WO2007036398A1 - Method for invoking an application server provided with different operating modes by means of an ip multimedia subsystem - Google Patents

Abstract

The invention relates to method for invoking application servers (APl, AP2, AP3, AP4, AP5) provided with different operating modes by means of an IP multimedia subsystem (IMS), to a method for invoking complex services of a telecommunications network by means of the IP multimedia subsystem (IMS), wherein each said service comprises the applications of the application servers (APl, AP2, AP3, AP4, AP5) provided with different operating modes of the telecommunications network. Said application servers (APl, AP2, AP3, AP4, AP5) must be run through in a defined sequence (RF) for invoking a service and the messages are processed by the application servers (APl, AP2, AP3, AP4, AP5) according to the respective operating mode. A message transmitted by the application server (APl, AP2, AP3, AP4, AP5) to the IP multimedia subsystem (IMS) is evaluated thereby according to invocation criteria (LS) stored therein. The application server (APl, AP2, AP3, AP4, AP5) operating mode by which the message is transmitted is detected by said IP multimedia subsystem (IMS) by means of the transmitted message heading and the invocation of the other application servers (APl, AP2, AP3, AP4, AP5) is controlled according to the operating mode. The invention makes it possible, in particular, to use the application servers (APl, AP2, AP3, AP4, AP5), provided with different operating modes, for services in the telecommunications network which are invoked by means of the IP multimedia subsystem (IMS) without restrictions with respect to the stored applications or data.

Description

description

A method of invoking application servers with different operating modes through an IP Multimedia Subsystem

The invention relates to a method for calling complex services of a telecommunication network through an IP multimedia subsystem, wherein each service comprises applications of application servers with different modes of operation. These application servers must be run through in a specific order for the call of the service, and thereby messages are processed by the application server according to the respective mode.

In recent years, telecommunications networks have become important communication media to mutually exchange data or information in the form of speech, writing, image, etc. Telecommunications networks, such as telephone networks, e.g. traditional, switched telephone networks, mobile networks, etc. and computer networks, in which usually different, primarily independent electronic systems are combined and from which data are usually transmitted in the form of packages - that is, packet-oriented.

From computer networks offering a variety of services, such as the provision and transmission of data and information, etc., protocols are used for the exchange of data between computers within the network or even different networks. If the so-called Internet Protocol IP is used for forwarding data in packet form, these computer networks are also referred to as IP-based computer networks. These IP-based computer networks are widely used today. A computer network that uses the Internet Protocol IP is the Internet known worldwide, such as the entirety of all interconnected computer networks which are also based on the Internet Protocol IP.

In the telephone networks since the nineties, especially the importance of mobile networks in which the terminals for telephony are not connected via local transfer point to the telephone network, but are mobile, through the development of new mobile radio standards such. Global System for Mobile Communications GSM has risen sharply. These standards form the basis for the so-called second-generation mobile networks, the first of which has provided network capacity for a mass market through the use of digital technology for voice and data transmission. Meanwhile, the mobile networks are protected by new standards such as e.g. Universal Mobile Telecommunications System UMTS have been optimized for higher data transmission rates and allow e.g. Services such as video telephony, the transfer of music or video files to a mobile terminal, audio / video messages, etc. The mobile networks based on these new standards are also referred to as third generation networks.

Due to the great importance of IP-based computer networks on the one hand and telephone networks, in particular mobile networks on the other hand, there are now efforts to resolve these two network types by convergence in so-called next generation networks or Next Generation Networks NGN. Next Generation Networks NGN will then take over the tasks of both network types (the telephone and the IP based computer network), i. They enable telephony (transmission of voice) and IP-based data transmission on the one hand.

For example, the convergence can be observed in telephony, where traditional telephone networks in Next Generation Networks, which allow telephoning over an IP-based network, are increasingly being resolved or, for example in the mobile networks, in addition to conventional services such as telephony, answering machine, multimedia or Short Message Service meanwhile also a large part of the IP-based networks such as the Internet made available, mostly based on the Internet Protocol IP services such as E-mail, access to the World Wide Web, exchange of multimedia data, loading of audio or video files to the terminal, instant messaging, etc. can be used on mobile devices.

In order to make these IP-based services available in a telephone network, in particular a mobile radio network, a special architecture structure is used in the Next Generation Networks - the so-called IP Multimedia Subsystem IMS. The IP multimedia subsystem has been standardized by the 3rd Generation Partnership Project 3GPP in a large number of technical specifications TS and represents an open, easily integrable architecture structure for network operators in their telecommunication network structure.

The access to the IP multimedia subsystem is available from any telephone. Computer network with packet-oriented data transmission possible. For the connection of traditional telephone networks such. The Public Switched Telephone Network PSTN uses its own interface systems. A user can therefore access the IP Multimedia Subsystem by various methods, depending on the network used (e.g., switched telephone network, cellular network, wireless LAN, etc.), usually using Internet Protocol IP for access.

For the use of IP-based services by the users, the IP Multimedia Subsystem provides a switching function - the so-called Call Session Control function CSCF. Through the Call Session Control function, the so-called switching computers of the IP Multimedia Subsystem is executed, the structure and process of a multimedia connection between users or to use an IP-based service controlled and controlled. As protocol for the management of these multimedia connections the so-called Session Initiation Protocol SIP is used, which was developed by the IETF (Internet Engineering Task Force) and by a number of Request for Comments RFC like RFC 3261, RFC 3265, etc . is defined.

The services that can be used via the IP Multimedia Subsystem are usually provided by so-called application servers. Usually, the applications and data belonging to the services are stored on these or the services are also executed on them. When using the service, the CaIl session control function uses the SIP protocol to access the corresponding application servers. A call of an application server is carried out, for example, by means of logical addressing by means of a so-called address and in the process a message-usually a SIP message-is sent to the address of the application server. This message is usually formed from a so-called header and a so-called body, where in the header no user data, but various

Administrative data such as Sender address, recipient address, etc. are transmitted and contained in the body, the actual user data.

However, a service may also be composed of several applications provided by different application servers. In such a case, the application servers necessary for the service must be called in a predetermined order and run through by the messages. For this purpose, a list is usually stored in the IP multimedia subsystem for each service user, in which the application servers necessary for the services together with the corresponding call server criteria - so-called filter expressions - are stored in an orderly manner. These filter expressions, which are evaluated by the CaIl Session Control function for each application server call, determine, in addition to the sequence of the application server calls, whether an application server is called or not.

The application servers, on which applications and data of the services are stored, can be installed either within the telecommunications network of the operator, who also operates the IP Multimedia System, or in another - so-called external telecommunications network. Depending on the services and applications provided, the application servers may be used by the operators in different modes - e.g. as a proxy application server or as a back-to-back user agent application server.

As a proxy application server, an application server is called, if it is mediated by this application server in the data traffic between computers of telecommunication networks. A proxy server is a server (i.e., a facility centrally provided for the computers of multiple users, the so-called clients, e.g., services, applications, or data) from which incoming messages pass substantially unchanged.

When a proxy application server is called by the call session control function of the IP multimedia subsystem, the received message is therefore processed by the proxy application server if necessary, and then the essentially unchanged message is sent back to the call session control function or to the switching computer. from which it is executed. The filter expressions can then be applied to this returned message in the IP multimedia subsystem and the message can be forwarded to another application server, so that several Applications for a service can be provided by multiple independent application servers.

Back-to-back user agent application servers are logical units which, as so-called user agent servers, receive and process messages from the IP multimedia subsystem.

In contrast to the proxy application server, which sends back a message received from the IP Multimedia subsystem in edited or unmodified form, the received message is answered by the back-to-back user agent application server. For the call session control function of the IP multimedia subsystem, the receipt of such a response message now means that the processing of the sent

Message is complete, and no more application servers are called.

The back-to-back user agent application server, however, creates a (technically speaking) new message in its role as user agent client, which message is forwarded instead of the message originally received. The back-to-back user agent application server enters an identification such as its name into the header.

The way in which a message is processed by an application server thus depends on the operating mode of the application server. Therefore, the calls of the application server by the IP multimedia subsystem during use of a service on the operating mode of the application server are affected. If a service comprises several applications that are provided by several application servers, the application servers are called up according to the list stored in the IP multimedia subsystem and run through messages. However, if one of the application servers in the chain of application servers to be traversed by messages is used as back-to-back user agent Running application server, so the passage of messages is interrupted. Because the back-to-back user agent app-cation server answers the message sent by the IP Multimedia Subsystem, which completes the chain of application server calls for the IP Multimedia Subsystem.

As a result, the IP Multimedia Subsystem operator has major limitations in setting up services that include applications on multiple application servers. Only one application server in the chain should be allowed to run calls to the service as a back-to-back user agent application server. In addition, this application server must also be called as the last application server in the chain for the service from the IP multimedia subsystem. However, since the application servers are often made available by operators other than the operator of the IP multimedia subsystem, the latter usually has little influence on the operating mode of the application server.

The present invention is therefore based on the object of specifying a method by which it is made possible for services provided in a telecommunication network which comprise applications of a plurality of application servers and wherein the application servers have to be called in a certain order by an IP multimedia subsystem To use application servers with different operating modes without any additional restrictions.

The solution of this object is achieved according to the invention by a method for calling complex services of a telecommunications network through an IP multimedia subsystem, in which each service includes applications of application servers with different mode, which must be run to call the service in a particular order, and wherein Application server messages are processed according to the respective mode, wherein a response message sent by an application server to the IP multimedia subsystem is evaluated according to call criteria stored on the IP multimedia subsystem, then the mode of the application server from which the response message has been sent is detected based on a header of the response message from the IP multimedia subsystem, and then In accordance with this operating mode, calls of further application servers are controlled.

The advantages that can be achieved with the method according to the invention are, in particular, that for services application servers with different operating modes can be used without restriction for the storage of applications or data. In addition, no restrictions with regard to the positions of the application server with different operating modes are necessary. This is particularly because the chain of calls by the IP Multimedia Subsystem, which is necessary for the execution of a service is not interrupted due to the inventive method, since the IP multimedia subsystem is recognized by the header of the response message of the application server, like the others To control calls from application servers.

It is favorable if the application servers called by the IP multimedia subsystem are operated on the principle of a proxy server, since the messages sent by the IP multimedia subsystem are usually sent back essentially unchanged or only in slightly edited form by a proxy application server.

It is advantageous if the application servers called by the IP multimedia subsystem are operated on the principle of a back-to-back user agent application server, because one of an application server after the

Back-to-back user agent principle sent message can be easily recognized by the IP multimedia subsystem, for example, from a back-to-back user agent application server his name is entered in the header of the sent message.

It is advisable to store addresses for the application server together with the corresponding call criteria user-specifically in ordered lists on the IP Multimedia Subsystem, whereby this call criteria can be controlled which application server should be called. These lists can be used to define the order in which the application servers are called for the services and to define the corresponding call criteria or filter printouts for the application servers. In addition, user-specific mapping allows the lists to be easily linked to the user's data, e.g. Permissions are administered.

It is useful if the Session Initiation Protocol SIP, which is based on the Internet Protocol IP, is used for sending the messages between the IP Multimedia Subsystem and the application servers, since SIP is one of the Internet Engineering Task Force IETF with an eye on the Internet specified network protocol for the establishment of communication links, which for the transmission of voice in packet-oriented telecommunications networks such can be used in IP telephony.

The invention is described below by way of example

Reference to the attached figures explained in more detail. Show it :

1 shows the flow of a call of a complex service by an IP multimedia subsystem, in which the service comprises applications of several application servers with different operating modes

2 shows the schematic structure of an exemplary list stored on the IP Multimedia Subsystem Call criteria for several application servers with different operating modes

FIG. 1 shows first, second, third, fourth and fifth application servers AP1, AP2, AP3, AP4, AP5, which are required for the execution of a complex service, since applications for this service on the application servers AP1, AP2, AP3, AP4, AP5 are deposited. Of these application servers AP1, AP2, AP3, AP4, AP5, the first, third and fifth application servers AP1, AP3 and AP5 are operated as proxy application servers. Therefore, messages received by the first, third and fifth application servers AP1, AP3 and AP5 in accordance with the mode of operation of a proxy application server are forwarded in possibly processed form.

The second and fourth application servers AP2 and AP4 use the operating mode of a back-to-back user agent application server. Corresponding to the operating mode as back-to-back user agent application server, the second and fourth application server AP2 and AP4 respond to a received message and then generate and forward a new message, whereby data for identifying such as e.g. a name of the back-to-back user agent application server can be entered, which can be used as second and fourth identifier ID2, ID4 for filter expressions.

FIG. 1 also shows an IP Multimedia Subsystem IMS which comprises a switching computer CSCF and a user-specific list LS for calling a service. Other components of the IP multimedia subsystem IMS, which are irrelevant to the processes explained by way of example, are not entered in FIG. 1 for reasons of simpler representation.

The switching computer CSCF performs the Call Session Control function, which is used for setup, control and management Control of a multimedia connection is responsible for the use of a service by a user. The call session control function of the switching computer CSCF likewise makes the first, second, third, fourth and fifth necessary for the execution of the service

Application server APl, AP2, AP3, AP4, AP5 called. To carry out the connection control and control and for access to these application servers APl, AP2, AP3, AP4, AP5 is used by the switching computer CSCF protocol as the Session Initiation Protocol SIP.

The list for the calls of the application servers AP1, AP2, AP3, AP4, AP5 is defined by the list LS specifically stored on the IP multimedia subsystem, wherein for each application server AP1, AP2, AP3, AP4, AP5 additionally corresponding call criteria in the list LS are stored.

In Fig. 2, the structure of the list LS is exemplified schematically. The list LS comprises in a first column RF the sequence for the calls of the application servers AP1, AP2, AP3, AP4, AP5 for the execution of the service. By means of a second column FD, the respective filter expressions for the call by the switching computer CSCF of the IP multimedia subsystem IMS are then assigned to each application server AP1, AP2, AP3, AP4, AP5. Thus, for example, the first application server AP1 is assigned a filter expression which specifies that the first application server AP1 is only called if no second and no fourth identifier ID2, ID4 of a second or a fourth application server AP2 are present in the header of a message. AP4, which are operated as a back-to-back user agent application server, is included, and a first call criterion AKl for the first application server is met.

Is now a user of a complex service whose applications are stored on multiple application servers APL, AP2, AP3, AP4, AP5, using the IP Multimedia Subsystem is called, then in a first step 1, a SIP message to the switching computer CSCF IP multimedia Subsystem IMS sent. In a second step 2, the head end of the SIP message is analyzed by the switching computer CSCF and the filter elements stored in the list LS are analyzed.

Queried expressions. Now applies the filter expression for the call of the first application server APL, since no second and no fourth identifier ID2, ID4, which are assigned to the second or fourth application server AP2, AP4, present in the header of the message and the first call criterion AKl met is, then in a third step 3, the first application server APl called by the switching processor CSCF and forwarded the SIP message there. In a fourth step 4, the SIP message from the first application server APl according to its mode of operation as proxy application server in unmodified or possibly edited form sent back to the switching computer CSCF.

In a fifth step 5, the switching computer CSCF again evaluates the header of the SIP message and polls the filter expressions stored in the list LS. Since no second and fourth identifiers ID2, ID4 for the second or the fourth application server AP2, AP4 are present in the header of the message and a second call criterion AK2 applies, in a sixth step 6 the second application server AP2 is used by the switching computer CSCF by means of the SIP Message called. Since the second application server AP2 is designed as a back-to-back user agent application server, it is created for the SIP message, a corresponding new SIP message in the header of the second application server AP2 the second, this assigned identifier ID2 entered becomes. This new SIP message is then sent in a seventh step 7 from the second application server AP2 to the switching computer CSCF. In an eighth step 8, the head end of the new SIP message is evaluated by the switching computer CSCF and the filter expressions stored in the list LS are queried. In this case, it is recognized by the switching computer CSCF that the second identifier ID2 is entered in the header of the new SIP message, whereby only the filter expression for calling a third application server AP3, in which no fourth identifier ID4 and a third call criterion AK3 is entered , can apply. Therefore, in a ninth step 9, the third application server AP3, which is operated as a proxy application server, is called. In a tenth step 10, analogously to the fourth step 4, the SIP message sent by the switching computer CSCF is sent back to the switching computer CSCF in possibly processed form.

In an eleven step 11, the switching computer CSCF retrieves the list LS and examines the header of the SIP message. Since in the header still the second, the second application server AP2 associated identifier

ID2, but no fourth identifier ID4 is present, the filter expression for the call of the fourth application server AP4 is recognized as true, provided that a fourth call criterion AK4 is met. Therefore, in a twelfth step 12, the fourth application server AP4, which is embodied as a back-to-back user agent application server, is called by the switching computer CSCF by means of the SIP message. From the fourth application server AP4 the SIP message is then answered according to its mode as a back-to-back user agent application server with a corresponding new SIP message, wherein in the header of the new SIP message the fourth, the fourth application server AP4 assigned Identifier ID4 is entered. In a thirteenth step 13, this new SIP message is transmitted from the fourth application server AP4 to the switching computer CSCF. In a fourteenth step 14, the switching computer CSCF evaluates the header of the new SIP message analogously to the eighth step 8 and polls the filter expressions stored in the list LS. In this case, the switching computer CSCF recognizes that the fourth identifier ID4 is entered in the header of the new SIP message, whereby only the filter expression for calling a fifth application server AP5, in which a fifth call criterion AK5 is entered, can apply , Therefore, in a fifteenth step 15, the fifth application server AP5, which is operated as a proxy application server, is called. In a sixteenth step 16, analogously to the fourth step 4 or to the seventh step 7, the SIP message sent by the switching computer CSCF is sent back to the switching computer CSCF in possibly processed form. In a seventeenth step 17, it is ascertained by the switching computer CSCF that all application servers AP1, AP2, AP3, AP4, AP5 necessary for the service have been passed through and the SIP message is forwarded to, for example, a user computer.

In the IP multimedia subsystem IMS, a distinction must additionally be made between services for the page of the calling user - the so-called originating page - and services for the page of the called user - the so-called terminating page. For it is necessary for the sequence of the method according to the invention for services which are executed on the originating side that the second or fourth application server AP2, AP4 with mode as back-to-back user agent application server on the originating page explicitly requested will also require that services on this page be run. According to the technical specification 3GPP TS 24.229 V6.6.0 Chapter 5.7.3 of the 3GPP, this is done by the second or fourth application server AP2, AP4 by providing the part P-Asserted Identity in the header of the SIP message and by setting a parameter for the origin in Route header of the SIP message reached.

Claims

claims

A method for calling complex services of a telecommunication network by an IP Multimedia Subsystem (IMS), wherein each service comprises applications of application servers (APl, AP2, AP3, AP4, AP5) with different modes of operation, which are used to call the service in a particular Sequence (RF) must be passed through, and wherein by application server (APl, AP2, AP3, AP4, AP5) messages are processed according to the respective mode, characterized in that one of an application server (APl, AP2, AP3, AP4, AP5) to the IP Multimedia Subsystem (IMS) sent message according to the IP Multimedia Subsystem (IMS) stored call criteria (LS) is evaluated that based on a header of the sent message from the IP Multimedia Subsystem (IMS) the mode of the application server (APl, AP2 , AP3, AP4, AP5) from which the message has been sent is detected, and that according to this mode

Calls of other application servers (APl, AP2, AP3, AP4, AP5) are controlled.

2. The method according to claim 1, characterized in that the called by the IP Multimedia Subsystem (IMS) application server (APL, AP2, AP3, AP4, AP5) are operated on the principle of a proxy server.

3. Method according to claim 1, characterized in that the application servers (AP1, AP2, AP3, AP4, AP5) called by the IP multimedia subsystem (IMS) are operated on the principle of a back-to-back user agent application server.

4. The method according to any one of claims 1 to 3, characterized in that addresses for the application server (APl, AP2, AP3, AP4, AP5) together with the corresponding call criteria (AKl, AK2, AK3, AK4, AK5) are stored user-specifically in ordered lists (LS) on the IP Multimedia Subsystem (IMS), and that it is possible by means of these call criteria to control which application server is to be called.

5. The method according to any one of claims 1 to 4, characterized in that for sending the messages between the IP Multimedia Subsystem (IMS) and the application servers (APl, AP2, AP3, AP4, AP5) the Session Initiation Protocol SIP, which on based on the Internet Protocol IP.