KR20100118407A - Apparatus system and method for providing packet service using mobile ip - Google Patents

Abstract

PURPOSE: A device for proving packet service using a mobile IP, and a system and a method thereof are provided to supply a packet service through an optimum routing in a mobile IPv4, thereby reducing the load of the net. CONSTITUTION: A packet service providing device(300) includes an random IP(Internet Protocol) address allocation unit(320), an address changing unit(330), and a communication unit(310). The temporary IP address allocation unit allocates one among a plurality of different IP addresses to the temporary IP address of a mobile terminal. The IP address changing unit changes a terminal IP address within a header of a packet data transmitted to the mobile terminal into the temporary IP address. The communication unit transmits the packet data to a first external device.

Description

Apparatus system and method for providing packet service using mobile IP}

The present invention relates to an apparatus, a system and a method for providing a packet service using mobile IP, and more particularly, to an apparatus, a system and a method for providing a packet service through optimized routing in Mobile IPv4.

The mobile communication system has been developed through the first generation analog Advanced Mobile Phone Systems (AMPS) method, the second generation cellular and personal communication service (PCS) method, and recently the third generation mobile communication system. IMT-2000 (International Mobile Telecommunication-2000) system is popular. IMT-2000 was developed for high speed data transmission and personal mobility guarantee to ensure mobility between countries by integrating systems of countries using different radio access standards. The IMT-2000 has been developed separately from a synchronous CDMA (Code Division Multiple Access) 2000 system centered on Korea and the United States, and a Universal Mobile Telecommunication Services (UMTS) or WCDMA system centered on Europe.

WCDMA system is leading the standardization in 3GPP (3 Generation Partnership Project). It is an asynchronous communication system developed by combining CDMA technology with European GSM method. It integrates various systems such as cellular, wireless telephone, wireless LAN and satellite communication. And provides international roaming to make calls anywhere in the world. In addition, it is possible to download a multimedia data, such as voice and image data, VOD streaming that can be played in real time, and MMS that can send and receive video files with a mobile phone is possible.

In addition, the high-speed downlink packet access (HSDPA) method, called 3.5th generation mobile communication service, is a core technology of Release 5 announced by the 3rd Generation Partnership Project (3GPP) in March 2002. It is a technology that can be provided. The HSDPA method can provide a service by improving the WCDMA system without additional investment in the base station.

The development of such a mobile communication system is combined with the existing wire-based infrastructure, there is a need to ensure mobility across wired and wireless. In order to guarantee such mobility, a method using mobile IP is mainly used, and is also used for roaming heterogeneous manganese. However, in order to provide mobile IP, a mobile IP stack that performs a mobile IP agent function interworking with a network had to be mounted in the mobile terminal. However, as the mobile IP stack is mounted on the mobile terminal with excessive load, the cost is increased, so that the mobile mobile IP can accommodate mobility in the network without implementing a separate stack on the mobile terminal. There is a discussion about the method.

Currently, in case of Mobile IPv6, there is a Routing Optimization method, and after setting up a MIP (Mobile IP) call, packet data is delivered with an optimal routing path between a mobile terminal and an application server. However, there is no optimized routing method in Mobile IPv4, so there is an overhead called tunneling.

Therefore, there is a need for a method capable of providing an optimized routing method for mobile IPv4.

An object of the present invention is to provide a packet service (i.e., packet data) through optimized routing in mobile IPv4.

The objects of the present invention are not limited to the above-mentioned objects, and other objects that are not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, the packet service providing apparatus using a mobile IP according to an embodiment of the present invention, a temporary IP address allocator for allocating one of a plurality of different IP addresses as a temporary IP address of the mobile terminal, An IP address changing unit for changing the terminal IP address included in the header of the packet data transmitted by the mobile terminal to the temporary IP address, and a communication unit transmitting the packet data including the temporary IP address to the first external device. do.

In addition, the packet service providing system using a mobile IP according to an embodiment of the present invention, the mobile terminal for transmitting the packet data, and assigns one of a plurality of different IP addresses as the temporary IP address of the mobile terminal, A packet service providing apparatus for transmitting a packet data including a temporary IP address after changing a terminal IP address included in a header of transmitted packet data to the temporary IP address, and receiving the packet data transmitted from the packet service providing apparatus It includes a first external device.

In addition, the packet service providing method using a mobile IP according to an embodiment of the present invention, the step of assigning one of a plurality of different IP addresses as a temporary IP address of the mobile terminal, the packet data transmitted by the mobile terminal Changing the terminal IP address included in the header to the temporary IP address, and transmitting the packet data including the temporary IP address to the first external device.

Specific details of other embodiments are included in the detailed description and the drawings.

Advantages and features of the present invention and methods for achieving them will be apparent with reference to the embodiments described below in detail with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but can be implemented in various different forms, and only the embodiments make the disclosure of the present invention complete, and the general knowledge in the art to which the present invention belongs. It is provided to fully inform the person having the scope of the invention, which is defined only by the scope of the claims. Like reference numerals refer to like elements throughout.

According to the packet service providing apparatus, system and method using the mobile IP of the present invention as described above has one or more of the following effects.

First, by providing packet services (ie, packet data) through optimized routing in mobile IPv4, there is an advantage of reducing the load on the network.

Second, by providing a packet service (that is, packet data) through optimized routing in mobile IPv4, there is an advantage that can effectively use a variety of wireless Internet services between heterogeneous networks.

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

1 is a call flow diagram illustrating a dynamic home agent allocation method for a proxy mobile IP in a WCDMA network.

The mobile terminal 100 performs a wireless network connection by establishing a traffic channel with the base station apparatus 200 through the wireless access network (S110).

When the mobile terminal 100 transmits an PDP context activation request message (Activate PDP Context Request) to the base station apparatus 200 (S115), the base station apparatus 200 sends a PDP context creation request message (Create PDP Context Request) to the GGSN ( 300 is delivered to (S120). In this case, since the mobile terminal 100 is in an initial connection state rather than a handover state, the IP option fields included in the PDP context activation request message and the PDP context creation request message (Create PDP Context Request) are not included. The initialization status value (ie 0.0.0.0) or the IP option field may not be included (ie null).

Meanwhile, the GGSN 300 transmits an IP access request message (Access Request) of the mobile terminal 100 to the subscriber information management server (hereinafter referred to as AAA) 400 (S125). Receiving an IP access request message (Access Request) AAA (400) checks the subscriber information of the mobile terminal 100 to perform the authentication process, and the authentication process result information and subscriber information of the mobile terminal 100 The IP access response message (Access Response) including the transmission to the GGSN (300) (S130).

In addition, the GGSN 300 checks the IP option field included in the PDP context request message (Create PDP Context Request) received in step S120 described above. As a result of the check, assuming that the mobile terminal 100 is not in the handover state, the IP option field may be initialized (ie, 0.0.0.0) or the IP option field may not be included. In this case, the GGSN 300 determines that the mobile terminal 100 is in an initial connection state, and the mobile terminal 100 initially connects to notify the home agent 500 (hereinafter, referred to as HA). The information indicating the status is transmitted to the HA 500 in an Agent Solicitation Request (S135). That is, the value 0 indicating the initial connection state of the mobile terminal 100 is set and sent to the Reserved field in the Agent Solicitation Request message. If the initial connection state is not set, the value 1 is sent. .

In contrast, the HA 500 determines that the mobile terminal 100 is in an initial connection state because the mobile terminal 100 is not in a handover state, and the HA 500 is suitable for the connection state of the mobile terminal 100 among at least one HA managed by the HA 500. By selecting it is recommended to the GGSN (300). Here, in detail, the GGSN 300 responds to the GGSN 300 by loading information on the HA with the smallest load in an Agent Advertisement Response (S140).

The GGSN 300 transmits a mobile IP registration request message to the recommended HA 500 (S145). At this time, the mobile IP registration request message (Reverse Tunneling) option is set and includes the CoA of the GGSN (300).

Upon receiving the Mobile IP Registration Request message, the HA 500 selects a specific IP address from its own IP address pool and includes the selected IP address in the Mobile IP Registration Response message. In response to the GGSN (300) (S150).

The GGSN 300 that receives the Mobile IP Registration Response message including the selected IP address loads the IP address obtained through the S150 process in a PDP Context Response message and creates a base station. It transmits to the device 200 (S155). The base station apparatus 200 having received this is loaded on the PDP context activation message (Activate PDP Context Response) and transmitted to the mobile terminal 100 again (S160).

After going through the above-described processes, the mobile terminal 100 sets the selected IP address as its IP address, and the HA 500 through the GGSN 300 in which the HA 500 and IP in IP tunneling (reverse tunneling) are set. The packet data is transmitted and received (S165).

However, there is a problem in that an overhead called tunneling exists between the GGSN 300 and the HA 500 in order to transmit and receive packet data through the above-described process. That is, in case of Mobile IPv6, there is a route optimization method, and after MIP (Mobile IP) call setup, the mobile terminal 100 and the application server 600 are transferred to an optimal routing path. There is a method, but there is no such optimized routing method in Mobile IPv4.

In view of the above problems, the following describes an apparatus and method for implementing routing optimization in mobile IPv4 according to an embodiment of the present invention.

2 is a diagram illustrating a packet service providing system using mobile IP according to an embodiment of the present invention.

As shown, a packet service providing system using mobile IP includes a base station apparatus 200 including a mobile terminal 100, a base station 210 and a base station controller 220, and a gateway GPRS support node (GGSN). Node) 300, Authentication Authorization Accounting (AAA) 400, a first external device 600, and a second external device 500.

The mobile terminal 100 receives a signal transmitted from the base station apparatus 200 in a serving cell, and wirelessly transmits a signal according to voice or data input from the subscriber to the base station apparatus 200. For transmitting and receiving packet data, the mobile terminal 100 uses a wireless application protocol (WAP), which is a wireless Internet access protocol, a Microsoft Internet Exporer (MIE) based on HTML using an HTTP protocol, and a handheld device transmission protocol (HDPT). It can also perform data transmission and reception to external IP network by using Handheld Device Transport Protocol).

The base station apparatus 200 serves as a radio access network (RAN), which guarantees mobility of the mobile terminal 100, and performs hand-off and radio resource management functions.

The base station 210 performs a radio access termination function with a subscriber station conforming to the 3rd Generation Partnership Project (3GPP) radio access standard. In this case, Node B plays a role and information transmitted from the physical layer of the mobile terminal is used as an uplink. And transmits data to the mobile terminal through the downlink, and serves as an access point for the mobile terminal, thereby transmitting and receiving voice, video, and data traffic. In addition, location registration is performed to identify the location of a terminal located in a cell unit and exists in a cell area under its control and allocates a radio channel for voice and data communication to the terminal.

The base station controller (RNC) 220 manages wired and wireless channels, protocol matching with the mobile terminal 100, protocol matching between base stations, soft handoff processing, protocol matching with the core network, GPRS (General Packet Radio Service) connection, and failure. It is responsible for the functions required for wireless call processing such as management, system loading, and so on. Here, GPRS supports a data rate of 384 Kbps, provides a multimedia mail, and is an asynchronous communication system that maximizes the efficiency of transmission lines by packet data transmission.

Meanwhile, the base station apparatus 200 may further include a Serving GPRS Support Node (SGSN) (not shown). In general, the SGSN is an Asynchronous Transfer Mode (ATM) based switch and routing for GPRS service. It is a node having a hardware structure for providing a connection and delivering packet data with the mobile terminal 100 in a service area. In addition, SGSN (not shown) performs a PDP context activation process to establish a session for packet data communication with the mobile terminal 100, SGSN activates a PDP context request message to the mobile terminal 100 (Activate PDP Context Request) ), And transmits a Create PDP Context Request message to the GGSN 300.

The Gateway GPRS Support Node (GGSN) 300 is a node that manages a connection function between a GPRS backbone network and an external packet data network (that is, an IP network). It functions as a routing process and provides an interface for connecting the core network with the external packet data network. In addition, the GPRS packet received from SGSN (not shown) is converted into an appropriate packet data protocol (PDP) format (for example, IP.X.25) and transmitted, and the PDP address of the received packet data is transferred to the mobile terminal 100. Converts to an IP address.

In addition, the GGSN 300 receives a Create PDP Context Request message including or without an IP option field from an SGSN (not shown) in an initialization state, and the IP address of the mobile terminal 100 is determined. A session is established with the mobile terminal 100 by sending the included PDP context response message (Create PDP Context Response) to the SGSN. Here, the GGSN 300 may include a terminal IP address and an IMSI value that is an identification number of the mobile terminal 100 in its database table.

In addition, the GGSN 300 according to an embodiment of the present invention assigns one of a plurality of different IP addresses as a temporary IP address of the mobile terminal 100. Here, the plurality of different IP addresses refers to IP addresses available in the IP pool of the GGSN 300. That is, the GGSN 300 may allocate another temporary IP address in addition to the session information of the mobile terminal 100.

In addition, the GGSN 300 changes the terminal IP address included in the header of the packet data transmitted by the mobile terminal 100 to the temporary IP address using the NAI information provided from the HA 500, and the HA 500. Based on the address of the first external device 600 received from the first external device 600, the packet data including the temporary IP address is transmitted to the first external device 600, thereby allowing direct routing with the first external device 600. . Here, the NAI (Network Access Identifier) refers to a key value that makes the mobile terminal 100 recognize the GGSN 300.

The AAA 400 performs subscriber management tasks such as subscriber access rights and authentication for the mobile terminal 100. In addition, it manages the subscription information for the proxy mobile IP service, and provides the subscription information to the GGSN 300 when performing authentication with the GGSN (300).

The second external device 500 registers mobility management and home address of the mobile terminal 100. Here, the second external device may be understood to perform the same role as the home agent (HA), hereinafter referred to as 'HA'.

In addition, the HA 500 includes a binding information list including a home address of the mobile terminal 100 and mapping information of a care of address (hereinafter referred to as CoA) of the GGSN 300 connected to the mobile terminal 100. Manage it. Here, the binding information is information including a load of each home agent, a pool of IP addresses managed by the HA 500, and a CoA of the GGSN 300.

In addition, the HA 500 detects an address and NAI information of the first external device 600 based on the packet data transmitted and received between the mobile terminal 100 and the first external device 600 to the GGSN 300. to provide. Here, the GGSN 300 can perform optimal routing through the address and NAI information of the first external device 600 provided by the HA 500.

The first external device 600 transmits and receives specific packet data with the mobile terminal 100, and serves to provide the packet data requested from the mobile terminal 100. Here, the first external device may be understood as performing the same role as the application server, and will be referred to as an "application server".

In addition, the application server 600 may directly route with the GGSN 300 by transmitting packet data to the temporary IP address changed by the GGSN 300.

3 is a block diagram of a packet service providing apparatus using mobile IP according to an embodiment of the present invention. Here, the packet service providing apparatus may be understood as the GGSN 300. In addition, the packet service providing apparatus 300 is an apparatus for implementing routing optimization in mobile IPv4.

As illustrated, the packet service providing apparatus 300 includes a communication unit 310, a temporary IP address allocating unit 320, an IP address changing unit 330, a storage unit 340, and a control unit 350. .

In this case, the term '~ part' used in the present embodiment refers to software or a hardware component such as an FPGA or an ASIC, and '~ part' performs certain roles. However, '~' is not meant to be limited to software or hardware. '~ Portion' may be configured to be in an addressable storage medium or may be configured to play one or more processors. Thus, as an example, '~' means components such as software components, object-oriented software components, class components, and task components, and processes, functions, properties, procedures, and the like. Subroutines, segments of program code, drivers, firmware, microcode, circuits, data, databases, data structures, tables, arrays, and variables. The functionality provided within the components and the 'parts' may be combined into a smaller number of components and the 'parts' or further separated into additional components and the 'parts'.

The communication unit 310 receives the address and the NAI information of the application server 600 transmitted from the HA 500, the mobile terminal 100 and the application server 600 Send a packet service.

In addition, the communication unit 310 transmits the packet data transmitted from the mobile terminal 100 to the application server 600, and receives the packet data transmitted from the application server 600.

The temporary IP address allocator 320 allocates one of a plurality of different IP addresses as a temporary IP address of the mobile terminal 100. Here, the plurality of different IP addresses may refer to IP addresses available in an IP pool of the GGSN 300, and the temporary IP address may include the packet service providing apparatus 300 in addition to the session information of the mobile terminal 100. The IP address used temporarily by.

The IP address changing unit 330 changes the terminal IP address included in the header of the packet data transmitted from the mobile terminal 100 to the temporary IP address using the NAI information provided from the HA 500. Here, the GGSN 300 can directly route with the application server 600 by changing the address included in the header of the packet to a temporary IP address.

In addition, the IP address changing unit 330 changes the temporary IP address included in the header of the packet data transmitted from the application server 600 to the original terminal IP address. Here, the IP address changing unit 330 changes the IP address using the routing table stored in the storage unit 340.

The storage unit 340 stores the temporary IP address allocated by the temporary IP address allocator 320 and stores the address and NAI information of the application server 600 provided from the HA 500. Here, the storage unit 340 stores a routing table in which the original IP address and the temporary IP address of the mobile terminal 100 are mapped.

The controller 350 controls operations of the respective functional blocks 310 to 340 constituting the packet service providing apparatus 300 using the mobile IP.

4 is a flowchart illustrating a packet service providing method using mobile IP according to an embodiment of the present invention.

First, the mobile terminal 100 establishes a traffic channel with the base station apparatus 200 through a wireless access network to perform a wireless network access (S410).

Next, when the mobile terminal 100 transmits an PDP context activation request message (Activate PDP Context Request) to the base station apparatus 200 (S415), the base station apparatus 200 generates a PDP context creation request message (Create PDP Context Request). It will be delivered to the GGSN (300) (S420).

On the other hand, the GGSN 300 transmits an IP access request message (Access Request) of the mobile terminal 100 to the AAA (400) (S425). Next, the AAA 400 receiving the IP access request message (Access Request) checks the subscriber information of the mobile terminal 100 to perform authentication processing, and the authentication process result information and the subscriber of the mobile terminal 100. An IP access response message (Access Response) including the information is transmitted to the GGSN 300 (S430).

Next, the GGSN 300 transmits information indicating that the mobile terminal 100 is in an initial connection state to the HA 500 in an Agent Solicitation Request (S435).

Next, the HA 500 selects a HA suitable for the connection state of the mobile terminal 100 and responds to the GGSN 300 by putting information on the corresponding HA in an Agent Advertisement Response (S440). Accordingly, the GGSN 300 transmits a mobile IP registration request message to the HA 500 (S445).

Next, the HA 500 receiving the Mobile IP Registration Request message selects a specific IP address from its own IP address pool and moves the selected IP address to the Mobile IP Registration Response message. ) And responds to the GGSN (300) (S450).

Next, the GGSN 300 that receives the Mobile IP Registration Response message including the selected IP address, loads the acquired IP address into a PDP context response message and creates a base station apparatus ( 200) (S455).

Next, the base station apparatus 200 transfers the obtained IP address to the PDP context activation response message (Activate PDP Context Response) to the mobile terminal 100 again (S460).

After the above processes, the mobile terminal 100 transmits and receives packet data to and from the HA 500 through the GGSN 300. In this case, the above-described process is an initial access procedure for Proxy Mobile IP in a general WCDMA network. In order to directly route the GGSN 300 to the application server 600, the above process must be performed once.

Next, the GGSN 300 allocates one of the plurality of different IP addresses as a temporary IP address of the mobile terminal 100 (S465). Here, the GGSN 300 allocates one more temporary IP address in addition to the session information of the mobile terminal 100.

Next, the HA 500 loads the address and NAI information of the application server 600 in a Route Optimization Request message and transmits it to the GGSN 300 (S470). Accordingly, the GGSN 300 receiving the Route Optimization Request message transmits a Route Optimization Response message and responds to the HA 500 at step S475.

Thereafter, when packet data is transmitted from the mobile terminal 100 (S480), the GGSN 300 assigns the terminal IP address included in the header of the packet data transmitted from the mobile terminal 100 in step S465. Change to the address is transmitted to the HA (500) (S485, S490).

Accordingly, the HA 500 directly transmits the transmitted packet data to the application server 600 as a destination. Here, the HA 500 does not receive the packet data by generating tunneling with the GGSN 300 as in the related art, and merely plays the role of transferring the packet data received from the GGSN 300 to the application server 600. . Thus, the GGSN 300 can obtain the effect of routing directly with the application server 600.

Thereafter, when the application server 600 transmits the packet data to the temporary IP address included in the header of the packet data, the HA 500 directly transmits the transmitted packet data to the destination GGSN 300.

Next, the packet data transmitted from the GGSN 300 application server 600 is received, the temporary IP address included in the header of the received packet data is changed to the original mobile terminal IP address, and the corresponding mobile terminal 100 Send packet data.

Although embodiments of the present invention have been described above with reference to the accompanying drawings, those skilled in the art to which the present invention pertains may implement the present invention in other specific forms without changing the technical spirit or essential features thereof. You will understand that. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

1 is a call flow diagram illustrating a dynamic home agent allocation method for a proxy mobile IP in a WCDMA network.

2 is a diagram illustrating a packet service providing system using mobile IP according to an embodiment of the present invention.

3 is a block diagram of a packet service providing apparatus using mobile IP according to an embodiment of the present invention.

4 is a flowchart illustrating a packet service providing method using mobile IP according to an embodiment of the present invention.

<Explanation of symbols on main parts of the drawings>

100: mobile terminal 300: GGSN

500: HA 600: Application Server

310: communication unit 320: temporary IP address allocation unit

330: IP address changing unit 340: Storage unit

350: control unit

Claims (10)

A temporary IP address allocator for allocating one of a plurality of different IP addresses as a temporary IP address of the mobile terminal;  An IP address changing unit for changing a terminal IP address included in a header of packet data transmitted by the mobile terminal into the temporary IP address; And And a communication unit for transmitting the packet data including the temporary IP address to a first external device. The method of claim 1, The IP address changing unit changes the terminal IP address included in the header of the packet data into a temporary IP address by using network access identifier (NAI) information provided from a second external device. The method of claim 1, And the IP address changing unit changes the temporary IP address included in the header of the packet data transmitted from the first external device to the terminal IP address of the mobile terminal. A mobile terminal for transmitting packet data; Assign one of a plurality of different IP addresses to the temporary IP address of the mobile terminal, change the terminal IP address included in the header of the transmitted packet data to the temporary IP address, and then packet data including the temporary IP address. Packet service providing apparatus for transmitting a; And And a first external device for receiving the packet data transmitted from the packet service providing device. The method of claim 4, wherein The packet service providing apparatus changes the terminal IP address included in the header of the packet data into a temporary IP address by using network access identifier (NAI) information provided from a second external device. . The method of claim 4, wherein And the first external device transmits the packet data to a temporary IP address included in a header of the received packet data. The method of claim 4, wherein The packet service providing apparatus changes a temporary IP address included in a header of packet data transmitted from the first external device into a terminal IP address of the mobile terminal. Allocating one of a plurality of different IP addresses as a temporary IP address of the mobile terminal;  Changing a terminal IP address included in a header of packet data transmitted by the mobile terminal to the temporary IP address; And And transmitting the packet data including the temporary IP address to a first external device. The method of claim 8, The step of changing to the temporary IP address, The method of claim 1, wherein the terminal IP address included in the header of the packet data is changed to a temporary IP address by using network access identifier (NAI) information provided from a second external device. The method of claim 8, And a temporary IP address included in a header of packet data transmitted from the first external device, to a terminal IP address of the mobile terminal.

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