KR100724232B1 - Method for identifying Protocol identification each IP version type in PPP link - Google Patents

Abstract

The present invention is to distinguish between IP versions using different protocol identifiers when establishing and authenticating a link when simultaneously serving dual IP versions in a PPP link, and a method for identifying a protocol for each IP version type in a PPP link according to the present invention. Encapsulates the signaling information of the protocol field of the PPP frame format of the PPP link protocol by dividing the dual IP version protocol identifier values, respectively, and provides the IP network service of the terminal according to the separated protocol identifier corresponding to the dual IP version. Characterized in that.

Here, the distinguished protocol identifiers in IP version 6 and IP version 4 of the dual IP version are separate PPP links of IPv4 and IPv6, respective LCP protocols for link establishment, respective PAP protocol information identifiers for authentication, and CHAP. It is characterized by distinguishing the protocol identifier, and each IP datagram and each IPCP protocol identifier.

According to the present invention, the IP version type (IPv4, IPv6) required by the terminal in the establishment and authentication phase of the PPP link can be distinguished by the protocol identifier value, so that the selection and charging management of the AAA server for authentication of the terminal is facilitated. To facilitate.

Description

Method for identifying Protocol identification each IP version type in PPP link}

1 is a PPP frame format configuration diagram.

2 is a table showing protocol values according to a conventional protocol type.

3 is a diagram illustrating a wireless Internet service network when providing an Internet access service based on IP version 4 according to an exemplary embodiment.

4 is a flowchart illustrating a PPP link establishment and authentication process according to the embodiment of FIG. 3.

5 is a diagram illustrating a wireless Internet service network when providing an Internet access service based on a dual IP version according to another exemplary embodiment of the present invention.

FIG. 6 is a flowchart illustrating IP packet setting, authentication, and communication when providing IP version 6 Internet service according to the embodiment of FIG. 5.

7 is a table illustrating protocol identification values for IP version types in a PPP link according to an embodiment of the present invention.

8 is a configuration diagram of a dual IP version serving node and a wireless Internet network according to an embodiment of the present invention.

9 is a simple IP packet setup, authentication and communication flow diagram of the dual stack terminal according to the embodiment of FIG.                 

10 is a diagram illustrating a protocol stack configuration of a dual stack terminal according to an exemplary embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

101,201,211,301,311,321 .... terminal

102,202,302 .... Base Station System Network

103,203,303 .... Network Server 104,204,304 ... IPv4 Internet

105,205,305 ... AAAv4 Server 114,214,314 ... IPv6 Internet

115,215,315 ... AAAv6 Server

When simultaneously serving dual IP versions (IPv6, IPv4) in a Point to Point Protocol (PPP) link according to the present invention, so that the PPP link end can simultaneously use dual IP network services by protocol identifiers distinguishing the dual IP versions. The present invention relates to a protocol identification method for each IP version type in a PPP link.

In detail, each IP version type in a PPP link provides a protocol identifier for distinguishing dual IP versions in the link establishment phase and authentication phase processing steps. It relates to a protocol identification method.

IP currently in use is version 4 (IPv4) adopted by Arpanet, 32-bit system, and IPv4 address system is composed of '000,000,000,000' number structure that is commonly used with alphabetic domain name. . The 32-bit IPv4 could theoretically address 4 billion computers, but concerns began to arise that the IPv4 addressing system would soon be exhausted. This is why IPv6. The Internet Technical Working Group (IETF), which is currently developing the Internet standard protocol, has organized a working group since 1993 to complete the standard for this protocol.

Since IPv6 adopts a 128-bit system, theoretically two 128-bit computers can be connected. This is the capacity of nearly a billion computers every second that can be used almost forever, even with new Internet connections. In IPv6, you can choose one of three address types: unicast, anycast, and multicast. Unicast can be used for Internet individual users and the like, Anycast can be used in a corporate computer network such as a LAN, and multicast can be used in an ISP (Internet access service company).

The link layer protocol for serial data communication between the terminal and the network server is the PPP link protocol (IEFT standard protocol). The basic negotiation procedure for the PPP link protocol is performed by the terminal and the network server. After the terminal authentication (authenticate), authentication process is completed, it goes through the process of network layer control setting.

After the PPP link is established, the link setting, the terminal authentication, and the protocol of the network layer to be used are completed, data communication is performed according to the established method, and the frame format shown in FIG. 1 is used for data communication. do.                         

Referring to FIG. 1, a format of a PPP protocol frame includes a protocol identification header (Protocol 8/16 bits), an information field to be delivered, and a configured PPP frame. It is divided into padding data to fit the length.

In addition, the protocol field classifies a protocol of data transmitted in the information field as shown in FIG. 2. In the range of classification, 0xxx ~ 3xxx is classified as a network layer protocol, 8xxx ~ bxxx is a Network Control Protocol (NCP), and cxxx ~ fxxx is a Link Control Protocol (LCP) protocol.

Referring to FIG. 2, the main protocol identifiers include c021: LCP, cO23: PAP, c223: CHAP, 8021: IPCP, 0021: IP (IPv4 datagram), 8057: IPv6CP, 0057: IPv6 datagram.

Here, the protocol identifier 0xc021 is an identifier used to transfer the LCP protocol related data to the information field, and indicates the LCP packet used in the link establishment step for establishing a PPP link between the first terminal and the network server. In this step, the network layer Except for the control function of the terminal and the network environment, such as link settings.

The protocol identifiers 0xc023 and 0xc223 are used for authenticating the terminal during the LCP process after completing the PPP link setup by the LCP. When the protocol identifiers are set, the terminal and the network server send authentication related data. When using PAP (Password Authentication Protocol) authentication, an identifier of 0xc023 is used, and when using CHAP (Challenged Handshake Authentication Protocol) authentication, 0xc223 is used.

The protocol identifier 0x8021 is used as an identifier for distinguishing IPCP protocol data for network control such as address assignment of a network layer to be used between the terminal and the network server after link establishment and terminal authentication are completed.

The protocol identifier 0x0021 is an identifier that delivers the user's IP datagram after completing the PPP link setup by LCP, terminal authentication by PAP / CHAP, and network layer control by IPCP.

The protocol identifier 0x8057 is a network layer control data transmission identifier of the next generation Internet based on IPv6, which corresponds to IPv4 based IPCP, becomes an IPv6 Control Protocol (IPv6CP) identifier of IPv6 rather than IPv4, and 0x0057 is an identifier that carries an IPv6 datagram. This is distinguished from 0x0021, an IP datagram identifier of IPv4.

Referring to FIGS. 3 and 4, operations of a terminal (MS) and a network server (PDSN: Packet Data Serving Node) according to the PPP protocol, which are classified into the frame format of FIG. 1 and the protocol type of FIG. As follows.

3 is a diagram illustrating a service network configuration based on IPv4, and FIG. 4 is a service flowchart when the cellular network provides a service for accessing the Internet based on IPv4 only.

3 and 4, when the terminal 101 wants to access the Internet, the base station BS and the base station controller BSC of the base station system (BSS) 102 are connected to the terminal 101. A bearer channel is established for the transmission of PPP link data between the network server and the PDSN (103).

Then, as shown in FIG. 4, the network server 103 establishes the PPP link by the link control protocol of the terminal (S101), and at this time, when the CHAP authentication is set for the terminal 101 when the link is opened, the network server 103 A CHAP-challenge message is transmitted to the terminal 101 (S102).

Then, the terminal 101 responds (CHAP-response) the CHAP request message to the network server 103 (S103), and the network server 103 receives the response message to receive the network access identifier (NAI) of the terminal 101. : A network access identifier by sending a request message including a Network Access Identifier), a request value and a response value, to an AAA server 105 located in the IPv4 Internet 104. A request is made as to whether the terminal subscriber, which is classified as an internet access permission (S104).

After the step S104, the AAA server 105 determines the authentication and authorization of the network access identification terminal by CHAP as a response to the access request, and when the result is authenticated, transmits an access authorization message to the network server 103. (S105), the network server 103 confirms that the terminal is authenticated by sending a CHAP success message to the terminal (S106).

Thereafter, the network server 103 and the terminal 101 assign an IP address to be assigned to the terminal 101 using IPCP (S107), and after the step S107, the network server 103 of the terminal 101 is connected to the PPP link. Send and receive Internet user data (IPv4 datagrams).

FIG. 5 is a diagram illustrating a network for providing a parallel service between IPv4 and IPv6 by constructing an IPv6 next-generation Internet having a 128-bit IP address as a wireless Internet is activated.

Referring to FIG. 5, the network server 203 may connect and service the Internet of the IPv4 213 and the next-generation Internet of the IPv6 223 simultaneously.

For this connection, the terminal is composed of a terminal (IPv4 MS) 201 having only the existing IPv4 Internet network access protocol, and a terminal (IPv4 / IPv6 MS) capable of selectively connecting IPv6 and IPv4. 211.

When the dual stack terminal 211 wants to access the IPv6 next generation Internet, the terminal 211 and the network server 203 allocate an IPv6 IP address and deliver an IPv6 datagram using the IPv6CP protocol shown in Table 1.

Since the base station system network 202 provides only a bearer channel for the PPP link data transfer between the terminal 211 and the network server 203, the base station system network 202 operates regardless of the IP versions IPv4 and IPv6 of the IP datagram.

The AAA server 210 operates as a home AAA for all terminals 201 and 211 regardless of the IP version of the terminal and is directly connected to the network server 203 so that the network access identifier (NAI) is independent of the IPv4 Internet or the IPv6 next-generation Internet. It is an AAA that performs authentication, authorization, and billing.

The AAAv4 205 is located in the IPv4 Internet 204 to operate as a home AAA server of the existing IPv4 terminal 201, and the AAAv6 215 is located in the IPv6 next-generation Internet 214 and is a terminal of IPv4 / IPv6 ( Act as the home AAA server.

Based on the existing PPP link protocol type defined in FIG. 2, the basic negotiation procedure when providing parallel services will be described with reference to FIGS. 5 and 6 as follows.

When the dual IP version (Pv4 / IPv6) terminal 211 wishes to access the IPv6 next-generation Internet 214 to the IPv6 223, it requests the packet service to the base station system network 202, and the base station system network 202 By establishing a bearer channel for the PPP link between the terminal 211 and the network server 203, a PPP link by the LCP is established between the network server 203 and the terminal (S201).

Thereafter, the network server 203 transmits a CHAP request message to the terminal 211 for authentication of the terminal 221 (S202), and the terminal 221 transmits a CHAP response message in response to the request message to the network server 203. (S203).

Here, as described above, the message setting steps S201 to S203 transmitted between the terminal 211 and the network server 203 may include information on whether the terminal 211 intends to use IPv4 or IPv6. It can be seen that the classification is not possible with the PPP protocol type.

To this end, when the network server 203 simultaneously services the network 204 of IPv4 and the network 214 of IPv6 as shown in FIG. 5, a method for authenticating a terminal connection by receiving a result of CHAP will be described later. You can choose one of three ways.

First, when the terminal 211 wants to access according to the IP type, the network access identifier is used according to IPv4 and IPv6, and the network server 203 is based on the NAI's home AAA server (AAAv4, AAAv6). Send each access request separately.

Second, there is a method in which an operator does not distinguish AAA servers according to IP versions by placing AAA 210 that does not distinguish home AAAs (AAAv4 and AAAv6) according to IP versions of terminals 211.

Third, the terminal 211 uses a method of registering with the home AAA server 205 or 215 according to the IP version that is mainly used without distinguishing the network access identifier according to the use of IPv4 and IPv6, and the network server 203 Randomly selects each of the network AAA servers 205 and 215 of the IPv4 213 and the IPv6 223 to request an access request for the terminal. At this time, there is a method of finding and relaying the home AAA server 205 or 215 through the network access identifier between the AAA servers 205 and 215.

Among the above three methods, when the home AAA of the terminal 211 is AAAv6 215, the network server 203 is homed from the network access identifier of the terminal 211 when the home AAA of the terminal 211 is AAAv6 215. The access request is randomly sent to the AAAv4 server 205 of the IPv4 Internet 204 without distinguishing the domains (S204).

The AAAv4 server 205 then recognizes that the home AAA is AAAv6 from the network access identifier and sends an access request message to the AAAv6 server 215 located on the IPv6 Internet 214 (S205), and the AAAv6 server 215 accesses the access. The acknowledgment message is returned to the AAAv4 server 205 (S206).

Then, the AAAv4 server 205 transmits an access authorization message back to the network server 203 (S207), and the network server 203 transmits a CHAP success message to the terminal 211 to permit network connection (S208). ).

Subsequently, the terminal 211 and the network server 203 can know that the IPv6CP is connected to the IPv6 214 by assigning an IPv6 address to the terminal 211 (S209).

Here, in step S204 of relaying in the parallel service as described above, the network server 203 randomly selects the home AAA server 210 so that the home AAAv6 server 225 is directly selected when the AAAv6 server 215 is directly selected. Since the access request message is sent, the relaying process can be omitted.

However, a third method of relaying to a home AAA server when performing a dual IP version parallel service is that the AAAv4 server 205 located in the IPv4 Internet 204 recognizes and communicates with the AAAv6 server 215 located in the Ipv6 Internet 214. There are disadvantages in that a complicated problem occurs, such as passing through a network address translator / protocol translator (NAT / PT) 220 of the IPv4 Internet 204.

In the case of the first method, the network access identifier is separately provided according to the IP network version to be used for one terminal 211, and the network server 203 analyzes the network access identifier to select the IP Internet. Since connection authentication is required to the AAA servers 205 and 215 of the Internet 204 and 214, there is an operational problem that an operator must manage a plurality of network access managers.

In the second method, both IPv4 and IPv6 must be managed with one network access identifier, and in order to effectively support push services, the AAA server 210 eventually uses the IPv4 Internet 204 and the IPv6 Internet. Since it is necessary to connect 214 at the same time, there is no meaning of a separate network.

Therefore, in the parallel service of the dual IP version as described above, a problem caused by not distinguishing the IP network version that the terminal intends to use in the link establishment step by the LCP and the authentication step by the CHAP / PAP between the network server and the terminal. to be.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and when a dual IP version of a parallel service is used, a terminal uses one network access identifier regardless of the IP network version, and the IP version 4 and the IP version 6 home on the Internet. It is an object of the present invention to provide a protocol identifier service method for each IP version type in a PPP link configured to individually configure a server so that the IP address and billing assigned to the terminal can be independently performed when the terminal visits the network.

The purpose of the present invention is to provide a protocol identifier service method for each IP version type in a PPP link that provides a protocol identifier that distinguishes an IP version 6 link control protocol for an IP version 4 in the link establishment step between a terminal and a network server. have.

In the authentication phase between the network servers of the terminal, the protocol identifier for distinguishing the IP version 6 PAP protocol separately from the IP version 4 and the protocol identifier for distinguishing the IP version 6 CHAP protocol from the IP version 4 shall be provided. The purpose is to provide a protocol identifier service method for each IP version type in a PPP link.

In order to achieve the above object, an IP version type protocol identifier service method in a PPP link according to the present invention,

Encapsulating the signaling information of the protocol field of the PPP frame format of the PPP link protocol by dividing the dual IP version protocol identifier values, and providing the IP network service of the terminal according to the separated protocol identifier corresponding to the dual IP version. It features.

Preferably, the distinguished protocol identifiers in IP version 6 and IP version 4 of the dual IP version are separate PPP links of IPv4 and IPv6, respective LCP protocols for link establishment, respective PAP protocol information identifiers for authentication, and CHAP. The protocol identifier of, and each IP datagram and each IPCP protocol identifier is characterized by distinguishing according to the IP version.

In detail, the LCP information for IP version 6 of the dual IP version is LCP protocol identifier 0xc041, which is distinguished from the previously defined 0xc021, and the PAP protocol information for IP version 6, which is distinguished from the previously defined 0xc023. The identifier is 0xc043, and the CHAP protocol information for IP version 6 is characterized by a CHAP protocol identifier 0xc243 which is distinguished from the protocol identifier 0xc223 previously defined.

According to another embodiment of the present invention, a method for providing a protocol identifier service according to an IP version type in a PPP link includes a PPP link when a terminal accessing a network server through a base station system receives a link for an IP version 6 service. It is characterized by providing a PPP frame protocol service that distinguishes a protocol identifier according to link establishment and authentication from a predefined LCP, PAP, and CHAP signaling information protocol.

Preferably, before the IPCP protocol data setting step of network control such as address assignment of the network layer to be used between the terminal and the network server, the IP address is divided and the access request message is transmitted to the corresponding home AAA server. Characterized in that.

The protocol identifier service method for each IP version type in a PPP link according to an embodiment of the present invention,

(a) accessing a network server from a terminal using the PPP link protocol for IP version 6 using the PPP link protocol;

(b) recognizing, by the network server, a PPP frame protocol that distinguishes LCP of IPv6, PAP of IPv6, and CHAP of IPv6 from predefined LCP, PAP, and CHAP signaling;

(c) transmitting an access request message to a network AAA server having a different IP version for a terminal to establish IPv4 and IPv6 PPP link settings;

(d) assigning different IP addresses to the terminal according to a successful access request to the AAA server of different IP versions.

Referring to the accompanying drawings, a method for identifying a protocol for dual IP version types in a PPP link according to an embodiment of the present invention as described above is as follows.

FIG. 7 is a table illustrating protocol identification values for IP version types in a PPP link according to an embodiment of the present invention. FIG. 8 is a diagram illustrating a configuration of a dual IP version serving node and a wireless Internet network according to an embodiment of the present invention. 7 is a flowchart illustrating a simple IP packet setup, authentication, and communication of the dual stack terminal according to the embodiment of FIG. 7, and FIG. 10 is a diagram illustrating a protocol stack of the dual stack terminal according to the embodiment of the present invention.

Referring to FIGS. 7 and 8, the terminal 321 is a terminal having a dual IP version stack as shown in FIG. 10 capable of simultaneously using IPv4 and IPv6. The cellular, PCS, and IMT interworking with the network server 303 may be described. Mobile stations such as desktop PCs, laptops, etc., using a 2000 terminal or a dial-up modem.

Then, the terminal 321 is a separate PPP link of IPv4 and IPv6, the IPv4 PPP and IPv6 PPP as shown in Figure 7, respectively LCP protocol (0xc021, 0xc041), PAP (0xc023, 0xc043), CHAP protocol identifier (0xc223, 0xc243) ), And IP datagrams (0x0021, 0x0057) and IPCP (0x8021, 0x8057), respectively.

Specifically, as the value of the protocol field of the PPP frame format of the PPP link protocol (RFC 1661), when encapsulating LCP, PAP, and CHAP signaling information for IPv6, the LCP of IPv4 previously defined in IPv4. By encapsulating signaling information of PAP of IPv4 and CHAP of IPv4, these are distinguished from each other and defined by different protocol identifier values.

The LCP information protocol for IPv4 is 0xc021, the LCP information protocol for IPv6 is 0xc041, the PAP information protocol for IPv4 is 0xc023, and the PAP information protocol for IPv6 is 0xc043. do.

The CHAP information protocol for IPv4 is 0xc223, the corresponding CHAP information protocol for IPv6 is 0xc243, and the datagram protocol (IP) for IPv4 is 0x0021, and the corresponding datagram protocol for IPv6. (IPv6) is set to 0x0057.

In addition, a control protocol (IPCP) for IPv4 is used as 0x8021 and a control protocol (IPv6CP) for IPv6 is used as 0x8057.

Such IPv4 protocol identifiers are defined previously, and the IPv6 protocol identifiers are additionally defined protocol identifiers in the link establishment step and the authentication step.

In addition, the terminal 321 may use the same network access identifier (NAI) according to IPv4 / IPv6 or may be used separately. The terminal 321 simultaneously establishes IPv4 and IPv6 PPP links with the network server 303 and simultaneously communicates with an IPv4 address and an IPv6 address.

The network server 303 supports the PPP link protocol type defined in FIG. 7, and has a function of distinguishing and processing an IP version required by the terminal 321 from a protocol type for distinguishing v4LCP and v6LCP in the LCP setting step. That is, the network server 303 is a PDSN serving an internet connection of a mobile communication terminal, or a RAS (Remote Access Server) terminating a PPP dial-up service and a PPP link through a gateway GSN (GGSN) or a PSTN. ), NAS (Network Access Server).

The network server 303 sets the PPP link of the IPv4 and the PPP link of the IPv6 separately, and simultaneously connects the IPv4 Internet 304 and the IPv6 Internet 314, that is, according to the IP version link type of the terminal 321. The IP packet of the terminal 321 is routed according to the required IP version.

8 and 9, when the terminal 321 having the dual IP version stack (IPv4 / IPv6, PPP IPv4 / PPP IPv6) as shown in FIG. 10 wants to connect the IPv6 next-generation Internet 314 to IPv6, The base station system network 302 requests packet service, and the base station system network 302 establishes a bearer channel for the PPP link between the terminal 321 and the network server 303.

If the terminal 321 requests PPP link establishment using a version 6 (v6) LCP, the network server 303 recognizes that it is a version 6 protocol (ie, an IPv6 LCP), and the terminal 321 and the network server. Link setting by version 6 is made between 303 (S301).

In addition, the network server 303 transmits a v6CHAP request message to the terminal 321 for authentication of the terminal 321 (S302), and the terminal 321 transmits a v6 CHAP response message to the network server 303 ( S303).                     

Then, since the network server 303 recognizes that the terminal 321 intends to use Ipv6 from the LCP and CHAP by v6, the network server 303 transmits an access request message to the AAAv6 315 of the Ipv6 Internet 314 (S304). ).

The AAAv6 server 315 authenticates the network access identifier of the terminal 321 and transmits an access authorization to the network server 303 (S305), and the network server 303 sends a CHAP success message to the terminal 321. Answer (S306).

The terminal 321 and the network server 303 allocate an IPv6 address to be used by the terminal 321 through IPv6CP (S307).

At this time, the network server 303 and the AAAv6 server 315 exchange a message for the start of charging (S308), the AAAv6 server 315 recognizes the IPv6 address assigned to the terminal 321.

Thereafter, the terminal 321 communicates with the CN (correspondent node) 316 of the IPv6 Internet 314 using the IPv6 address (S309).

The terminal 321 having the dual IP version (IPv4 / IPv6) stack is allocated to the Ipv6 address by the above process and registered in the network server 303 to communicate with the IPv6 Internet 314. .

In this state, when a PPP link is to be established and registered with the IPV4 address in the network server 303 to access the Internet 304 of IPv4, the network server 303 simultaneously registers IPv6 and IPv4 for one terminal 321. It can be registered, and the establishment and authentication of PPP link for IPv4, IP address allocation, etc. can be performed continuously as shown in FIG.

When the terminal 321 in the state capable of communicating with the IPv6 Internet 314 requests the PPP link establishment by the v4 LCP, the network server 303 recognizes that it is a v4 protocol and the terminal 321 and the network server ( 303) link setting by v4 is made (S310).

In addition, the network server 303 transmits a v4CHAP request message to the terminal 321 for authentication of the terminal 321 (S311), and the terminal 321 transmits a v4CHAP response message to the network server 303 (S312). ).

Since the network server 303 recognizes that the terminal 321 intends to use IPv4 from the LCP and CHAP by v4, the network server 303 transmits an access request message to the AAAv4 305 located in the IPv4 Internet 304 (S313). .

Then, the AAAv4 server 305 authenticates the network access identifier of the terminal 321 and transmits an access authorization message to the network server 303 (S314), and the network server 303 succeeds in CHAP to the terminal 321. Reply with a message (S315).

At this time, the terminal 321 and the network server 303 assigns an IPv4 address to be used by the terminal 321 by IPCP (S316), the network server 303 and the AAAv4 server 305 at the accounting start. Exchange the message (S317), the AAAv4 server 305 recognizes the IPv4 address assigned to the terminal 321.

Then, the terminal 321 communicates with the IP host 306 of the Ipv4 Internet 304 by using the IPv4 address (S318).                     

The terminal 321 having the dual IP version (IPv4 / IPv6) stack as described above can be registered to the network server 303 by assigning the IPv4 and IPv6 addresses simultaneously to access the two networks, and the network server 303 and The terminal 321 may transmit / receive and route the IPv4 datagram and the IPv6 datagram by using the protocol types 0x0021 and 0x0057 of FIG. 7, thereby enabling simultaneous access service.

When the network server 303 intends to use the IPv6 link in the terminal 211, the network server 303 recognizes the IPv4 and IPv6 PPP link settings by using the protocol identifier as described above, and distinguishes them in the previous step of the IPCP protocol setting. In the authentication phase, access request messages can be sent to the home AAA server located in each IPv4 network and the IPv6 network according to the IP version required by the terminal. Therefore, the IPv4 address and the IPv6 address can be used simultaneously.

As described above, according to the protocol identification method for each type of dual IP version in the PPP link according to the present invention, it is possible to simultaneously provide IPv4 and IPv6 parallel services of a terminal simultaneously accessing an IPv4 and IPv6 network from a network server. There is.

In addition, the IP version type (IPv4, IPv6) required by the terminal is distinguished during the establishment of the PPP link, so it is easy to select an AAA server for authentication of the terminal, and the AAA server is installed in the IPv4 network and the IPv6 network. By managing the network access identifier for the terminal assigned the IP address of the network and the assigned IP address, it is possible to easily manage the service based on the assigned IP address.

In addition, since the AAA server that performs authentication and billing of the terminal does not need to interwork with an IPv4 network and IPv6, there is an effect of easily building an IPv6 network.

In addition, the terminal can be used to receive the IPv4 address and IPv6 address at the same time, there is an effect that can use a better service.

Claims (11)

PPP that encapsulates signaling information of the protocol field of the PPP frame format of the PPP link protocol by dividing the dual IP version protocol identifier values, and provides an IP network service of the terminal according to the separated protocol identifier corresponding to the dual IP version. Protocol identification method by IP version type on a link. The method of claim 1, The distinguished protocol identifiers in IP version 6 and IP version 4 of the dual IP version are separate PPP links of IPv4 and IPv6, respective LCP protocols for link establishment, respective PAP protocol information identifiers for authentication, or protocol identifiers of CHAP. And distinguishing each IP datagram and each IPCP protocol identifier. The method of claim 1, LCP information for the IP version 6 of the dual IP version of the IP version type protocol identification method for the PPP link, characterized in that the LCP protocol identifier distinguished from the predefined 0xc021. The method of claim 1, The PAP protocol information for IP version 6 of the dual IP version is a PAP protocol identifier distinguished from the previously defined 0xc023. The method of claim 1, The CHAP protocol information for the IP version 6 of the dual IP version is a CHAP protocol identifier distinguished from the protocol identifier 0xc223 previously defined. When using the PPP link to receive the service for the IP version 6 link with the terminal accessing the network server through the base station system, the protocol identifier according to the PPP link establishment and authentication is defined with the LCP, PAP, CHAP signaling information protocol. Protocol identification method for each IP version type in a PPP link, characterized by providing a PPP frame protocol service for distinguishing. The method of claim 6, The method of identifying a protocol for each IP version type in a PPP link characterized by dividing a link establishment protocol and an authorization processing protocol of IP version 4 and IP version 6 of the terminal by a protocol identifier value. The method of claim 6, Before the IPCP (Internet Protocol Control Protocol) protocol data setting step of network control such as address assignment of the network layer to be used between the terminal and the network server, each IP version is divided and an access request message is transmitted to the corresponding home AAA server. A protocol identification method for each IP version type in a PPP link. The method of claim 6, The network server uses IP v6 and provides a dual IP version in parallel to a mobile station including a mobile communication terminal interworking with the network server and a communication device using a dial-up modem. Type identification protocol. The method of claim 8, The terminal is assigned dual IP addresses through a server including a serving PDSN supporting the Internet connection of the mobile communication terminal, a dial service via GGSN, PSTN, and a RAS or NAS terminating the PPP link as a gateway. Protocol identification method for each IP version type in a PPP link. Accessing a network server from a terminal using the PPP link protocol for IP version 6 using the PPP link protocol; Recognizing and processing by the network server a PPP frame protocol that distinguishes LCP of IPv6, PAP of IPv6, and CHAP of IPv6 from predefined LCP, PAP, and CHAP signaling; Transmitting an access request message to a network AAA server having a different IP version for a terminal to establish IPv4 and IPv6 PPP link; And assigning different IP addresses to the terminal according to the success of the access request to the AAA server of the different IP versions.

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