EP1854323A1

EP1854323A1 - Method for processing quality of service of a data transport channel

Info

Publication number: EP1854323A1
Application number: EP06726216A
Authority: EP
Inventors: Nathalie Beziot; Aude Pichelin; Laëtitia FONTAINE
Original assignee: France Telecom SA
Current assignee: Orange SA
Priority date: 2005-03-03
Filing date: 2006-03-03
Publication date: 2007-11-14
Also published as: FR2882879A1; US7796559B2; CN101069451A; US20080279108A1; WO2006092541A1

Abstract

The invention concerns a method for processing quality of service of a signalling data transport channel in a packet transmission network comprising at least one management node (4), wherein, for a data transport channel, the management node (4) receives a quality of service profile associated with said channel, containing a parameter (SI) indicating signalling, detects (E2) whether, in the quality of service profile, the signalling indicating parameter is activated so as to determine whether it is a signalling data transport channel, and in that case, processes the signalling data transport channel as a priority over any other media data transport channel during execution of at least one quality of service processing mechanism applied to the signalling data transport channel.

Description

Title: Quality of Service Processing Process for a Data Transport Channel

A method for processing the quality of service of a data transport channel, such as Packet Data Protocol (PDP) context, for the transport of signaling data, and a management node for implementing implementation of this process.

IMS (IP Multimedia Subsystem) is a subsystem of the UMTS system

(Universal Mobile Telecommunication System), introduced in UMTS Release 5, intended to allow dynamic establishment and control of multimedia sessions between at least two devices (for example between two user terminals or between a user terminal and a user terminal). application server).

Establishing a multimedia session (for example audio, video and / or text) between two pieces of equipment, for example two mobile terminals, calling and called respectively, in the IMS is done in two stages: 1. PDP primary context signaling

The calling equipment activates a first signaling session, called primary signaling PDP context. During this signaling session, calling and called equipment exchange signaling data to negotiate the characteristics of the call (including supported coding types). 2. Secondary PDP Context of Data Transport

After the negotiation phase of the characteristics of the call, the calling equipment activates a second session, called a secondary context PDP media data transport, for the transport of data relating to the call itself. It can for example be a video and audio data transport session, a multimedia server consultation or a simple voice over IP session.

The term "media data" is intended to mean the data specific to a communication, in particular audio, video and / or textual data, distinct from the signaling data already exchanged in the primary PDP context.

When activating a PDP context (signaling data transport or media data) at the initiative of a device, ie access network the UMTS radio (UTRAN), and more particularly the equipment attached to the Network Control Station (RNC), allocates network resources to it by activating a communication channel, commonly called a "RAB" (Radio). Access Bearer Parameters), at the level of the radio access network. The RAB is defined by a set of quality of service parameters corresponding globally to those of the quality of service profile of the activated PDP context.

Subsequently, the term "data transport channel" will be used to designate both a PDP context and a RAB.

Enabling any channel, whether PDP or RAB, to transport signaling data or transport media data requires pre-negotiating QoS parameters related to this channel. The present invention relates more particularly to the activation of a signaling channel (that is to say a signaling data transport channel), the negotiation of the quality of service parameters and the prioritization at the transport level of the signaling data. such a channel.

It is essential that the activation of the primary signaling PDP context, during which the signaling parameters for the secondary PDP context of call-related media data transport, are negotiated correctly, otherwise this secondary context can be active. It should therefore be treated as a priority. For this, the 3GPP (3 ^nl Generation Partnership Project) standard introduced a Signaling Indication (SI) parameter indicating whether the packets that will be transmitted in the PDP context belong or not to signaling, depending on whether it is associated with the value. "Yes" or "No". This SI parameter is part of the set of parameters specifying the quality of service requested by a device wishing to open a PDP context. When an equipment wishes to open a signaling PDP context, it indicates: "SI = Yes".

The 3GPP standard recommends using the Traffic Handling Priority (THP) parameter when the parameter Sl = YES. This parameter THP, related to the class of traffic differentiates Interactive Sessions from each other in terms of quality of service. Each interactive session is associated with a THP parameter that can be 1, 2 or 3, with the value 1 corresponding to the highest priority level. In other words, the standard suggests, when SI parameter is enabled (SI = Yes), to set the value of THP parameter to 1. The signaling PDP context thus benefits from the priority level due to parameter value 1. THP. However, if when activating a new context

PDP primary signaling, PDP contexts corresponding to interactive sessions, having a THP parameter equal to 1, are already activated or being activated, the network treats in the same way the PDP contexts enabled corresponding to the interactive sessions in progress and the PDP context of signaling. The present invention therefore aims at providing a method for processing the quality of service of a data transport channel in a packet transmission network comprising at least one management node, in which, for a data transport channel the management node receives a quality of service profile associated with this channel, containing a signaling indication (SI) parameter, such as to improve the priority processing of data packets containing signaling.

This problem is solved by the fact that the management node detects whether, in the quality of service profile, the signaling indication parameter is enabled to determine whether it is a data transport channel of signaling, and if so, treats the signaling data transport channel as a priority over any other media data transport channel when performing at least one applied quality of service processing mechanism to the signaling data transport channel.

Note that the "management node" is meant to designate a node of the network whose role is to manage the data flow traffic. These include, but not limited to:

- for UMTS, RXC, SGSN and GGSK - for GPRS, BSC, SGSN and GGSK and for any other mobile phone system, routers, or nodes, able to handle packet flow traffic.

The invention therefore firstly consists in diffrocessing the signaling channel processing with a priority level different from that of any other media data transport channel, during the activation process of the signaling channel and / or on a channel established signaling. For example, the management node may process the signaling channel in priority over any other channel for the transport of media data: during the execution of an admission control of the signaling channel being activated , when preempting (in progress or after activation of the channel) and / or when allocating differentiated resources (in progress or after activation of the channel).

Advantageously, in order to prioritize the signaling channel to be activated, the management node modifies the quality of service profile received so as to increase the priority level of the signaling channel to be activated.

The modification of the quality of service profile received preferably consists of modifying at least one of the parameters of the group comprising a class of traffic, a parameter defining a relative priority of the signaling channel for the allocation of resources and a parameter defining a relative priority of the signaling channel for preemption.

As a parameter defining a relative priority of the signaling channel for resource allocation and / or preemption, the following may be used as non-limiting examples: the parameter ARP (Allowance Retention Priority), the parameter THP (Traffic Handling) Priority) or a parameter derived from several quality of service attributes such as an attribute relating to the priority level of the subscriber, for example FARP. an attribute relating to the priority level of the service used, for example the class of traffic Thanks to such a modification of the quality of service profile of the signaling channel, that is treated primarily not only by the node having modified the profile, but also by the other nodes of the network whose role is to make transit the data conveyed by this channel, without this necessitates intrinsically modifying these other nodes.

Advantageously, the management node modifies, in the quality of service profile received, at least one rate parameter through the channel in order to optimize the use of the network resources.

The amount of data conveyed in a signaling channel is relatively small compared to that conveyed in a media data transport channel. The invention therefore makes it possible to reduce the bit rate or speeds specified in the quality of service profile requested in order to reduce the bit rate allocated to the signaling channel and thus optimize the use of network resources.

In an advantageous variant of the invention, the management node marks the signaling data packets conveyed by said signaling channel so that the network provides priority processing of said packets during their transport.

As a result, the signaling channel is prioritized at the transport level (i.e., after it has been activated) during the transport of the signaling data packets. Tagging signaling data packets allows other nodes in the network to pass these packets in the network to automatically detect their priority level and process them accordingly, without using either the SI parameter or the THP parameter.

It will be noted here that in the case of a network comprising several management nodes, for example a UMTS network comprising RNCs. SGSN and GGSN, the quality of service profile of the signaling channel can be modified, at the control level, by a first node, for example by the SGSN, while at the transport level, the signaling packets can be unmarked by a second node, for example the

RNC which, firstly, receives the signaling data and has the role of retransmitting them in the network, through an IP link, in the form of packets. Preferably, the management node marks the signaling data packets carried by said signaling channel using a DSCP (DiffSen- Code Point) field.

At the transport layer, the network uses Diffscrv mechanism, defined by I ¹ (IETF Internet Ingineering Task Force), to differentiate QoS treatments applied to data packets carried by different PDP contexts for data transport. Each packet of data has, in its header, a DSCP field "DiffServ Code Point" that can take different values encoded on six bits. Each DSCP value corresponds to a behavior called "Diffserv PHB" (Per Hop Behavior) at the nodes of the network all along the path of the packet. The "EF" (Expedited Forwarding) behavior, corresponding to the "101110" value of the DSCP field, provides priority service with low delay, low jitter (Δt between different packets to cross a node or network) and low packet loss. The association "GSMA" (GSM Association) proposes to mark the flow packets of the "conversational" traffic class with the DSCP field corresponding to the behavior EF in order to make them priority with respect to the flows belonging to the other classes of traffic. It is therefore particularly interesting to divert the use of this DSCP field to make the signaling flows more priority, for example by attributing to the DSCP fields of these streams the value "101110" corresponding to the behavior "EF". As a result, signaling flows become as important as conversational flows.

A second aspect of the invention relates to a management node for a packet mode transmission network, comprising

signaling channel detecting means arranged to determine whether, in a quality of service profile associated with a data transport channel, a signaling indication (SI) parameter is activated to detect whether is a signaling channel,

means for controlling the node to process said signaling channel as a priority over any other channel for transporting media data during the execution of at least one quality of service processing mechanism applied to the signaling channel.

A third aspect of the invention relates to a packet transmission network, comprising at least one node as defined above.

A fourth aspect of the invention relates to a software module for processing a signaling channel, for a management node of a packet mode transmission network, comprising software instructions able to control the execution of the steps of the method previously defined by the management node, as well as the recording medium, readable by a computer, on which this software module is registered.

The invention will be better understood with the aid of the following description of a particular embodiment of the method of the invention, as well as the management nodes and the software module for the implementation of this method, with reference to the annexed drawings in which: FIG. 1 represents a simplified diagram of the architecture of the IMS system and of the UMTS network, FIGS. 2A and 2B represent the various steps of the activation process of a PDP context; FIG. 3 represents a functional block diagram of a network management node and FIG. 4 represents a table of correspondence between UMTS quality of service parameters, Dffserv behaviors and DSCP values. In FIG 1. there is shown a mobile communication network in packet mode, corresponding in this case to domain PS (Packet Switched domain), which will be referred to as "packet domain"', the UMTS network heart ₃ and the TP (IMS) multimedia subsystem. The packet domain of the UMTS core network comprises a SGSN node (Sening GPRS Support Mode) playing the role of locating the subscriber in a location area, called RA (Routing Arca) and managing the communication link with the access network. The SGSN stores the profile of each subscriber and performs a control of the network resources requested by each subscriber, and a GGSN (Gateway GPRS Support Mode) node acting as a bridge between the UMTS network and the external packet-switched networks (the Public Internet, a private intranet, etc.).

The UMTS access network, called the UMTS Terres trial Radio Access Network (UMTS), which constitutes the radio part of the UMTS network, comprises radio transmission equipment, called NodeB, to which the user terminals, also called UEs ( User Equipment), connect, and RNC (Radio Network Controller) controllers, each RNC controlling a plurality of NodeBs.

FIG. 2 shows a transmission chain comprising a UE 1, a NodeB 2, an RNC 3, an SGSN 4 and a GGSN 5. As already explained, the establishment of a communication session between UE 1 and another UE (or AS application server) in the IMS is carried out in two stages: UE 1 activates first a primary signaling PDP context to exchange with the other UE signaling data (encoded supported, type of media data exchanged, etc.) then a secondary PDP context for the transport of media data (video, audio and / or textual for example) specific to the multimedia communication session or simple media.

The activation and marking process of the primary PDP signaling context will now be described with reference to FIGS. 2A and 2B.

EtojjeJEi: L ¹ UB 1 sends to his home SGSJN 4 a request for activation of a primary PDP context - SM Actnare PDP Context Request - with a profile of QoS requested quality of service, commonly called QoS (Qualiîy of Service) profile, including a set of quality of service parameters defined in the 3GPP standard, such as: traffic class (Conversational, Streaming, Interactive on Background) indicating the type of traffic desired, the THP parameter (Traffîc Handling Priority), for the class of "Interactive" traffic, which can take the value 1, 2 or 3 and making it possible to prioritize the streams of the "Interactive" traffic class with one another. relative to the others, - the guaranteed rate on the uplink, defining the minimum bit rate for the real-time traffic on the uplink, for the "Conversational" and "Streaming" traffic classes, and the guaranteed bit rate on the downlink, defining the bit rate minimum for downlink real-time traffic, for the "Conversational" and "Streaming" traffic classes, the maximum rates, on upstream and downstream links, defining the maximum throughput on links ascending and descending set, for all traffic classes (Conversational, Streaming, Interactive and Background), and - the SI (Signalling Indication) parameter, set to "Yes" or "No", indicating whether the PDP context carries data signaling or not.

The primary PDP context to be activated being a signaling PDP context, the SI parameter of the requested QoS profile is activated (SI - Yes). The UE 1 thus indicates that the PDP context to be activated will convey signaling traffic.

Step E2: This step is divided into three sub-steps shown in Figure 2B.

Step E2.1: Addition of ARP parameter in the requested QoS profile The SGSN 4 receives the request for activation of a primary PDP context, from the UE 1. It then consults the UEl subscriber's profile in the Home Location Register (HLR) database, containing the information relating to to the subscribers managed by the operator, extracts the value of the ARP parameter (Subscription / Retention Priority) subscribed by the subscriber and adds it to the quality of service profile requested by I ¹ UEl.

Sub-step E2.2: Modification of the requested QoS profile The SGSN 4 detects whether, in the quality of service profile requested by UE1, the SI parameter is activated (SI = Yes) in order to determine whether it is a PDP signaling context. If this is the case, it modifies, if necessary, in the requested QoS profile, at least one of the two parameters "traffic class" and "ARP", so as to increase the priority level of the signaling PDP context to be activated. . In the particular example of the description, SGSN 4 modifies the class of traffic by assigning it the value "Conversational" and the parameter ARP by assigning it the value 1. The signaling PDP context thus benefits from the priority due to the PDP contexts of type "Conversational" having a priority level of ARP equal to 1.

If the traffic class originally requested by UEl is neither "Conversational" nor "Streaming", the QoS profile requested by UEl and received by SGSN 4 does not contain guaranteed data rates. In this case, after having changed the traffic class to "Conversational", the SGSN 4 adds in the requested QoS profile the guaranteed rates on the upstream link and the downlink link. The values of these guaranteed flows are set to optimize the use of network resources. If the QoS profile requested by UEL and received by the SGSK 4 already has guaranteed rates of uplink and downlink _"the SGSN 4 decreases to optimize the use of network resources. Since signaling flows require only a few network resources, it is useless to allocate them too much data. As a non-limitative example, if the originally requested guaranteed rates are 384 kbits, dry, the SGSN 4 decreases them to 32 or 64 kbps / sec, so as to make optimal use of the resources of the system. network,

LCMS 4 also decreases the maximum data rates (on upstream and downstream links) contained in the QoS profile requested by LEI and received by SGSN 4. Sub-step E2.3: Application of QoS Processing Mechanisms

The SGSN 4 processes the PDP signaling context to be activated in priority with respect to any other PDP context (during activation or already activated) for the transport of media data during the execution of a first data processing mechanism. the quality of service, namely admission control, applied to the signaling PDP context to be activated.

SGSN 4 also processes the signaling PDP context to be prioritized over any other PDP context for media data transport when performing the following two other QoS processing mechanisms applied to the PDP context at the same time. enable: preemption of resources and allocation of differentiated resources.

The preemption mechanism is for SGSN 4, in case of congestion, to pre-empt the resources of one or more media data transport PDP context (s), already activated, to allocate them to the PDP context of signaling to activate.

The differentiated resource allocation mechanism is for the SGSN

4, to optimize the use of network resources when allocating resources to the signaling PDP context. As already explained above, the signaling PDP contexts carry a relatively small amount of data with respect to the media data transport PDP contexts (already activated or being activated).

Step E3: SGSN 4 sends the activation request for a PDP context to

GGSN 5 Create PDP Coniext Requesi - with the quality of service profile requested by ITJlE 1 and modified by SGSN 4.

Step E4: Upon receipt of the activation request from the PDP context, the

GGSN 5 applies the mechanisms of seruity quality processing - admission control, preemption and allocation of differentiated resources taking into account the modified quality of service profile ("Conversational" traffic class, ARP = I ₅ reduced guaranteed bit rates and / or reduced maximum bit rates).

Step ES: The GGSN 5 sends the SGSN 4 a positive response to the Create PDP Context Response signaling PDP activation request, including the negotiated QoS profile for this context.

Step E6: The SGSN receives the GGSN's approval to activate the PDP signaling context, with the negotiated QoS profile. It will be recalled here that, following the modification of the QoS profile requested by the SGSN 4 in step E2.2, the ARP parameter is equal to 1. The SGSN 4 declines the ARP into four sub-parameters as follows: priority = 1 (high priority) Preemption vulnerability = NO Preemption capability = YES Allowed queuing = NO

Step E7: SGSN 4 sends RNC 3 a Radio Access Bearer (RAB AssReq) allocation request with a list of QoS attributes associated with the RAB corresponding globally to the quality of service parameters requested by the RAB. originated by I ¹ EU 1 and modified by the SGSN 4.

Step E8: The RNC 3 receives the RAB allocation request with the list of quality of service attributes including the parameter SI = Yes and the other quality of service parameters requested by ÎUE 1 and possibly modified by the SGSK 4 and the GGSN 5, as in step E2. the RNC 3 determines that the requested RAB is intended to carry signaling data, by detecting the SI ^~ Yes parameter in the list of required quality of service attributes. It then processes the signaling RAB to be activated in priority with respect to any other RAB (currently active or active) for the transport of media data during the execution of the signaling RAB admission control mechanism. to activate. RNC 3 calculates the resources needed to activate this new signaling RAB and prioritize it over any other RAB for media data transport when executing resource preemption and differentiated resource allocation mechanisms.

Step E9: The RNC 3 notifies the SGSN the acceptance of the RAB allocation request by sending the RAB AssRes message.

ETO Step: After RAB is set up, SGSN 4 sends the UE 1 a message - SM Activate PDP ContexI Accept - indicating that activation of the signaling PDP context is accepted.

After the step ElO, the primary signaling PDP context is activated and conveys signaling data between the UE 1 and the other UE (or the application server AS) with which the UE 1 wanted to establish a multimedia session. in the IMS.

• Marking PDP context of signaling

After activation of the signaling PDP context, on detection of the activated SI parameter (SI = Yes), the signaling data is marked by a node of the network. The marking is done in the DSCP field here by assigning the value

"101110" corresponding to the EF behavior. As a result, the signaling data is processed with the highest priority level. This marking is carried out here by the attachment RNC 3 of UE 1, in the upstream direction of the link with respect to FUEL and by the home RNC of the other UE. in the downstream direction of the link to FUEL When transporting this data in the network, each of the other management node (SGSN and GGSN) determines that it is signaling data by detection of the parameter SI activated I SI = Yes) and then verifies that the DSCP field of these signaling data has the value "101 1 10" corresponding to the behavior EF, Each network management node (RNC, SGSN and GGSN) is actually arranged for, when receiving data:

- determine if it is signaling data by detection of the parameter

Sl enabled (Sl = Yes) - if this is the case, check the DSCP field of this data. o if this field has a value other than that corresponding to the behavior EF ("101110"), modify the DSCP field by assigning it the value corresponding to the behavior EF ("101110"). o otherwise, do not modify it.

In general, the node marking the signaling data with the DSCP field "1011" corresponding to the behavior EF is preferably the node of the network which, firstly, receives this data and has the role of retransmitting them to the network. through an IP link and, therefore, in the form of an IP packet. Thus, the packets are treated with a high priority level from the beginning of their transport in the network. However, one could consider that this marking is carried out by another node, for example the SGSN.

Since the DSCP field of the signaling packets with the value "101110" corresponds to the EF behavior, the network management nodes process these packets with a high priority, due to the streams of the "Conversational" traffic class, although it does not. not act of such a type of flow but of a simple flow of signaling.

When traffic conditions change, the network management nodes (RNC, SGSN and / or GGSN) may have to preempt resources and / or different resource allocation! by modifying the respective resources attributed to the various PDP contexts om erts. When applying these quality of service processing mechanisms, the nodes treat the active signaling PDP context as a priority over any other PDP context (currently being activated or already activated) for transporting media data. as in step E2.3, We will now describe the management node SGSN 4, with reference to Figure 3. For clarity, only the elements of the node 4 related to the invention will be explained.

Node 4 comprises a module 40 for processing a signaling data transport channel. It is a software module comprising software instructions for controlling the execution by the node of the steps of the previously described method. More specifically, the module 40 comprises the following elements: a brick 41 for detecting a signaling channel, the latter being associated with a quality of service profile, - a control brick 42 intended to control a priority processing of a signaling channel with respect to any other media data transport channel, when applying different quality of service processing mechanisms, a brick 43 for modifying the quality of service profile of a signaling channel and a brick 44 for marking the signaling data packets conveyed by a signaling channel, arranged to check the marking of the signaling data packets and, if necessary, to carry out this marking, so that the network ensures priority processing of these signaling data packets. packages during their transport.

Brick 41 is arranged to determine whether, in the quality of service profile of a data transport channel (being activated or already activated), the signaling indication SI parameter is activated (SI - Yes) , to detect if it is a signaling channel.

The control brick 42 is arranged to control the node 4 so that it processes a signaling channel (being activated or already activated) as a priority over any other media data transport channel when the application of the different mechanisms of quality of service processing, in this case admission control, pre-emption of resources and differentiated allocation of resources.

Brick 43 for modifying the quality of service profile of a signaling channel is arranged to modify at least one of the two traffic class and ARP parameters so as to increase the priority level of the signaling channel. , add guaranteed debits on upstream and downstream links to the QoS profile, if necessary, or modify the guaranteed debits on upstream and downstream links already present in the QoS profile, as well as the maximum rates on upstream and downstream links of the signaling channel in order to optimize the use of network resources.

It will be recalled that, in the particular example of the description, the brick 43 is arranged to, if necessary, modify the class of traffic by assigning it the value

"ConversationaF and ARP by assigning it a value of 1, add or reduce guaranteed debits (on up and down links) and reduce maximum debits (on up and down links).

Brick 43 could be arranged to modify other parameters of the quality of service profile of the signaling channel.

The marking brick 44 is arranged to, on receipt of signaling data (the latter having been detected by the brick 41), check the DSCP field in the signaling data o if the DSCP field has a value other than that corresponding to the EF behavior ("101110"), modify the DSCP field by assigning it the value corresponding to the behavior EF ("101110"). o otherwise, do not modify it,

In the particular example described above, the marking of the signaling data by the DSCP field "1011 10" is carried out by the RNCs 3. The other nodes of the network (SGSK 4 and GGSN 5) are content to unregister the marking. In the particular example of the description, the other nodes of the network (RNC 3 and GGSN 5) also integrate a software module 40 for processing signaling data transport channels, comprising the software bricks 41 (detection of a data channel). signaling), 42 (control), 43 (modification of the QoS profile) and 44 (marking). One could also consider that some nodes have only some of these software bricks. For example, RNCs 3 and GGSNs 5 might not incorporate QoS profile modification brick 43, as long as the SGSNs incorporate it.

Claims

A method of processing the quality of service of a signaling data transport channel in a packet mode transmission network comprising at least one management node (4), wherein, for a data transport channel, the management node (4) receives a quality of service profile associated with said channel, containing a signaling indication (SI) parameter, characterized in that the management node (4) detects (E2) whether, in the the signaling indication parameter is enabled to determine whether it is a signaling data transport channel, and if so, signaling in priority over any other media data transport channel during the execution of at least one quality of service processing mechanism applied to the signaling data transport channel.

2. Method according to claim 1, wherein, in order to prioritize the signaling channel to be activated, the management node (4) modifies (E2) the quality of service profile received, so as to increase the priority level. the signaling channel to activate.

The method according to claim 2, wherein, to modify the quality of service profile received, the management node (4) modifies at least one of the parameters of the group comprising a traffic class, a parameter defining a relative priority. the signaling channel for resource allocation and a parameter defining a relative priority of the signaling channel for preemption

4, Method according to one of claims 1 to 3. wherein the management node (4} modifies "in the quality of service profile received, at least one rate parameter through the channel to optimize the quality of service. use of network resources

5. Method according to one of claims 1 to 4, wherein the management node (4) marks the signaling data packets carried by said signaling channel so that the network provides priority processing of said packets during their transport.

The method of claim 5, wherein the management node (4) marks the signaling data packets conveyed by said signaling channel using a DSCP (DiffSen? Code Point) field.

7. Method according to one of claims 5 and 6, wherein, in the case where the network comprises a plurality of management nodes, the node which marks the signaling data packets is the one which, first, receives these data. and has the role of retransmitting them to the network through an IP link.

8. Method according to one of claims 1 to 7, wherein, during the activation of the channel, the management node (4) treats (E2) the signaling channel to be activated in priority over any other channel for transporting media data when executing an admission control mechanism of the signaling channel to be activated.

The method according to claim 8, wherein the management node (4) processes (E2) the signaling channel to be activated in priority with respect to any other channel for the transport of media data during the execution of the at least one of the following two quality of service processing mechanisms: the differentiated resource allocation mechanism and the resource preemption mechanism of another channel for the benefit of the congestion signaling channel.

10. Management node for a packet mode transmission network, comprising signaling channel detecting means (41) arranged to determine whether, in a received quality of service profile, associated with a data transport channel, a signaling indication parameter (Sl) is enabled to to detect if it is a signaling channel,

means (42) for controlling the node to process said signaling channel in priority over any other channel for carrying media data when executing at least one processing mechanism; quality of service applied to the signaling channel.

The management node according to claim 10, comprising means (43) for modifying the quality of service profile received, associated with said signaling channel, in order to increase the priority level of the signaling channel to be activated.

The management node according to claim 11, wherein the means for modifying the quality of service profile received are arranged to modify at least one of the parameters of the group comprising a class of traffic, a parameter defining a relative priority of the channel. signaling for resource allocation and a parameter defining a relative priority of the signaling channel for preemption.

The management node according to one of claims 10 to 12, wherein the means (43) for modifying the quality of service profile received are arranged to modify, in the quality of service profile received, at least one data rate. through the channel to optimize the use of network resources.

14. Management node according to one of the re-endings 10 to 13. comprising means (44) for marking, arranged to mark the signaling data packets so that the network provides a pnoriîaue treatment of said packets during of their transport

15. Packet transmission network comprising at least one node according to one of claims 10 to 14.

A data processing software module (40) for a management node of a packet transmission network comprising software instructions for controlling the execution by the node of the steps of the method according to one of claims 1. to 9.

17. A computer-readable recording medium on which the software module according to claim 16 is stored.