JP4630214B2 - Information management method, information management apparatus, data relay apparatus, and information management system - Google Patents

Description

  The present invention relates to an information management method for sharing and managing address information for data communication by connecting an information management apparatus to which indefinite address information is assigned and a data relay apparatus to form a dedicated network, and data relay The present invention relates to an apparatus and an information management system.

  Conventionally, a specific authentication password is used based on MAC address information between a router as a data relay device constituting a network and a DNS server as an address management information management device using a DNS (Domain Name System) function. There has been a system that creates and communicates the authentication password and performs authentication, then acquires address information necessary for communication from a DNS server, and performs data communication via the network.

JP 2005-286944 A

  However, if the address information of all routers and DNS servers that make up the network is temporarily specified but the address information is dynamically changed (hereinafter referred to as “indefinite address”), communication is performed. I can't. That is, in order for the router to connect to the DNS server, the IP address information of the DNS server is necessary. Since this address information is dynamically changed, the address information of the DNS server is changed. Every time you need to change the router settings. In this case, since the router does not know the changed DNS server address information, it is necessary for the operator to check the DNS server address information by telephone or the like every time, and the confirmation operation becomes complicated. Therefore, at least one DNS server to which fixed address information that does not change is assigned is installed in the private network, and the router first asks the DNS server for the address information of the destination router for data communication. However, in this service, if there is insufficient address information to be allocated, it is difficult to allocate a fixed address, and the service for receiving the provision of the fixed address is expensive.

  The present invention has been made in view of the above, and dynamically learns address information that is changed due to a change in the situation or environment, and reflects it in the setting information of the information management device or the data relay device itself. An object of the present invention is to provide an information management method, a data relay device, and an information management system.

  In order to solve the above-described problems and achieve the object, an information management method according to the present invention includes a plurality of information management devices and data set to indefinite address information in which address information indicating itself is temporarily specified. A dedicated network is formed by connecting with a relay device, and information for the data relay device to perform data relay is shared and managed by each information management device, and the data according to an inquiry from the data relay device In the information management method for providing information for relaying, a first registration step in which the information management apparatus and the data relay apparatus register address information indicating each information management apparatus, and the information management apparatus includes: Connect to the other information management device in which the address information indicating the information management device is registered, periodically transmit the address information indicating the self, and receive the address information. The first update step in which the other information management device updates the registered address information based on the address information, and the information that the data relay device inquires about the information for performing the data relay. When there is no response from the management device, it connects to another information management device other than the information management device and inquires address information indicating the information management device, and the other information management device makes an inquiry from the data relay device And a first providing step of sending and providing address information indicating the corresponding information management device from among the registered address information.

  In the information management method according to the second aspect of the present invention, in the above invention, the data relay device updates the registered address information based on the address information provided in the first provision step. A second update step is further included.

  An information management method according to a third aspect of the present invention is the information management method according to the above invention, wherein the data relay device is connected to the information management device and periodically indicates another information management device other than the information management device. Inquiring information, and in response to an inquiry from the data relay device, the information management device transmits and provides address information indicating the corresponding other information management device from among the registered address information. A providing step; and a third updating step in which the data relay device updates the registered address information based on the address information provided in the second providing step. And

  According to a fourth aspect of the present invention, there is provided an information management method according to the above invention, wherein the data relay device is connected to each information management device and periodically transmits address information indicating the self, Each of the received information management devices further includes a second registration step of registering the address information.

  The information management device according to the invention of claim 5 is connected to at least one information management device and a plurality of data relay devices set to indefinite address information in which address information indicating itself is temporarily specified. To configure a dedicated network, share information for the data relay device to perform data relay with the other information management device, and perform the data relay in response to an inquiry from the data relay device In the information management device that provides the information, the first registration means for registering the address information indicating each information management device and the other information management device in which the address information indicating each information management device is registered are connected. The address information indicating the self is periodically transmitted and the address information indicating the other information management apparatus periodically transmitted from the other information management apparatus is received. And an address indicating the other information management device received from the connected data relay device, and first update means for updating the address information registered by the first registration means based on the address information In response to the information inquiry, the address information indicating the other information management device is searched from the address information registered by the first registration means, and is sent to the data relay device and provided. Providing means.

  According to a sixth aspect of the present invention, there is provided a data relay device connected to a plurality of information management devices set to indefinite address information in which address information indicating itself is temporarily specified and another data relay device. In a data relay apparatus that configures a dedicated network and inquires each information management apparatus for information for performing data communication, a second registration unit that registers address information indicating each information management apparatus, and the data relay apparatus When there is no response from the information management apparatus that has inquired the information, the information management apparatus is connected to another information management apparatus other than the information management apparatus, inquires address information indicating the information management apparatus, and the other information is responded Second update for updating the address information registered by the second registration means based on address information indicating the information management device provided from the management device Characterized in that it comprises a stage, a.

  According to a seventh aspect of the present invention, in the data relay device according to the present invention, the data relay device is connected to the information management device and periodically inquires for address information indicating another information management device other than the information management device. A third updating means for updating the address information registered by the second registration means based on address information indicating the other information management apparatus provided from the information management apparatus according to It is characterized by providing.

  According to an eighth aspect of the present invention, there is provided an information management system for connecting a plurality of information management devices set to indefinite address information in which address information indicating itself is temporarily specified and a data relay device to connect a dedicated network. The information management device shares and manages information for the data relay device to perform data relay, and provides information for performing the data relay in response to an inquiry from the data relay device In the information management system, the information management device is connected to first registration means for registering address information indicating each information management device and another information management device in which address information indicating each information management device is registered. The address information indicating the other information management device is periodically transmitted from the other information management device and the address information indicating the self is periodically transmitted. First update means for receiving information and updating the address information registered by the first registration means based on the address information, and the other information management apparatus received from the connected data relay apparatus In response to the address information inquiry indicating, the address information indicating the other information management device is searched from the address information registered by the first registration means, and is transmitted to the data relay device and provided. The data relay device includes: a second registration unit that registers address information indicating each information management device; and an information management device that inquires about information for performing the data relay. When there is no response, it connects to another information management device other than the information management device, inquires for address information indicating the information management device, and responds to the inquiry with the other information management device. Based on the address information indicating the information management apparatus provided placed al, characterized in that it comprises a second updating means for updating the address information registered in the second registration means.

  An information management system according to a ninth aspect of the present invention is the information management system according to the above invention, wherein the data relay device is connected to the information management device and periodically indicates an information management device other than the information management device. Inquiring information, and updating the address information registered by the second registration means based on address information indicating the other information management device provided from the information management device in response to the inquiry. The update means is further provided.

  An information management method, a data relay device, and an information management system according to the present invention comprise a dedicated network by connecting a plurality of information management devices having their own address information indefinite and a data relay device, and the information management device And the other information management apparatus updates the registered address information based on the received address information, and the data When there is no response from the information management apparatus that inquired information for relaying, the data relay apparatus is connected to another information management apparatus, and inquires for address information indicating the information management apparatus, By receiving the address information indicating the corresponding information management device from the information management device, it dynamically learns the address information that changes according to changes in the situation and environment. An effect that can be reflected in the information management apparatus and a data relay device its configuration information.

  Embodiments of an information management method, a data relay device, and an information management system according to the present invention will be described below in detail with reference to the drawings of FIGS. The present invention is not limited to these embodiments, and various modifications can be made without departing from the scope of the present invention.

(Embodiment 1)
FIG. 1 is a system configuration diagram showing a schematic configuration of Embodiment 1 of an information management system according to the present invention. In the figure, a plurality of DNS servers 1 and 2 that are information management apparatuses and routers 3 and 4 that are data relay apparatuses are connected by a communication line (not shown) to form a dedicated network 10 such as a VPN (Virtual Private Network). is doing. The dedicated network 10 includes an address distribution server 20 that distributes IP address information. The IP address information of the DNS servers 1 and 2 and the routers 3 and 4 is stored in the address distribution server as the situation and environment change. Indefinite IP address information changed by 20 is assigned. In this information management system, for example, “AAAA :: A” is stored in the DNS server 1 as “IPAA :: A”, “BBBB :: B” is stored in the DNS server 2, and “CCCC” :: C ”is assigned to the router 4 and“ DDDD :: D ”is assigned thereto. Each DNS server 1 and 2 registers the address assigned to itself and its own host name in the DNS memory unit described later as DNS information. The routers 3 and 4 register the address information assigned to the DNS servers 1 and 2 and the host names of the DNS servers 1 and 2 as address cache information in an address cache unit described later. The record attribute is registered, for example, with an NS record, or with an AAAA record for an IP address.

  The DNS servers 1 and 2 periodically communicate with other DNS servers via the dedicated network 10 to perform operations for registering their own IP address information in other DNS servers, and for the IP addresses of the other DNS servers. An operation of registering address information as address cache information is performed.

  The DNS servers 1 and 2 share and manage the address information of the routers 3 and 4 as information for performing data relay, and in response to the inquiry from the routers 3 and 4, the address information of the router to be inquired is dedicated. This is provided to the inquiry destination router via the network 10. These DNS servers 1 and 2 have the same configuration as shown in the block diagram of FIG. In FIG. 2, the DNS servers 1 and 2 include an interface unit 11, a database 12 as a first registration unit, an address notification unit 13 as a first update unit, and an address notification as a first update unit. The reception processing unit 14 and a DNS address resolution unit 15 as a first providing means for performing address resolution are configured. The address notification unit 13, the address notification reception processing unit 14, and the DNS address resolution unit 15 are connected to other DNS servers and routers 3 and 4 via the dedicated network 10 to enable data communication with these devices. ing.

  The database 12 is DNS information possessed only by the DNS server. For example, the DNS memory unit 12a in which the domain name, IP address, authentication information, etc. are registered, and the combination information of the domain name of the DNS server and the IP address information are registered. Address cache unit 12b, and a configuration memory unit 12c for storing operation settings of the DNS server, setting information for connecting to other DNS servers and hub routers 3 and 4, and the like. The DNS information in the DNS memory unit 12a is referred to when responding to a request from the DNS server, and the registered DNS information is dynamically changed by a request from another host (DNS server). . The address cache unit 12b is composed of a non-volatile memory, and all of the routers 3 and 4 learn. In the DNS server, the address cache unit 12b is first used to perform DNS registration with another DNS server. The configuration memory unit 12c is composed of a nonvolatile memory, and is changed by setting from a console (terminal device), but does not change dynamically.

  The interface unit 11 is connected to, for example, an external information input unit (not shown). An IP address is assigned to the interface unit 11 by a provider or the like, and is assigned to the DNS memory unit 12a as its own DNS information. The registered IP address and its own host name are registered.

  The address notification unit 13 has a function of notifying another DNS server of its own address information (DNS information) input from the interface unit 11. Here, the address information of another DNS server serving as destination information is referred to from the address cache unit 12b. The DNS information notification is periodically performed using, for example, a name registration packet of HTTP (HyperText Transfer Protocol).

  The address notification reception processing unit 14 registers the DNS information in the DNS memory unit 12a with, for example, an NS record or an AAAA record when receiving notification of DNS information of the DNS server from another DNS server. 12b is updated.

  When the DNS address resolution unit 15 receives a DNS name resolution request packet from another host (including other DNS servers, routers 3 and 4), the DNS address resolution unit 15 stores the address information corresponding to the requested name in the DNS memory unit. A DNS name resolution response packet is created by searching from 12a and notified.

  The routers 3 and 4 are connected to other routers and terminal devices (not shown) that perform data communication via a LAN, for example, and have a hub (HUB) function that relays data, for example. Some have the functions of a DNS server. Since the DNS server function is the same as the DNS servers 1 and 2 described above, the hub function will be described with reference to the block diagram of FIG.

  The routers 3 and 4 as hubs periodically communicate with all the DNS servers 1 and 2 via the dedicated network 10 to perform operations for registering their own IP addresses in all the DNS servers, and for all the DNS servers 1. , 2 is registered as address cache information. When the routers 3 and 4 are connected to other hub routers, they learn the IP addresses of the other hub routers using the DNS servers 1 and 2, and based on this IP address, Communicate.

  In FIG. 3, routers 3 and 4 include an interface unit 31, a database 32 as a second registration unit, an address notification unit 33, and DNS address resolution units as second and third update units that perform address resolution. 34. The address notification unit 33 and the DNS address resolution unit 34 are connected to other DNS servers and routers 3 and 4 via the dedicated network 10 to enable data communication with these devices. Routers 3 and 4 serve as relay means (not shown) for relaying encrypted data between a terminal device (not shown) connected via a communication line and other routers and DNS servers 1 and 2. A data relay processing unit is provided.

  The database 32 includes, for example, an address cache unit 32a in which combination information of a DNS server domain name and IP address is registered, operation settings of hub routers (including connection settings with other hub routers and spoke routers described later), DNS servers, The configuration memory unit 32b stores setting information for connection. The address cache unit 32a is composed of a non-volatile memory and is referred to when connecting to a DNS server. When the IP address of the DNS server is changed, it can be dynamically changed by inquiring and obtaining address information from another DNS server. The configuration memory unit 32b is composed of a non-volatile memory, and is changed by setting from a console (terminal device), but does not change dynamically.

  Similarly to the interface unit 11, the interface unit 31 is connected to an external information input unit (not shown), and the IP address of the assigned DNS server itself is input to the interface unit 11 by a provider or the like. In the cache unit 32a, for example, an assigned IP address and its host name are registered as its own IP address information.

  The address notification unit 33 has a function of notifying the hosts of all DNS servers 1 and 2 of its own address information input from the interface unit 31. Here, in order to notify its own address information, it is necessary to register the address information (all) allocated to the DNS server host in the address cache unit 32a. The notification of the address information is performed regularly, for example.

  The DNS address resolution unit 34 acquires, for example, an NS record of the DNS server from the primary DNS server, and updates and maintains the address cache information registered in the address cache unit 32a.

  Next, operations related to sharing of address information between the DNS servers 1 and 2 will be described based on the sequence of FIG. 4, in each DNS server 1 and 2, for example, by initial setting of a console (terminal device), the interface unit 11 registers the address information of the other DNS server as address cache information in the address cache unit 12b (step S101). , S201). In this embodiment, the address information “BBBB :: B” of the DNS server 2 is stored in the address cache unit 12b of the DNS1, and the address information “AAA :: B” of the DNS server 1 is stored in the address cache unit 12b of the DNS2. A "is registered.

  Then, each DNS server 1 and 2 starts an IP address registration operation (steps S102 and S202). First, it additionally registers its own address information as DNS information in the DNS memory unit 12a (steps S103 and S203). Next, the DNS servers 1 and 2 notify DNS information. The DNS information is notified using, for example, an HTTP name registration packet including an IP header, a TCP header, and an HTTP request shown in FIG. First, the address notification unit 13 of the DNS server 1 refers to the address cache information, and the destination of the IP header is the address information “BBBB :: B” of the DNS server 2 and the transmission source is the address information “AAAA” of the DNS server 1. :: A "creates a name registration packet with its own name and address information" AAAA :: A "added using port number 80, and transmits it to the DNS server 2 (step S104).

  When the name registration packet is received from the DNS server 1, the address notification reception processing unit 14 of the DNS server 2 registers and registers the DNS server 1 address information “AAAAA :: A” in the DNS memory unit 12a as DNS information. Is completed (step S204), the address notification unit 13 of the DNS server 2 refers to the address cache information, and the destination of the IP header is the address information “AAA :: A” of the DNS server 1, and the transmission source is the DNS server. 2 creates a name registration packet with its own name and address information “BBBB :: B” added using the port number 80 with the address information “BBBB :: B” of No. 2 and transmits it to the DNS server 1 (step S205).

  When the name registration packet is received from the DNS server 2, the address notification reception processing unit 14 of the DNS server 1 registers the address information “BBBB :: B” of the DNS server 2 as DNS information in the DNS memory unit 12 a (step S105). This DNS information notification and registration operation is performed periodically.

  Next, operations related to sharing of address information between DNS servers when the address information of the DNS server 2 is changed due to changes in the situation or environment, for example, construction of network facilities, etc., based on the sequence of FIG. explain. In FIG. 7, when the address information of the DNS server 2 is changed from “BBBB :: B” to “XXXX :: X” by the setting from the address distribution server 20 in the private network 10, the interface unit 11 The address information “XXXX :: X” is registered and updated in the DNS memory unit 12a as DNS information (step S210).

  Next, in the DNS server 1, from the address notification unit 13, the destination of the IP header is the address information “BBBB :: B” of the DNS server 2, and the transmission source is the address information “AAAAA :: A” of the DNS server 1. A name registration packet with its own name and address information “AAAA :: A” added thereto is transmitted to the DNS server 2 using the port number 80 (step S110), but the address of the DNS server 2 has changed. Therefore, the name registration packet does not reach the DNS server 2.

  Next, the DNS server 2 periodically transmits a name registration packet. Since the address information of the DNS server 2 has already been changed, the address notification unit 13 of the DNS server 2 sets the destination of the IP header to the DNS server 1. Address information “AAA :: A”, the address is “XXXX :: X” of the DNS server 2 and the DNS information “XXXX :: X” is added using the port number 80. The registration packet is transmitted to the DNS server 1 (step S211).

  When receiving the name registration packet from the DNS server 2, the DNS server 1 registers the address information “XXXX :: X” of the DNS server 2 as DNS information in the DNS memory unit 12 a. When registration is completed (step S111), the DNS address resolution unit 15 creates a name resolution packet. Here, as shown in FIG. 6, the name resolution packet includes an IP header, a UDP header, and a DNS Query / Response indicating whether the address information request or response is to be resolved, and the DNS address resolution unit of the DNS server 1 15 is the address information “XXXX :: X” of the DNS server 2 in the name resolution packet, the address information “AAA :: A” of the DNS server 1 and the address in DNS Query. A name resolution request packet specifying the name of the DNS 2 to be resolved and the attribute of the record is transmitted to the DNS server 2 (step S112).

  When the name resolution request packet is received from the DNS server 1, the DNS address resolution unit 15 of the DNS server 2 sends the requested name, in this case, for example, DNS information (address information) corresponding to its own domain to the DNS memory unit. Search from 12a. Then, the DNS address resolution unit 15 includes the address information “AAAA :: A” of the DNS server 1 in the name resolution packet and the address information “XXXX :: X” of the DNS server 2 as the transmission source. The name resolution response packet specifying the address information “XXXX :: X” corresponding to the request in the DNS Response is transmitted to the DNS server 1 (step S212).

  When receiving the name resolution response packet from the DNS server 2, the DNS address resolution unit 15 of the DNS server 1 resolves that the specified address information “XXXX :: X” in the packet is the address information of DNS 2. By registering (for example, overwriting) this address information in its own address cache unit 12b, the address information of the address cache unit is updated. From then on, the DNS server 1 and the DNS server 2 periodically notify each other's address information using the name registration packet, as in FIG.

  As described above, in this embodiment, when the address information of any DNS server is changed due to a change in the situation or environment, for example, construction of network facilities, the DNS server whose address has been changed periodically. By receiving the notified name registration packet, the changed address information can be dynamically detected, and the address information can be registered and updated by reflecting it in the DNS information registered in the DNS memory unit of the server itself. Therefore, in this embodiment, the DNS information of the server itself can be dynamically changed, and this DNS information can be used for system operation, and the system operation is continued without artificially changing the settings. be able to.

  In this embodiment, the address information of the DNS server is transmitted to the DNS server whose address has been changed, by communicating a name resolution packet using the DNS information of the DNS server as address information. It can be dynamically learned and updated by reflecting it in the address cache information registered in the address cache unit of the server itself. In addition, since the dynamically learned address information is registered in the address cache unit, which is a non-volatile memory, the operation can be continued without any disappearance of the address information even when the power is turned OFF / ON.

  In this embodiment, the address cache information is updated by performing address resolution of the changed DNS server using the name resolution packet. For example, the name registration packet periodically communicated from the DNS server whose address has been changed. The address notification reception processing unit can update the address cache information in the address cache unit based on the detected address information.

  Next, the address resolution operation performed between the router and the DNS server will be described based on the sequence of FIG. Since the routers 3 and 4 perform the same operation, the address resolution operation performed between the router 3 and the DNS servers 1 and 2 will be described here as a representative.

  In FIG. 8, in the router 3, as with the DNS servers 1 and 2, the interface unit 31 uses the address information of the DNS servers 1 and 2 as address cache information by the initial setting of the console (terminal device), for example, to the address cache unit 32a. Register (step S301). That is, in this embodiment, the address information “AAAA :: A” of the DNS server 1 and the address information “BBBB :: B” of the DNS server 2 are registered in the address cache unit 32 a of the router 3.

  Then, the router 3 starts an IP address registration operation (step S302), and the address notification unit 33 has the IP header destination address information “AAAA :: A” of the DNS server 1 or the address information “BBBB” of the DNS server 2. :: B ", the address information" CCCC :: C "of the router 3 as the transmission source, and the name registration packet with its own name and address information" CCCC :: C "added using the port number 80, It transmits to the DNS server 1 and the DNS server 2 (steps S303 and S304).

  When the name registration packet is received from the router 3, the address notification reception processing unit 14 of the DNS servers 1 and 2 registers the address information “CCCC :: C” of the router 3 as DNS information in the DNS memory unit 12a (step S120). , S220). This notification and registration of address information is performed regularly.

  Next, an address resolution operation performed between the router and the DNS server when the address information of the router 3 is changed due to a change in the situation or environment will be described based on the sequence of FIG. In FIG. 9, when the address information of the router 3 is changed from “CCCC :: C” to “YYYY :: Y” by the setting from the address distribution server 20, the address notification unit 33 is changed from the interface unit 31. The address information “YYYY :: Y” is taken in, and the IP address registration operation is started (step S310). As in steps S303 and S304, name registration with its own name and address information “YYYY :: Y” added is performed. A packet is created and transmitted to the DNS server 1 and the DNS server 2 (steps S311 and S312).

  When the name registration packet is received from the router 3, the address notification reception processing unit 14 of the DNS servers 1 and 2 registers and updates the address information “YYYY :: Y” of the router 3 in the DNS memory unit 12 a as DNS information. (Steps S130 and S230), notification and registration of this address information are performed periodically.

  As described above, in this embodiment, when the address information of any router is changed due to a change in the situation or environment, a name registration packet periodically notified from the router whose address has been changed is received. Thus, the changed address information can be dynamically detected and registered in the DNS information registered in the DNS memory unit of the server. Therefore, similar to the DNS server address change described above, the DNS information of the server itself can be dynamically changed, and the DNS information can be used for system operation. Can be continued.

  Similarly to the above address change of the DNS server, for example, the address notification reception processing unit performs the address cache based on the detected address information by receiving the name registration packet periodically communicated from the router whose address has been changed. It is also possible to update the address cache information in the department.

  Next, the address resolution operation performed between the router and the DNS server when the address information of the DNS server 1 is changed due to a change in the situation or environment will be described based on the sequence of FIG. In this embodiment, the DNS address resolution unit 34 of the router 3 has the function of the third update means, and is set to transmit the name resolution packet periodically. In FIG. 10, when the address information of the DNS server 1 is changed from “AAAA :: A” to “XXXX :: X” by the setting from the address distribution server 20, an address information registration operation is performed (step S140). . Here, the interface unit 11 first registers the address information “XXXX :: X” as DNS information in the DNS memory unit 12a to update the DNS information. The address notification unit 13 uses the port number 80 with the IP header destination address information “BBBB :: B” of the DNS server 2 and the source address information “XXXX :: X” of the DNS server 1. Then, the name registration packet to which its own DNS information “XXXX :: X” is added is transmitted to the DNS server 2.

  When the DNS server 2 receives the name registration packet from the DNS server 1, the address notification reception processing unit 14 registers the address information “XXXX :: X” of the DNS server 1 as DNS information in the DNS memory unit 12 a. Then, registration of the address change is completed (step S240).

  Next, the router 3 receives from the address notification unit 33 that the destination of the IP header is the address information “AAAA :: A” of the DNS server 1 or the address information “BBBB :: B” of the DNS server 2 and the transmission source is the router 3. The address information “CCCC :: C” is sent to the DNS server 1 and the DNS server 2 by using the port number 80 and the name registration packet to which the name and address information “CCCC :: C” are added. (Steps S320 and S321) Since the address of the DNS server 1 has changed, this name registration packet does not reach the DNS server 1.

  Next, the router 3 sends the address information “BBBB :: B” of the DNS server 2 and the address information “CCCC :: C” of the router 3 from the DNS address resolution unit 34, and A name resolution request packet in which the name of DNS 1 whose address is to be resolved by DNS Query and the attribute of the record are designated is periodically transmitted to the DNS server 2 (step S322).

  When the name resolution request packet is received from the router 3, the DNS address resolution unit 15 of the DNS server 2 sends the requested name, in this case, for example, DNS information (address information) corresponding to the domain of DNS1 to the DNS memory unit 12a. Search from. Then, the DNS address resolution unit 15 requests the IP address destination is the address information “CCCC :: C” of the router 3, the transmission source is the address information “BBBB :: B” of the DNS server 2, and the DNS response is used. A name resolution response packet designating the corresponding address information “XXXX :: X” is transmitted to the router 3 (step S241).

  Upon receiving the name resolution response packet from the DNS server 2, the DNS address resolution unit 34 of the router 3 resolves that the specified address information “XXXX :: X” in the packet is the address information of DNS 1, By registering (for example, overwriting) this address information in its own address cache unit 32a, the address information in the address cache unit 32a is updated to complete the address change operation (step S323). Thereafter, as in FIG. 9, the router 3 periodically notifies the DNS server 1 and the DNS server 2 of address information using the name registration packet, and uses the name resolution packet to perform the DNS server. 2 periodically inquires and provides the address information of the DNS server 1.

  Thus, in this embodiment, when the address information of any DNS server is changed due to a change in the situation or environment, the router addresses the DNS server other than the DNS server whose address has been changed. Since the address information of the changed DNS server is inquired and the address information is provided from another DNS server, the address information of the DNS server is dynamically learned on the source router side, and the address of the router itself It can be updated by reflecting it in the address cache information registered in the cache unit. In addition, since the dynamically learned address information is registered in the address cache unit, which is a non-volatile memory, the operation can be continued without any disappearance of the address information even when the power is turned OFF / ON.

  In the first embodiment, the case of the hub router and the DNS server has been described. However, the DNS server can have the same function instead of the hub router, and other DNS servers are changed by the name registration packet. In addition to obtaining an address, for example, by communicating the name resolution packet shown in FIG. 10 with another DNS server, it becomes possible to obtain the changed address of the other DNS server, and the versatility of the system is improved. There is an effect.

(Embodiment 2)
FIG. 11 is a system configuration diagram showing a schematic configuration of Embodiment 2 of the information management system according to the present invention. In addition, the same code | symbol shall be attached about the component similar to Embodiment 1. FIG. In the figure, a plurality of DNS servers 1 and 2 that are information management devices, a hub router 3 that is a data relay device, and spoke routers 5 and 6 that are data relay devices are respectively connected by communication lines (not shown). A dedicated network 10 such as a VPN is configured. Also in this embodiment, the address information of the DNS servers 1 and 2 and the router 3 are indefinite addresses, and the indefinite address is also assigned to the address information of the spoke routers 5 and 6, as in the first embodiment. ing. Also in this information management system, for example, “EEEE :: E” is assigned to the spoke router 5 and “FFFF :: F” is assigned to the spoke router 6 as IP addresses at the time of initial setting. The DNS servers 1 and 2 and the hub router 3 are assigned address information having the same contents as the address information shown in the first embodiment. The configurations of the DNS servers 1 and 2 and the hub router 3 are the same as those in the first embodiment, and are omitted here. In the private network 10, there is an address distribution server as in FIG.

  In this embodiment, the spoke routers 5 and 6 perform data communication via the host hub router 3. The spoke routers 5 and 6 start data communication with respect to the address information of the hub router 3. Since the address information of the hub router 3 is an indefinite address, the DNS router host, for example, the DNS server 1 is used to Data communication is started after deriving IP address information from the name. However, since the DNS server address information is also an undefined address, when a plurality of DNS server hosts, for example, two DNS servers 1 and 2 are prepared and the address information of the DNS server 1 is changed, another DNS server is provided. 2 is a mechanism for inquiring for name resolution.

  The spoke routers 5 and 6 have the same configuration as shown in the block diagram of FIG. In FIG. 12, the spoke routers 5 and 6 comprise a database 51 as second registration means and a DNS address resolution unit 52 as second and third update means for performing address resolution. The DNS address resolution unit 52 is connected to the hosts of the DNS servers 1 and 2 and the hub router 3 via the dedicated network 10, and enables data communication with these hosts.

  The database 51 includes, for example, an address cache unit 51a in which the combination information of the DNS server domain name and IP address is registered, operation settings of the spoke router (including connection settings with the hub router), and setting information for connecting to the DNS server. And the like, and a configuration memory unit 51b that stores and the like. The address cache unit 51a is composed of a non-volatile memory, and is referred to when connecting to a DNS server. When the IP address of the DNS server is changed, it can be dynamically changed by inquiring and obtaining address information from another DNS server. The configuration memory unit 51b is composed of a nonvolatile memory, and is changed by setting from a console (terminal device), but does not change dynamically.

  The DNS address resolution unit 52 acquires, for example, an NS record of the DNS server from the primary DNS server, and updates and maintains the address cache information registered in the address cache unit 51a.

  Next, the name resolution operation performed between the spoke router and the DNS server will be described based on the sequence of FIG. Since the spoke routers 5 and 6 perform the same operation, the address resolution operation performed between the spoke router 5 and the DNS servers 1 and 2 will be described here representatively.

  In FIG. 13, in the spoke router 5, the address information of the DNS servers 1 and 2 is registered in advance in the address cache unit 51a as the address cache information (step S401). That is, in this embodiment, the address information “AAAA :: A” of the DNS server 1 and the address information “BBBB :: B” of the DNS server 2 are registered in the address cache unit 51 a of the spoke router 5.

  Then, the spoke router 5 starts a name resolution operation (step S402), and the DNS address resolution unit 52 sets the address information “AAAA :: A” of the DNS server 1 or the address information “DNSA” of the DNS server 2 as the destination of the IP address. The DNS server sends a name resolution request packet that specifies the name of the hub router 3 and the attribute of the record that the address is "EEEE :: E" of the spoke router 5 and whose address is to be resolved by the DNS Query. 1 and 2 are periodically transmitted (steps S403 and S404).

  When the name resolution request packet is received from the spoke router 5, the DNS address resolution unit 52 of the DNS servers 1 and 2 receives DNS information (address information “CCCC” corresponding to the requested name, in this case, for example, the domain of the hub router 3). :: C ") is retrieved from the DNS memory unit 12a. Then, the DNS address resolution unit 15 of the DNS servers 1 and 2 has the IP address destination address information “EEEE :: E” of the spoke router 5 and the transmission source address information “AAAA :: A” of the DNS server 1 or A name resolution response packet specifying the address information “BBBB :: B” of the DNS server 2 and the address information “CCCC :: C” corresponding to the request in the DNS response is transmitted to the spoke router 5 (steps S150 and S250). ).

  When the name resolution response packet is received from the DNS servers 1 and 2, the DNS address resolution unit 52 of the spoke router 5 receives the specified setting information (the address information “CCCC :: C” of the hub router 3) in the packet as the hub router. 3, the data communication to the hub router 3 is made possible.

  Further, the spoke router 5 receives the address information “AAAA :: A” of the DNS server 1 from the DNS address resolution unit 52 and the address information “EEEE :: E” of the spoke router 5 from the DNS server 1. In addition, the name resolution request packet specifying the DNS 2 name and the record attribute to be address-resolved by the DNS Query is sent to the DNS server 1, and the IP address destination is the DNS server 2 address information “BBBB :: B”, the transmission source Periodically transmits to the DNS server 2 a name resolution request packet in which the address information “EEEE :: E” of the spoke router 5 and the name of the DNS 1 whose address is to be resolved by the DNS Query and the attribute of the record are specified (step). S405, S406).

  Upon receiving this name resolution request packet, the DNS address resolution unit 15 of the DNS server 1 searches the DNS memory unit 12a for the requested name, in this case, for example, DNS information (address information) corresponding to the domain of DNS2. . Then, the DNS address resolution unit 15 requests that the IP address destination is the address information “EEEE :: E” of the spoke router 5, the transmission source is the address information “AAA :: A” of the DNS server 1, and the DNS Response is used. A name resolution response packet designating the address information “BBBB :: B” of the DNS server 2 corresponding to is transmitted to the spoke router 5 (step S151).

  Upon receiving this name resolution request packet, the DNS address resolution unit 15 of the DNS server 2 sends the requested name, in this case, for example, DNS information (address information) corresponding to the domain of DNS1 from the DNS memory unit 12a. Search for. Then, the DNS address resolution unit 15 requests that the IP address destination is the address information “EEEE :: E” of the spoke router 5, the transmission source is the address information “BBBB :: B” of the DNS server 2, and is DNS response. A name resolution response packet designating the address information “AAAA :: A” of the DNS server 1 corresponding to is sent to the spoke router 5 (step S251).

  Next, the name resolution operation performed between the spoke router and the DNS server when the address information of the DNS server 1 is changed due to a change in the situation or environment will be described based on the sequence of FIG. In FIG. 14, when the address information of the DNS server 1 is changed from “AAAA :: A” to “XXXX :: X” by the setting from the address distribution server 20, an address information registration operation is performed. Here, the interface unit 11 first registers the address information “XXXX :: X” as DNS information in the DNS memory unit 12a to update the DNS information. The address notification unit 13 uses the port number 80 with the IP header destination address information “BBBB :: B” of the DNS server 2 and the source address information “XXXX :: X” of the DNS server 1. Then, the name registration packet to which its own DNS information “XXXX :: X” is added is transmitted to the DNS server 2 (step S152).

  When the DNS server 2 receives the name registration packet from the DNS server 1, the address notification reception processing unit 14 registers the address information “XXXX :: X” of the DNS server 1 as DNS information in the DNS memory unit 12 a. Then, registration of the address change of the DNS server 1 is completed (step S252).

  Next, the spoke router 5 periodically transmits a name resolution request packet similar to that in step S405 to the DNS server 1 (step S407). However, since the address of the DNS server 1 has changed, the spoke router 5 Does not receive this name registration packet.

  Next, the spoke router 5 receives the address information “BBBB :: B” of the DNS server 2 from the DNS address resolution unit 52 and the address information “EEEE :: E” of the spoke router 5 from the DNS server 2. The name resolution request packet specifying the name of DNS 1 and the attribute of the record whose address is to be resolved by the DNS Query is transmitted to the DNS server 2 (step S408).

  Upon receiving the name resolution request packet from the spoke router 5, the DNS address resolution unit 15 of the DNS server 2 sends the requested name, in this case, for example, DNS information (address information) corresponding to the domain of DNS1 to the DNS memory unit. Search from 12a. Then, the DNS address resolution unit 15 requests that the IP address destination is the address information “EEEE :: E” of the spoke router 5, the transmission source is the address information “BBBB :: B” of the DNS server 2, and is DNS response. The name resolution response packet designating the address information “XXXX :: X” corresponding to is transmitted to the spoke router 5 (step S253).

  When the name resolution response packet is received from the DNS server 2, the DNS address resolution unit 52 of the spoke router 5 resolves that the designated address information “XXXX :: X” in the packet is the address information of DNS1. By registering (for example, overwriting) this address information in its own address cache unit 51a, the address information of the address cache unit 51a is updated, and the address change operation is completed (step S409). Thereafter, the spoke router 5 periodically notifies the DNS server 1 and the DNS server 2 of address information using the name resolution request packet, similarly to steps S405 and S406 in FIG. 13 (step S410). , S411), the name resolution response packet is received from the DNS servers 1 and 2 for the name resolution request packet (steps S153 and S254).

  As described above, in this embodiment, when the address information of any DNS server is changed due to a change in the situation or environment, a spoke router is provided to other DNS servers other than the DNS server whose address has been changed. Since the address information of the DNS server whose address has been changed is inquired and the address information is provided from another DNS server, the address information of the DNS server is dynamically learned on the spoke router side of the transmission source, and the spoke router It can be updated by reflecting in the address cache information registered in its own address cache unit. In addition, since the dynamically learned address information is registered in the address cache unit, which is a non-volatile memory, the operation can be continued without any disappearance of the address information even when the power is turned OFF / ON.

  In the second embodiment, the case of the spoke router and the DNS server has been described. However, the hub router can also have the same function instead of the spoke router, and when the DNS server address information is changed, By communicating the name resolution packet with another DNS server, it is possible to acquire a changed address of a certain DNS server, and there is an effect that versatility of the system is improved.

1 is a system configuration diagram showing a schematic configuration of Embodiment 1 of an information management system according to the present invention. It is a block diagram which shows an example of a structure of a DNS server. It is a block diagram which shows an example of a structure of a hub router. It is a sequence figure for demonstrating the operation | movement in connection with sharing of address information between DNS servers. It is a figure which shows the format of a name registration packet. It is a figure which shows the format of a name resolution packet. It is a sequence figure for demonstrating the operation | movement in connection with sharing of address information between DNS servers when the address information of a DNS server is changed. It is a figure of the sequence for demonstrating the operation | movement of the address resolution performed between a router and a DNS server. It is a sequence diagram for explaining the operation of address resolution performed between the router and the DNS server when the address information of the router is changed. It is a sequence figure for demonstrating the operation | movement of the address resolution performed between a router and a DNS server when the address information of a DNS server is changed. It is a system block diagram which shows schematic structure of Embodiment 2 of the information management system concerning this invention. It is a block diagram showing an example of composition of a spoke router. It is a figure of the sequence for demonstrating operation | movement of the name resolution performed between a spoke router and a DNS server. It is a figure of the sequence for demonstrating the operation | movement of the name resolution performed between a spoke router and a DNS server when the address information of a DNS server is changed.

Explanation of symbols

1, 2 DNS server 3, 4 Hub router 5, 6 Spoke router 10 Dedicated network 11, 31 Interface unit 12, 32, 51 Database 12a DNS memory unit 12b, 32a, 51a Address cache unit 12c, 32b, 51b Config memory unit 13, 33, 52 Address notification unit 14 Address notification reception processing unit 15, 34 Address resolution unit 20 Address distribution server

Claims (9)

A dedicated network is formed by connecting a plurality of information management devices set to undefined address information for which address information indicating itself is temporarily specified and a data relay device, and the data relay device performs data relay In the information management method for sharing information by each information management device and providing information for performing the data relay in response to an inquiry from the data relay device,
A first registration step in which the information management device and the data relay device register address information indicating each information management device;
The information management device is connected to the other information management device in which address information indicating each information management device is registered, and periodically transmits the address information indicating the self, and the other that has received the address information. A first update step of updating the registered address information based on the address information;
When the data relay apparatus does not receive a response from the information management apparatus that has inquired information for performing the data relay, an address indicating the information management apparatus is connected to another information management apparatus other than the information management apparatus Inquiring information, and in response to an inquiry from the data relay device, the other information management device transmits and provides address information indicating the corresponding information management device from the registered address information. Providing step;
An information management method comprising: A second updating step in which the data relay device updates the registered address information based on the address information provided in the first providing step;
The information management method according to claim 1, further comprising: The data relay device is connected to the information management device and periodically inquires address information indicating another information management device other than the information management device, and the information management device responds to an inquiry from the data relay device. A second providing step of transmitting and providing address information indicating the corresponding other information management device from among the registered address information;
A third updating step in which the data relay device updates the registered address information based on the address information provided in the second providing step;
The information management method according to claim 1, further comprising: The data relay device connects to each information management device, periodically transmits address information indicating the self, and each information management device that receives the address information registers the address information. Step
The information management method according to claim 1, further comprising: A dedicated network is configured by connecting to at least one information management device and a plurality of data relay devices set to indefinite address information in which address information indicating itself is temporarily specified, and the data relay device performs data relay In the information management apparatus for sharing information with the other information management apparatus for management and providing information for performing the data relay in response to an inquiry from the data relay apparatus,
First registration means for registering address information indicating each information management device;
The address information indicating each information management device is connected to the other information management device in which the address information is registered, and the address information indicating the self is periodically transmitted and periodically transmitted from the other information management device. First update means for receiving address information indicating the other information management apparatus and updating address information registered by the first registration means based on the address information;
In response to an address information inquiry indicating the other information management device received from the connected data relay device, the other information management device corresponding to the address information registered by the first registration means is selected. First addressing means for retrieving address information to be shown and transmitting the address information to the data relay device;
An information management device comprising: Information for performing data communication by connecting to a plurality of information management devices and other data relay devices that are set to indefinite address information in which address information indicating itself is temporarily specified and configuring a dedicated network In the data relay device that inquires each information management device,
Second registration means for registering address information indicating each information management device;
When there is no response from the information management apparatus that inquires about the information for performing the data relay, the information management apparatus is connected to another information management apparatus other than the information management apparatus, and inquires for address information indicating the information management apparatus, A second updating means for updating the address information registered by the second registration means based on address information indicating the information management apparatus provided from the other information management apparatus according to
A data relay device comprising: Connected to the information management device, periodically inquires address information indicating another information management device other than the information management device, and the other information management device provided from the information management device in response to the inquiry A third updating means for updating the address information registered by the second registration means based on the address information shown;
The data relay device according to claim 6, further comprising: A dedicated network is formed by connecting a plurality of information management devices set to undefined address information for which address information indicating itself is temporarily specified and a data relay device, and the data relay device performs data relay In the information management system for sharing and managing the information of each information management device, and providing information for performing the data relay according to the inquiry of the data relay device,
The information management device is connected to a first registration means for registering address information indicating each information management device, and the other information management device in which address information indicating each information management device is registered. The address information indicating is periodically transmitted and the address information indicating the other information management device periodically transmitted from the other information management device is received, and the first registration is performed based on the address information. In response to an inquiry about address information indicating the other information management apparatus received from the connected data relay apparatus, the first registration means updates the address information registered by the means. First providing means for retrieving address information indicating the corresponding other information management device from the registered address information and transmitting the address information to the data relay device;
The data relay device is a device other than the information management device when there is no response from the second registration means for registering address information indicating each information management device and the information management device inquiring about the information for performing the data relay. Connected to another information management device, inquires address information indicating the information management device, and based on the address information indicating the information management device provided from the other information management device in response to the inquiry, An information management system comprising: a second update unit configured to update the address information registered by the second registration unit.   The data relay device is connected to the information management device, periodically inquires address information indicating other information management devices other than the information management device, and provided from the information management device in response to the inquiry 9. The apparatus according to claim 8, further comprising third update means for updating the address information registered by the second registration means based on address information indicating another information management apparatus. Information management system.

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