KR100625166B1 - Packet Data Transmission Method, Server and System for Designating Access Network - Google Patents

Abstract

The present invention relates to a packet data transmission method, a server and a system for designating an access network.

The present invention includes the steps of: (a) receiving an IP packet including packet data as a part via an Internet Protocol (IP) network; (b) searching the IP header of the IP packet to determine whether system designation information included in the IP packet is valid; (c) setting system identification information in a Generic Routing Encapsulation (GRE) header based on the system designation information when the system designation information is valid as a result of the determination of step (b); (d) converting the IP packet into a GRE packet including a GRE header and transmitting it to a packet controller; And (e) retrieving the GRE packet from the packet controller to identify the system identification information, and transmitting the GRE packet to the access network designated by the system identification information. to provide.

According to the present invention, since the load of the 1x system or the EV-DO system can be shared, radio resources can be efficiently used.

Packet data, service type, access network, IP header, option field, GRE header, flag field

Description

Packet Data Transmission Method, Server and System for Designating Access Network

1 is a block diagram schematically illustrating a 1x EV-DO system to which a preferred embodiment of the present invention is applied;

2 is a view for explaining the configuration of a flat data protocol stack between each of the AN, PCF, PDSN and SIP server;

3A is a diagram for explaining the configuration of an IP header used for transmitting an IP packet according to a preferred embodiment of the present invention;

3B is a view for explaining the configuration and field values of an option field according to an embodiment of the present invention;

4 is a view for explaining the configuration of a GRE packet according to an embodiment of the present invention;

5 is a flowchart illustrating a method of transmitting packet data by selectively designating an access network according to a preferred embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

110: HAT 120: AN

122: 1x Transmitter (BTS) 124: 1x Controller (BSC)

126: EV-DO transmitter (ANTS) 128: EV-DO controller (ANC)

130: voice communication network 140: PCF

150: PDSN 160: IP network

170: HA 180: SIP server

190: Internet 310: Options Field

320: code field 322: carrier unique number

330: length field 340: data field

342: IP header system identifier 410: flag field

420: preliminary field 430: system identification identifier

440: GRE header system delimiter

The present invention relates to a method for transmitting packet data by designating an access network according to a type of a packet data service in a CDMA 2000 1x EV-DO (hereinafter, referred to as '1x EV-DO') system, a server and It's about the system. More specifically, voice data is transmitted and received in a circuit switched method through an access network of a CDMA 2000 1x (hereinafter referred to as '1x') system, and packet data is transmitted to a CDMA 2000 EV-DO (hereinafter, referred to as 'EV-DO'). In a 1x EV-DO system that transmits and receives a packet through a system access network, a Session Initiation Protocol (SIP) server determines a service type of packet data to be transmitted to an access terminal and designates an access network. The present invention relates to a method, a server, and a system for transmitting packet data through a packet data serving node and a packet control function.

The mobile communication system has been developed through a first generation analog AMPS (Advanced Mobile Phone System) method, a second generation cellular (Cellular) / personal communication service (PCS) method, and recently, a third generation high speed data. International Mobile Telecommunication-2000 (IMT-2000) has been developed. The 1X system is called 2.5 generation because it uses some of the same frequency bands (800 MHz, 1.8 GHz) as the second generation of cellular / PCS services and provides some of the IMT-2000 functionality called the third generation.

In the 1x system, the voice communication is performed by the mobile communication terminal through the 1x transmitter and the 1x controller of the access network to the general switched telephone network through the mobile communication exchange station, and perform voice communication between the mobile communication terminals or between the mobile communication terminal and the landline telephone. do. In the 1x system, the data communication is performed by the mobile communication terminal connecting to the Internet through the PDSN via the 1x transmitter and the 1x controller of the access network.

In the case of data communication, a process of transmitting data from the Internet to a mobile communication terminal through a mobile communication network is called forward transmission. On the contrary, a process of transmitting data from the mobile communication terminal to the Internet through a mobile communication network is called reverse transmission. In 1X systems, the data rate is usually 307.2 Kbps in the forward direction and 153.6 Kbps in the reverse direction.

However, in the 1X system supporting the forward speed of 307.2 Kbps, there was a limit to transmitting a large amount of multimedia data. Therefore, 3GPP2 (3GPP2), the international standardization organization, defines the standard of the synchronous IMT-2000 system for multimedia mobile communication service.Qualcomm's HDR (High Data) is a method for high-speed packet transmission. The method based on Rate is named '1x EV (Evolution)' and it is confirmed as an international standard. The 1x EV-DO system is an evolution of the 1X system by adding an EV-DO system to transmit data only in the 1X system.

In addition, the data rate in the 1x EV-DO service is generally 2.4 Mbps in the forward direction and the data rate in the reverse direction is 153.6 Kbps, which is the same as that of the 1x system. Therefore, it is possible to transmit a large amount of data packets, it is possible to provide not only video telephony but also multimedia services such as video implementation. However, the amount of multimedia data is getting larger, and users' demands for diverse and high-speed multimedia services continue to increase.

A hybrid access terminal (HAT) capable of accessing each of the 1x and EV-DO systems to perform voice communication and data communication is provided once the packet data service is provided by accessing the 1x or EV-DO system. Regardless of the type of service, the service is provided only through the access network of the connected system.

However, various packet data services serviced by the 1x EV-DO system in the mobile communication terminal require bandwidth according to the type (eg, Best Effort service, VOD streaming service, video telephone service, etc.). Since packet data services are provided in such a conventional manner, packet data, which can be serviced even by a 1x system, is transmitted to the EV-DO system, which wastes expensive radio resources.

Meanwhile, a SIP server performing a function of providing a mobile communication service such as audio and video using a SIP (Session Initiation Protocol) at a higher level than a packet data serving node (PDSN) in a 1x EV-DO system. Since the call setup is performed with the hybrid terminal, it is possible to determine the type of packet data service provided to the hybrid terminal and to determine a system (1x system or EV-DO system) suitable for providing the packet data service. have.

Therefore, the system designation information determined by the SIP server is transferred to the access network (1x or EV-DO system) of the designated system through the packet data serving node and the packet controller (PCF) and the access network of the system. By providing this packet data service, when the access network of the 1x system and the access network of the EV-DO system perform load sharing with each other, it is possible to more efficiently use expensive radio resources in operating the system. Will be.

However, the dynamic load sharing between the access network of the 1x system and the access network of the EV-DO system since the packet data serving node does not control the access network to provide packet data service until now. This is not true.

In order to solve the above problems, the present invention, if the SIP server designates the access network to set the access network designation information using the option field of the IP header of the IP packet, and transmits the IP packet to the packet data serving node, packet data The serving node analyzes the option field of the IP header, checks the system specific information, and sets the access network specific information using the flag field of the GRE header of the GRE (Generic Routine Encapsulation) packet data. The present invention provides a method, a server, and a system for transmitting packet data to a packet controller and designating an access network according to a packet data service type for causing a designated access network to provide a packet data service through the packet controller.

In order to achieve this object, a method of transmitting packet data by designating an access network to be transmitted to a mobile terminal according to a type of packet data service in a code division multiple access (CDMA) 1x EV-DO system that provides a packet data service. A method comprising: (a) receiving an IP packet including as part of packet data through an Internet Protocol (IP) network; (b) searching the IP header of the IP packet to determine whether system designation information included in the IP packet is valid; (c) setting system identification information in a Generic Routing Encapsulation (GRE) header based on the system designation information when the system designation information is valid as a result of the determination of step (b); (d) converting the IP packet into a GRE packet including a GRE header and transmitting it to a packet controller; And (e) retrieving the GRE packet from the packet controller to identify the system identification information, and transmitting the GRE packet to the access network designated by the system identification information. to provide.

In addition, according to another object of the present invention, in a Code Division Multiple Access (CDMA) 1x EV-DO system that provides a packet data service, the packet data serving node checks the system designation information set in the IP packet to GRE system identification information. A method for setting a packet, comprising: (a) determining whether an IP header included in an IP packet includes an option field; (b) As a result of the determination in step (a), if the IP header of the IP packet is configured to include an option field, it is determined whether to utilize the information designating the CDMA 2000 1x system or the CDMA 2000 EV-DO system in the code field of the option field. Determining whether a service provider unique number for indicating whether or not is set; (c) As a result of the determination in step (b), when the carrier unique number is set in the code field of the option field, the source IP address of the IP header indicates that the CDMA 2000 1x system or the CDMA 2000 EV-DO system is Determining whether an IP address of a designated Session Initiation Protocol (SIP) server is present; And (d) if the source IP address of the IP header is an IP address of a Session Initiation Protocol (SIP) server designating a CDMA 2000 1x system or a CDMA 2000 EV-DO system, as a result of the determination in step (c), IP header system that indicates the system-specific information set in the data field of the option field of the IP header by setting the value of the system identification identifier, which is an identifier indicating whether system identification information is utilized in the GRE header of the GRE packet, to '1'. It provides a method for transmitting packet data by specifying an access network comprising the step of setting the value of the delimiter to the value of the GRE header system identifier indicating system identification information in the GRE header of the GRE packet.

In addition, according to another object of the present invention, in the Code Division Multiple Access (CDMA) 1x EV-DO system for providing a packet data service, by specifying the access network to be transmitted to the mobile communication terminal according to the type of packet data service packet data A system for transmitting a network comprising: an IP (Internet Protocol) network for receiving an IP packet including packet data and relaying transmission of the packet data; Receives an IP packet through an IP network, retrieves an IP header, determines whether system-specific information included in the IP packet is valid, and if the system-specific information is valid, based on system-specific information, GRE (Generic Routing Encapsulation) A packet data serving node that sets system identification information in a header, converts an IP packet into a GRE packet including a GRE header, and transmits the packet; A packet controller receiving the GRE packet, retrieving the GRE header to confirm system identification information, and transmitting the GRE packet to an access network designated by the system identification information; And an access network receiving the GRE packet and transmitting the packet data included in the GRE packet to the mobile communication terminal.

According to still another object of the present invention, a server for transmitting packet data by designating an access network to be transmitted to a mobile communication terminal according to a type of packet data service, receives an IP packet, retrieves an IP header, and includes the same in an IP packet. It is determined whether the system designation information is valid according to the type of packet data service, and if the system designation information is valid, the system identification information is set in the Generic Routing Encapsulation (GRE) header based on the system designation information, Provides a packet data transmission server specifying the access network, characterized in that for transmitting to the GRE packet including the GRE header.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

1 is a block diagram schematically illustrating a 1x EV-DO system to which a preferred embodiment of the present invention is applied.

1x EV-DO system to which the preferred embodiment of the present invention is applied is a hybrid terminal (HAT: Hybrid Access Terminal, hereinafter referred to as "HAT") 110, Access Network (hereinafter referred to as "AN") 120 , Voice communication network 130, packet controller (PCF: Packet Control Function, hereinafter referred to as 'PCF') 140, Packet Data Serving Node (PDSN: hereinafter referred to as 'PDSN') 150, It is configured to include an IP network 160, a home agent 170, a session initiation protocol (SIP) server 180, and the internet 190.

The HAT 110 is a terminal for 1x EV-DO data service, and is a dual configuration that is hardware-separated so that a voice service can be provided through a 1X system and a high speed data service can be provided through an EV-DO system. Has The HAT 110 is switched to the 1X mode to communicate through the 1X system in the standby state waiting for communication. However, the HAT 110 switches to the EV-DO mode at regular intervals to check whether the call is received by the EV-DO system. Performs the operation to return to 1X mode again.

In addition, while receiving data in the EV-DO mode traffic state, the HAT 110 switches to the 1X mode at regular intervals and checks again whether there is an incoming signal such as a voice signal using the 1X system. The operation of returning to the DO mode is repeatedly performed.

In the AN 120, the EV-DO system and the 1X system are mixed and configured in hardware, and operations are performed separately. In other words, the AN 120 is provided with a channel card and channel board for 1x EV-DO system and a channel card and channel board for 1x system, respectively.

Thus, AN 120 includes a 1x transmitter (BTS) 122 and a 1x controller (BSC) 124 of the 1x system, as well as an EV-DO transmitter for an 1x EV-DO system (ANTS: Access Network Transceiver Subsystem). , An &quot; ANTS " 126, and an EV-DO controller (ANC: &quot; ANC &quot;) 128.

Accordingly, data communication is performed through the ANTS 126 and the ANC 128 in the case of data communication, and voice is provided through the 1x transmitter (BTS) 122 and the 1x controller (BSC) 124 in the case of voice communication. Communication takes place. Accordingly, the ANTS 126 serves to transmit only packet data to the HAT 110, and the ANC 128 relays packet data between the ANTS 126 and the PDSN 150 and controls the ANTS 126. It plays a role.

The AN 120 to which the preferred embodiment of the present invention is applied is applied when the packet data is transmitted from the PCF 140 to the 1x access network including the 1x transmitter (BTS) 122 and the 1x controller (BSC) 124. When the packet data is transmitted to the HAT 110 through the network and transmitted to the EV-DO access network including the ANTS 126 and the ANC 128, the packet data is transmitted to the HAT 110 through the EV-DO access network. send.

The voice communication network 130 is configured to include a mobile communication switching center (not shown) and a public switched telephone network (PSTN) (not shown) and is connected to the 1x controller (BSC) 128 to connect with the HAT 110. Perform voice communication.

The PCF 140 is connected to the 1x controller (BSC) 124, the ANC 128, and the PDSN 150 to establish / maintain / release the connection with the PDSN 150, and the 1x controller (BSC). Requests 124 and ANC 128 to allocate radio resources for packet data transmission, and collects billing information and transmits it to PDSN 150. In addition, the buffering function and the state management function of the mobile communication terminal (not shown) are performed until the packet data received from the PDSN 150 is transmitted to the HAT 110 through the AN 120.

The PCF 140 to which the preferred embodiment of the present invention is applied receives the GRE packet from the PDSN 150, searches for the GRE header to confirm system classification information, and transmits the GRE packet to an access network designated by the system identification information. Play a role.

The HAT 110 is connected to the PDSN 150 based on TCP / IP via the 1x transmitter (BTS) 122 and the 1x controller (BSC) 124 of the AN 120 or the ANTS 126 and the ANC 128. Connect and send and receive various data. The PDSN 150 processes data between the HAT 110 and the IP network 160 through the AN 120. The PDSN 150 provides a movement management function when the user receives data while moving, so that the moving HAT 110 can continue to receive data service through communication with the Internet 190. In addition, when the HAT 110 moves and moves to another cell, the HAT 110 manages the HAT 110 entering its area and informs the HA 170 of the current location of the HAT 110.

The PDSN 150 according to the preferred embodiment of the present invention receives an IP packet to which the IP header is attached through the IP network 160 from one or more SIP servers 180 or one or more HA 170 to retrieve the IP header. It is determined whether the system designation information included in the IP packet is valid.If the system designation information is valid, the system identification information is set in the Generic Routing Encapsulation (GRE) header based on the system designation information. It converts into a GRE packet including a and transmits to the PCF 140.

IP network 160 is a network for connecting PDSN 150, HA 170, SIP server 180, Internet 190, etc., and relays data transmission between all components connected to IP network 160. It plays a role.

The HA 170 serves to manage the location tracking of the HAT 110 along with the PDSN 150. When the HAT 110 accesses the mobile communication system for data service, the HA 170 assigns a unique identification IP address to the HAT 110. This address is fixed because the Internet 190 is the only address that can identify the HAT 110, and is used as an address that enables communication with the HAT 110 from the system.

In addition, the HAT 110 receives a temporary IP address from the PDSN 150 when moving to another cell. This temporary IP address will indicate where the HAT 110 is located. Since the PDSN 150 and the HA 170 track and manage the location of the HAT 110 by exchanging a fixed IP address and a temporary IP address of the HAT 110, the HAT 110 is always on the go regardless of the location. Data service is available.

The HA 170 according to the preferred embodiment of the present invention converts the packet data into an IP packet and transmits the packet data to the PDSN 150 through the IP network 160.

The SIP server 180 performs a function of providing a mobile communication service such as audio and video using SIP. SIP is a simple text-based application layer control protocol. It is a signaling protocol for Internet video conferencing, Internet telephony, and so on. Unlike H.323, SIP is a client / server protocol.

SIP server 180 according to a preferred embodiment of the present invention to identify the type of packet data service, and specify the system type of the access network 120 for providing the packet data service to the HAT (110) option field of the IP header It plays a role of setting IP header system identifier indicating system specific information in data field of option field of IP number and option field of IP header to indicate whether to use information specifying system type of access network in code field of.

The Internet 190 refers to a global open computer network architecture that provides the TCP / IP protocol and various services that exist in the upper layers, namely HTTP, Telnet, FTP, DNS, SMTP, SNTP, NFS, and NIS.

FIG. 2 is a diagram for describing the configuration of a planar data protocol stack between the steps of the AN 120, the PCF 140, the PDSN 150, and the SIP server 180 illustrated in FIG. 1.

As shown, the SIP server 180 has a protocol stack for communicating with the PDSN 150. The protocol stack provides a physical layer for coding and modulation of data, and accurate transmission of a message. To this end, it is divided into a link layer for performing functions such as error correction, flow control, and synchronization, and an IP layer for designating a transmission destination for communication with the PDSN 150.

Under such a protocol stack, the SIP server 180 adds an IP header to the data packet, configures the IP packet, and transmits the IP packet to the PDSN 150. A general configuration of an IP header of an IP packet will be described below with reference to the drawings.

PDSN 150 includes the layers of the protocol stack of SIP server 180 to communicate with SIP server 180, and IP packet data to HAT 110 to communicate with PCF 140. The Point to Point Protocol (PPP) layer to encapsulate and transmit the packet, and the A10 layer to transmit packet data by configuring the PCF 140 and the Generic Routing Encapsulation (GRE) tunnel. It has a protocol stack divided into an IP layer, a link layer, and a physical layer.

In such a protocol stack structure, the PDSN 150 encapsulates packet data into a GRE and sends it to the PCF 140. A general configuration of the GRE header of the GRE packet will be described below with reference to the drawings.

PCF 140 has a protocol stack having an A10 layer, an IP layer, a link layer, and a physical layer for communication with PDSN 150. In addition, a protocol divided into an A8 layer, an IP layer, a link layer, and a physical layer for transmitting packet data by configuring a generic routing encapsulation (GRE) tunnel with the AN 120 for communication with the AN 120. Has a stack.

Finally, AN 120 has a protocol stack having an A8 layer, an IP layer, a link layer, and a physical layer for communication with PCF 140. In addition, it has a protocol stack divided into a media access control (MAC) layer and a physical layer corresponding to the A8 layer, the IP layer, and the link layer for communication with the HAT 110.

The SIP server 180 determines the type of packet data service provided to the HAT 110 to determine an access network of a system (1x system or EV-DO system) suitable for providing the packet data service, and the PDSN 150. Specify the system in the option field of the IP header that is appended for transmission.

3A is a diagram for explaining the configuration of an IP header used for transmitting an IP packet according to a preferred embodiment of the present invention.

As shown, the IP header includes a version field indicating the version number of the IP protocol, an IP header length field (IHL) indicating the size of the IP header field, and a service type indicating the quality of service required by the IP packet. Field, the total length field indicating the total length of the IP packet in units of bytes combined with the IP header field and the IP data field, the identification field for identifying the IP packet of the upper layer, and the fragmentation of the IP packet. A flag field indicating information about the fragment, a fragment offset field indicating a location of original data of each divided IP packet, a time to live field indicating a remaining number of traversable routers, an IP The protocol type field indicating the protocol type code for identifying the upper protocol of the IP included in the data field, and the IP header field. Header checksum field indicating a checksum for error detection, an option field 310 and an option field used to instruct processing to request a router or the like when transmitting an IP packet, a destination IP address, a destination IP address, etc. are used. If it is configured to include a padding (Padding) field that is a redundant part.

3B is a diagram for explaining the configuration and field values of the option field 310 according to the preferred embodiment of the present invention.

The SIP server 180 designates the access network 120 of the system that transmitted the packet data according to the packet data service type in the option field 310 of the IP header field shown in FIG. 3A, which is an option field 310. As shown in FIG. 3B, the code field 320 includes a code field 320, a length field 330, and a data field 340 each having 1 byte. The last 5 bits 322 of the code field indicate the mobile carrier's identification number (for example, '11011' as shown in the case of SK Telecom), and if the mobile carrier identification number is present, The IP header system identifier (A) 342 of the data field to be described next is valid, and the system access network is designated according to the value set in the IP header system identifier (A) 342.

In addition, the length field 330 is a field indicating the total length of the option field 310, the data field 340 is a six-bit reserved field and a one-bit IP header system identifier (A) 342 It is composed.

Table 1 shows system types according to values of the IP header system identifier (A) 342.

The value of the IP header system identifier (A) 342 is a binary value of '0' or '1'. If this value is '0', the system specified by the SIP server 180 according to the packet data service type is 1x. If the value is '1', the system designated by the SIP server 180 according to the packet data service type is EV-DO.

The PDSN 150 receives the IP packet coded as described above, retrieves the option field of the IP header, checks the IP header system identifier (A) 342, and confirms the GRE header of the GRE packet to be transmitted to the PCF 140. The GRE packet is transmitted to the PCF 140 by coding the system specific information.

4 is a view for explaining the configuration of a GRE packet according to an embodiment of the present invention.

As shown, a GRE packet is divided into a GRE header field and a GRE data field. The GRE header field consists essentially of a two-byte flag field 410 and a protocol type field, respectively. Also, a checksum field used to determine the accuracy of the data, an offset field indicating the length of the data, a key field used to identify each traffic in the GRE tunnel, and a sequence indicating the order of the packet data. A sequence number field and a routing field indicating a data transmission path may be additionally included by selection.

Looking specifically at the flag field 410 consisting of two bytes, the C (Checksum), R (Reserved), K (Key Present), S (Sequence Number Present), and s from the 0th bit to the 4th bit of the first byte. It is defined as (Strict Source Routing), so it is set to the appropriate value according to the type of field additionally included by selection. The 3 bits from the 5th bit to the 7th bit are the default values as Recur (Recursion Control). Is defined as '000'.

In addition, 5 bits from the 0th bit to the 4th bit of the second byte are reserved bits, and are normally set to '00000' and transmitted, and the 5th to 7th bits are bits for indicating the version of the GRE header. .

In the present invention, the reserved field 420 is used among the flag fields 410 of the GRE header to transmit system specific information to the PCF 140. The last bit of the reserved field 420 of the flag field 410 is a GRE header system identifier by copying the value of the IP header system identifier (A) 342 retrieved from the option field 310 of the IP header of the received IP packet. Bit for setting the value of (A +) 440, and the second bit from the last is the value of the system identification identifier (A ') 430 to indicate whether the GRE header system identifier (A +) 440 is utilized. This is the bit that is set.

GRE header system identifier (A +) 440 has the same value as IP header system identifier (A) 342. Therefore, the meaning according to the set value is also shown in Table 1.

Table 2 shows whether or not to use the system identifier according to the value of the system identification identifier (A ') 430.

5 is a flowchart illustrating a method of transmitting packet data by selectively designating an access network according to a preferred embodiment of the present invention.

When the HA 170 receives the packet data, the SIP server 180 performs call setup with a mobile communication terminal (not shown). In this process, the SIP server 180 determines the type of packet data service, designates a system suitable for providing the packet data service, and defines system designation information as an IP header system identifier (A) 342 to define an IP header. Is set in the option field 310 of (S504), the IP header is attached to the packet data, converted into an IP packet, and transmitted to the PDSN 150.

The PDSN 150 receives the IP packet from the SIP server 180 in the case of the SIP-based packet data service or from the HA 170 in the case of the general packet data service (S502), and receives the IP header attached to the IP packet. In operation S506, it is determined whether the option field 310 exists in the IP header during the search. Since the option field 310 of the IP header is optional in constructing the IP header, packet data not set by the SIP server 180 does not have the option field 310 in the IP header when converted into an IP packet. Will not. Therefore, since the packet data having no option field 310 in the IP header is transmitted without specifying the access network, the packet data is transmitted to the PCF 140 without setting the information specifying the access network in the GRE packet.

As a result of the determination in step S506, if the IP header system identifier (A) 342 is not set, the process proceeds to step S516. If the IP header system identifier (A) 342 is set, the option field of the IP header ( It is determined whether the unique number 322 of the operator who operates the system exists in the code field 320 of 310 (S508).

When the packet data having the option field 310 in the IP header uses the option field 310 for other purposes, the access network is not specified, so that the carrier unique number 322 is set in the code field 320. Only the information that specified the access network becomes valid. Therefore, as a result of the determination in step S508, if the provider unique number 322 does not exist, the process proceeds to step S516. If the provider unique number 322 exists, the SIP server 180 in which the destination IP address of the IP header is already registered. It is determined whether or not the IP address of (S510).

If the received IP packet is not an IP packet received from the SIP server 180 designating the system, the access network is not specified. Therefore, the system is assigned only to the packet data received from the SIP server 180 registered in the PDSN 150. Set the information and convert it to a GRE packet.

Therefore, as a result of the determination in step S510, if the destination IP address is not an already registered IP address, the flow advances to step S516. If the destination IP address is an already registered IP address, the system designation information is sent to the PCF 140. Set the value of the system identification identifier (A ') 430 to' 1 'in the reserved field 420 of the flag field 410 of the GRE header for transmission (S512), and the IP header system identifier (A) 342. ) Is set to the value of the GRE header system identifier (A +) 440 (S514).

The PDSN 150 converts the packet data into a GRE packet including the GRE header and transmits the packet data to the PCF 140. The PCF 140 receives the GRE packet (S516), and includes a system identification identifier (A ') included in the GRE header. It is determined whether or not the value of 430 is '1' (S518). As a result of the determination in step S518, if the value of the system identification identifier (A ') 430 is' 0', the value set in the GRE header system identifier (A +) 440 is invalid. ) And the data is transmitted to the access network of the system to which the session is connected (S520), and if the value of the system identification identifier (A ') 430 is' 1', the value set in the GRE header system identifier (A +) 440. Since the validity is determined, the set value is determined to determine whether the value of the GRE header system identifier (A +) 440 included in the GRE header is '1' (S522).

As a result of the determination in step S524, if the value of the GRE header system identifier (A +) 440 is '0', the packet data is transmitted to the 1x access network (S524), and the value of the GRE header system identifier (A +) 440 is determined. If '0', the packet data is transmitted to the EV-DO access network (S526).

The 1x access network or the EV-DO access network receiving the packet data transmits the received packet data to the HAT 110, thereby sharing the load between the 1x access network and the EV-DO access network, thereby making it possible to efficiently operate the mobile communication system. It becomes possible.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

As described above, according to the present invention, an EV-DO system is required to identify a type of a packet data service at an upper level of a mobile communication system, to designate a system suitable for the service type, and to transmit data at high speed. The packet data service is provided through an access network, and when the data is transmitted at a low speed, the packet data service is provided through an access network of a 1x system, thereby efficiently using expensive radio resources.

In addition, by sharing the load between the 1x system and the EV-DO system, it is possible to prevent the load from being concentrated to any one system, thereby preventing a system error or aging of the system that may occur due to the load concentration.

Claims (42)

In a code division multiple access (CDMA) 1x EV-DO system providing a packet data service, a method of transmitting packet data by designating an access network to be transmitted to a mobile communication terminal according to the type of the packet data service, (a) receiving an IP packet including the packet data as a part via an Internet Protocol (IP) network; (b) searching the IP header of the IP packet to determine whether system designation information included in the IP packet is valid; (c) setting system identification information in a Generic Routing Encapsulation (GRE) header based on the system designation information when the system designation information is valid as a result of the determination of step (b); (d) converting the IP packet into a GRE packet including the GRE header and transmitting it to a packet controller; And (e) searching for the GRE packet in the packet controller to identify system classification information, and transmitting the GRE packet to an access network designated by the system identification information; Packet data transmission method specifying the access network comprising a. The method of claim 1, wherein step (a) comprises: And receiving the IP packet with the IP header from at least one Session Initiation Protocol (SIP) server or at least one Home Agent (HA). The method of claim 2, The SIP server identifies the type of the packet data service, specifies a system type of an access network that provides the packet data service to the mobile communication terminal, and identifies a service provider unique number and an IP header system identifier in an option field of the IP header. A packet data transmission method specifying the access network, characterized in that for setting. The method of claim 1, wherein in step (a), the IP packet is: And a packet data transmission method comprising the packet data and the IP header. The method of claim 1, wherein step (b) comprises: (b1) determining whether the IP header of the IP packet includes an option field; (b2) When the IP header of the IP packet includes the option field as a result of the determination in step (b1), it is determined whether a service provider unique number is set in the code field of the option field. step; And (b3) If the service provider unique number is set in the code field of the option field as a result of the determination in step (b2), a SIP (Session Initiation) in which a source IP address of the IP header has already been registered; Protocol) determining whether the server is an IP address Packet data transmission method specifying the access network comprising a. The method according to claim 3 or 5, wherein the service provider unique number, And each bit is configured by a combination of five bits each having a value of '0' or '1' in the code field of the option field. The method of claim 1, wherein step (c) comprises: In the step (b), if the system designation information is valid, (c1) setting a value of a system identification identifier in the GRE header to '1'; And (c2) setting a value of an IP header system identifier of the IP packet to a value of a GRE header system identifier in the GRE header of the GRE packet. Packet data transmission method specifying the access network comprising a. 8. The system of claim 3 or 7, wherein the IP header system identifier is A system identifier set in the data field of the option field of the IP header. The system identifier is set to any one of '0' or '1' and is set to a value of '0'. Multiple Access) A packet data transmission method designating an access network, which means that it is a 2000 1x system, and if it is set to a value of '1', it means that the designated system is a CDMA 2000 EV-DO system. delete The method of claim 1, wherein step (e) (e1) determining whether a value of the system identification identifier set in the GRE header is '1'; (e2) determining that the GRE header system identifier is '1' when the value of the system identifier is '1' as a result of the determination of step (e1); And (e3) transmitting the packet data to an access network of a code division multiple access (CDMA) 2000 EV-DO system when the GRE header system identifier is '1' as a result of the determination of step (e2). Packet data transmission method specifying the access network comprising a. The method of claim 10, wherein the method is (e21) When the value of the system identification identifier is '0', as a result of the determination of step (e1), the access network of the CDMA (Code Division Multiple Access) 2000 1x system in which a session is established for the packet data. Or transmitting to an access network of a CDMA 2000 EV-DO system The packet data transmission method specifying the access network, characterized in that it further comprises. The method of claim 10, wherein the method is (e4) transmitting the packet data to an access network of a code division multiple access (CDMA) 2000 1x system when the GRE header system identifier is '0' as a result of the determination of step (e2). The packet data transmission method specifying the access network, characterized in that it further comprises. The method according to any one of claims 7, 10 and 11, The system identification identifier, An identifier for indicating whether the GRE header system identifier is used or not, and when set to a value of '0' or '1' and set to a value of '0', the identifier is related to the value of the GRE header system identifier. This means that the packet data is transmitted through an access network in which a session with the current mobile communication terminal is established. If the value is set to '1', the packet data is transmitted through the access network specified by the GRE header system identifier. Packet data transmission method specifying the access network, characterized in that means to transmit. The method according to any one of claims 7, 10 and 12, The GRE header system identifier is As a system identifier set in the GRE header, and is set to any one of '0' or '1' and is set to a value of '0', the designated system is a CDMA 2000 Codex 1x system. And if set to a value of '1', means that the designated system is a CDMA 2000 EV-DO system. In a Code Division Multiple Access (CDMA) 1x EV-DO system providing packet data service, a packet data serving node checks system designation information set in an IP packet and sets system division information in a GRE packet. (a) determining whether the IP header included in the IP packet includes the Option field; (b) When the determination result of step (a) indicates that the IP header of the IP packet includes an option field, a CDMA 2000 1x system or a CDMA 2000 EV-DO system is designated in a code field of the option field. Determining whether a service provider unique number for indicating whether to utilize the information is set; (c) If the service provider unique number is set in the code field of the option field, the source IP address of the IP header is the CDMA 2000 1x system or CDMA. Determining whether an IP address of a Session Initiation Protocol (SIP) server designating a 2000 EV-DO system is determined; And (d) When the source IP address of the IP header is the IP address of the Session Initiation Protocol (SIP) server designating the CDMA 2000 1x system or the CDMA 2000 EV-DO system, as a result of the step (c). In the GRE packet, the system identification information, which is an identifier for indicating whether system identification information is used or not, is set to '1', and system designation information set in the data field of the option field of the IP header is set to '1'. Setting a value of an IP header system identifier indicating a to a value of a GRE header system identifier indicating the system identification information in the GRE header of the GRE packet. Method for transmitting packet data by specifying an access network comprising a. The method of claim 15, wherein the service provider unique number, And the bit field is composed of a combination of five bits each having a value of '0' or '1' in the code field of the option field. The method of claim 15, wherein the IP header system identifier, If the value is set to any one of '0' or '1' and is set to a value of '0', it means that the designated system is a Code Division Multiple Access (CDMA) 2000 1x system and is set to a value of '1'. If it is, the method for transmitting the packet data by specifying the access network, characterized in that the designated system is a CDMA 2000 EV-DO system. The method of claim 15, wherein the system identification identifier, If set to any one of '0' or '1', and set to a value of '0', regardless of the value of the GRE header system identifier, an access network to which a session is currently established with the mobile communication terminal is established. It means to transmit the packet data through, and if it is set to a value of '1' means to transmit the packet data through the access network specified by the GRE header system identifier, the packet by specifying the access network How to transfer data. 16. The system of claim 15, wherein the GRE header system identifier is If the value is set to any one of '0' or '1' and is set to a value of '0', it means that the designated system is a Code Division Multiple Access (CDMA) 2000 1x system and is set to a value of '1'. If it is, the method for transmitting the packet data by specifying the access network, characterized in that the designated system is a CDMA 2000 EV-DO system. delete delete delete delete delete A system for transmitting packet data by designating an access network to be transmitted to a mobile communication terminal according to a type of the packet data service in a code division multiple access (CDMA) 1x EV-DO system that provides a packet data service, An Internet Protocol (IP) network for receiving an IP packet including the packet data and relaying the transmission of the packet data; Receiving the IP packet through the IP network, searching the IP header and determining whether the system designation information included in the IP packet is valid. If the system designation information is valid, the GRE is based on the system designation information. A packet data serving node that sets system identification information in a Generic Routing Encapsulation header, converts the IP packet into a GRE packet including the GRE header, and transmits the packet; A packet controller for receiving the GRE packet, retrieving the GRE header to confirm the system identification information, and transmitting the GRE packet to the access network designated by the system identification information; And The access network for receiving the GRE packet and transmitting the packet data included in the GRE packet to a mobile communication terminal Packet data transmission system specifying the access network comprising a. delete The method of claim 25, wherein the packet data serving node, And receiving the IP packet to which the IP header is attached from at least one Session Initiation Protocol (SIP) server or at least one home agent (HA). The method of claim 27, wherein the SIP server, Identify a type of the packet data service, designate a system type of the access network that provides the packet data service to the mobile communication terminal, and designate a system type of the access network in a code field of the option field of the IP header; And an IP header system identifier indicating system specific information in a service provider unique number for indicating whether to utilize the information and a data field of the option field of the IP header. The method of claim 25, wherein the packet data serving node, It is determined whether the IP header of the IP packet is configured to include an option field, and if the IP header of the IP packet is configured to include an option field, access network code field of the option field. It is determined whether or not a service provider unique number is set to indicate whether to utilize the system type specified information. If the service provider unique number is set in the code field of the option field, transmission of the IP header is performed. It is determined whether a source IP address is an IP address of a Session Initiation Protocol (SIP) server designating the CDMA 2000 1x system or the CDMA 2000 EV-DO system, and the source IP address of the IP header is the CDMA 2000. If this is the IP address of the Session Initiation Protocol (SIP) server that specified the 1x system or CDMA 2000 EV-DO system, place the system in the GRE header. The value of the system identification identifier, which is an identifier for indicating whether the classification information is used, is set to '1', and the value of the IP header system identifier indicating the system designation information set in the data field of the option field of the IP header is read. And a GRE header system identifier indicating the system identification information in the GRE header of the GRE packet. 30. The method of claim 29, wherein the service provider unique number, And the bit field is composed of a combination of five bits each having a value of '0' or '1' in the code field of the option field. 30. The method of claim 28 or 29, wherein the IP header system identifier is If the value is set to any one of '0' or '1' and is set to a value of '0', it means that the designated system is a Code Division Multiple Access (CDMA) 2000 1x system, and the value of '1'. If set to, the packet data transmission system for access network designation, characterized in that the specified system is a CDMA 2000 EV-DO system. delete The method of claim 25, wherein the packet controller, It is determined whether the value of the system identification identifier set in the GRE header is '1', and when the value of the system identification identifier is '0', the code division multiple (CDMA) in which a session is set for the packet data is set. Access) Packet data transmission system for specifying an access network, characterized in that the transmission to the access network of the 2000 1x system or the access network of the CDMA 2000 EV-DO system. The method of claim 25, wherein the packet controller, When the value of the system identification identifier set in the GRE header is '1', it is determined whether the GRE header system identification is '1'. When the GRE header system identification is '1', the packet data is converted into CDMA (Code). Division Multiple Access) The access network designation is transmitted to the access network of the 2000 EV-DO system, and when the GRE header system identifier is '0', the packet data is transmitted to the access network of the CDMA 2000 1x system. Packet data transmission system. The method according to any one of claims 29, 33 and 34, The system identification identifier, An identifier for indicating whether the GRE header system identifier is used or not, and when set to a value of '0' or '1' and set to a value of '0', the identifier is related to the value of the GRE header system identifier. This means that the packet data is transmitted through an access network in which a session with the current mobile communication terminal is established. If the value is set to '1', the packet data is transmitted through the access network specified by the GRE header system identifier. Packet data transmission system for access network designation, characterized in that to transmit. The method of claim 29 or 34, The GRE header system identifier is As a system identifier set in the GRE header, and is set to any one of '0' or '1' and is set to a value of '0', the designated system is a CDMA 2000 Codex 1x system. And if it is set to a value of '1', it means that the designated system is a CDMA 2000 EV-DO system. A server for transmitting packet data by designating an access network to be transmitted to a mobile terminal according to a type of packet data service. Receives an IP packet, retrieves an IP header, determines whether system designation information according to the type of the packet data service included in the IP packet is valid, and if the system designation information is valid, based on the system designation information. And setting system identification information in a Generic Routing Encapsulation (GRE) header, converting the IP packet into a GRE packet including the GRE header, and transmitting the same. The method of claim 37, wherein the GRE packet, A flag field and protocol including a GRE header system identifier and a system identification identifier as the system identification information used to distinguish a Code Division Multiple Access (CDMA) 2000 1x system and a CDMA 2000 EV-DO system using a plurality of bits. A GRE header field including a protocol type field indicating a type of a; And GRE data field containing the packet data Packet data transmission server specifying the access network comprising a. The method of claim 38, And the GRE header system identifier and the system identification identifier are set in a reserved field of the flag field. The method of claim 39, And the reserved field includes a bit for setting a value of the GRE header system identifier and a bit for setting a value of the system identification identifier. 41. The system of claim 40, wherein the GRE header system identifier is If the value is set to any one of '0' and '1' and is set to a value of '0', it means that the designated system is the CDMA 2000 1x system. Packet data transmission server designating an access network, characterized in that the system is the CDMA 2000 EV-DO system. 41. The system of claim 40, wherein the system distinguished identifier is If set to any one of '0' or '1', and set to a value of '0', regardless of the value of the GRE header system identifier, an access network to which a session is currently established with the mobile communication terminal is established. It means to transmit the packet data through, and when set to a value of '1' means that the packet data to transmit the packet data through the access network specified by the GRE header system identifier. Transport server.

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