KR100442356B1 - Apparatus for general packet radio service - Google Patents

Abstract

The present invention relates to a general packet data transmission apparatus, and the conventional general packet data transmission apparatus has a problem that the efficiency of use is lowered because the device is not optimized. In view of the above problems, the present invention provides a wireless packet data service request from a terminal and outputs it via wire, and also UTRAN for applying the wired packet data to the terminal via wireless; SGSN which manages the location and mobility of the terminal and receives a packet data service requested by the terminal through UTRAN and performs a call admission control function for the terminal; An HLR for storing the location area of the terminal and informing the number of the SGSN for paging when the terminal uses a fixed IP; An S-GGSN connected to the HLR and performing a gateway function for matching with the Internet or an intranet when the terminal requests a packet data service using a fixed IP address; In case of using dynamic IP by connecting to SGSN through the backbone of general packet transmission system, D-GGSN consists of D-GGSN which assigns IP address to each terminal and performs gateway function for matching with Internet or intranet. It is possible to operate without establishing a database for IMSI mapping of IP addresses, and because S-GGSN uses a fixed IP address already assigned at the time of subscription, it is not necessary to implement a protocol for DHCP function. There is.

Description

General Packet Data Transmitter {APPARATUS FOR GENERAL PACKET RADIO SERVICE}

The present invention relates to a general packet data transmission apparatus, and in particular, a general packet data transmission apparatus suitable for optimizing a general packet transmission service by separating a region for allocating a fixed IP from a gateway general packet transmission service providing node into a separate node. It is about.

1 is a block diagram of a conventional general packet data transmission apparatus. As shown in FIG. 1, a wireless packet data service request from a terminal 1 is received and outputted through a wire, and wirelessly transmits packet data applied through a wire. A UTRAN (UMTS Terrestrial Radio Access Network, 2) for applying to the terminal 1 through a; A Serving GPRS Support Node, SGSN, which manages the location and mobility of the terminal 1 and receives a packet data service requested by the terminal 1 through the UTRAN 2 and performs a call admission control function for the terminal 1. )Wow; A home location register (HLR) 4 for storing a location area of the terminal 1 and informing the number of the SGSN 3 for paging when the terminal 1 uses a fixed IP; When connected to each of the HLR (4) and the terminal 1 requests a packet data service using a dynamic IP address, the terminal assigns an IP address to each terminal 1, a gateway for matching with the Internet or intranet (6) It consists of a Gateway GPRS Support Node (GGSN) 5 that performs a function.

Hereinafter, a conventional general packet data transmission apparatus configured as described above will be described in more detail.

FIG. 2 is a schematic diagram of a process of allocating a dynamic IP address in a conventional general packet data transmission apparatus. As shown in FIG. 2, a terminal 1 requests an activate packet data protocol context. This is then transmitted wirelessly to the UTRAN 2, which connects a bearer channel between the terminal 1 and the SGSN 3.

Next, the SGSN 3 sets up a traffic bearer according to the quality of service (QoS) required by the terminal 1, and then applies the activating packet data protocol context to the GGSN 5. To request dynamic IP address assignment.

Next, the GGSN 5 that has been requested to allocate the dynamic IP address allocates an idle IP address stored therein to the terminal 1 through the Dynamic Host Configuration Protocol (DHCP) that manages the IP address in the provider network. Assign a dynamic IP address and keep it until the packet service ends.

That is, the GGSN 5 generates a packet data protocol response message and transmits an IP address assigned to the terminal 1 to the SGSN 3, and the SGSN 3 transmits packet data for location management of the terminal 1. After making a protocol context and notifying the terminal 1 of the result through an activate packet data protocol context allow message, the packet data service is started.

Next, FIG. 3 is a schematic diagram of a process of transmitting a packet when a fixed IP is assigned to the terminal 1, and as shown in FIG. 3, when a fixed IP is first assigned to the terminal 1, the packet data service user first starts. The IP address is registered in the HLR (4) because the IP address is assigned from the time of joining. When the packet data service request is performed, the same operation as described above is performed, but the process of assigning the IP from the GGSN (5) is omitted. do.

In addition, since the same IP address is always assigned to the terminal 1, the packet data can be transmitted to the terminal at any time as long as the terminal 1 can receive paging.

When an arbitrary node sends packet data to transmit and receive data to the terminal 1 having a fixed IP, it is applied to the GGSN 5.

The GGSN 5 then finds a value in the internal database corresponding to the IP address of the terminal 1 to which packet data is to be transmitted and applies routing information to the HLR 4.

Then, the HLR 4 receiving the routing information transmits the number of the SGSN 3 to which the terminal to which packet data belongs is included in the routing information response message to the GGSN 5.

In this way, after the specific terminal 1 to which packet data is to be transmitted in the GGSN 5 recognizes the number of the SGSN 3 wirelessly connected, the packet data to be transmitted to the specific terminal 1 to the corresponding SGSN 3. The SGSN 3 sends a packet data protocol context activation message to the terminal 1 so that the terminal 1 can perform a procedure of receiving a packet.

However, the conventional general packet data transmission device as described above does not need to use HLR for dynamic IP allocation, but is required to find the currently connected SGSN area of the terminal when assigning a fixed IP address, and fixed in GGSN. By maintaining the database to know which terminal the IP address is assigned to, there is a problem that the efficiency of the use is reduced because the device is not optimized.

It is an object of the present invention to provide a general packet data transmission apparatus capable of optimizing a path of an apparatus by dividing a packet transmission path of a terminal using dynamic IP and fixed IP.

1 is a block diagram of a conventional general packet data transmission apparatus.

FIG. 2 is a schematic diagram of a process of allocating IP when using dynamic IP in FIG. 1; FIG.

3 is a schematic diagram of a process of receiving packet data when the terminal has a fixed IP in FIG.

4 is a block diagram of a general packet data transmission apparatus of the present invention.

FIG. 5 is a schematic diagram of a process of allocating IP when using dynamic IP in FIG. 4; FIG.

FIG. 6 is a schematic diagram of a process of requesting a packet data protocol context when having a fixed IP in FIG. 4; FIG.

7 is a schematic diagram of a process of receiving packet data when the terminal has a fixed IP in FIG.

* Description of the symbols for the main parts of the drawings *

1: Terminal 2: UTRAN

3: SGSN 4: HLR

5: S-GGSN 7: D-GGSN

The purpose of the above is to receive a wireless packet data service request from the terminal and to output it over the wire and UTRAN for applying the wired packet data to the terminal over the air; SGSN which manages the location and mobility of the terminal and receives a packet data service requested by the terminal through UTRAN and performs a call admission control function for the terminal; An HLR for storing the location area of the terminal and informing the number of the SGSN for paging when the terminal uses a fixed IP; An S-GGSN connected to the HLR and performing a gateway function for matching with the Internet or an intranet when the terminal requests a packet data service using a fixed IP address; When using the dynamic IP by connecting to the SGSN through the backbone of the general packet transmission system is achieved by configuring the D-GGSN to assign an IP address to each terminal and performs a gateway function for matching with the Internet or intranet, If described in detail with reference to the accompanying drawings, the present invention as follows.

4 is a block diagram of a general packet data transmission apparatus of the present invention. As shown in FIG. 4, a wireless packet data service request from a terminal 1 is received and outputted through a wire and packet data applied through a wire. A UTRAN (UMTS Terrestrial Radio Access Network) 2 for applying to the terminal 1 via radio; A Serving GPRS Support Node, SGSN, which manages the location and mobility of the terminal 1 and receives a packet data service requested by the terminal 1 through the UTRAN 2 and performs a call admission control function for the terminal 1. )Wow; A home location register (HLR) 4 for storing a location area of the terminal 1 and informing the number of the SGSN 3 for paging when the terminal 1 uses a fixed IP; Static IP Gateway GPRS Support (S-GGSN), which is connected to the HLR 4 and performs a gateway function for matching with the Internet or an intranet 6 when the terminal 1 requests a packet data service using a fixed IP address Node, 5); When the terminal 1 requests a packet data service using a dynamic IP address by connecting to the SGSN 3 through a backbone of a general packet transmission system, an IP address is assigned to each terminal 1 and the Internet or an intranet It consists of a D-GGSN (Dynamic IP Gateway GPRS Support Node, 6) that performs a gateway function for matching with (6).

Hereinafter, the operation of the general packet data transmission device of the present invention configured as described above will be described.

First, Figure 5 is a schematic diagram showing a process of assigning a dynamic IP to the terminal in the general packet data transmission device of the present invention, as shown in the activate packet data protocol context (activate packet data protocol) in the terminal 1 When a context is requested, it is transmitted to the UTRAN 2 wirelessly, and the UTRAN 2 connects a bearer channel between the terminal 1 and the SGSN 3.

Then, the SGSN 3 sets up a traffic bearer according to the quality of service (QoS) required by the terminal 1, and then activates the activated packet data protocol context in the D-GGSN 7. Authorizes the request, assigning a dynamic IP address.

At this time, the SGSN 3 and the D-GGSN 7 are connected using the backbone, not through the HLR 4.

Next, the D-GGSN 7 which is requested to allocate the dynamic IP address allocates the idle IP address stored therein or manages the IP address in the corresponding provider network through the DHCP (Dynamic Host Configuration Protocol) DHCP (1). Assign a dynamic IP address and keep it until the packet service ends.

That is, the D-GGSN 7 generates a packet data protocol response message and transmits the IP address assigned to the terminal 1 to the SGSN 3, and the SGSN 3 manages the location of the terminal 1. After creating a packet data protocol context and notifying the terminal 1 of the result through an activate packet data protocol context allow message, the packet data service is started.

FIG. 6 is a schematic diagram illustrating a process of receiving a packet data protocol context when a fixed IP is assigned to a terminal 1 in the general packet data transmission device of the present invention. As shown in FIG. The same as the method, but since the IP address is assigned to the terminal 1 itself, the process of allocating an IP in the S-GGSN 7 is omitted.

7 is a schematic diagram showing a process of transmitting packet data from the outside to the terminal 1 in the general packet data transmission device of the present invention. As shown in FIG. 7, the same IP is always assigned to the terminal 1. Therefore, the packet data can be delivered to the terminal 1 at any time, as long as the terminal can receive PAGING.

That is, when packet data is transmitted from any node, the packet data is authorized to S-GGSN (5) having a fixed IP address, and S-GGSN (5) is an IMSI (International) corresponding to the corresponding IP address. The Moval Support ID) value is found in the internal database and included in a message called routing information and applied to the HLR 4.

Then, the HLR 4 includes the number of the SGSN 3 to which the terminal 1 having the IP included in the authorized routing information is connected wirelessly in the routing information response message and again includes the S-GGSN 5. To send.

Then, the S-GGSN 5 notifies the corresponding SGSN 3 that there is a transmitted packet, and if so, transmits the packet data to the terminal 1 having the corresponding fixed IP address.

As described above, the present invention divides the gateway general packet transmission service providing node (GGSN) into a node performing packet call processing using a fixed IP and a node performing packet call processing using a dynamic IP, and fixed IP. By connecting only the node using IP to the HOME LOCATION REGISTER, the node using dynamic IP can operate without building a database for IMSI (International Moval Support ID) mapping to IP address. However, since the node using the static IP uses the fixed IP address already assigned at the time of joining, it is not necessary to implement the protocol for the DHCP function, so the device is optimized and the efficiency of use is improved.

Claims (1)

A UTRAN (UMTS Terrestrial Radio Access Network) for receiving a wireless packet data service request from a terminal and outputting the packet data service request through a wire, as well as applying the wired packet data to the terminal via a wireless wire; A Serving GPRS Support Node (SGSN) that manages the location and mobility of the terminal and receives a packet data service requested by the terminal through UTRAN and performs a call admission control function for the terminal; A home location register (HLR) for storing the location area of the terminal and informing the number of the SGSN for paging when the terminal uses a fixed IP; A static IP gateway GPRS support node (S-GGSN) that is connected to the HLR and performs a gateway function for matching with the Internet or an intranet when the terminal requests a packet data service using a fixed IP address; When a terminal requests a packet data service using a dynamic IP address through a backbone of a general packet transmission system, the terminal assigns an IP address to each terminal and performs a gateway function for matching with the Internet or an intranet. General packet data transmission device, characterized in that consisting of D-GGSN (Dynamic IP Gateway GPRS Support Node).