KR100811337B1 - Method for setting call inter GGSN - Google Patents

Abstract

The present invention relates to a GGSN (Gateway GPRS Support Node) system, which is a network element of a core network responsible for packet communication in an asynchronous or synchronous wireless mobile communication network.

The method for establishing a call with multiple GGSNs of the present invention is a first process of requesting an address of a GGSN system from an SGSN to a DNS connected to a GGSN and an SGSN in a mobile communication system having one or more data processors, GGSN and SGSN. and; A second step of searching for a load of the GGSN systems stored in a list in the DNS; A third step of informing SGSN of the address of the GGSN having the least load as a result of the search; In the SGSN, a fourth step of transmitting a request message for call establishment to the GGSN; And a fifth process in which the SGSN sends a request message for call setup to the GGSN and establishes a call with the GGSN that has responded.

Therefore, according to the present invention, the GGSN system having the least load is selected among the multiple GGSN systems, so that a particular GGSN system is overloaded and resources of some GGSN systems are prevented from being wasted.

Description

How to set up call with multiple WANs {Method for setting call inter GGSN}             

1 is a block diagram of a synchronous / asynchronous mobile communication system having two or more GGSNs using the conventional and the present invention DNS.

2 is a flowchart illustrating a call setup process in which an MS transmits an Activate PDP Context Request message (or an Activate Secondary PDP Context Request message) to a Serving GPRS Support Node (SGSN).

3 is a flowchart illustrating a call release process from an MS;

4 is a flowchart illustrating a call release procedure from SGSN.

5 is a flowchart illustrating a call release procedure from a GGSN.

6 is a block diagram illustrating an overview of selecting a GGSN system with a minimum load using DNS.

7 is a flowchart illustrating a method of selecting an optimal GGSN according to a load in a multiple GGSN system.

The present invention relates to a GGSN (Gateway GPRS Support Node) system, which is a network element of a core network responsible for packet communication, in an asynchronous or synchronous wireless mobile communication network, especially when the GGSN system is configured as multiple systems instead of a single system on the network. It is about how to use these system resources effectively.

More specifically, the present invention relates to a mobile communication system having at least one data processor, a SGSN (Serving GPRS Support Node) and two or more GGSNs, wherein the GGSN and GGSN are connected to the GGSN and the DNS (Domain Name System). When requesting the address of the system, the DNS retrieves the load of the GGSN systems stored in the list calculated by the number of calls charged to the GGSN system and / or the total number of resources allocated to the SGSN. The SGSN sends a request message for call setup to the GGSN to establish a call with the GGSN.

If the SGSN transmits a request message for call setup to the GGSN and does not receive a response, the present invention relates to a method for establishing a call with a GGSN having a low load that responds to the process again.

Hereinafter, the prior art will be described.

1 is a block diagram of a synchronous / asynchronous mobile communication system having two or more GGSNs using the conventional and the present invention DNS.                         

 1, a mobile terminal (MS) 10 and a base transceiver station (BTS) / base station (Node B) 11a and a base station controller (BSC) / wireless for a user Wirelessly connected to a UMTS Terrestrial Radio Access Network (UTRAN) 11 configured as a Radio Network Controller (RNC) 11b, the base station controller / wireless network controllers 11b are packet controllers (PCFs). Control Function (SGSN) / Serving GPRS Support Node (SGSN) 13 is connected, and the PCF / SGSN 13 is a Packet Data Serving Node (PDSN) / Gateway Support via an IP network. The node is connected to a Gateway GPRS Support Node (GGSN) 14, and the PDSN / GGSN 14 and the PCF / SGSN 13 are connected to a domain name system (DNS) 12.

The prior art is based on the standardization document of 3GPP, which performs the standardization work of the asynchronous mobile communication network.

In summary, in Section 9.2 of 3GPP TS 23.060 V3.3.1, the procedure for establishing a call between a terminal and the Internet is as follows.

As shown in FIG. 2, the MS transmits an Activate PDP Context Request message (or an Activate Secondary PDP Context Request message) to a Serving GPRS Support Node (SGSN).

Then, SGSN finds the IP address of GGSN through DNS (Domain Name System), and then sends Create PDP Context Request message to corresponding GGSN system for call setup. GGSN sends a Create PDP Context Response message to SGSN when it is successfully prepared to set up the call through resource allocation and authentication, and SGSN receives an Activate PDP Context Accept message (or Activate Secondary PDP Context Accept message) to the MS. ) To finish the call setup preparation process.

After the call is over, the terminal sends a Deactivate PDP Context Request message to the SGSN as shown in FIG. 3, and the SGSN sends a Delete PDP Context Request message to the GGSN.

When receiving a Delete PDP Context Request message to request a call release, GGSN informs SGSN that it is ready to release the call through the procedure of releasing the allocated resources for the call and sending billing information. After completing the release process, send the MS a Deactivate PDP Context Accept message to inform the MS of the call release process.

Call release process may be required by SGSN or GGSN as shown in FIG.

The operation of the prior art is described below.

The conventional procedure for call setup in an asynchronous mobile communication network is a method for a mobile communication network in which MS, SGSN, and GGSN are configured in a single system.

When the method for such a single system is generally extended and applied, it can be applied as a method for a mobile communication network in which one GGSN system is interworked with several SGSNs and one SGSN is interworked with several MSs. have.                         

Several terminals make a call setup request to one SGSN managing this, and in the same principle, several SGSNs may request a call setup from one GGSN.

What is assumed in this method is that one GGSN performs better than SGSN to accommodate multiple SGSNs.

The prior art considers a method in a many-to-one interworking structure in which several SGSNs are connected to one GGSN.

In the many-to-many interworking structure, in which several SGSNs are connected to multiple GGSNs, as a method of determining which GGSN's system resources are to be prepared for call setup by the SGSN, Section 7.3.1 of 3GPP TS 29.060 V3.5.0 Listed in The address of the GGSN that SGSN chooses to send a Create PDP Context Request message to set up a call is selected at the beginning of the list stored in DNS.

If there is no reply from the Create PDP Context Request message from the selected GGSN, the call setup request message is transmitted by selecting the address of the next GGSN.

However, in the conventional technology, the GGSN system selected from the DNS for call establishment among multiple GGSN system resources is sequentially selected from the front, thereby increasing the load on only a specific GGSN system and wasting resources of the GGSN system at the back of the list stored in the DNS. I have a problem.

When the GGSN system at the back of the list stored in DNS is used, SGSN requires another address of GGSN in DNS because the resources of the GGSN system stored at the front of the list are exhausted and can no longer accept call setup requests. to be.                         

Therefore, due to the process of inquiring the GGSN address several times, there is a problem that a large delay occurs in preparation for call setup using the GGSN system at the back of the list compared to the call setup using the GGSN system at the front of the list.

The present invention proposes a method for calculating a load rate of each GGSN in DNS and setting up a call accordingly in order to improve system efficiency according to a method sequentially selected from the front regardless of the conventional GGSN load as described above.

The method for establishing a call with multiple GGSNs of the present invention is a first process of requesting an address of a GGSN system from an SGSN to a DNS connected to a GGSN and an SGSN in a mobile communication system having one or more data processors, GGSN and SGSN. and; A second step of searching for a load of the GGSN systems stored in a list in the DNS; A third step of informing SGSN of the address of the GGSN having the least load as a result of the search; In the SGSN, a fourth step of transmitting a request message for call establishment to the GGSN; And a fifth process in which the SGSN sends a request message for call setup to the GGSN and establishes a call with the GGSN that has responded.

Other objects and features of the present invention will become apparent from the detailed description of the embodiments with reference to the accompanying drawings.                     

Hereinafter, a call setup method according to a GGSN load of the present invention will be described with reference to the accompanying drawings.

6 is a block diagram illustrating an overview of selecting a GGSN system with a minimum load using DNS.

Referring to FIG. 6, a mobile station (MS) 61 for a user is wirelessly connected to a UMTS Terrestrial Radio Access Network (UTRAN) 62, and the UTRAN is connected to a Serving GPRS Support Node (SGSN) 63. The SGSN 63 is connected to a plurality of Gateway GPRS Support Nodes (GGSN) 64, and the GGSN 64 and SGSN 63 are connected to a Domain Name System (DNS) 65.

The configuration of FIG. 6 is a method for configuring a mobile communication network using a plurality of GGSN systems because the performance of one GGSN system does not satisfy a user's requirement level.

Therefore, it is necessary when one or several SGSNs interwork with two or more GGSN systems.

In the proposed method of FIG. 6, when SGSN requests the address of the GGSN system from DNS, SGSN informs the address of the GGSN system having the least load considering the GGSN load, instead of selecting the GGSN at the front of the list. This is a method to select a GGSN system with the least load.

In order to support the ability of DNS to select the GGSN system with the least load, in the conventional method, the DSN simply stores the addresses of the GGSN systems, whereas in the proposed method, the DNS provides the load information as well as the addresses of the GGSN systems. You must also have

Therefore, in FIG. 6, GGSN 2 and a call will be set.

In the following description, in the proposed method, when SGSN inquires the address of GGSN to DNS for call setup, the GGSN system address having the minimum load is obtained by searching all the loads of the GGSN systems stored in the list in DNS. Notify SGSN to send Create PDP Context Request message for call setup.

If there is no response from the GGSN system with the least load for reasons such as a failure, SGSN asks the DNS again for the address of the GGSN system and DNS tells SGSN the address of the GGSN system with the next least load. At this time, the load of the GGSN system to be used is to use the total number of calls assigned to each GGSN system or the total resources allocated to the calls.

In addition to the conventional method, an additional process in the proposed method is a process of managing load information of GGSN systems in DNS. When setting up a call to manage load information in DNS, the load information of the GGSN system to which this call is assigned should be increased, and the load information of the GGSN system to which this call is assigned should be reduced when the call is released.

Therefore, when the call is released, it is necessary to send a message related to the call release from the GGSN system or the SGSN system to the DNS.

7 is a flowchart illustrating a method of selecting an optimal GGSN according to a load in a multiple GGSN system.                     

First, one or more SGSNs and two or more GGSNs are configured. (Step 71,72).

Request the address of the GGSN system from SGSN to DNS. (Step 73).

Accordingly, DNS retrieves the load of the GGSN system stored in the list. (Step 74).

The load is calculated by the number of calls imposed on each GGSN system and / or the sum of the allocated resources, and the updating of the load of the GGSN increases the load information of the GGSN system to which the call is assigned when the call is set up. Upon release, the load information of the GGSN system to which the call is assigned is reduced.

In step 74, the DNS informs the SGSN of the GGSN with the least load. (Step 75).

The SGSN sends a Create PDP Context Request message to the GGSN to set up the call (step 76). If there is a response, the GGSN and the call with the minimum load responded are set. GGSN and a call are set up. (Step 77,78).

As described above, in the present invention, in a system having one or more data processor SGSNs (Serving GPRS Support Nodes) and two or more GGSNs, a method for establishing a GGSN and a call with the least load by searching for the loads of the GGSN systems It is about.

Although the preferred embodiment of the present invention has been described above, the present invention may use various changes, modifications, and equivalents. It is clear that the present invention can be applied in the same manner by appropriately modifying the above embodiments.                     

For example, as shown in FIG. 1, when applying to a synchronous method, when selecting one system among multiple PDSNs (or Access Gateway) in PCF for call setup, a PDSN (or a minimum load using DNS) may be used. It can be applied to the method of selecting (Access Gateway).

Therefore, the above description is not limited to the scope of the present invention by the claims.

Therefore, according to the present invention, using the proposed method selects the GGSN system with the least load among the multiple GGSN systems, thus preventing a particular GGSN system from being overloaded and wasting resources of some GGSN systems.

That is, the GGSN system with the least load among the GGSN systems is selected and assigned to each call to provide the best communication quality. It also prevents excessive call setup time for certain calls, which can occur in the process of selecting an assignable GGSN system when some GGSN systems are overloaded.

Claims (5)

In a mobile communication system having at least one data processor, GGSN and SGSN, Requesting an address of a GGSN system from the SGSN by a DNS connected to the GGSN and the SGSN; A second step of searching for a load of the GGSN systems stored in a list in the DNS; A third step of informing SGSN of the address of the GGSN having the least load as a result of the search; SGSN, the fourth step of transmitting a request message for call setup to the GGSN; call setup method with multiple GGSN. The method of claim 1, wherein the SGSN sends a request message for call setup to the GGSN and sets up a call with the GGSN. According to claim 1, If the SGSN transmits a request message for the call setup to the GGSN is not received, the multi-GGSN and the GGSN is characterized in that the call is set up with a small load to respond to the process How to set up an arc. 2. The method of claim 1, wherein the load of the GGSN is calculated by the number of calls imposed on the GGSN system and / or the sum of the allocated resources. 5. The method of claim 4, wherein the updating of the load of the GGSN includes: increasing load information of the GGSN system to which the call is assigned when a call is set up; And reducing load information of the GGSN system to which the call is assigned when the call is released.

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