control and creates a list of the LAN;
A selection unit that selects the network address of the first LAN and the network address of the second LAN using the list;
A relay communication system comprising: In the relay communication system according to claim 1 or 2,
The first routing device is a client terminal connected to the first relay server and capable of communicating with the second relay server via the first relay server;
The relay communication system, wherein the client terminal shares the routing setting information with the first relay server and the second relay server. The relay communication system according to any one of claims 1 to 3,
The relay communication system, wherein the second routing device is the second relay server.

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