KR100582543B1 - IPv4/IPv6 tunnel broker system - Google Patents

Abstract

The present invention relates to an apparatus and method for managing a tunnel, and an IPv4 tunnel / IPv6 tunnel setup method according to the present invention requests an IPv4 tunnel, which is a predetermined path on an IPv6 network, connecting an IPv6 host existing in an IPv6 network to an IPv4 network. Transmitting an IPv4 tunnel request; Transmitting an IPv6 tunnel request requesting an IPv6 tunnel, which is a predetermined path on the IPv4 network, connecting the IPv4 host existing in the IPv4 network to the IPv6 network; And when receiving the IPv4 tunnel request, transmitting the first IPv4 tunnel configuration information to the IPv6 network and the tunnel server existing in the IPv4 network, transmitting the second IPv4 tunnel configuration information to the IPv6 host, and receiving the IPv6 tunnel request. The method includes transmitting first IPv6 tunnel configuration information to a tunnel server and transmitting second IPv6 tunnel configuration information to an IPv4 host, and automatically managing IPv6 tunnel requests of an IPv4 host as well as IPv4 tunnel requests of an IPv6 host. Manage it automatically.

Description

IP4 / IPv6 tunnel broker system {IPv4 / IPv6 tunnel broker system}

1 is a block diagram of a conventional IPv6 tunnel broker system.

2 is a diagram illustrating a packet transmission and reception through a conventional IPv6 tunnel.

3 is a block diagram of an IPv4 tunnel broker system according to an embodiment of the present invention.

4 is a diagram illustrating a packet is transmitted and received through an IPv4 tunnel according to an embodiment of the present invention.

5 is a configuration diagram of an IPv4 / IPv6 tunnel broker system according to an embodiment of the present invention.

6 is a flowchart illustrating a method for establishing an IPv4 tunnel / IPv6 tunnel according to an embodiment of the present invention.

7 is a detailed configuration diagram of each component of the IPv4 / IPv6 tunnel broker system according to an embodiment of the present invention.

The present invention relates to an apparatus and method for managing a tunnel, and more particularly, to an apparatus and method for managing an IP (Internet Protocol) tunnel.

Recently, interest in Internet Protocol version 6 (IPv6), which is the next generation Internet protocol, has been increasing. Complementing the shortcomings of the currently used Internet Protocol version 4 (IPv4), IPv6 standardization around the IPv6 Working Group (WG) of the Internet Engineering Task Force (IETF) is almost completed and is in the stage of practical application. . However, due to the nature of the network, the transition from IPv4 to IPv6 is not instantaneous, and it is expected that IPv4 and IPv6 will coexist for a considerable period of time. Therefore, before going to a full IPv6 environment, communication between an IPv4-compliant network (hereinafter referred to as an "IPv4 network") and an IPv6-compliant network (hereinafter referred to as an "IPv6 network") must take place for a considerable period of time. Methods have been devised. The tunnel broker to be described below is also one of these various methods. The technology is currently being serviced by several organizations (eg Manis, Freenet6, Cernet, etc.).

1 is a block diagram of a conventional IPv6 tunnel broker system.

Referring to FIG. 1, an IPv6 tunnel broker system includes an IPv4 host 11, a tunnel broker 12, a tunnel server 13, and a DNS (Domain Name Server) 14. This IPv6 tunnel broker 12 system is specified in Request For Comments (RFC) 3053. This is a system for automatically managing the IPv6 tunnel request of the IPv4 host 11 by establishing a dedicated server called the tunnel broker 12 as shown in FIG. In other words, the tunnel broker 12 may be regarded as a virtual IPv6 providing an IPv6 connection to a user who is already connected to the IPv4 Internet. The IPv4 host 11, tunnel broker 12, tunnel server 13, and DNS 14 exist in an IPv4 network, in particular the tunnel server 13 exists in an IPv6 network as well as an IPv4 network. Connects to an IPv6 network.

The IPv4 host 11 has a dual stack (hereinafter referred to as "IPv4 / IPv6 dual stack") including an IPv4 protocol stack and an IPv6 protocol stack for communication with an IPv6 host existing in an IPv6 network. . The IPv4 host 11 requests the tunnel broker 12 an IPv6 tunnel, which is a predetermined path on the IPv4 network connecting the IPv4 host 11 to the IPv6 network. RFC 3053 proposes an IPv4 HyperText Transfer Protocol (HTTP) web page by requesting an IPv6 tunnel. That is, the user of the IPv4 host 11 can access the IPv4 HTTP web page provided by the tunnel broker 12 and make an IPv6 tunnel request. The IPv6 tunnel request includes information such as an IPv4 address of the IPv4 host 11, a domain name corresponding to the IPv6 address of the IPv4 host 11, system information of the IPv4 host 11, and the like.

When the tunnel broker 12 receives an IPv6 tunnel request from the IPv4 host 11, information required for IPv6 tunnel establishment, such as the IPv6 address of the IPv4 host 11 and the life time of the IPv6 tunnel (hereinafter referred to as "IPv6 tunnel"). Setting information), and select one tunnel server 13 among the plurality of tunnel servers 13 and transmit IPv6 tunnel setting information to the IPv4 host 11 and the selected tunnel server 13. do. In addition, the tunnel broker 12 registers the IPv6 address and the domain name of the IPv4 host 11 in the DNS 14 so that the domain name can be converted into an IPv6 address. When the IPv6 tunnel is established in the IPv4 host 11 and the tunnel server 13 based on the IPv6 tunnel setting information, the IPv4 host 11 can communicate with the IPv4 host existing in the IPv6 network.

2 is a diagram illustrating a packet transmission and reception through a conventional IPv6 tunnel.

2, an IPv6 packet is transmitted from the IPv6 source host 21. The IPv4 packet transmitted from the IPv6 source host 21 is transmitted to the IPv4 / IPv6 host 22 which is one endpoint of the IPv6 tunnel. The IPv4 / IPv6 host 22 has an IPv4 / IPv6 dual stack, adds an IPv4 header to the transmitted IPv6 packet, and transmits an IPv4 packet having the IPv4 header added thereto through an IPv6 tunnel. IPv4 packets transmitted from the IPv4 host 22 are transmitted through the IPv6 tunnel to the IPv4 / IPv6 host 23 which is the remaining endpoint of the IPv6 tunnel. The IPv4 / IPv6 host 23 also has an IPv4 / IPv6 dual stack, separates the IPv4 header from the transmitted IPv4 packet, and transmits the IPv6 packet from which the IPv4 header is separated to the IPv6 destination host 24.

The conventional tunnel broker system is for a case where an IPv4 host in an IPv4 network wants to communicate with an IPv6 host in an IPv6 network, and an IPv6 host in an IPv6 network communicates with an IPv4 host in an IPv4 network. If desired, there was a problem in that the communication could not be enabled by automatically setting a channel as described above. In the future, most new networks will be IPv6 networks, so many newer IPv6 networks will want to access existing IPv4 applications and IPv4 servers. Therefore, the above problem will be more highlighted.

An object of the present invention is to provide an apparatus and method for automatically managing an IPv4 tunnel request of an IPv6 host as well as automatically managing an IPv6 tunnel request of an IPv4 host.

An IPv4 tunnel / IPv6 tunnel establishment method according to the present invention for solving the technical problem is (a) IPv4 tunnel requesting an IPv4 tunnel which is a predetermined path on the IPv6 network connecting the IPv6 host existing in the IPv6 network to the IPv4 network Sending a request; (b) transmitting an IPv6 tunnel request requesting an IPv6 tunnel, which is a predetermined path on the IPv4 network connecting an IPv4 host existing in the IPv4 network to the IPv6 network; And (c) when the IPv4 tunnel request is received, transmit first IPv4 tunnel configuration information to the IPv6 network and the tunnel server existing in the IPv4 network, and transmit second IPv4 tunnel configuration information to the IPv6 host, And when receiving the IPv6 tunnel request, transmitting first IPv6 tunnel configuration information to the tunnel server, and transmitting second IPv6 tunnel configuration information to the IPv4 host.

Tunnel broker according to the present invention for solving the other technical problem is an IPv4 tunnel request for requesting an IPv4 tunnel which is a predetermined path on the IPv6 network connecting the IPv6 host to the IPv4 network from an IPv6 host existing in the IPv6 network and / Or a tunnel request receiver configured to receive an IPv6 tunnel request for requesting an IPv6 tunnel, which is a predetermined path on the IPv4 network, connecting the IPv4 host to the IPv6 network from an IPv4 host existing in the IPv4 network; When an IPv4 tunnel request is received in the tunnel request receiver, first IPv4 tunnel configuration information, which is IPv4 tunnel configuration information of the tunnel server existing in the IPv6 network and the IPv4 network, is generated, and the IPv4 tunnel configuration is configured in the IPv6 host. Generating second IPv4 tunnel configuration information, and generating IPv6 tunnel configuration information, which is IPv6 tunnel configuration information at the tunnel server, when an IPv6 tunnel request is received at the tunnel request receiver; And a tunnel configuration management unit that generates second IPv6 tunnel configuration information that is IPv6 tunnel configuration information.

An IPv6 host existing in an IPv6 network according to the present invention for solving the above technical problem is a tunnel broker requesting an IPv4 tunnel request for an IPv4 tunnel, which is a predetermined path on the IPv6 network connecting the IPv6 host to an IPv4 network. An IPv4 tunnel request unit for transmitting; An IPv4 tunnel configuration information receiver configured to receive IPv4 tunnel configuration information from the tunnel broker that receives the IPv4 tunnel request transmitted from the IPv4 tunnel request unit; And an IPv4 tunnel setting unit configured to set the IPv4 tunnel at the IPv6 host based on the IPv4 tunnel setting information received at the IPv4 tunnel setting information receiving unit.

According to another aspect of the present invention, there is provided a tunnel server in an IPv6 network and an IPv4 network, and an IPv4 tunnel, which is a predetermined path on the IPv6 network, connects an IPv4 host existing in the IPv6 network to the IPv4 network. Receiving IPv4 tunnel configuration information and / or IPv6 tunnel configuration information, which is information for setting an IPv6 tunnel, which is a predetermined path on the IPv4 network connecting the IPv6 host existing in the IPv4 network, to the IPv6 network; A tunnel configuration information receiver; When the IPv4 tunnel configuration information is received in the tunnel configuration information receiver, the IPv4 tunnel is configured based on the received IPv4 tunnel configuration information. When the IPv6 tunnel configuration information is received, the received IPv6 tunnel configuration information. It includes a tunnel setting unit for setting the IPv6 tunnel based on.

In order to solve the above another technical problem, the present invention provides a computer-readable recording medium having recorded thereon a program for executing the above-described IPv4 tunnel / IPv6 tunnel setting method in a computer.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a block diagram of an IPv4 tunnel broker system according to an embodiment of the present invention.

Referring to FIG. 3, the IPv4 tunnel broker system is composed of an IPv6 host 31, a tunnel broker 32, a tunnel server 33, and a DNS 34. The IPv6 host 31, tunnel broker 32, tunnel server 33, and DNS 34 are present in the IPv6 network, in particular the tunnel server 33 is present in the IPv4 network as well as in the IPv6 network. It connects to an IPv4 network.

The IPv6 host 31 present in the IPv6 network has an IPv4 / IPv6 dual stack for communication with the IPv4 host present in the IPv4 network. The IPv6 host 31 requests the tunnel broker 32 an IPv4 tunnel, which is a predetermined path on the IPv6 network connecting the IPv6 host 31 to the IPv4 network. A user of the IPv6 host 31 may access an IPv6 HTTP web page provided by the tunnel broker 32 and make an IPv4 tunnel request. The IPv4 tunnel request includes information such as an IPv6 address of the IPv6 host 31, a domain name corresponding to the IPv4 address of the IPv6 host 31, and system information of the IPv6 host 31.

When the tunnel broker 32 receives an IPv6 tunnel request from the IPv6 host 31, information required for IPv6 tunnel establishment, such as the IPv4 address of the IPv6 host 31 and the life time of the IPv4 tunnel (hereinafter, referred to as "IPv6 tunnel"). Setting information ", and selects one tunnel server 33 among the plurality of tunnel servers, and transmits IPv6 tunnel setting information to the IPv6 host 31 and the selected tunnel server 33. In addition, the tunnel broker 32 registers the IPv4 address and the domain name of the IPv6 host 31 in the DNS 34 so that the domain name can be converted into an IPv4 address. When the IPv4 tunnel is established in the IPv6 host 31 and the tunnel server 33 based on the IPv4 tunnel setting information, the IPv6 host 31 can communicate with the IPv4 host existing in the IPv4 network.

4 is a diagram illustrating a packet transmission and reception through an IPv4 tunnel according to an embodiment of the present invention.

Referring to Fig. 4, an IPv4 packet is transmitted from the IPv4 source host 41. The IPv4 packet transmitted from the IPv4 source host 41 is transmitted to the IPv4 / IPv6 host 42 which is one endpoint of the IPv4 tunnel. The IPv4 / IPv6 host 42 has an IPv4 / IPv6 dual stack, adds an IPv6 header to the transmitted IPv4 packet, and transmits an IPv6 packet to which the IPv6 header is added through an IPv4 tunnel. IPv6 packets transmitted from the IPv4 / IPv6 host 42 are transmitted through the IPv4 tunnel to the IPv4 / IPv6 host 43, which is the remaining endpoint of the IPv4 tunnel. The IPv4 / IPv6 host 43 also has an IPv4 / IPv6 dual stack, separates the IPv6 header from the transmitted IPv6 packet, and transmits the IPv4 packet from which the IPv6 header is separated to the IPv4 destination host 44.

5 is a configuration diagram of an IPv4 / IPv6 tunnel broker system according to an embodiment of the present invention.

Referring to FIG. 5, the IPv4 / IPv6 tunnel broker system includes an IPv6 host 51, an IPv4 host 52, a tunnel broker 53, a tunnel server 54, and a DNS 55. The IPv6 host 51, tunnel broker 53, tunnel server 54, and DNS 55 are present in the IPv6 network. IPv4 host 52, tunnel broker 53, tunnel server 54, and DNS 55 reside in an IPv4 network. Unlike the IPv6 tunnel broker system and the IPv4 tunnel broker system described above, the tunnel broker 52 and the DNS 54 exist in both the IPv6 network and the IPv4 network, and request the IPv4 tunnel in the IPv6 network, or the IPv6 tunnel in the IPv4 network. It plays the role of enabling communication between IPv6 network and IPv4 network regardless of whether it requests a.

6 is a flowchart illustrating a method for establishing an IPv4 tunnel / IPv6 tunnel according to an embodiment of the present invention.

5 and 6, an IPv4 tunnel / IPv6 tunnel establishment method is composed of the following steps.

The IPv6 host 51 present in the IPv6 network transmits an IPv4 tunnel request for requesting an IPv4 tunnel, which is a predetermined path on the IPv6 network connecting the IPv6 host 51 to the IPv4 network (61). A user of the IPv6 host 51 may access an IPv4 / IPv6 HTTP web page provided by the tunnel broker 53 and make an IPv4 tunnel request. The IPv4 tunnel request includes information such as an IPv6 address of the IPv6 host 51, a domain name corresponding to the IPv4 address of the IPv6 host 51, system information of the IPv6 host 51, and the like.

The IPv4 host 52 present in the IPv4 network transmits an IPv6 tunnel request 62 requesting an IPv6 tunnel which is a predetermined path on the IPv4 network connecting the IPv4 host 52 to the IPv6 network. A user of the IPv4 host 52 may access an IPv4 / IPv6 HTTP web page provided by the tunnel broker 53 and make an IPv6 tunnel request. The IPv6 tunnel request includes information such as an IPv4 address of the IPv4 host 52, a domain name corresponding to the IPv6 address of the IPv4 host 52, and system information of the IPv4 host 52.

Subsequently, when the tunnel broker 53 receives the IPv4 tunnel request (63), the IPv6 address of the IPv6 host 51, the domain name of the IPv6 host 51, and the system of the IPv6 host 51 are included in the IPv4 tunnel request. The first IPv4 tunnel configuration information to be transmitted to the tunnel server 54 and the second IPv4 tunnel configuration information to be transmitted to the IPv6 host 51 are generated with reference to the information and the like. The first IPv4 tunnel configuration information includes the IPv6 address of the IPv6 host 51 and the survival time of the IPv4 tunnel. The second IPv4 tunnel configuration information includes the IPv6 address of the tunnel server 54, the IPv4 address of the IPv6 host 51, and the survival time of the IPv4 tunnel. In addition, the tunnel broker 53 selects one tunnel server 54 to receive the first IPv4 tunnel configuration information among several tunnel servers, and the IPv4 address and domain name of the IPv6 host 51 in the DNS 55. Register. In addition, the tunnel broker 53 transmits the first IPv4 tunnel configuration information generated to the selected tunnel server 54 and simultaneously transmits the second IPv4 tunnel configuration information generated to the IPv6 host 51 (64).

Subsequently, when the tunnel server 54 receives the first IPv4 tunnel configuration information, the tunnel server 54 establishes an IPv4 tunnel based on the received first IPv4 tunnel configuration information (65). That is, the tunnel server 54 refers to the IPv6 address of the IPv6 host 51 included in the first IPv4 tunnel configuration information and the survival time of the IPv4 tunnel, and converts the IPv6 address of the IPv6 host 51 to one endpoint of the IPv4 tunnel. Then, an IPv4 tunnel is set in which the IPv6 address of the tunnel server 54 is the remaining endpoint of the IPv4 tunnel. When the IPv6 host 51 receives the second IPv4 tunnel configuration information, the IPv6 host 51 establishes an IPv4 tunnel based on the received second IPv4 tunnel configuration information (65). That is, the IPv6 host 51 refers to the IPv6 address of the tunnel server 54 included in the second IPv4 tunnel configuration information, the IPv4 address of the IPv6 host 51, and the survival time of the IPv4 tunnel. An IPv4 tunnel is set so that the IPv6 address of the IPv4 address is one end point of the IPv4 tunnel and the IPv6 address of the tunnel server 54 is the other end point of the IPv4 tunnel.

Subsequently, when the IPv6 host 51 wants to transmit predetermined data to a destination host existing in the IPv4 network, the IPv6 host 51 generates an IPv6 packet in the form of an established IPv4 tunnel, and transmits the generated IPv6 packet through the IPv4 tunnel (66). ). That is, the IPv6 host 51 is configured in the form of an IPv4 tunnel set with reference to the IPv6 address of the tunnel server 54 included in the second IPv4 tunnel configuration information, the IPv4 address of the IPv6 host 51, and the survival time of the IPv4 tunnel. Therefore, an IPv6 header is generated using an IPv6 address of the IPv6 host 51 as a source address, an IPv6 address of the tunnel server 54 as a destination address, an IPv4 address of the IPv6 host 51 as a source address, and a destination host. An IPv4 header whose IPv4 address is the destination address is generated, and an IPv6 packet including the generated IPv6 header, the generated IPv4 header, and predetermined data is generated.

Subsequently, when the tunnel server 54 receives an IPv6 packet in the form of an IPv4 tunnel from the IPv6 host 51, the tunnel server 54 extracts an IPv4 packet from the received IPv6 packet and transmits the extracted IPv4 packet to the destination host (67). ). That is, tunnel server 54 separates the IPv6 header from the IPv6 packet. At this time, the remainder is an IPv4 packet, which is transmitted to the destination host through the IPv4 network. If the tunnel server 54 receives an IPv4 packet from an originating host existing in an IPv4 network, the tunnel server 54 generates an IPv6 packet by adding an IPv6 header to the received IPv4 packet, and generates the IPv6 packet through an established IPv4 tunnel. And transmits to host 51 (68). Subsequently, the IPv6 host 51 receives the IPv6 packet transmitted from the tunnel server 54 through the established IPv4 tunnel, and extracts the IPv4 packet from the received IPv6 packet (69). In other words, the IPv6 host 51 separates the IPv4 header from the received IPv6 packet. At this time, the remainder is the IPv4 packet transmitted by the source host.

If the tunnel broker 53 receives the IPv6 tunnel request (63), the IPv6 address of the IPv4 host 52, the domain name of the IPv4 host 52, the system of the IPv6 host 52 in the IPv6 tunnel request The first IPv6 tunnel configuration information to be transmitted to the tunnel server 54 and the second IPv6 tunnel configuration information to be transmitted to the IPv4 host 52 are generated with reference to the information and the like. The first IPv6 tunnel configuration information includes the IPv4 address of the IPv4 host 52 and the survival time of the IPv6 tunnel. The second IPv6 tunnel configuration information includes the IPv4 address of the tunnel server 54, the IPv6 address of the IPv4 host 52, and the survival time of the IPv6 tunnel. In addition, the tunnel broker 53 selects one tunnel server 54 to receive first IPv6 tunnel configuration information among a plurality of tunnel servers, and configures the first IPv6 tunnel generated by the selected tunnel server 54. Information is transmitted, and second IPv4 tunnel configuration information generated to the IPv4 host 52 is simultaneously transmitted (610).

 Subsequently, when the tunnel server 54 receives the first IPv6 tunnel configuration information, the tunnel server 54 establishes an IPv6 tunnel based on the received first IPv6 tunnel configuration information (611). That is, the tunnel server 54 refers to the IPv4 address of the IPv4 host 52 included in the first IPv6 tunnel configuration information and the survival time of the IPv6 tunnel, and converts the IPv4 address of the IPv4 host 52 to one endpoint of the IPv4 tunnel. Then, an IPv6 tunnel is set in which the IPv4 address of the tunnel server 54 is the remaining endpoint of the IPv6 tunnel. In addition, when the IPv4 host 52 receives the second IPv6 tunnel configuration information, the IPv4 host 52 establishes an IPv6 tunnel based on the received second IPv6 tunnel configuration information (611). That is, the IPv4 host 52 refers to the IPv4 address of the tunnel server 54 included in the second IPv6 tunnel configuration information, the IPv6 address of the IPv4 host 52, and the survival time of the IPv6 tunnel. An IPv6 tunnel whose IPv4 address is an end point of the IPv4 tunnel and the IPv4 address of the tunnel server 54 as the other end point of the IPv6 tunnel is set.

Subsequently, when the IPv4 host 52 intends to transmit predetermined data to a destination host existing in the IPv6 network, the IPv4 host 52 generates an IPv4 packet in the form of an established IPv6 tunnel, and transmits the generated IPv4 packet through the IPv6 tunnel (612). ). That is, the IPv4 host 52 is configured in the form of the IPv4 tunnel set with reference to the IPv4 address of the tunnel server 54 included in the second IPv6 tunnel configuration information, the IPv6 address of the IPv4 host 52, and the survival time of the IPv6 tunnel. Therefore, an IPv4 header is generated using the IPv4 address of the IPv4 host 52 as the source address, the IPv4 address of the tunnel server 54 as the destination address, the IPv6 address of the IPv4 host 52 as the source address, and the destination host. An IPv6 header whose IPv6 address is the destination address is generated, and an IPv4 packet including the generated IPv4 header, the generated IPv6 header, and predetermined data is generated.

Subsequently, when the tunnel server 54 receives an IPv4 packet in the form of an IPv6 tunnel from the IPv4 host 52, the tunnel server 54 extracts an IPv6 packet from the received IPv4 packet and transmits the extracted IPv6 packet to the destination host (613). ). In other words, the tunnel server 54 separates the IPv4 header from the IPv4 packet. At this time, the remainder is an IPv6 packet, which is transmitted to the destination host through the IPv6 network. If the tunnel server 54 receives an IPv6 packet from a source host existing in an IPv6 network, the tunnel server 54 generates an IPv4 packet by adding an IPv4 header to the received IPv6 packet, and generates the IPv4 packet through an established IPv6 tunnel. Transmit to host 52 (614). Subsequently, the IPv4 host 52 receives the IPv4 packet transmitted from the tunnel server 54 through the established IPv6 tunnel, and extracts the IPv6 packet from the received IPv4 packet (615). That is, the IPv4 host 52 separates the IPv6 header from the received IPv4 packet. At this time, the remainder is the IPv6 packet transmitted by the source host.

7 is a detailed configuration diagram of each component of the IPv4 / IPv6 tunnel broker system according to an embodiment of the present invention.

Referring to FIG. 7, the IPv6 host 51 includes an IPv4 tunnel requester 511, an IPv4 tunnel setup information receiver 512, an IPv4 tunnel setup 513, and an IPv6 packet transceiver 514. The IPv6 host 51 exists in an IPv6 network and has an IPv4 / IPv6 dual stack for communication with a host present in the IPv4 network.

The IPv4 tunnel request unit 511 transmits an IPv4 tunnel request to the tunnel broker 53 requesting an IPv4 tunnel, which is a predetermined path on the IPv6 network connecting the IPv6 host 51 to the IPv4 network. A user of the IPv6 host 51 may access an IPv4 / IPv6 HTTP web page provided by the tunnel broker 53 and make an IPv4 tunnel request. The IPv4 tunnel request includes information such as an IPv6 address of the IPv6 host 51, a domain name corresponding to the IPv4 address of the IPv6 host 51, system information of the IPv6 host 51, and the like.

The IPv4 tunnel configuration information receiver 512 receives the IPv4 tunnel configuration information from the tunnel broker 53 that receives the IPv4 tunnel request transmitted from the IPv4 tunnel request unit 511. Here, the IPv4 tunnel setting information includes the IPv6 address of the tunnel server 54, the IPv4 address of the IPv6 host 51, and the survival time of the IPv4 tunnel. Such information is generated by the tunnel broker 53.

The IPv4 tunnel setting unit 513 sets up an IPv4 tunnel at the IPv6 host 51 based on the IPv4 tunnel setting information received by the IPv4 tunnel setting information receiving unit 512. That is, the IPv4 tunnel setting unit 513 sets an IPv4 tunnel in which the IPv6 address of the IPv6 host 51 is the end point of the IPv4 tunnel and the IPv6 address of the tunnel server 54 is the remaining end point of the IPv4 tunnel.

When the IPv6 packet transceiver 514 wants to transmit predetermined data to a destination host existing in the IPv4 network, the IPv6 packet transceiver 514 generates an IPv6 packet in the form of an IPv4 tunnel set by the IPv4 tunnel setting unit 513, and generates the generated IPv6 packet. Transmit through an IPv4 tunnel. That is, the IPv6 packet transmitter / receiver 514 is configured in the form of an IPv4 tunnel set by referring to the IPv6 address of the tunnel server 54 included in the IPv4 tunnel configuration information, the IPv4 address of the IPv6 host 51, and the survival time of the IPv4 tunnel. Therefore, an IPv6 header is generated using an IPv6 address of the IPv6 host 51 as a source address, an IPv6 address of the tunnel server 54 as a destination address, an IPv4 address of the IPv6 host 51 as a source address, and a tunnel server. An IPv4 address of 54 is generated for an IPv4 header, and an IPv4 packet including an generated IPv6 header, an generated IPv4 header, and predetermined data is generated. In addition, the IPv6 packet transceiver 514 receives the IPv6 packet transmitted from the tunnel server 54 through the IPv4 tunnel, and extracts an IPv4 packet from the received IPv6 packet.

Referring to FIG. 7, the IPv4 host 52 includes an IPv6 tunnel requester 521, an IPv6 tunnel setup information receiver 522, an IPv6 tunnel setup 523, and an IPv4 packet transceiver 524. The IPv4 host 52 resides in an IPv4 network and has an IPv4 / IPv6 dual stack for communication with hosts present in the IPv6 network.

The IPv6 tunnel request unit 521 transmits an IPv6 tunnel request to the tunnel broker 53 requesting an IPv6 tunnel, which is a predetermined path on the IPv4 network connecting the IPv4 host 52 to the IPv6 network. A user of the IPv4 host 52 may access an IPv4 / IPv6 HTTP web page provided by the tunnel broker 53 and make an IPv6 tunnel request. The IPv6 tunnel request includes information such as an IPv4 address of the IPv4 host 52, a domain name corresponding to the IPv6 address of the IPv4 host 52, and system information of the IPv4 host 52.

The IPv6 tunnel configuration information receiver 522 receives IPv6 tunnel configuration information from the tunnel broker 53 that receives the IPv6 tunnel request transmitted from the IPv6 tunnel requester 521. Here, the IPv6 tunnel setting information includes the IPv4 address of the tunnel server 54, the IPv6 address of the IPv4 host 52, and the survival time of the IPv6 tunnel. Such information is generated by the tunnel broker 53.

The IPv6 tunnel setting unit 523 sets up an IPv6 tunnel at the IPv4 host 52 based on the IPv6 tunnel setting information received by the IPv6 tunnel setting information receiving unit 522. That is, the IPv6 tunnel setting unit 523 establishes an IPv6 tunnel in which the IPv4 address of the IPv4 host 52 is the end point of the IPv6 tunnel, and the IPv4 address of the tunnel server 54 is the remaining end point of the IPv6 tunnel.

When the IPv4 packet transceiver 524 wants to transmit predetermined data to a destination host existing in the IPv6 network, the IPv4 packet transceiver 524 generates an IPv4 packet in the form of an IPv6 tunnel set by the IPv6 tunnel setting unit 523, and generates the generated IPv4 packet. Transmit through an IPv6 tunnel. That is, the IPv4 packet transmitter / receiver 524 is configured to refer to the IPv4 address of the tunnel server 54 included in the IPv6 tunnel configuration information, the IPv6 address of the IPv4 host 52, and the survival time of the IPv6 tunnel. Accordingly, an IPv4 header is generated using the IPv4 address of the IPv4 host 52 as the source address, the IPv4 address of the tunnel server 54 as the destination address, the IPv6 address of the IPv4 host 52 as the source address, and the tunnel server An IPv6 address of 54 is generated for an IPv6 header, and an IPv6 packet including a generated IPv4 header, a generated IPv6 header, and predetermined data is generated. In addition, the IPv4 packet transceiver 524 receives an IPv4 packet transmitted from the tunnel server 54 through an IPv6 tunnel, and extracts an IPv6 packet from the received IPv4 packet.

Referring to FIG. 7, the tunnel broker 53 includes a tunnel request receiver 531, a tunnel setup manager 532, and a tunnel setup information transmitter 533. The tunnel broker 53 according to the present embodiment exists in an IPv6 network and an IPv4 network, and provides an IPv4 / IPv6 HTTP web page. Accordingly, the tunnel broker 53 may provide tunnel broker service for both the IPv6 host 51 present in the IPv6 network and the IPv4 host 52 present in the IPv4 network.

The tunnel request receiving unit 531 may request an IPv4 tunnel request and / or an IPv4 network from the IPv6 host 51 existing in the IPv6 network to request an IPv4 tunnel, which is a predetermined path on the IPv6 network connecting the IPv6 host 51 to the IPv4 network. An IPv6 tunnel request is received from an existing IPv4 host 52 requesting an IPv6 tunnel, which is a predetermined path on the IPv4 network connecting the IPv4 host 52 to the IPv6 network.

When the tunnel request receiving unit 532 receives the IPv4 tunnel request, the tunnel setting manager 532 generates the first IPv4 tunnel setting information, which is IPv4 tunnel setting information of the tunnel server 54 existing in the IPv6 network and the IPv4 network. Then, the second IPv4 tunnel setting information which is IPv4 tunnel setting information in the IPv6 host 51 is generated. In addition, the tunnel setting manager 532 selects one tunnel server 54 to receive the first IPv4 tunnel setting information among the plurality of tunnel servers, and the IPv4 address and domain of the IPv6 host 51 in the DNS 55. Register the name. Here, the first IPv4 tunnel configuration information includes the IPv6 address of the IPv6 host 51 and the survival time of the IPv4 tunnel, and the second IPv4 tunnel configuration information includes the IPv6 address of the tunnel server 54 and the IPv6 host 51. IPv4 address, and survival time of the IPv4 tunnel.

If the IPv6 tunnel request is received by the tunnel request receiving unit 531, the first IPv6 tunnel configuration information, which is IPv6 tunnel configuration information at the tunnel server 54, is generated, and IPv6 tunnel configuration information at the IPv4 host 52 is generated. Generate the second IPv6 tunnel configuration information. At this time, the tunnel configuration manager 532 selects one tunnel server 54 to receive the first IPv6 tunnel configuration information among the plurality of tunnel servers, and the IPv6 address and domain of the IPv4 host 52 in the DNS 55. Register the name. Here, the first IPv6 tunnel configuration information includes the IPv4 address of the IPv4 host 52 and the survival time of the IPv6 tunnel, and the second IPv6 tunnel configuration information includes the IPv4 address of the tunnel server 54 and the IPv4 host 52. IPv6 address, and survival time of the IPv6 tunnel.

The tunnel configuration information transmitting unit 533 transmits the generated first IPv4 tunnel configuration information to the tunnel server 54 when the tunnel configuration management unit 532 generates the first IPv4 tunnel configuration information and the second IPv4 tunnel configuration information. The second IPv4 tunnel configuration information generated by the IPv6 host 51 is transmitted. If the first IPv6 tunnel configuration information and the second IPv6 tunnel configuration information are generated by the tunnel configuration management unit 532, the first IPv6 tunnel configuration information is transmitted to the tunnel server 54, and the IPv4 host 52 is transmitted. Transmits the generated second IPv6 tunnel configuration information;

Referring to FIG. 7, the tunnel server 54 includes a tunnel setting information receiver 541, a tunnel setup unit 542, and a packet transmitter 543. The tunnel server 54 exists in an IPv6 network and an IPv4 network, and serves to connect the IPv6 network and the IPv4 network.

The tunnel configuration information receiver 541 exists in the IPv4 tunnel configuration information and / or the IPv4 network, which is information for establishing an IPv4 tunnel, which is a predetermined path on the IPv6 network connecting the IPv4 host 52 existing in the IPv6 network to the IPv4 network. IPv6 tunnel configuration information, which is information for establishing an IPv6 tunnel, which is a predetermined path on the IPv4 network connecting the IPv6 host 51 to the IPv6 network, is received. Here, the IPv4 tunnel configuration information includes the IPv6 address of the IPv6 host 51 and the survival time of the IPv4 tunnel, and the IPv6 tunnel configuration information includes the IPv4 address of the IPv4 host 52 and the survival time of the IPv6 tunnel. Such information is generated by the tunnel broker 53.

The tunnel setting unit 542 sets the IPv4 tunnel based on the received IPv4 tunnel setting information when the IPv4 tunnel setting information is received by the tunnel setting information receiving unit 541, and receives the IPv6 tunnel setting information when the IPv4 tunnel setting information is received. IPv6 tunnel is configured based on IPv6 tunnel configuration information. That is, when the IPv4 tunnel configuration information is received by the tunnel configuration information receiver 541, the tunnel setting unit 542 refers to the IPv6 address of the IPv6 host 51 included in the IPv4 tunnel configuration information and the survival time of the IPv4 tunnel. An IPv4 tunnel is set in which the IPv6 address of the IPv6 host 51 is one end point of the IPv4 tunnel, and the IPv6 address of the tunnel server 54 is the other end point of the IPv4 tunnel. If the IPv6 tunnel configuration information is received by the tunnel configuration information receiver 541, the IPv4 address of the IPv4 host 52 may be referred to by referring to the IPv4 address of the IPv4 host 52 included in the IPv6 tunnel configuration information and the survival time of the IPv6 tunnel. An IPv6 tunnel is set up with the address as one end point of the IPv6 tunnel and the IPv4 address of the tunnel server 54 as the other end point of the IPv6 tunnel.

When the packet transmitter 543 receives an IPv6 packet according to the IPv4 tunnel format from the IPv6 host 51 through the IPv4 tunnel set by the tunnel setting unit 542, the packet transmitter 543 extracts an IPv4 packet from the received IPv6 packet, and extracts the extracted IPv4 packet. Forwards the received IPv4 packet to the destination host on the IPv4 network. In other words, the packet transmitter 543 separates the IPv6 header from the IPv6 packet. At this time, the remainder is an IPv4 packet, which is transmitted to the destination host through the IPv4 network. If an IPv4 packet is received from the source host existing in the IPv4 network, an IPv6 packet is added to the IPv4 packet to generate an IPv6 packet, and the generated IPv6 packet is transmitted to the IPv6 host 51 through the IPv4 tunnel.

If an IPv4 packet in the form of an IPv6 tunnel is received from the IPv4 host 52 through the IPv6 tunnel configured by the tunnel setting unit 542, an IPv6 packet is extracted from the received IPv4 packet, and the extracted IPv6 packet is IPv6. Send to the destination host on the network. In other words, the packet transmitter 543 separates the IPv4 header from the IPv4 packet. At this time, the remainder is an IPv6 packet, which is transmitted to the destination host through the IPv6 network. If the IPv6 packet is received from the source host existing in the IPv6 network, the IPv4 packet is added to the IPv6 packet to generate an IPv4 packet, and the generated IPv4 packet is transmitted to the IPv4 host 52 through the IPv6 tunnel.

Meanwhile, the above-described embodiments of the present invention can be written as a program that can be executed in a computer, and can be implemented in a general-purpose digital computer that operates the program using a computer-readable recording medium.

The computer-readable recording medium may be a magnetic storage medium (for example, a ROM, a floppy disk, a hard disk, etc.), an optical reading medium (for example, a CD-ROM, a DVD, etc.) and a carrier wave (for example, the Internet). Storage medium).

So far I looked at the center of the preferred embodiment for the present invention. Those skilled in the art will appreciate that the present invention can be implemented in a modified form without departing from the essential features of the present invention. Therefore, the disclosed embodiments should be considered in descriptive sense only and not for purposes of limitation. The scope of the present invention is shown in the claims rather than the foregoing description, and all differences within the scope will be construed as being included in the present invention.

According to the present invention, not only automatically manages an IPv6 tunnel request of an IPv4 host, but also automatically manages an IPv4 tunnel request of an IPv6 host, such that an IPv4 host existing in an IPv4 network desires communication with an IPv6 host existing in an IPv6 network. In addition to the case, the communication between the IPv6 host existing in the IPv6 network and the IPv4 host existing in the IPv4 network has an effect that the communication can be automatically set up if desired. In other words, we propose a general-purpose tunnel broker model that can communicate regardless of the type of Internet protocol in the mixed environment of IPv4 and IPv6 networks, so that users can easily communicate until the next generation of IPv6 network is completely settled. It is effective. Since the new network will be the IPv6 network in the future, the new IPv6 network will be more likely to want to access existing IPv4 applications and IPv4 servers, and thus the above-mentioned effects will be more manifested. In addition, according to the present invention, since the existing tunnel broker system can be expanded and used without changing, it only needs to be additionally installed in the existing system, so that the activation of the present invention can be easily induced. A quick transition to an IPv6 network can be achieved.

Claims (20)

(a) transmitting an IPv4 tunnel request requesting an IPv4 tunnel which is a predetermined path on the IPv6 network connecting an IPv6 host existing in the IPv6 network to an IPv4 network; (b) transmitting an IPv6 tunnel request requesting an IPv6 tunnel, which is a predetermined path on the IPv4 network connecting an IPv4 host existing in the IPv4 network to the IPv6 network; And (c) when the IPv4 tunnel request is received, transmit first IPv4 tunnel configuration information to the IPv6 network and the tunnel server existing in the IPv4 network, and transmit second IPv4 tunnel configuration information to the IPv6 host; When receiving an IPv6 tunnel request, transmitting first IPv6 tunnel configuration information to the tunnel server and transmitting second IPv6 tunnel configuration information to the IPv4 host. . The method of claim 1, In step (c), if the IPv4 tunnel request is received, the first IPv4 tunnel configuration information and the second IPv4 tunnel configuration information are generated, and the generated first IPv4 tunnel configuration information is transmitted to the tunnel server. And transmits the generated second IPv4 tunnel configuration information to the IPv6 host, generates the first IPv6 tunnel configuration information and the second IPv6 tunnel configuration information when the IPv6 tunnel request is received, and generates the tunnel server. Transmitting the generated first IPv6 tunnel configuration information to the IPv4 host, and transmitting the generated second IPv6 tunnel configuration information to the IPv4 host. The method of claim 1, In the step (c), the tunnel server is selected when the IPv4 tunnel request is received, the first IPv4 tunnel configuration information is transmitted to the selected tunnel server, and the tunnel is received when the IPv6 tunnel request is received. And selecting a server and transmitting the first IPv6 tunnel configuration information to the selected tunnel server. The method of claim 1, (d) when the first IPv4 tunnel configuration information is received, establishes an IPv4 tunnel at the tunnel server based on the received first IPv4 tunnel configuration information, and when the first IPv6 tunnel configuration information is received; Establishing an IPv6 tunnel at the tunnel server based on the received first IPv6 tunnel configuration information; (e) if the second IPv4 tunnel configuration information is received, establishing an IPv4 tunnel at the IPv6 host based on the received second IPv4 tunnel configuration information; And (f) if the second IPv6 tunnel configuration information is received, establishing an IPv4 tunnel / IPv6 tunnel configuration based on the received second IPv6 tunnel configuration information; Way. The method of claim 4, wherein (g) generating an IPv6 packet in the form of the set IPv4 tunnel and transmitting the generated IPv6 packet through the IPv4 tunnel, if the predetermined data is to be transmitted to a destination host existing in the IPv4 network; And (h) when receiving an IPv6 packet in the form of the IPv4 tunnel from the IPv6 host, extracting an IPv4 packet from the received IPv6 packet, and transmitting the extracted IPv4 packet to the destination host. Characterized by IPv4 tunnel / IPv6 tunnel setup method. The method of claim 4, wherein (g) when receiving an IPv4 packet from the source host existing in the IPv4 network, adds an IPv6 header to the received IPv4 packet to generate an IPv6 packet, and generates the IPv6 packet through the set IPv4 tunnel through the IPv6 tunnel; Transmitting to a host; And (h) receiving an IPv6 packet transmitted from the tunnel server through the set IPv4 tunnel, and extracting the IPv4 packet from the received IPv6 packet. The method of claim 4, wherein (g) generating an IPv4 packet in the form of the IPv6 tunnel and transmitting the generated IPv4 packet through the IPv6 tunnel, if the predetermined data is to be transmitted to a destination host existing in the IPv6 network; And (h) when receiving an IPv4 packet in the form of the IPv6 tunnel from the IPv4 host, extracting an IPv6 packet from the received IPv4 packet, and transmitting the extracted IPv6 packet to the destination host. Characterized by IPv4 tunnel / IPv6 tunnel setup method. The method of claim 4, wherein (g) when receiving an IPv6 packet from a source host existing in the IPv6 network, adds an IPv4 header to the received IPv6 packet to generate an IPv4 packet, and generates the IPv4 packet through the configured IPv6 tunnel; Transmitting to a host; And (h) receiving an IPv4 packet transmitted from the tunnel server through the set IPv6 tunnel, and extracting the IPv6 packet from the received IPv4 packet. Requesting the IPv4 host from an IPv4 host requesting an IPv4 tunnel which is a predetermined path on the IPv6 network connecting the IPv6 host to the IPv4 network from an IPv6 host existing in the IPv6 network and / or from the IPv4 host existing in the IPv4 network A tunnel request receiver configured to receive an IPv6 tunnel request for requesting an IPv6 tunnel which is a predetermined path on the IPv4 network connecting to an IPv6 network; When an IPv4 tunnel request is received in the tunnel request receiver, first IPv4 tunnel configuration information, which is IPv4 tunnel configuration information of the tunnel server existing in the IPv6 network and the IPv4 network, is generated, and the IPv4 tunnel configuration is configured in the IPv6 host. Generating second IPv4 tunnel configuration information, and generating IPv6 tunnel configuration information, which is IPv6 tunnel configuration information at the tunnel server, when an IPv6 tunnel request is received at the tunnel request receiver; And a tunnel configuration manager for generating second IPv6 tunnel configuration information, which is IPv6 tunnel configuration information. The method of claim 9,  Transmit the generated first IPv4 tunnel configuration information to the tunnel server, transmit the generated second IPv4 tunnel configuration information to the IPv6 host, and transmit the generated first IPv6 tunnel configuration information to the tunnel server; And a tunnel configuration information transmitter configured to transmit the generated second IPv6 tunnel configuration information to the IPv4 host. The method of claim 9, The tunnel configuration manager selects the tunnel server when the IPv4 tunnel request is received, transmits the first IPv4 tunnel configuration information to the selected tunnel server, and when the IPv6 tunnel request is received, the tunnel server. And selecting and transmitting the first IPv6 tunnel configuration information to the selected tunnel server. 10. The method of claim 9, wherein the first IPv4 tunnel configuration information comprises an IPv6 address of the IPv6 host, the second IPv4 tunnel configuration information includes an IPv6 address of the tunnel server and an IPv4 address of the IPv6 host, The first IPv6 tunnel configuration information includes an IPv4 address of the IPv4 host, and the second IPv6 tunnel configuration information includes an IPv4 address of the tunnel server and an IPv6 address of the IPv4 host. For IPv6 hosts in an IPv6 network, An IPv4 tunnel request unit configured to transmit an IPv4 tunnel request to a tunnel broker requesting an IPv4 tunnel, which is a predetermined path on the IPv6 network, connecting the IPv6 host to an IPv4 network; An IPv4 tunnel configuration information receiver configured to receive IPv4 tunnel configuration information from the tunnel broker that receives the IPv4 tunnel request transmitted from the IPv4 tunnel request unit; And And an IPv4 tunnel setting unit configured to set the IPv4 tunnel in the IPv6 host based on the IPv4 tunnel setting information received by the IPv4 tunnel setting information receiving unit. The method of claim 13, The IPv4 tunnel configuration information includes the IPv6 address of the tunnel server, And the IPv4 tunnel setting unit configures an IPv4 tunnel using an IPv6 address of the IPv6 host as an endpoint of the IPv4 tunnel and an IPv6 address of the tunnel server as the remaining endpoint of the IPv4 tunnel. The method of claim 13, When the predetermined data is to be transmitted to a destination host existing in the IPv4 network, an IPv6 packet is generated in the form of an IPv4 tunnel set by the IPv4 tunnel setting unit, the generated IPv6 packet is transmitted through the IPv4 tunnel, And an IPv6 packet transceiver for receiving an IPv6 packet from the tunnel server existing in the IPv6 network and the IPv4 network, and extracting an IPv4 packet from the received IPv6 packet. The method of claim 15, The IPv4 tunnel configuration information includes an IPv4 address of the IPv6 host and an IPv6 address of the tunnel server. The IPv6 packet transmitting / receiving unit generates an IPv6 header having an IPv6 address of the IPv6 host as a source address, an IPv6 address of the tunnel server as a destination address, an IPv4 address of the IPv6 host as a source address, and Generate an IPv4 header for the IPv4 address, and generate an IPv4 packet including the generated IPv6 header, the generated IPv4 header, and the predetermined data; In a tunnel server existing in an IPv6 network and an IPv4 network, IPv4 tunnel configuration information and / or IPv6 host existing in the IPv4 network, which is information for establishing an IPv4 tunnel which is a predetermined path on the IPv6 network connecting the IPv4 host existing in the IPv6 network to the IPv4 network, A tunnel configuration information receiver configured to receive IPv6 tunnel configuration information, which is information for configuring an IPv6 tunnel, which is a predetermined path on the IPv4 network connected to the network; When the IPv4 tunnel configuration information is received in the tunnel configuration information receiver, the IPv4 tunnel is configured based on the received IPv4 tunnel configuration information. When the IPv6 tunnel configuration information is received, the received IPv6 tunnel configuration information. Tunnel server, characterized in that for setting the IPv6 tunnel based on the tunnel server. The method of claim 17, The IPv4 tunnel configuration information includes an IPv6 address of the IPv6 host, the IPv6 tunnel configuration information includes an IPv4 address of the IPv4 host, When the IPv4 tunnel configuration information is received, the tunnel setting unit sets an IPv4 tunnel including an IPv6 address of the IPv6 host as one endpoint of the IPv4 tunnel, and an IPv6 address of the tunnel server as the other endpoint of the IPv4 tunnel. And, when the IPv6 tunnel configuration information is received, set up an IPv6 tunnel having an IPv4 address of the IPv4 host as one endpoint of the IPv6 tunnel and an IPv4 address of the tunnel server as the other endpoint of the IPv6 tunnel. Tunnel Server. The method of claim 17, When receiving an IPv6 packet according to the format of the IPv4 tunnel from the IPv6 host through the IPv4 tunnel configured by the tunnel setting unit, an IPv4 packet is extracted from the received IPv6 packet, and the extracted IPv4 packet is extracted from the IPv4 network. In the case of receiving an IPv4 packet from a source host existing in the IPv4 network and generating an IPv6 packet by adding an IPv6 header to the IPv4 packet, the generated IPv6 packet is generated and the IPv6 packet is generated. And a packet transmitter configured to transmit the packet to the IPv6 host through a tunnel. The method of claim 17, When receiving an IPv4 packet in the form of the IPv6 tunnel from the IPv4 host through the IPv6 tunnel configured by the tunnel setting unit, an IPv6 packet is extracted from the received IPv4 packet, and the extracted IPv6 packet is extracted from the IPv6 network. In the case of receiving an IPv6 packet from a destination host existing in the IPv6 network, adding an IPv4 header to the received IPv6 packet to generate an IPv4 packet, and generating the generated IPv4 packet. And a packet transmitter configured to transmit the IPv4 host to the IPv4 host through an IPv6 tunnel.

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