DE102005013905A1 - Determining the assignment of data streams to payload connections by notifying detected data of at least one data stream to a control node - Google Patents

Abstract

The invention describes a method, a network unit and a system for determining the assignment of data streams to payload connections by notifying a control node (PDF, CRF) of detected data of at least one data stream in a network unit (GGSN, PDG) of a communication network. According to the invention, at least one packet filter sent from the control node (PDF, CRF) in the network unit (GGSN, PDG) evaluates data of at least one data stream relating to the match with at least one parameter of the packet filter and DOLLAR A from the network unit (GGSN, PDG) Depending on the evaluation result to the control node (PDF, CRF) at least one piece of information regarding the evaluated data of the at least one data stream is sent.

Description

The The invention relates to a method, a network unit and a system for determining the assignment of data streams to payload connections by notifying a control node at detected data of at least one Data stream in a network unit of a communication network.

In 3GPP standardization is for service-dependent authorization of construction from IP user connections via the packet-oriented so-called "General Packet Radio Service" (GPRS) mobile network the so-called "service Based Local Policy "(SBLP) standardized in TS 23.207 and TS 29.207 and TS 29.208. The GPRS Payload connections are point-to-point connections and are also called "Packet Data Protocol "(PDP) Called contexts. The structure initiated by the mobile device, the so-called "user equipment" (UE) and the modification of PDP contexts is done at the so called "Gateway GPRS Support Node "(GGSN) about the so called go interface of the so-called "policy decision function" (resource decision function) (PDF), which knows the services currently used by the terminal. The PDF is over these services from one or more so-called "Application Functions "(application functions) (AF) informed with the terminal to negotiate the service Exchange signaling messages, for example, in the like called "IP Multimedia core network subsystem "(IMS) of 3GPP used SIP protocol, IETF RFC 3261. The authorization sets the allowed for the PDP context so-called "Quality of Service " (QoS), ie the bandwidth and the so-called QoS Class the allowed delay the packages.

The PDF knows which IP data streams belong to a service. Under a data stream here is a sequence of data packets with the same sender and recipient Address, as well as the same type of user data transported therein be understood. In case of IP / UDP or IP / TCP transport should the IP data stream in addition characterized by the same UDP or TCP port numbers of sender and receiver be. It is possible, that a terminal builds several PDP contexts for the GGSN and uses them at the same time. to Authorization of a PDP contexts, the PDF must therefore know which IP data streams be transported in it.

The previously standardized in TS 29.207 for SBLP, which allows the PDF to recognize which IP data streams in a PDP context, uses the so-called "authorization token." This token becomes for a service session generated by the PDF at the request of the application function and signaled by the application function to the terminal. The terminal uses the token as well as so-called "flow Identifier ", ie additional Indexes that specify the IP stream within the service in construction and change indicate a PDP context in the corresponding signaling, for which IP streams the PDP context should be used. Authorization tokens and Flow Identifiers are collectively referred to as "Binding Info." The GGSN passes this information from the PDP context signaling over the Go interface to PDF on.

The However, using the authorization token has a number of Disadvantages result. So must the signaling between the application function and the terminal support the transport of the token, what is present only for the SIP signaling is the case. Also, the need for the useful connection belonging Signaling in the access network to support the transport of Binding Info, what though for the PDP contexts of the GPRS, but not for alternative access networks, which are in the 3GPP of interest, such as WLAN or DSL. For GPRS gives it's the limitation that first from the terminal Built-up PDP context does not support Binding Info, and the terminal Therefore, upon receipt of a token further build PDP context (s) got to. Therefore, the first established PDP context can not be monitored via SBLP become.

In the case of GPRS, the establishment or modification of a PDP context is triggered by the terminal by means of standardized signaling in TS 29.060. In this case, the terminal informs the GGSN by means of packet filters in the so-called "Traffic Flow Template" (TFT, coding according to TS 24.008) how IP data streams received from the IP core network are to be distributed to PDP contexts for further transport to the terminal only contain packet filters for data streams in so-called "downlink" direction, ie from the IP core network to the terminal. By contrast, packet filters for data streams in the so-called "uplink" direction, ie from the terminal to the IP core network, are not included If the GGSN signals the TFT to the resource decision function as already standardized for FBC, the resource decision function can also use this information, However, it is not always possible for the resource decision function to use the information contained in TFT to unequivocally distribute the downlink IP data streams described by the application function to PDP contexts, for example, the application function can only provide information to the IP address and / or port number of the recipient, while the terminal in the TFT only gives details of the sender of the IP packets It is not possible to assign uplink data streams to PDP contexts using the information contained in the TFT.

task The invention is a control node, such as a Resource decision function (PDF unit) or a charging control function (ORF unit), by means of an efficient and simple procedure to enable to know which data streams in which PDP context are transported.

The Task is inventively each things the independent one claims solved. Further developments of the invention are specified in the subclaims.

One The core of the invention is to be seen in that a control node a communication network, for example a resource decision function (PDF unit) or a charging control function (CRF unit), in another network unit of a communication network, for example, in a Gateway GPRS Support Node (GGSN) or in another gateway, to individual user connections to the access network, For example, PDP contexts, associated packet filters installed, the one or more data streams describe, and that the further network unit of a communication network with at least one packet filter obtained from the control node Evaluates data of at least one data stream, an evaluation result created and if so according to the packet filter to be detected data of at least one data stream to be detected becomes at least one information concerning the evaluation result sent to the control node. This is called the communication network a cellular mobile network, a packet-switched network, an IP network etc. used. It will be at least one parameter of the packet filter compared with parameters of the data of at least one data stream and at agreement the control node informed accordingly. So it's the control node, for example, a PDF unit, a CRF unit, etc., possible to recognize which IP data streams in which PDP context are transported.

Next the authorization can the control node this information use to inform the application function about events, the one used to transport the corresponding IP data connections PDP context concern, for example, the reduction of the user connection.

Next the use described in the context of SBLP is the present Invention also for also in the 3GPP in TS 23.125 as well as TS 29.210 and TS 29.211 standardized so-called "flow Based Charging "(FBC) applicable. For FBC, so-called "charging rules" from the so-called charging control function "Charging Rules Function "(CRF) on the Gx interface to, for example, the GGSN for specific PDP context (s) Installed. The billing rules describe IP data streams also for they apply rules for billing. The CRF unit selects the Charging Rules under consideration from present from the terminal services used, via which is informed by application functions via the Rx interface.

For FBC is so far no solution standardized to the CRF unit (Charging Rules Function) in any case made it possible to know which IP data streams in which PDP context are transported. Charging Rules therefore become correspondingly frequent installed in several PDP contexts. That's why the standard looks so far only very limited Notifications of the CRF unit to the application function. Also This is why the CRF unit often has to identical charging rules install in many PDP contexts.

The CRF unit can be the information which IP streams in which PDP context, via the inventive method receive. The CRF unit can use this information on the one hand, around the billing rules accordingly over Distribute PDP contexts, and thus the number of charging rules required by the GGSN and thus also to reduce the processing load for data streams. In addition, can the CRF unit will use the information in a similar way to the PDF unit the application function via To notify events that are relevant to the transport of the corresponding IP data connections used PDP contexts. So far sees the standard only requires the CRF unit to inform the application function, when all PDP contexts to a terminal have ended. So that can the application function will not be sure to be informed if the for a service used PDP contexts are terminated because of other PDP contexts used. Also it was the CRF unit so far not possible, the application function to give the information which data streams in which PDP contexts be transported. The application function could use this information for statistics or the fee saved data, which is better with the GGSN collected Data can be correlated.

3GPP is currently using alternative packet-oriented access networks examined for GPRS, for example WLAN and DSL. Again, the use of SBLP and FBC of interest and the method of the invention is applicable. Here, another so-called "Packet Data Gateway" (PDG = packet data gateway) assumes the role of the GGSN and extends packet payload data between the point-to-point connections to terminals in the access network and the core packet network, for example The point-to-point connections are often emulated when using a packet network as the access network, for example, through the use of IP over IP technology.

The The CRF unit and the PDF unit can be considered as control nodes which are signaling messages with the packet data gateway (e.g., GGSN) to exchange the treatment of point-to-point connections to Access network and / or the treatment of received user data in the packet data gateway to influence. The control node knows which packet streams from and to a terminal are to be expected, for example because they correspond to an application function Received information. The control node does not know, like the terminal the packet streams over its Distributed PDP contexts.

The inventive method provides that a control node, such as a PDF unit or a CRF unit, on a network unit, for example a "Packet Data Gateway" (PDG), a GGSN etc., to individual Nutzver connections to the access network, for example PDP contexts, associated packet filters installed, the one or several data streams identify and the network entity hereafter the control node informs that it receives data packets matching the packet filter, where the network unit notifies the user connection used and the or the data stream or data streams identified by the packet filter or indicates the packet filter.

One Packet filter allows the identification of one or more data streams and is by receiver and possibly also sender address, direction of the data stream (to the Kennetz or to the access network), as well as possibly the type of user data transported therein defined. For IP packet filters the definition also includes receiver and possibly transmitter port number.

It is possible, that the control node first qualifies the same packet filters for all of the data streams establish future useful connections. The useful compounds in question can identify the control node, for example, by the address of the terminal. For this purpose, the network unit must notify the control node of this address, when a payload connection is established. In the case of GPRS can the GGSN also assigns to the control node the one associated with a PDP context TFT signal, and the control node can also this information use to select the useful compounds in question.

To the Detecting a data stream, it suffices if the network unit the first data packet matching the corresponding packet filter is received. Around the effort at the network unit and the signaling load at the The interface to the control node needs to be kept low Network unit does not tell the control node whether and how often the Network unit further matching data of at least one data stream receives. In a variant of the invention, the network unit shares the control node but also with, when over does not receive any matching data packets over a certain timeframe. These For example, in the case of SBLP or FBC, information can be the PDF unit or forward the CRF unit to the application function. The PDF unit can also use this information to get the authorized QoS of the PDP context. The related behavior of the PDF unit may also depend on the service concerned. For example, it can for telephony to longer Breaks in the data stream come while a permanent one with other services Data stream is expected.

In an advantageous embodiment of the invention, the control node of the network unit at the Install each packet filter to see if they have a notification for this packet filter wishes if the network unit receives corresponding data streams. The control node can in certain cases to waive an appropriate notification to signaling load at the interface to the network unit and processing load the network unit to save, for example, if the terminal only one Useful connection used or if the PDP context used a uses low and thus cheap QoS class.

In addition, can the control node of the network unit when installing a Packet filters also tell if he wants a notification when the network unit over does not receive any matching (IP) data packets for a certain amount of time, and define the appropriate time frame. The control node can this depends decide on the corresponding service.

It is to be expected that after establishing or changing a payload connection, the network unit will often discover multiple data streams at almost the same time, all of which are required for a new service. Therefore, it is advantageous if the network unit for a defined period of time after the Setup or change a user connection waits, and then all detected in this period data streams reported at once. In the case of SBLP, however, the period used in the GGSN must be less than the time period used by the PDF unit.

In stores a further advantageous embodiment of the invention the network unit the information determined, which IP data stream in which useful connection is transported, first yourself and shares this information with the control node in signaling in terms of other events concerning the user connection. This variant is advantageous if the control node this information only needed to respond to the signaled event. For SBLP is the variant, however, not suitable.

In a further advantageous embodiment of the invention finds the message about the state of all packet filters for the connections of a terminal regularly. The time interval should be configurable by the operator. This variant is advantageous to the individual messages to Minimize control node. The downside is that the information about the state of the packet filter by the configurable time interval delayed can be.

According to the invention, SBLP can result from:
According to the already standardized SBLP, the PDF unit installs so-called "gates" at the GGSN for the PDP contexts used by SBLP A "gate" includes a packet filter as well as information for the GGSN to discard or forward corresponding IP packets, ie how data should be treated. However, the standardized SBLP does not yet provide notification according to the invention to the PDF unit if data packets corresponding to the gate are detected. According to the invention, the GGSN notifies the PDF unit when it receives data packets corresponding to a gate.

If the GGSN the PDF unit to the authorization of a new or modified PDP context, the PDF unit must first gates for everyone in Install question coming IP data streams. Similarly, the PDF unit must first appropriate Gates in all of her already known and for an IP data stream in question install future PDP contexts, for example, if the PDF from the description of a new service from an application function learns that this IP data stream will start soon. Installed according to the invention the PDF unit standardized the same gates differently than before possibly in multiple PDP contexts, and selects the corresponding PDP contexts not using the Binding Info out. Instead, choose the PDF unit the for an IP data stream in question PDP contexts using the the IPv4 address assigned to the PDP context or the IPv6 address prefix of the terminal out. additionally For example, the PDF unit may have the TFT information associated with the PDP context consider.

According to the previous one SBLP standard, the GGSN also uses the gates to downlink data streams to PDP Distribute contexts. However, this requires a gate in exactly a PDP context is installed. Since it may be necessary according to the invention to install a gate in multiple PDP contexts uses the GGSN according to the invention for selecting the Downlink IP data streams on a PDP context the TFT packet filter signaled by the terminal instead of the gates, when the UE for the PDP context has signaled no binding info. Of which is the functionality the gates, data streams also to reject, Not affected as the gates on all eligible PDP contexts be installed. The GGSN first applies the received downlink data streams to the TFT filters on to the data streams assign to a PDP context. Then the GGSN applies for everyone PDP context separately disconnects each installed gates to decide whether the downlink data stream is transported in the PDP context or must be discarded. This data streams, the to fit any gate, discarded.

There the terminal in the construction or the change of a PDP context the corresponding IP data streams still does not send, the PDF unit must first, for example, for a defined period, the PDP context without knowledge of it later promoted IP data streams authorize. For this, the PDF unit has to be so high for the PDP context QoS (quality of the service) authorize that it is sufficient for each distribution of the IP data streams. For example, the PDF unit may have high preconfigured values use. However, it is beneficial if the PDF unit is included considered, which IP data streams for the PDP Context as described above, and only the highest for one the eligible IP data stream required QoS class as well as for all in Question coming IP data streams needed together Authorize bandwidth.

During the transition period, the PDF unit expects the GGSN to inform them which IP streams were discovered in the PDP context. The PDF unit stores the information which IP data streams were discovered in the PDP context for each monitored PDP context. At the end of the defined period of time, the PDF unit determines the IP data streams detected quality of the service QoS of the PDP context to be used in the PDP context, whereby the algorithm standardized in TS 29.208 can be used unchanged, and signals the GGSN the correspondingly changed authorized quality of the service QoS with already standardized commands, preferably only if it originated from the original authorized quality of service QoS deviates. The GGSN will, according to the existing standard, upon receiving such signaling, correspondingly lower the quality of the QoS service of the PDP context.

It is advantageous to the signaling at the Go interface so too change, that the PDF unit when querying the authorization of the PDP context from the GGSN over from the terminal required quality the service QoS is informed. In this case, the PDF unit becomes only those of the terminal required quality of the service to authorize QoS. As the terminal is already under construction or the change of the PDP context knows which IP data streams promoted in it It will only be the quality of service actually required QoS demand. This quality QoS service is common less than the quality of the service initially estimated by the PDF unit QoS. Thus, often can the signaling of the changed authorized quality QoS at the end of the transitional period be avoided.

The PDF unit can be the length dependent on the defined period from the service described by the application function. For example, some services require that User of a terminal accepts the call before data streams are sent while at an answer by a "machine" or terminal essential fast data streams are to be expected. The PDF unit can be the expiration of the defined Period also depends on it make the application function prompt them to instruct the GGSN the received ones belonging to the service IP data streams not to reject but to pass on, that means the corresponding ones Gates open. This can be done during of building a service will be beneficial, as often no streams be sent, for example, until a user in the case of telephony the phone picks up. For the IMS (IP multimedia core network subsystem) becomes the operator It is recommended to open the gates only at this time.

The PDF unit can be the final one Quality of the Determine service QoS of a PDP context also as described above and finish the defined period as soon as they are for each for example, from the service descriptions signaled by an application function known IP data stream from or to a terminal that may be transporting in the PDP context is received information in which PDP context the Data stream is transported.

The PDF unit can then remove a gate in a PDP context if they from the GGSN about it is informed that the corresponding data stream in another PDP context was discovered in order to find the necessary computing power to find the GGSN matching gates for received IP data packets and also to reduce the necessary memory. This embodiment assumes, however, that the terminal transmits the PDP context a data stream does not change.

The PDF unit can also gates after the defined period of time for in remove IP data streams not discovered in PDP context in this PDP context, at the GGSN the necessary Computing power to find matching gates for received IP data packets and also the necessary memory to diminish. This embodiment However, has the disadvantage that only after the expiry of the defined Periodic data streams and should therefore only be used by the PDF unit if the PDF unit knows that matches the gate streams either immediately upon receipt of appropriate information from the application function or not expected at all.

If the PDF unit to the terminal enable want, data streams at any one time from one PDP context to another to relocate leaves the Gates PDF unit in all relevant PDP contexts installed as long as the IP stream may be transferring becomes. This embodiment is especially for so-called uplink data streams advantageous, So for streams from the terminal to the GGSN.

The terminal must in so-called downlink data streams, ie in data streams from the GGSN to the terminal, modify the TFT information in one or more PDP contexts to the transport of a data stream in another PDP context and the GGSN notifies the PDF unit in this Case. If the PDF unit is informed by the GGSN that a in the PDF unit already assigned in a first PDP context Data stream discovered in another PDP context, notes the PDF unit that the data stream now in the other PDP context is transported. additionally The PDF unit matches the authorized quality of the QoS service in the first one PDP Context so that the data stream is no longer considered there will, and will fit the authorized quality of service QoS further PDP context so that the data stream is considered there.

There the PDF unit has the information which IP data streams in one PDP context can be transported, the PDF unit can the responsible for these data streams application functions Messages about pass on these PDP related events, for example via the Degradation of the PDP context or the temporary loss of the connection at the air interface. The PDF unit can also handle the affected Specify IP data streams.

Besides the PDF unit can store the stored information about the Distribution of IP data streams via PDP Then consider contexts if, in the following, the GGSN is about authorization for a new or the change of an existing PDP context. This can be for example come when the terminal starts another service in addition to an existing service. in this connection be for the determination of the authorized quality of the service QoS for one new PDP context only considers IP data streams, which so far none PDP context are assigned. For the determination of the authorized quality of the service QoS of a modified Existing PDP context will be the context previously assigned to this PDP context IP data streams considered as well as IP data streams, the have not yet been assigned to any PDP context. This embodiment assumes, however, that the terminal does not have the PDP context for transmitting a Data stream changes.

If the PDF unit to the terminal enable want, data streams at any one time from one PDP context to another to relocate the PDF unit all eligible data streams when the GGSN order authorization for one new or changing one existing PDP context. The candidate data streams determined the PDF unit as described above, for example, based on the address of the terminal and the TFT information and taken into account as well as data streams, which the GGSN has already reported in another PDP context.

If the GGSN of the PDF unit signals that it is a packet filter receives matching IP packets or not receiving anymore, the GGSN must have the appropriate IP data stream in the signaling express. It is advantageous if the GGSN in the TS 29.207, Annex C defined so-called "flow Identifier "used also in the signaling between the application function and the PDF unit used to detect the detected IP data stream express. In order to make this possible, the signaling at the Go interface must be extended so that the PDF unit to the GGSN already during the installation of a packet filter the corresponding flow identifiers (s) (data stream identifiers) telling. With signaling is basically the replacement at least a signaling message between participating network units to understand. additionally it is advantageous if at least one parameter for identification of the service described by an application function the flow identifier is assigned to the packet filter.

In an alternative embodiment The GGSN of the PDF unit directly signals an analogous description the packet filter, as with the installation of the packet filter used when matching IP packet packets to a packet filter receives or no longer receives. This description includes sender and recipient address as well as port number for IP Packages, as well as the type of user data transported therein.

For FBC, the method according to the invention can be used as follows:
According to the invention, the GGSN notifies the CRF unit when it receives data packets corresponding to a charging rule "Charging Rule".

The charging rule contains already "flow Identifier "for everyone in it corresponding IP data streams. In the sensible use the billing rules Does it make sense to use it as a charging rule depending Weil only one data stream and only one packet filter contains. Alternatively, the standardized data structure for the charging rule be changed according to the invention that each packet filter within the charging rule individually "Flow Identifier" are assigned.

If the GGSN assigns the CRF unit billing rules for a new or modified PDP context, install the CRF unit according to the existing one Standard first charging rules for all eligible IP data streams. Likewise, the CRF unit initially installs appropriate charging rules in all of her already known and for an IP data stream in question coming PDP contexts, for example, if the CRF unit out the description of a new service from an application function learns that this IP data stream will start soon.

According to the invention, the CRF unit may remove a billing rule in a PDP context if it is informed by the GGSN that all data streams corresponding to the billing rule have been discovered in other PDP contexts. As a result, the necessary computing power for finding suitable charging rules for received IP data packets and also the necessary memory can be reduced at the GGSN. This Ausfüh However, in the case of uplink data streams, the terminal does not assume that the PDP context used to transport a data stream does not change. In so-called downlink data streams, ie data streams from the GGSN to the terminal, the terminal changes the TFT information in one or more PDP contexts to achieve the transport of a data stream in another PDP context, and the GGSN notifies the CRF unit in this case.

In an advantageous embodiment, the corresponding signaling by means of at least one signaling message to remove multiple billing rules, wait the CRF unit for a defined period of time after which you set up the GGSN or has taught the modification of the PDP context and sends then a common message to remove all billing rules, for the the GGSN all corresponding data streams in other PDP contexts has discovered.

If the GGSN informs the CRF unit that the TFT of an existing Changed context or a new PDP context has been built, install the CRF unit re-charging rules in all relevant PDP contexts. The candidate streams detects the CRF unit as already described, for example based on the address of the terminal and the TFT information and taken into account as well as data streams, which the GGSN has already reported in another PDP context. This embodiment is only required if the CRF unit is changing the terminal one for want to enable a downlink data stream used PDP context.

In an advantageous embodiment The invention stores the CRF unit in which PDP context which IP data streams were discovered. This allows the CRF unit to do this for them streams competent Application Functions Messages concerning this PDP context Pass on events, for example about the reduction of the PDP context or the temporary loss of the connection at the air interface. The CRF unit can also specify the affected IP data streams.

One greater Advantage of the invention is that the invention SBLP without Use of an authorization token and the associated allows described disadvantages. So is SBLP for Enables services, that do not use the SIP protocol as a signaling protocol. In addition, will enables the use of other access networks in addition to the GPRS network. The functionality remains of SBLP compared to the variant with authorization token almost Completely receive. The changes across from the existing standard is kept as small as possible.

One Another advantage of the invention is that the invention a improved functionality of FBC compared to the current one Standard offers. So can charging rules (Charging Rules) better about PDP contexts are distributed, bringing the number of charging rules needed in the GGSN can be minimized and thus the load on the GGSN is reduced. About that In addition, the CRF unit of the application function can be improved Notification about Provide events that relate to PDP contexts by the corresponding service be used. In addition, the ORF unit is also enabled the application function to give the information which data streams in which PDP Contexts are transported. The application function could be this Use information, for example, in the context of statistics or billing. The changes across from the existing standard is kept as small as possible.

The The invention is based on an embodiment shown in a figure explained in more detail. there demonstrate

1 a typical network configuration,

2 the method according to the invention in the context of SBLP,

3 the method according to the invention in the context of FBC,

4 a network unit according to the invention (GGSN),

5 another network unit according to the invention (PDF).

1 shows a typical network configuration. Shown are a terminal UE, which may be, for example, a mobile terminal, a mobile computer, a computer, a mobile organizer, etc., an application function AF, and a resource decision function PDF, CRF (control node), for example in the case of SBLP a policy decision Function PDF and in the case of FBC a Charging Rules Function CRF. The terminal in this example uses two PDP contexts A and B as connections to the GGSN through the mobile access network GPRS.

• 1. Das Endgerät UE und die Applikationsfunktion AF handeln mittels Signalisierung einen Dienst beispielsweise mit zwei IP Datenströmen a und b aus, die beide vom Endgerät UE über GPRS in das IP Kernnetz gesendet werden sollen.
• 2. Die Applikationsfunktion AF informiert die Ressourcen-Entscheidungsfunktion PDF, dass ein Dienst mit dem Endgerät UE gestartet werden soll. Die IP Adresse des Endgerätes UE wird angegeben und die Datenströme a und b werden beschrieben. Die Ressourcen-Entscheidungsfunktion PDF kann die Messung eines definierten Zeitraumes bereits jetzt beginnen.
• 3. Das Endgerät UE beschließt, für Datenströme a und b getrennte PDP Kontexte A bzw. B zu verwenden. Es sendet für PDP Kontext A einen so genannten „PDP Context Activation Request" als Anfrage zur Netzeinheit GGSN und gibt dabei die gewünschte Qualität des Dienstes QoS-A für den PDP Kontext A an, um den Aufbau des PDP Kontextes A anzufordern.
• 4. Die Netzeinheit GGSN ersucht die für das Endgerät UE zuständige Ressourcen-Entscheidungsfunktion PDF über die Go-Schnittstelle um Autorisierung des PDP Kontextes A. Das bereits standardisierte entsprechende Kommando wird erfindungsgemäß so verändert, dass einerseits keine „Binding Information" angegeben wird und andererseits die geforderte QoS-A sowie die IPv4 Adresse oder der IPv6 Adress-Präfix des Endgerätes UE angegeben wird.
• 5. Die Ressourcen-Entscheidungsfunktion PDF weiß zu diesem Zeitpunkt noch nicht, welche Datenströme in PDP Kontext A transportiert werden. Sie wählt als Kandidaten alle Datenströme aus, die von oder zu dem über die IP Adresse identifizierten Endgerät UE gehen, hier Datenströme a und b. Die Ressourcen-Entscheidungsfunktion PDF kann erfindungsgemäß zu diesem Zeitpunkt nur Obergrenzen für eine sinnvolle Qualität des Dienstes QoS für den PDP Kontext ermitteln. Die QoS Klasse sollte nicht höher sein als die höchste für mindestens einen der Datenströme a und b benötigte QoS Klasse und die Bandbreite sollte die Summe der für die Datenströme a und b erforderlichen Bandbreiten nicht überschreiten. Als einfachere Variante kann die Ressourcen-Entscheidungsfunktion PDF fest konfigurierte Werte für die Obergrenze verwenden. Falls die geforderte Qualität des Dienstes QoS größer ist als die ermittelte Obergrenze, wird sie in der Autorisierung entsprechend herabgesetzt. In einer einfacheren Implementierung kann die Ressourcen-Entscheidungsfunktion PDF zu diesem Zeitpunkt die geforderte Qualität des Dienstes QoS in jedem Fall autorisieren. In 1 ist dargestellt, dass die Ressourcen-Entscheidungsfunktion PDF die geforderte Qualität des Dienstes QoS-A auch autorisiert. Die Ressourcen-Entscheidungsfunktion PDF signalisiert an die Netzeinheit GGSN, dass der PDP Kontext A unter Verwendung von QoS A autorisiert ist, und dass für die Datenströme a und b entsprechende Gates a bzw. b installiert werden sollen. Die zur Beschreibung der Gates verwendete Datenstruktur kann erfindungsgemäß so verändert werden, dass sie die den Gates entsprechenden „Flow Identifier" entsprechend TS 29.207 enthält. Ansonsten wird das bereits standardisierte entsprechende Kommando unverändert verwendet. Falls die Ressourcen-Entscheidungsfunktion PDF wie unter Schritt 2. die Messung des definierten Zeitraumes noch nicht begonnen hat, beginnt die Ressourcen-Entscheidungsfunktion PDF nun die Messung des definierten Zeitraumes, der dem PDP Kontext A zugeordnet ist. Die Ressourcen-Entscheidungsfunktion PDF speichert die autorisierte QoS-A sowie die installierten Gates a und b.
• 6. Die Netzeinheit GGSN sendet an das Endgerät UE einen so genannten „PDP Kontext Activation Response" als Antwort, um den Aufbau von PDP Kontext A abzuschließen.
• 7.–10. Analog Schritten 3. bis 6. wird PDP Kontext B aufgebaut und autorisiert.
• 11. Das Endgerät UE beginnt, Datenstrom a über PDP Kontext A in das IP Kernnetz zu senden.
• 12. Die Netzeinheit GGSN entdeckt mit Hilfe des in Gate a enthaltenen Paketfilters, dass zu detektierende Daten des Datenstroms a detektiert wurden und informiert erfindungsgemäß die Ressourcen-Entscheidungsfunktion PDF, dass Datenstrom a in PDP Kontext A entdeckt wurde. Dazu ist eine neue noch zu bestimmende Nachricht erforderlich, die Datenstrom a beispielsweise mit Hilfe eines „Flow Identifier" entsprechend TS 29.207 beschreiben kann. Die Ressourcen-Entscheidungsfunktion PDF speichert, dass Datenstrom a in PDP Kontext A transportiert wird. In einer nicht dargestellten optimierten Variante der Erfindung kann die Netzeinheit GGSN die Nachricht für eine gewisse Zeit verzögern, um abzuwarten, ob bald darauf noch weitere IP Datenströme entdeckt werden, und die entsprechenden Nachrichten dann zusammenzufassen.
• 13.–14. Analog Schritten 11. bis 12. beginnt das Endgerät UE Datenstrom b über PDP Kontext B zu senden und die Netzeinheit GGSN unterrichtet die Ressourcen-Entscheidungsfunktion PDF.
• 15. Die Ressourcen-Entscheidungsfunktion PDF stellt fest, dass der definierte Zeitraum beendet ist. Dies kann entweder durch Ablauf einer festgelegten Zeit geschehen, oder weil die Ressourcen-Entscheidungsfunktion PDF nun für alle ihr bekannten Datenströme weiß, in welchem PDP Kontext sie befördert werden.
• 16. Nach Ende des definierten Zeitraumes überprüft die Ressourcen-Entscheidungsfunktion PDF die Autorisierung für den PDP Kontext A. Die Ressourcen-Entscheidungsfunktion PDF weiß nun, dass nur Datenstrom a in diesem PDP Kontext A befördert wird und ermittelt mit Hilfe dieser Information und dem in TS 29.208 bereits standardisierten Algorithmus die autorisierte Qualität des Dienstes QoS für diesen PDP Kontext. In 1 wird angenommen, dass die neu ermittelte autorisierte Qualität des Dienstes QoS-a kleiner ist als die zunächst autorisierte QoS-A. Die Ressourcen-Entscheidungsfunktion PDF erkennt auch erfindungsgemäß, dass Gate b nicht in PDP Kontext A benötigt wird. Deswegen signalisiert die Ressourcen-Entscheidungsfunktion PDF an die Netzeinheit GGSN, dass für PDP Kontext A die autorisierte Qualität des Dienstes QoS auf QoS-a herabgesetzt und Gate b entfernt werden soll. Dazu kann ein bereits standardisiertes Kommando unverändert verwendet werden.
• 17. Die Netzeinheit GGSN signalisiert zum Endgerät UE, um die Qualität des Dienstes QoS des PDP Kontext A auf QoS-a herabzusetzen.
• 18. Nach Ende des definierten Zeitraumes überprüft die Ressourcen-Entscheidungsfunktion PDF die Autorisierung für PDP Kontext B analog Schritt 16. In 2 wird angenommen, dass die neu ermittelte autorisierte Qualität des Dienstes QoS der zunächst autorisierten Qualität des Dienstes QoS-B entspricht. Deswegen signalisiert die Ressourcen-Entscheidungsfunktion PDF an die Netzeinheit GGSN, dass Gate a entfernt werden soll.
• 19. Nach einiger Zeit beschließt das Endgerät UE, PDP Kontext A zu beenden, und signalisiert das an die Netzeinheit GGSN.
• 20. Die Netzeinheit GGSN teilt der Ressourcen-Entscheidungsfunktion PDF mittels eines bereits standardisierten Kommandos mit, dass PDP Kontext A beendet wird.
• 21. Die Ressourcen-Entscheidungsfunktion PDF nutzt die bereits erfindungsgemäß unter Schritt 12 empfangene und abgespeicherte Information, um die Applikationsfunktion AF zu benachrichtigen, dass ein PDP Kontext beendet wurde, der Datenstrom a transportierte.

2 the inventive method in the context of SBLP. It will be the signaling for the inventive method is shown, which is exchanged between a terminal UE, an application function AF, a policy decision function (resource decision function) PDF and a gateway GPRS support node GGSN. These network elements are located in the in 1 illustrated configuration or in the illustrated system. However, it is assumed that the signaling between the application function AF and the terminal UE in another, in 1 not shown PDP context is transmitted. The signaling sequence is as follows:

• 1. The terminal UE and the application function AF act by signaling a service, for example, with two IP data streams a and b, both of which should be sent from the terminal UE via GPRS in the IP core network.
• 2. The application function AF informs the resource decision function PDF that a service is to be started with the terminal UE. The IP address of the terminal UE is specified and the data streams a and b are described. The resource decision function PDF can already start the measurement of a defined period of time.
• 3. The UE UE decides to use separate PDP contexts A and B for data streams a and b. It sends for PDP Context A a so-called "PDP Context Activation Request" as a request to the network unit GGSN and indicates the desired quality of the service QoS-A for the PDP context A to request the structure of the PDP context A.
• 4. The network unit GGSN requests the responsible for the terminal UE resource decision function PDF via the Go interface for authorization of the PDP context A. The already standardized corresponding command is inventively changed so that on the one hand no "binding information" is specified and on the other hand Requested QoS-A and the IPv4 address or the IPv6 address prefix of the terminal UE is specified.
• 5. The resource decision function PDF does not yet know at this time which data streams are transported in PDP context A. It selects as candidates all data streams which go from or to the terminal UE identified via the IP address, in this case data streams a and b. According to the invention, the resource decision function PDF can only determine upper limits for a meaningful quality of the service QoS for the PDP context at this time. The QoS class should not be higher than the highest QoS class needed for at least one of the data streams a and b and the bandwidth should not exceed the sum of the bandwidths required for the data streams a and b. As a simpler alternative, the resource decision function PDF can use fixed upper limit values. If the required quality of the service QoS is greater than the determined upper limit, it is correspondingly reduced in the authorization. In a simpler implementation, the resource decision function PDF at that time can authorize the required quality of service QoS in any case. In 1 It is shown that the resource decision function PDF also authorizes the required quality of the service QoS-A. The resource decision function PDF signals to the network unit GGSN that the PDP context A is authorized using QoS A, and that gates a and b respectively for the data streams a and b are to be installed. According to the invention, the data structure used to describe the gates can be modified such that it contains the "flow identifier" corresponding to the gates in accordance with TS 29.207 Otherwise, the already standardized corresponding command is used unchanged If the resource decision function PDF as in step 2. the Measurement of the defined period has not yet begun, the resource decision function PDF now begins the measurement of the defined period associated with the PDP context A. The resource decision function PDF stores the authorized QoS-A and the installed gates a and b.
• 6. The network unit GGSN sends to the terminal UE a so-called "PDP Context Activation Response" in response to complete the establishment of PDP Context A.
• 7-10th As in steps 3 to 6, PDP Context B is built and authorized.
• 11. The UE starts to send data stream a via PDP context A to the IP core network.
• 12. The network unit GGSN discovers, with the aid of the packet filter contained in gate a, that data to be detected of the data stream a have been detected and, according to the invention, informs the resource decision function PDF that data stream a has been detected in PDP context A. For this purpose, a new message still to be determined is required, which can describe data stream a, for example with the aid of a "flow identifier" in accordance with TS 29.207 The resource decision function PDF stores that data stream a is transported in PDP context A. In an optimized variant, not shown According to the invention, the network unit GGSN can delay the message for a certain time in order to wait for further IP data streams to be discovered soon thereafter and then to combine the corresponding messages.
• 13th-14th Analogously steps 11 to 12, the terminal UE starts to send data stream b via PDP context B and the network unit GGSN notifies the resource decision function PDF.
• 15. The resource decision function PDF determines that the defined period has ended. This can either be done by lapse of a fixed time, or because the resource decision function PDF now knows for all its known data streams in which PDP context they are being transported.
• 16. At the end of the defined period, the resource decision function PDF verifies the authorization for the PDP context A. The resource decision function PDF now knows that only data stream a is carried in this PDP context A and determines with the help of this information and the one in TS 29,208 already standardized algorithm the authorized quality of service QoS for this PDP context. In 1 it is assumed that the newly determined authorized quality of the service QoS-a is smaller than the initially authorized QoS-A. The resource decision function PDF also recognizes according to the invention that gate b is not needed in PDP context A. Therefore, the resource decision function PDF to the network entity GGSN signals that for PDP context A, the authorized quality of the QoS service should be lowered to QoS-a and gate b removed. For this purpose, an already standardized command can be used unchanged.
• 17. The network unit GGSN signals to the terminal UE in order to reduce the quality of the service QoS of the PDP context A to QoS-a.
• 18. After the end of the defined time period, the resource decision function PDF checks the authorization for PDP Context B in step 16. In 2 it is assumed that the newly determined authorized quality of the service QoS corresponds to the initially authorized quality of the service QoS-B. Therefore, the resource decision function PDF signals to the network entity GGSN that gate a should be removed.
• 19. After some time, the terminal UE decides to terminate PDP Context A and signals this to the network entity GGSN.
• 20. The network unit GGSN notifies the resource decision function PDF by means of an already standardized command that PDP context A is terminated.
• 21. The resource decision function PDF uses the information already received and stored under step 12 according to the invention in order to notify the application function AF that a PDP context has been completed that transported data stream a.

• 1. Das Endgerät UE und die Applikationsfunktion AF handeln mittels Signalisierung einen Dienst beispielsweise mit zwei IP Datenströmen a und b aus, die beide vom Endgerät UE über GPRS in das IP Kernnetz gesendet werden sollen.
• 2. Die Applikationsfunktion AF informiert die Ressourcen-Entscheidungsfunktion CRF, dass ein Dienst mit dem Endgerät UE gestartet werden soll. Die IP Adresse des Endgerätes UE wird angegeben und die Datenströme a und b werden beschrieben.
• 3. Das Endgerät UE beschließt, für Datenströme a und b getrennte PDP Kontexte A bzw. B zu verwenden. Es sendet für PDP Kontext A einen so genannten „PDP Context Activation Request" als Anfrage zur Netzeinheit GGSN, um den Aufbau des PDP Kontextes A anzufordern.
• 4. Die Netzeinheit GGSN informiert die für das Endgerät UE zuständige Ressourcen-Entscheidungsfunktion CRF über die Gx-Schnittstelle über den Aufbau des PDP Kontextes A.
• 5. Die Ressourcen-Entscheidungsfunktion CRF weiß zu diesem Zeitpunkt noch nicht, welche Datenströme in PDP Kontext A transportiert werden. Sie wählt alle Datenströme aus, die von oder zu dem über die IP Adresse identifizierten Endgerät UE gehen, hier Datenströme a und b. Die Ressourcen-Entscheidungsfunktion CRF signalisiert an die Netzeinheit GGSN, dass in PDP Kontext A die den Datenströmen a und b entsprechende Vergebührungsregeln CR a bzw. CR b installiert werden sollen.

3 shows the inventive method in the context of FBC. The signaling for the method is shown, which is exchanged between a terminal UE, an application function AF, a charging rules function CRF (charging control function) and a gateway GPRS support node GGSN. These network elements are located in the in 1 illustrated configuration or in the illustrated system. The signaling sequence is as follows:

• 1. The terminal UE and the application function AF act by signaling a service, for example, with two IP data streams a and b, both of which should be sent from the terminal UE via GPRS in the IP core network.
• 2. The application function AF informs the resource decision function CRF that a service is to be started with the terminal UE. The IP address of the terminal UE is specified and the data streams a and b are described.
• 3. The UE UE decides to use separate PDP contexts A and B for data streams a and b. It sends for PDP context A a so-called "PDP Context Activation Request" as a request to the network unit GGSN to request the establishment of the PDP context A.
• 4. The network unit GGSN informs the UE responsible resource decision function CRF via the Gx interface on the structure of the PDP context A.
• 5. The resource decision function CRF does not yet know at this time which data streams are transported in PDP context A. It selects all data streams which go from or to the terminal UE identified via the IP address, in this case data streams a and b. The resource decision function CRF signals to the network unit GGSN that in PDP context A the charging rules CR a or CR b corresponding to the data streams a and b are to be installed.

• 6. Die Netzeinheit GGSN sendet an das Endgerät UE einen so genannten „PDP Kontext Activation Response" als Antwort, um den Aufbau von PDP Kontext A abzuschließen.
• 7.–10. Analog zu den Schritten 3. bis 6. wird PDP Kontext B aufgebaut und die Ressourcen-Entscheidungsfunktion CRF installiert die Vergebührungsregeln CR a und CR b darin.
• 11. Das Endgerät UE beginnt, Datenstrom a über PDP Kontext A in das IP Kernnetz zu senden.
• 12. Die Netzeinheit GGSN entdeckt mit Hilfe des in CR a enthaltenen Paketfilters, dass das erste Datenstrom a entsprechendes IP Daten-Paket empfangen wurde und informiert erfindungsgemäß die Ressourcen-Entscheidungsfunktion CRF, dass Datenstrom a in PDP Kontext A detektiert wurde. Dazu ist eine Nachricht erforderlich, die Datenstrom a beispielsweise mit Hilfe eines „Flow Identifier" entsprechend TS 29.207 beschreiben kann. Die Ressourcen-Entscheidungsfunktion CRF speichert, dass Datenstrom a in PDP Kontext A transportiert wird. In einer nicht dargestellten optimierten Variante der Erfindung kann die Netzeinheit GGSN die Nachricht für eine gewisse Zeit verzögern, um abzuwarten, ob bald darauf noch weitere IP Datenströme entdeckt bzw. detektiert werden, und die entsprechenden Nachrichten dann zusammenzufassen.
• 13. Die Ressourcen-Entscheidungsfunktion CRF weiß nun, dass nur Datenstrom a in diesem PDP Kontext A befördert wird. Die Ressourcen-Entscheidungsfunktion CRF erkennt erfindungsgemäß daraus, dass CR a nicht in PDP Kontext B benötigt wird. Um Prozessierungslast und Arbeitsspeicher in der Netzeinheit GGSN zu sparen, signalisiert die Ressourcen-Entscheidungsfunktion CRF an die Netzeinheit GGSN, dass CR a aus PDP Kontext B entfernt werden soll. Dazu kann ein bereits standardisiertes Kommando unverändert verwendet werden.
• 14.–16. Analog Schritten 11. bis 13. beginnt das Endgerät UE Datenstrom b über PDP Kontext B zu senden und die Netzeinheit GGSN unterrichtet die Ressourcen-Entscheidungsfunktion CRF. Die Ressourcen-Entscheidungsfunktion CRF entfernt CR b aus PDP Kontext A.
• 17. Nach einiger Zeit beschließt das Endgerät UE, PDP Kontext A zu beenden, und signalisiert das an die Netzeinheit GGSN.
• 18. Die Netzeinheit GGSN teilt die Ressourcen-Entscheidungsfunktion CRF mittels eines bereits standardisierten Kommandos mit, dass PDP Kontext A beendet wird.
• 19. Die Ressourcen-Entscheidungsfunktion CRF nutzt die bereits erfindungsgemäß unter Schritt 12 empfangene und abgespeicherte Information, um der Applikationsfunktion AF zu benachrichtigen, dass ein PDP Kontext beendet wurde, der Datenstrom a transportierte.

According to the invention, the data structure used to describe the billing rules can be changed such that each packet filter is assigned a corresponding "flow identifier" in accordance with TS 29.207 Otherwise, the already standardized corresponding command is used unchanged The resource decision function CRF stores the installed billing rules CR a and CR b.

• 6. The network unit GGSN sends to the terminal UE a so-called "PDP Context Activation Response" in response to complete the establishment of PDP Context A.
• 7-10th Analogous to steps 3 to 6, PDP Context B is established and the resource decision function CRF installs the charging rules CR a and CR b therein.
• 11. The UE starts to send data stream a via PDP context A to the IP core network.
• 12. The network unit GGSN discovers with the aid of the packet filter contained in CR a that the first data stream a corresponding IP data packet has been received and informs erfindungsge According to the resource decision function CRF, data stream a has been detected in PDP context A. For this purpose, a message is required which can describe data stream a, for example with the aid of a "flow identifier" in accordance with TS 29.207 The resource decision function CRF stores data stream a in PDP context A. In an optimized variant of the invention, not shown, the Network unit GGSN delay the message for a certain time to wait, whether soon after further IP data streams are detected or detected, and then summarize the corresponding messages.
• 13. The resource decision function CRF now knows that only data stream a is being carried in this PDP context A. According to the invention, the resource decision function CRF recognizes that CR a is not needed in PDP context B. In order to save processing load and memory in the network unit GGSN, the resource decision function CRF signals to the network unit GGSN that CR a should be removed from PDP context B. For this purpose, an already standardized command can be used unchanged.
• 14th-16th Analogously steps 11 to 13, the terminal UE starts to send data stream b via PDP context B and the network unit GGSN informs the resource decision function CRF. The resource decision function CRF removes CR b from PDP context A.
• 17. After some time, the UE decides to terminate PDP context A and signals this to the network entity GGSN.
• 18. The network unit GGSN notifies the resource decision function CRF by means of an already standardized command that PDP context A is ended.
• 19. The resource decision function CRF uses the information already received and stored under step 12 in accordance with the invention in order to notify the application function AF that a PDP context has been completed which has transported data stream a.

4 shows a network unit GGSN according to the invention with a receiving unit E, a transmitting unit S and a processing unit V for performing the method according to

2 and 3 , In this case, the network unit is used to determine the payload connections used for the transport of data streams and to notify a control node (PDF, CRF) of detected data of at least one data stream.

5 shows a control node according to the invention for performing the method according to 2 and 3 , The control node has a receiving unit EE, a transmitting unit SE and a processing unit VE.

Claims (44)

Method for determining the assignment of data streams to payload connections by notifying a control node (PDF, CRF) of detected data of at least one data stream in a network unit (GGSN, PDG) of a communication network, characterized in that at least one of the control node (PDF, CRF) sent Packet filter in the network unit (GGSN, PDG) data of at least one data stream with respect to the match with at least one parameter of the packet filter are evaluated and that of the network unit (GGSN, PDG) depending on the evaluation result to the control node (PDF, CRF) at least one the evaluation result information is sent. Method according to claim 1, characterized in that that the information concerning the evaluation result at least indicates a data stream. Method according to claim 2, characterized in that that the information concerning the evaluation result at least indicates a data stream by means of a respective flow identifier. Method according to claim 1, characterized in that that the information concerning the evaluation result at least specifies a packet filter. Method according to claim 1, characterized in that that the information concerning the evaluation result at least indicates a user connection. Method according to claim 1, characterized in that that the control node (PDF, CRF) together with a packet filter for the Data of at least one data stream one each the packet filter associated flow identifier for sends the data stream to the network unit (GGSN, PDG). Method according to claim 1, characterized in that that the control node (PDF, CRF) a at least one data stream appropriate packet filter for every user connection, via transmit the data to be detected of the at least one data stream can be sends. Method according to Claim 7, characterized in that the control node (PDF, CRF) uses the user-defined connection via which data of at least one data stream to be detected can be transmitted with the aid of the address of a terminal (UE). selects. Method according to claim 7, characterized in that that the control node (PDF, CRF) the user connection, via the transmit data to be detected at least one data stream can be using the TFT information selects. Method according to one of the preceding claims, characterized characterized in that upon detection of the first data packet to detecting data of at least one data stream from the network unit (GGSN, PDG) at least one information concerning the evaluation result sent to the control node (PDF, CRF). Method according to one of the preceding claims, characterized in that the network unit (GGSN, PDG) is the control node (PDF, CRF) sends an information if over a defined period of time detected no data to be detected at least one data stream become. Method according to one of the preceding claims, characterized characterized in that at least with the at least one packet filter a parameter is sent from the control node (PDF, CRF), the indicates whether at least one information concerning the evaluation result to be sent to the control node (PDF, CRF). Method according to one of the preceding claims, characterized characterized in that at least with the at least one packet filter a parameter is sent from the control node (PDF, CRF), the indicates whether to send information to the control node (PDF, CRF) should be, if over a defined period of time no data to be detected at least a data stream are detected. Method according to one of the preceding claims, characterized characterized in that by the network unit (GGSN, PDG) with at least a packet filter data of at least one data stream over one defined period are detected and at least one the evaluation result relevant information after the expiration of the period to the control node (PDF, CRF). Method according to one of the preceding claims, characterized characterized in that the evaluation result of the network unit (GGSN, PDG) is stored. Method according to claim 15, characterized in that that the network unit (GGSN, PDG) all in a defined period of time stored evaluation results together with at least one signaling message to the control node (PDF, CRF). Method according to claim 15, characterized in that that the network unit (GGSN, PDG) at least one stored evaluation result in a signaling message to the resource decision function (PDF, CRF) which also sends information regarding other events of the payload contains for example, a notification about the structure or the change the useful connection. Method according to claim 15, characterized in that that of the network unit (GGSN, PDG) the control node (PDF, CRF) at periodic intervals at least one information concerning the evaluation result sent becomes. Method according to one of the preceding claims, characterized in that the network unit (GGSN, PDG) is a gateway GPRS support node (GGSN), a packet data gateway (PDG) and / or a gateway used become. Method according to one of the preceding claims, characterized in that the control node (PDF, CRF) of the network unit (GGSN, PDG) sends the at least one packet filter when it is sent from the network unit (GGSN, PDG) at least one signaling message in terms of of construction or change receives a payload connection. Method according to one of the preceding claims, characterized in that the control node (PDF, CRF) of the network unit (GGSN, PDG) sends the at least one packet filter when it is sent from a further network unit (AF) at least one signaling message in terms of the for needed a service streams receives. Method according to one of the preceding claims, characterized characterized in that the control node (PDF, CRF) upon receipt at least one signaling message concerning the detection of data of at least one data stream of the network entity from the network entity (GGSN, PDG) stores data to be detected of a data stream in the specified by means of at least one signaling message Nutzverbindung were detected. Method according to one of the preceding claims, characterized in that the control node (PDF, CRF) upon receipt of at least one signaling message from the network unit (GGSN, PDG) with respect to at least one event concerning at least one user connection, for example with respect to the degradation or modification of a user connection , at least one application function (AF) at least one signa lisierungsnachricht respect to the at least one event sends and therein indicates the data streams whose data has been detected in the at least one user connection. Method according to one of the preceding claims, characterized characterized in that the control node (PDF, CRF) upon receipt at least one signaling message concerning the detection of Data of at least one data stream from the network unit (GGSN, PDG) The network unit (GGSN, PDG) signals that the packet filter for that data at least one data stream is removed from a payload should. A method according to claim 24, characterized in that the control node (PDF, CRF) signaling to remove multiple packet filters summarized by the control node before submitting a defined period of time to further signaling messages the network unit (GGSN, PDG) waits for data from further data streams to be detected were. Method according to one of the preceding claims, characterized in a request for authorization a new or modified payload connection from the network device (GGSN, PDG) at the control nodes (PDF, CRF) of the control nodes (PDF, CRF) one at least the requirements of all the control node known data streams, for the Data about the Transfer useful connection can be appropriate quality authorized by the service. Method according to claim 26, characterized in that that the control node (PDF, CRF) is the sum of the bandwidths of the him (PDF, CRF) known data streams for the data transmitted via the user connection can be authorized. Method according to claim 26, characterized in that that the control node (PDF, CRF) authorizes the highest QoS class, the for at least one of the data streams known to it (PDF, CRF) is required is for the data over transmit the user connection can be. Method according to one of the preceding claims, characterized characterized in that the signaling at the go interface changed like that, that when querying the authorization of Nutzverbindung in the Network unit (GGSN, PDG) of the control nodes (PDF, CRF) at least an information about from the terminal (UE) required quality receives the service. Method according to one of the preceding claims, characterized in a request for authorization a new or modified payload connection from the network device (GGSN, PDG) at the control nodes (PDF, CRF) of the control nodes (PDF, CRF) from the terminal (UE) required quality of the QoS service. Method according to one of the preceding claims, characterized characterized in that after a defined period of time in a request concerning the authorization of a new or modified user connection from the network unit (GGSN, PDG) to the control node (PDF, CRF) the control node (PDF, CRF) that meets the requirements of those Data streams, for the Data were detected in the payload, corresponding to used quality of the service QoS for determines the user connection. Method according to claim 31, characterized in that that the length dependent on the defined period from the service whose data is transmitted in at least one data stream should be. Method according to one of the preceding claims, characterized characterized in that the control node (PDF, CRF) for a user connection the the requirements of those data streams for the data in the payload were detected, corresponding quality of the service to be used QoS for determines the payload as soon as for all the control node known data streams for the data on the Useful connection to be transmitted could, data in a Nutzverbindung were detected. A method according to claim 31 or 33, characterized characterized in that the control node (PDF, CRF) determined the quality of the service QoS for a user connection to the network unit (GGSN, PDG) signals. A method according to claim 34, characterized that the control node (PDF, CRF) the determined quality of the service QoS for one User connection to the network unit (GGSN, PDG) only signaled when asked by the request for the authorization of a new or modified user service authorized quality of service QoS deviates. Method according to one of the preceding claims, characterized characterized in that the packet filter is contained in a gate. A method according to claim 36, characterized in that the network unit (GGSN, PDG) instead of gates TFT filter information for assigning data from downlink data streams to Nutz used connections, if the control node (PDF, CRF) gates were sent for the payload to the network unit, but the network unit (GGSN, PDG) has received no binding information for the user connection from the terminal (UE). Method according to one of the preceding claims, characterized characterized in that the packet filter in a charging rule (Charging Rule) is included. Method according to one of the preceding claims, characterized characterized in that the payload is a PDP context. Method according to one of the preceding claims, characterized in that the control node (PDF, CRF) is a PDF unit (PDF) and / or a CRF unit (CRF). Method according to one of the preceding claims, characterized characterized in that the communication network is a cellular mobile radio network, is a packet-switched network and / or an IP network. Network unit (GGSN, PDG) of a communication network for determining the useful connections used for transporting data streams and for notifying a control node (PDF, CRF) when detected Data of at least one data stream, - with a receiving unit (E) and a transmitting unit (S) for performing the communication, - with a Processing unit (V) for evaluating the match with at least one parameter of the packet filter of data at least a data stream with at least one from the control node (PDF, CRF) and for sending at least one piece of information the evaluated data of at least one data stream depending from the evaluation result to the control node (PDF, CRF). System for determining the assignment of data streams to payload connections and for notifying a control node (PDF, CRF) when detected Data of at least one data stream in a network unit (GGSN, PDG) a communication network, - with the control node (PDF, CRF) for sending at least one packet filter to the network unit (GGSN, PDG), - With the network unit (GGSN, PDG) for evaluating compliance with at least one parameter of the packet filter of data at least a data stream with at least one sent by the control node Packet filter and for sending at least one piece of information regarding the evaluated data of the at least one data stream depending from the evaluation result to the resource decision function. Control node (PDF, CRF) of a communication network to provide packet filters, to send the packet filters a network entity (GGSN, PDG) and for receiving information concerning the detected data of at least one data stream of the network unit (GGSN, PDG), - with a receiving unit (EE) and a transmitting unit (SE) for performing the communication, - with a Processing unit (VE) for selecting and providing at least a packet filter to the network unit (GGSN, PDG) and to evaluate the information transmitted by the network entity (GGSN, PDG) regarding the detected with the at least one provided packet filter Data of at least one data stream.