FI108185B - Procedure for checking connections - Google Patents

Abstract

The invention is concerned generally with packet data transmission in cellular telecommunication system, and more particularly with handling of speech connections transmitted using packet data transmission. According to the invention, the GPRS system is arranged to monitor IP telephony call state change messages, which can be performed by monitoring a transport layer service access point (TSAP), which the IP telephony system uses for call state change signaling. The invention can be used with any IP telephony protocol, such as the H.323 protocol and the SIP protocol. Such a TSAP may be for example a specific UDP (User Datagram Protocol) or TCP (Transmission Control Protocol) port at the IP address corresponding to the mobile station. The monitoring may be performed for example by the GPRS control entities in the mobile station, whereby they are able to determine if a new requested packet connection will be used for a H.323 speech or video connection and negotiate and set up a PDP context having a corresponding level of service. Monitoring in the mobile station is advantageous in mobile originated H.323 calls. The monitoring may as well be performed by a GSN, which is advantageous for mobile terminated H.323 connections.

Description

108185

Connection Management Method - Technical Field of the Invention

The invention relates generally to packet data transmission in a cellular telecommunication system, and in particular to the processing of voice connections transmitted using packet data transmission. In particular, the invention relates to a method according to the preamble of claim 1.

BACKGROUND OF THE INVENTION A. GPRS System 10 The General Packet Radio Service (GPRS) system is for transmitting data using packet switched connections. The GPRS system is designed to be added to existing GSM networks. It is also used in UMTS (Universal Mobile Telecommunication System) networks. The packet data services provided by GPRS are ideal for non-real-time services such as e-mail and / or file transfer services. In the following, the structure of the GPRS system will be described with reference to Figure 1.

The GPRS system introduces two new network elements compared to the GSM framework, namely two types of GPRS support nodes (GSN) 50, 60: the serving GPRS support node (SGSN) 50 and the gateway support node GPRS (GGSN) 60. The SGSN 50 is at the same level on July 20 as MSC (Mobile Services Switching Center) 40. SGSN's main function is to serve mobile stations 10, i.e., to track the location of mobile stations, send data to mobile stations, and perform manufacturing operations and access control. The SGSN is coupled to the base station subsystem 20.30. The gateway GSN (GGSN) 60 connects the GPRS network to external networks such as Internet 90 or X.25 80. 25 The functions of SGSN and GGSN can be combined with the same physical device, or they can be implemented on different physical devices. Further, the GPRS subscriber information is stored in the home location register (HLR) 45. The GSN nodes are interconnected using an IP protocol based on a packet data network 70.

When data packets for mobile communication arrive from external ver 30, 80, 90, they are first received at GGSN 60, which routes the packets to serving GSN 50 at mobile station 10. If GGSN 60 has no information on MS SGSN The GGSN may request location information regarding the MS from the HLR 45. The SGSN forwards the packets to the MS 10 via the base station subsystem 20, 30.

The system supports three different classes of mobile stations. A Class A mobile station may simultaneously use both GPRS and circuit switched services. The Class B mobile 5 message monitors the control channels for GPRS and other network services at the same time, but it can only use another service at a time, either packet or circuit switched. A Class C mobile may only use GPRS services.

In a GPRS system, a PDP (Packet Data Protocol) connection is established before the 10 mobile stations can send or receive data. A PDP connection is a service provided by the GPRS system for a PDP address associated with a mobile station. The PDP address is the address of the MS according to the external network assignment scheme with which the MS wishes to communicate. Further, the PDP connection includes portions of the MS, SGSN, and GGSN that control the traffic associated with the PDP address. The PDP connection also has 15 other parameters, such as service negotiated quality (QoS) and other configuration parameters. Zero, one or more static or permanent PDP addresses can be assigned to a mobile station. Dynamic PDP addresses can also be assigned to the mobile station. The dynamic PDP address is only valid for the specific connection for which the dynamic address is assigned.

The GPRS system is described in more detail in GSM 03.60.

B. H.323 Specification • Packet based networks are increasingly used for both audio and video transmission. The H.323 specification has been created by the International Telecommunications Union (ITU) to provide a standard framework for transmitting voice, video, and data over networks that do not provide quality of service (QoS). Examples of such networks are IP-based networks such as corporate LANs and the Internet. The purpose of the H.323 specification is to enable multimedia products and applications from different manufacturers to work together. The H.323 specification defines functions for call control, multimedia slide and bandwidth management as well as interconnection. H.323-30 defines four main types of network elements: terminals, gateways (GW), gatekeepers (GK), and multipoint control units (MCUs). These will be briefly described below with reference to Figure 1.

Terminal 120, 130 is a client device in a network that typically provides real-time two-way traffic to a user. All H.323 terminals must support voice traffic and must also support picture and data traffic. The H.323 specification defines the various operating states required for different terminals to communicate with each other. The terminal may be implemented using a personal computer (PC) 130, or the terminal may be a separate unit, such as a telephone 120. Other examples - 5 terminals are Internet telephones, voice conferencing terminals and video conferencing terminals.

Gateway 100 is used to connect the H.323 network to other types of networks and / or terminals. For example, the gateway may convert transmission formats or protocols between networks. The gateway may also participate in call set-up procedures between networks.

10 The Gatekeeper 110 acts as a control unit for a particular part of the H.323 network, i.e. the H.323 area. Gatekeeper provides control services for registered endpoints. Further, the gatekeeper performs address mappings between local area names for terminals and gateways to IP addresses. The gatekeeper can also perform bandwidth management, i.e. control of transmission resources. The gatekeeper can also be used to route H.323 calls, in which case the gatekeeper controls the voice, which provides a simple way to provide many different types of services and traffic management features. Although the structure of a gatekeeper is logically different from that of a gateway or multipoint control unit (MCU), the gatekeeper can be implemented on the same physical device as the gateway or MCU.

20 The Multipoint Control Unit (MCU) 140 is a unit that manages a conference call, i.e., connections with at least three participants. The multipoint controller has a multipoint controller (MC) and may also have multipoint processors (MP). MC hand; negotiate relationship management negotiations between the parties. The multipoint processors take care of the actual processing of the data queues, i.e. they perform the mixing, switching and 25 other processing of the audio, image and / or data queues. The MCU functions can be implemented in a dedicated network element, or the functions can be implemented in another H.323 component.

C. Some problems with prior art

Since the GPRS system is a system that provides packet data transmission 30, voice and picture communications according to the H.323 specification can be established via the GPRS system. However, the GPRS rigid system is optimized for data transmission and not for real-time services such as voice or image transmission. Therefore, transmitting voice over a GPRS network such as the H.323 protocol is problematic. Voice transmission in the GPRS system occurs, for example, when the user of the H.323, 108185 4 voice terminal 120 wants to call the mobile station 10, in which case data packets of the voice signal are transmitted over the H.323 network 150, the Internet 90 and the GPRS system 60, 70, 50, 30. 20 through. One particular problem is how the GPRS system can identify which packet data connection is a real-time connection and requires high-quality connection quality, and which connection is a normal data connection. If the GPRS system is unable to correctly detect real-time connections such as voice or video, and to provide a corresponding service level instead of the standard service level used for data connections, the user is distracted by possible delays that are acceptable and normal for data connections.

10 Summary of the Invention

It is an object of the present invention to provide a method for managing real-time connections in a GPRS system. It is a further object of the present invention to provide a system capable of detecting real-time connections.

The objects of the invention are achieved by adapting the GPRS system to monitor a transport layer service access point (TSAP) such as a particular UDP port (User Datagram Protocol) used for IP call setup and release signaling.

The features of the method of the present invention will be apparent from the characterizing part of the independent method claim. The system 20 of the present invention is characterized by what is set forth in the characterizing part of the system independent claim. The network element of the present invention is characterized by what is defined in the characterizing part of the independent requirement for the network element. The mobile station of the present invention is characterized by what is defined in the characterizing part of the independent communication claim 25. The subclaims represent preferred embodiments of the invention.

According to the present invention, the GPRS system is adapted to monitor IP call set-up messages, which may be performed by monitoring the Transport Layer Service Access Point (TSAP) used by the IP telephone system for call set-up signaling. Such a TSAP can be, for example, a specific UDP (User Datag-30 ram Protocol) or TCP (Transmission Control Protocol) port at an IP address corresponding to the mobile station. The term TSAP identifier is used to refer to a specific port number or equivalent identifier in a TSAP. For example, monitoring may be performed with GPRS control entities in the mobile station, whereby the control entities can determine whether the packet connection needs more transmission capacity due to the connection being used for real-time services such as speech or video. The control entities are then able to establish a PDP connection having a corresponding service level. Mobile monitoring is advantageous for outgoing IP calls from a mobile station. Monitoring can also be performed on a GSN, which is advantageous for IP connections terminating in the mobile station.

The invention can be used in an IP call protocol such as the H.323 protocol and the SIP protocol. The following description provides several examples of H.323 protocol connections. However, the invention is not limited to use with the H.323 protocol because other IP call protocols, such as the SIP protocol, can also be used.

Brief description of the figures

The invention will now be described in more detail with reference to the accompanying figures, in which: Figure 1 shows a GPRS system and an H.323 area interconnected according to the prior art, Figure 2 shows a signaling sequence according to a preferred embodiment of the invention, Figure 3 shows another example signaling sequence in accordance with a further preferred embodiment,. FIG. 4 shows a third example of a signaling sequence according to a further preferred embodiment of the invention, FIG. 5 shows a fourth example of a signaling sequence according to a further preferred embodiment of the invention; Figure 7 shows an example of a system according to a preferred embodiment of the invention.

The same reference numerals are used for corresponding entities in the figures.

DETAILED DESCRIPTION 6 108185 1. A first preferred embodiment of the invention

In a preferred embodiment of the invention, a well-known transport layer service access point (TSAP) identifier is used. A commonly known TSAP identifier 5 according to the H.323 specification is a TSAP identifier allocated by the authorities responsible for configuring the TSAP identifiers in a particular network protocol and its associated transport protocol. For example, port 1720 is allocated for use as a TSAP in the UDP protocol. This means that when the UDP protocol is used as a transport protocol for H.323 connections, the connection set-up messages to the network 10 test element or terminal are routed to the UDP port 1720 at the IP address of the network element or terminal.

In this embodiment of the invention, the GPRS system can monitor UDP port number 1720. The detected H.323 call set-up signals on the port then indicate that the corresponding call is an H.323 call, whereby the required capacity for service 15 can be reserved, for example by establishing a corresponding PDP connection.

In the case where the origin of the H.323 call is a GPRS mobile station, the entity performing the monitoring is a mobile station, more particularly a GPRS entity in the mobile station. When the GPRS entity detects H.323 call set-up signaling messages addressed to the UDP port 1720 at the destination, it then requests the network ak-20 to activate the PDP connection according to the call requirements.

In the event that the GPRS terminal is a receiving terminal in an H.323 call, a network element such as SGSN or GGSN can monitor incoming messages addressed to UDP port 1720 at the receiving terminal and activate the corresponding PDP connection establishment at the receiving terminal. terminal.

2. Another Advantageous Embodiment of the Invention According to the H.323 specification, the terminal may use a dynamically allocated port for voice generation signaling. In this case, the output terminal requests a port identifier from the gatekeeper in its area. The gatekeeper returns a port detector, which identifies the port to be used to the receiving terminal, which is then used by the port terminal for call setup signaling.

In a preferred embodiment of the invention, a dynamically determined TSAP is used for call setup signaling. Such an embodiment is accomplished in 7,108,185 ways when the gatekeeper function is integrated into a GPRS network element such as SGSN. In such an embodiment, the gatekeeper may establish the required PDP connection in response to a request from the mobile station for a dynamic TSAP identifier.

In still another preferred embodiment of the invention, the GSN, which acts as a gatekeeper, begins to monitor call setup messages addressed to a specified TSAP after the SGSN has allocated the TSAP identifier and communicated the allocated identifier to the mobile station requesting that the TS AP identifier be allocated. When SGSN detects call setup messages, it can establish matching PDP connections for the call.

3. Example of signaling sequence

Figure 2 shows a signaling sequence according to a preferred embodiment of the invention. FIG. 2 illustrates signaling between H.323 entity 10A mobile station 10, GPRS entity 10B mobile station 10, SGSN 50, GGSN 60 and H.323 remote 15 terminal 120. The H.323 entity 10A in the mobile station 10 may, for example, have a voice conferencing program that can establish and use H.323 connections.

The signaling of Figure 2 may occur, for example, when the MS is in a dormant state, or, for example, when an H.323 call is activated using a PDP address corresponding to an inactive PDP connection, i.e., another PDP connection or those already in existence active.

In this example, the GPRS entity 10B in the MS performs H.323 call set-up: signaling monitoring.

In a first step 205, the H.323 entity 10A in the mobile station 10 initiates call set-up signaling according to the H.323 protocol and sends a PDU 25 (protocol data unit) containing a call set-up message. The PDU is first received by the GPRS entity 10B in the mobile station 10. The GPRS entity 10B detects that the PDU is assigned to TSAP on an external packet network, such as UDP port 1720 at the external network address, and that the PDU contains an H.323 call setup message. The GPRS entity 10B may determine the properties of the H.323 call from the setup message 30 and initiate the PDP connection activation sequence with corresponding parameters.

The PDP connection activation sequence continues according to the GSM 03.60 specification, such as. is shown in steps 210 through 230. The MS 10 transmits 210 ACTIVATES THE PDP CONNECTION

REQUEST message to the SGSN listing the required connection parameters as message parameters. In the next step 215, the MS and SGSN may optionally exchange messages relating to security functions. In the next step 220, the SGSN sends a FORM PDP CONNECTION REQUEST to the GGSN, which connects the GPRS system to the external network. The GGSN responds by sending the 225 FORMS PDP-5 CONNECTION RESPONSE message back to the SGSN. In the next step, the SGSN terminates the PDP connection sequence by sending 230 ACTIVATE PDP CONFIRMATION message to the MS listing the PDP connection parameters as message parameters. The PDP connection activation sequence in steps 210-230 is described in more detail in section 9.2.2.1 GSM 03.60 configuration version 6.2.0.

10 When the ACCEPT message is received, the GPRS entity 10B in MS can send 235 H.323 applications to the H.323 remote terminal of the PDU via SGSN and GGSN. Thereafter, the H.323 entity 10A in MS and the H.323 remote terminal 120 can normally continue call setup signaling and call data transmission.

4. Another Example of Signaling Sequence Figure 3 shows a signaling sequence in accordance with yet another preferred embodiment of the invention. Figure 3 illustrates signaling between H.323 entity 10A in mobile station 10, GPRS entity 10B in mobile station 10, SGSN 50, GGSN 60 and H.323 remote terminal 120. For example, the H.323 entity 10A in the mobile station 10 may have a voice conferencing program that can generate and use H.323 connections.

The signaling of Figure 3 may occur, for example, when the MS already has an active PDP connection and the PDP address of the active PDP connection is used in the H.323 call.

In this example, SGSN entity 10B in MS performs monitoring of H.323 call set-up signaling.

In a first step 305, the H.323 entity 10A in the mobile station 10 initiates call setup signaling according to the H.323 protocol and sends a PDU (protocol data unit) containing a call setup message. The PDU is first received by the GPRS entity 10B in the mobile station 10 which forwards 310 PDUs to the SGSN. The SGSN entity 50 detects that the PDU is addressed to TSAP in an external packet network 30, such as UDP port 1720 at the external network address, and that the PDU contains an H.323 call setup message. The SGSN 50 may determine the properties of the H.323 call from the setup message and initiate a PDP connection modification sequence which modifies the active PDP connection accordingly.

The PDP connection modification sequence proceeds according to the GSM 03.60 specification as shown in steps 315 through 330. In the next step 315, the SGSN 50 sends an UPDATE PDP CONNECTION REQUEST to GGSN 60, to which the GGSN responds by sending a 320 UPDATE PDPSNESS a. Steps 315 and 320 5 are optional according to the GSM 03.60 specification and do not always have to be performed. Next, the SGSN sends 325 MODIFY PDP CONNECTION REQUEST to the MS listing the new parameters of the PDP connection as message parameters. The MS responds by sending a 330 MODIFY PDP CONFIRMATION message back to the SGSN. The PDP connection modification sequence in steps 315 to 330 is described in more detail in section 9.2.3.1 of the GSM 03.60 specification, version 6.2.0.

Once the PDP connection modification sequence is completed, the SGSN will continue to transmit the PDU from the 335 MS through the GGSN to the H.323 remote terminal as normal.

In yet another preferred embodiment, the GPRS entity 10B of the MS performs data packet monitoring, and if a call set-up message is detected, the GPRS entity 10B transmits the message to the SGSN. Preferably, the GPRS entity 10B appends the parameters from the call setup message as a parameter in the message it sends to the SGSN. Upon receipt of the message, the SGSN may perform the PDP connection modification sequence as set forth in steps 315-330 above, after which the MS may continue to send the PDUs as before.

5. A third example of a signaling sequence

Figure 4 shows a signaling sequence according to a further preferred embodiment of the invention. Figure 4 shows signaling between H.323 entity 10A in mobile station 10, GPRS entity 10B in mobile station 10, SGSN 50, GGSN 60 and H.323 remote terminal 120. For example, the H.323 entity 10A in the mobile station 10 may have a voice conferencing program that can establish and use H.323 connections.

Signaling according to Figure 4 may occur, for example, when the H.323 remote terminal transmits · call set-up messages to the MS and the PDP connection of the corresponding PDP address of the MS is inactive.

In this example, the GGSN entity performs monitoring of H.323 call set-up signaling.

First, the H.323 remote terminal 120 transmits 405 a call set-up message in a PDU (protocol φ data unit) addressed to TSAP at the MS PDP address. Upon receipt of the 10,108,185 PDUs, the GGSN checks the 406 PDUs and detects that it is addressed to the TSAP and contains a call setup message. Next, the GGSN retrieves 408 information about the call setup message regarding the nature of the call, for example information about the required quality of service. If the GGSN does not have information about the location of the addressed MS, that is, does not know which GSN is serving the GSN for the MS, the GGSN may at this point request routing information from the HLR. For illustrative purposes, the signaling between the HLR and the GGSN is not shown in Figure 4. In the next step 410, the GGSN sends 410 a PDU NOTICE REQUEST message to the SGSN. Preferably, the GGSN appends the previously extracted data as a parameter to the message informing the SGSN of the required call service level. 10 The SGSN responds by sending a 415 PDU NOTICE RESPONSE message to the GGSN. After transmitting this message, the SGSN sends a 420 REQUEST PDP CONNECTION ACTIVATION message to the MS touching the normal PDP connection activation sequence as described in the following steps 210-230.

The PDP connection activation sequence continues according to the GSM 03.60 specification as shown in steps 210 through 230. MS 10 sends 210 ACTIVATE PDP CONNECTION REQUEST to the SGSN, listing the desired connection parameters as message parameters. In the next step 215, the MS and SGSN may optionally exchange messages regarding security access functions. In the next step 220, the SGSN sends a CREATE PDP CONNECTION REQUEST message to the GGSN by connecting the GPRS system to the external network 20. The GGSN responds by sending a 225 CREATE PDP CONNECTION RESPONSE message back to the SGSN. In the next step, the SGSN terminates the PDP connection sequence by sending a 230 ACTIVATE PDP-ACCEPTANCE message to the MS listing the PDP connection parameters as message parameters. The PDP connection activation sequence in steps 210 to 230 is described in more detail in section 9.2.2.1 of GSM 03.60 specification version 6.2.0 25.

When the PDP connection activation sequence is complete, the GGSN transmits 425 PDUs received from the remote terminal to the SGSN, which forwards 430 to the GPRS entity 10B in the MS, after which the PDU is assigned to the 435 H.323 entity 10A. MS.

* · «30 In another preferred embodiment, the SGSN performs monitoring. In this embodiment, activating the PDP connection after the GPRS system receives the PDU from the H.323 remote terminal is performed according to prior art, for example, as described in section 9.2.2.2.1 of the GSM 03.60 specification version 6.2.0. After the PDP connection is activated, the data packets begin to flow through the SGSN. Kim SGSN v 35 detects a call setup message in the data packet, the SGSN initiates a PDP connection modification procedure as previously described with reference to steps 315-11118185303 in FIG. 3 or, for example, as shown in section 9.2.3.1 of the GSM 03.60 specification version 6.2.0. This embodiment has the advantage that the function of the invention can be fully implemented in SGSN without the need for new signaling messages.

6. A fourth example of a signaling sequence

Figure 5 shows a signaling sequence according to another preferred embodiment of the invention. Figure 5 shows signaling between H.323 entity 10A in mobile station 10, GPRS entity 10B in mobile station 10, SGSN 50, GGSN 60 and H.323 remote terminal 120. For example, H.323 entity 10A in mobile station 10 may have a voice conferencing program that can establish and use H.323 connections.

The signaling of Figure 5 may occur, for example, when the H.323 remote terminal sends call setup messages to the MS and the PDP connection of the corresponding PDP address of the MS is already active.

In this example, the SGSN entity performs monitoring of H.323 call set-up signaling.

First, the H.323 remote terminal 120 transmits 505 a call setup message in a protocol data unit (PDU) assigned to the TSAP at the MS PDP address. The GGSN forwards 510 PDUs to the SGSN. Upon receipt of the PDU, the SGSN checks the 511 PDU and detects that it is addressed to the TSAP and contains a call setup message. Following this, the SGSN decrypts 512 information about the call set-up message regarding the nature of the call, for example information about the required quality of service. If the service level is not: good enough for the call, the SGSN may initiate the PDP connection modification sequence, which is the case described in Figure 5. The modification sequence has steps 315 to 330, which will be described below.

The PDP connection modification sequence continues according to the GSM 03.60 specification as shown in steps 315 to 330. In the next step 315, the SGSN 50 sends a UPDATE PDP CONNECTION REQUEST to GGSN 60, to which the GGSN responds by sending 320 UPDATE PDP CONNECTION RESPONSE. Steps 315 to 320 are optional according to the GSM 03.60 specification and do not always have to be performed. Next, the SGSN sends 325 MODIFY PDP CONNECTION REQUEST message to the MS listing the new parameters of the PDP connection as message parameters. The MS responds by sending a 330 MODIFY PDP CONNECTION ACCEPTABLE message back to \ 'SGSN. The PDP connection modification sequence in steps 315 to 330 is described in more detail in section 9.2.3.1 of the GSM 03.60 specification version 6.2.0.

12 108185

When the PDP connection modification sequence is completed, the SGSN transmits a 515 PDU containing a call setup message to a GPRS entity in 10B MS, then the PDU is assigned to 520 H.323 entity in 10A MS.

7. Example of Method 5 The method according to a preferred embodiment of the invention will now be described with reference to Figure 6. In this method, data packets transmitted by the GPRS system are monitored in step 605 for packets containing connection set-up messages. If such a data packet is not detected in step 610, monitoring continues in step 605. If a packet containing a connection message 10 is detected, the information contained in the connection message is extracted from the message in step 615 and used to determine at least one parameter in the PDP connection. The monitoring may advantageously be performed in the serving GPRS support node, the gateway support node GPRS or, for example, in the GPRS mobile station. For example, the parameter may be the maximum allowable delay, priority, or amount of transmission resources reserved for 15 PDP connections. Preferably, said connection set-up messages being monitored are H.323 connection set-up messages.

The next step 625 checks whether the PDP connection is already active for the connection. If the PDP connection is not active when the packet is detected, said PDP connection is established 630 at least partially according to said at least one parameter.

If said PDP connection is active when a packet is detected, said PDP connection is modified at least partially according to said at least one parameter.

8. Example of system

Figure 7 shows an example of a system according to a preferred embodiment of the invention. Figure 7 illustrates a portion of a GPRS system, namely, a GGSN 60 connected to an external network 80, 90, such as an X.25 network or the Internet, SGSN 50, and an internal IP network 70 in a GPRS system. Figure 7 further shows a home register 45 connected to the GPRS network 70, a base station controller (BSC) 30, two base stations 20 and a mobile station 10.

The system 700 according to the invention has means 710 for monitoring data packets transmitted in a GPRS system, means 720 for detecting a call set-up message in the data packet and means 730 for determining at least one connection parameter based on information in the detected call set-up message. '' 108185 13

Preferably, the system further comprises means 740 that initiate the establishment of the PDP connection, at least in part, based on said at least one connection parameter. Further, the system preferably comprises means 750 for initiating, at least partially, modifying the PDP connection based on said at least one connection parameter.

The system of the invention may advantageously be implemented in a single network element 50, 60 in a GPRS system. Preferably, the network element may be a serving GPRS support node. Further, the system may also be implemented as a gateway in a GPRS support node.

However, the invention is not limited to a system that is comprised in a single element, since different means for implementing system functions can also be implemented in more than one separate network element.

According to a preferred embodiment, mobile station 10 has means 710 for monitoring data packets, means 720 for detecting a call set-up message in the da-15 packet and means 730 for determining at least one connection parameter based on information in the detected call set-up message.

Preferably, the means 710, 720, 730, 740, 750 are implemented using software stored in the memory element of the network element control unit or in the mobile devices which programs are executed in the microprocessor of the control unit.

20 9. Connection Status Change Signaling; The foregoing examples illustrate the use of the invention in connection with call setup signaling. However, the invention can also be used in connection with other types of call state change signaling, such as call release signaling.

In such an embodiment of the invention, if call release signaling is detected, a corresponding PDP connection modification or release procedure is initiated.

For example, in one example of such an embodiment of the invention, the GPRS system may monitor UDP port 1720. The detected H.323 call release signals on the port thus indicate that resources for a corresponding call can be released, for example, by releasing the corresponding PDP connection.

In yet another embodiment of the invention, signaling of connection status, such as signaling associated with a change in connection parameters, is monitored. For example, f - · if the data rate of the H.323 connection changes during the connection, the GPRS system detects the associated signaling, interprets the signaling to estimate how much resources are needed after the change, and changes at least one parameter in the corresponding PDP connection. accordingly.

In the following claims, the term connection status change message refers to call set-up messages, call release messages, and messages intended to change the characteristics of the corresponding call.

The entity performing the monitoring of the connection state change signaling, such as call release signaling, may preferably be an SGSN associated with the call.

10. Other Aspects Although the method of the invention has been described in the foregoing description using examples of a GPRS rigid system, the invention is not limited to use in a GPRS system since the invention can also be used in other packet data radio systems such as those developed from the second generation GPRS system.

As described earlier, the invention can be used in an IP call protocol such as the H.323 protocol and the SIP protocol. The previous discussion provides several examples of connections to the H.323 protocol. However, the invention is not limited to use with the H.323 protocol as other IP speech protocols, such as the SIP protocol, can also be used.

The name of a particular function entity, such as a base station controller, is often different for different cellular-20 traffic systems. For example, in a UMTS system, a function entity corresponding to a base station controller (BSC) is a radio network controller (RNC). Therefore, the terminology used for the various functional entities in this specification is merely an example of a GSM system and is not intended to limit the invention in any way. Further, the various command names used in this description are merely examples and the invention is not limited to the use of the command names used herein.

Through the foregoing description, one skilled in the art will appreciate that the invention may be modified in various ways within the scope of the invention. Although a preferred embodiment of the invention has been described in detail, it will be apparent that many modifications and modifications are possible, all of which are within the spirit and scope of the invention.

Claims (19)

108185 15 A method for managing connections in a packet data radio system, characterized in that data packets transmitted by the packet data radio system are monitored for packets containing connection status change messages, and if 5 packets containing a connection status change message are detected, in connection with the packet data of the tar radio system. A method according to claim 1, characterized in that said connection status change messages being monitored are connection establishment messages. A method according to claim 1, characterized in that said connection state change messages being monitored are connection release messages. The method of claim 1, characterized in that said connection status change messages being monitored are H.323 connection status change messages. A method according to claim 1, characterized in that said connection state change messages being monitored are connection state change messages according to the SIP protocol. 6. A method according to claim 1, characterized in that the packet data system is a GPRS system. A method according to claim 1, characterized in that the method • comprises the steps of establishing, at least in part, said packet data connection of a packet data radio system according to at least one of said parameters. A method according to claim 1, characterized in that the method comprises the steps of modifying at least partially said packet data connection of the packet data radio system according to at least one of said parameters. • · A method according to claim 6, characterized in that said monitoring is performed in the serving GPRS support node. The method of claim 6, characterized in that the monitoring is performed in a GPRS gateway support node. • «*. 16 108185 The method of claim 6, characterized in that said monitoring is performed in a GPRS mobile station. A system for managing connections in a packet radio system, characterized by: means for monitoring data packets transmitted in a packet radio system, means for detecting a call set-up message in the data packet, and means for determining at least one connection parameter based on information in the detected call set-up message. The system of claim 12, characterized in that the system 10 further comprises means for establishing, at least in part, a packet data connection of the packet radio system based on said at least one connection parameter. A system according to claim 12, characterized in that the system further comprises means for modifying the packet data connection of the packet radio system, at least in part, based on said at least one connection parameter. 15. A network element of a packet data radio system, characterized by: means for monitoring data packets transmitted by a network element, means for detecting a call set-up message in the data packet, and means for determining at least one connection parameter based on information in the detected call set-up message. The network element of a packet data radio system according to claim 15, characterized in that it is a GPRS network element. The network element of a packet data radio system according to claim 16, characterized in that the network element is a serving GPRS support node. The packet data radio system network element of claim 16, characterized in that the network element is a GPRS gateway support node. A mobile station, characterized by: means for monitoring data packets, means for detecting a call set-up message in the data packet, and means for determining at least one connection parameter based on information in the call set-up message. 108185 17