FR2965999A1 - METHOD FOR PROCESSING PRESENCE STREAMS IN A SIP NETWORK - Google Patents

Abstract

When a user A belonging to a first SIP network (1) has requested to be notified of changes in the presence status of an external correspondent B to said first SIP network (1) and identified by such a URI containing its number the method according to the invention comprises the following steps: identification, in a database contained in an RLS server (27) of the first SIP network (1) or associated with said RLS server (27), with a SIP- Presumed URI of said correspondent B stored as an alias of said tel-URI; and sending to a second SIP network (2) containing said presumed SIP-URI of a subscription request to the Presence state of the correspondent B. Said alias was obtained beforehand by means of the following steps: discovery of the SIP-URI correspondent B by means of said tel-URI of the corresponding B; and storing in said database of this SIP-URI as an alias of the tel-URI of the correspondent B. Application to the IMS networks.

Description

The present invention relates to telecommunications networks of IP ("Internet Protocol") type, and in particular those of IP networks that are able to implement advanced session control protocols. . IP networks allow the broadcasting of conversational data, such as "VoIP" (VoIP), "Content Sharing", or "Instant Messaging". More particularly, the present invention relates to the means implemented in an IP network using the session control protocol SIP (initials of the words "Session Initiation Protocol" meaning "Session Initiation Protocol"), designated hereinafter by "SIP network", to provide a service called "Presence". It will be said that a device-client ("User Equipment" in English) "belongs" to the network of a given operator when the user of this device-client has an account with this operator, and this, whatever the Access network used by the client device to connect to the operator network. These client devices may for example be a fixed or mobile terminal, or a residential gateway (English) or located in a company, or a network operator gateway ("Voice Gateway" in English) such as a DSLAM-SIP (DSLAM) are the initials of the words "Digital Subscriber Line Access Multiplexer" meaning "Digital Subscriber Line Access Multiplexer", it is a device that collects DSL data traffic that passes through on a number of telephone lines). The SIP protocol has been defined by the IETF in RFC 3261. This protocol allows the establishment, modification and termination of multimedia sessions in a network using the IP protocol. The SIP protocol was then extended in particular in RFC 3265. This extension allows event notification procedures. The SIP protocol is used in particular in infrastructure type IMS (initials of the words "IP Multimedia Subsystem" meaning "Multimedia subsystem over IP"). IMS has been defined by the 3rd Generation Partnership Project (3GPP) and TISPAN (Telecommunications and Internet Converged Services and Protocols for Advanced Networking). It is a network architecture introduced by 3GPP for mobile networks, then taken over by TISPAN for fixed networks. This architecture enables the dynamic establishment and control of multimedia sessions between two clients as well as the reservation of resources at the level of the network for transporting multimedia streams. With this architecture, network operators can conveniently implement a management policy, provide a predetermined Quality of Service, and calculate billings to customers. The IMS currently provides access to telephony, videophone, Presence and Instant Messaging services, which it also manages.

When a user wishes to benefit from the services offered by an IMS network, he sends signaling messages to the network that may include various types of requests. First of all, the client device of the user must, with some exceptions (in the case of certain emergency calls), register on the network. When the network is unable to link this record to a previous record (for example, due to a network failure, or following a termination of the terminal for a duration longer than a predetermined value), the record is considered to be a initial registration. After an initial registration, the user's client device must periodically send the network a request to confirm that it wishes to maintain its registration. In order to be able to register the client devices, the IMS networks comprise one or more servers, generally called "S-CSCF" (initials of the words "Serving-Cali Server Conta) / Function" meaning "Call Waiting Control Function". "Service"), able (among other functions) to manage the registration procedure of devices connected to the network. In addition, these networks include one or more servers, generally referred to as "I-CSCFs" (initials of the English words "Interrogating-Call Server Control Function" meaning "Query Call Server Control Function"). elsewhere often physically combined with S-CSCF servers to form servers denoted "I / S-CSCF" - which, at the time of registration of a client device, query a server called "HSS" (initials English words "Home Subscriber Server" meaning "Nominal Subscriber Server"), in order to be able to select an S-CSCF server having the characteristics which are obligatorily (and, if necessary, optionally) required to reach the level of service subscribed by the user. The HSS servers each contain a client database, and are therefore the equivalent in IP networks of the "HLR" servers (initials of the English words "Home Location Register" meaning "Nominal Location Register") used in GSM networks. . Each HSS server contains the "profile" of a number of client devices in the network, this profile including their registration status, authentication and location data, and subscribed services. Indeed, each user can, after an S-CSCF server has been so assigned, send a subscription request to certain services valid for the current connection. The general principle is that a SIP client device can subscribe to the state of a resource from a server using a SIP signaling message called SUBSCRIBE, and that server can then send notifications to this client device using a SIP signaling message called NOTIFY. For example, notifications are sent as soon as the status of the resource changes. It may be for example an event notification service: when the user of a terminal has a voice mailbox on the network, this terminal can subscribe to a message deposit notification, it is that is, it can request to be notified each time a message has been recorded on that mailbox; the user's terminal can likewise request to be notified of its own registration status, and so on. Initial subscription requests are issued either automatically just after the start of an application, or following a user action on the terminal interface. After the initial subscription request, the client device must send periodically to the server a SIP request SUBSCRIBE to renew its subscription (we speak of "refreshment" of the subscription). For each subscription (whether an initial subscription or a refresh), the server indicates to the client device the refresh period desired by the network operator for this subscription. In particular, these mechanisms can be used to provide a Presence service for exchanging Presence information. This Presence information may include the willingness and ability of a user to communicate with other users. For example, the client device of a user can provide, via a network connection to a Presence server, Presence information that is stored in a Presence data record, which can be made available for distribution to other users. other users (called "observers") having previously requested this information. Presence information has many applications in many communication services, and is one of the innovations behind the recent popularity of Instant Messaging and some Voice over IP services. A user can publish a Presence status to indicate his current communication status. This published report informs other users wishing to contact the user of his availability and his agreement to communicate. The most common use of the Presence service is the display on Instant Messaging client devices of an indicator icon, usually chosen from graphic symbols with easy-to-convey meanings, as well as a list of corresponding textual descriptions. for each state of Presence. Among the classic statements about the availability of a user are: "free to chat", "busy", "out", "do not disturb", and "lunch party". Such states exist in many variations in modern Instant Messaging client devices. Current standards offer an abundant choice of additional Presence attributes, such as the user's mood or location. Presence services are a rapidly growing tool in the business world for more effective communication. Presence information allows someone to immediately see who's available in their corporate network, giving them more flexibility to set up meetings and conference calls on short notice. Presence information is highly sensitive, and in complex systems the Presence service may set limits for Presence information to be disclosed to different observers. For example, a worker may want his coworkers to see detailed Presence information about him only during office hours. Simple versions of this idea are already common in Instant Messaging clients, such as the "Blocking" feature, which allows users to appear as unavailable to selected observers. The 2.5G and even 3G mobile networks can provide access to Presence services and their management for mobile handsets. Presence requires collaboration between, on the one hand, a number of electronic devices (e.g., an Instant Messaging client device, a home telephone, a mobile phone, and an electronic calendar), and on the other hand the Presence servers with which each of them is connected. Significant efforts have therefore been and are being made in several working groups to standardize Presence service protocols. In 2001, the SIMPLE Working Group (initials of the "Session Initiation Protocol for Instant Messaging and Presence Leveraging Extensions" meaning "Session Initiation Protocol Extensions for Instant Messaging and Presence") was formed in within the IETF to develop standards for Presence and Instant Messaging applications using the SIP protocol. The SIMPLE protocol specifies extensions to the SIP protocol that pertain to a publication and subscription mechanism for Presence information and for sending Instant Messages. These extensions include rich Presence document formats, privacy control, "partial" publications and 30 notifications, past and future Presence, and so on.

These IETF standards were then used by other standardization bodies to specify Presence services as well as the architectures needed to render these services. The OMA (initials of the words "Open Mobile Alliance" meaning "Alliance Mobile Open") defines an architecture using the SIMPLE protocol and intended to implement the Presence service. This standardized architecture allows an operator (or service provider) to offer a Presence service to its users, but also to interconnect with other operators (or service providers) offering the same service (provided that they use the same protocol). The architecture proposed to the OMA relies, for implementing the Presence service, on RLS servers (initials of the English words "Resource List Server" meaning "Resource List Server"), on Presence servers. , and on an IMS core network (including in particular the servers S-CSCF and I-CSCF). More precisely: an RLS server is an entity that manages subscriptions to lists of correspondents, and is responsible for subscribing to the Presence information of each of the correspondents present in these lists; thus, a user merely subscribes once for the list of his correspondents with his RLS server; the RLS server then takes care of subscribing to the presence information of each member of the user's list of correspondents; - Presence server is an entity that receives, stores and distributes Presence information of a user; this entity receives and manages subscription requests for the presence of the users it manages, and takes care of the notification of Presence information of its users.

In the implementation of certain Presence services, the only identifiers known to the users of the service are their telephone numbers. These identifiers do not make it possible to determine the SIP network managing the correspondent associated with this telephone number. The RLS server therefore sends to the heart of the SIP network the requests (SUBSCRIBE) of Presence intended for this correspondent. The SIP core network has the particular function of routing these requests to the network hosting this correspondent. It is recalled in this respect that the SIP identities can be of the form "SIP-URI" as defined in RFC 3261, or of the form "tel-URI" as defined in RFC 3966. A SIP-URI is of the form "user @ host" (for example, alice @ domain1), where the "host" part identifies the network of the operator responsible for the identity represented by the "user" part. Such a URI is of the form "tel: telephone number" (for example, tel: +336123456789). One way to route a SIP request for such a URI is to use an ENUM (defined in RFC 3761), in order to retrieve a SIP-URI associated with the telephone number contained in the tel-URI. The interrogation of this ENUM base can be carried out by the SIP core network, and in particular, in the case of an IMS network, by the S-CSCF function. Finally, the knowledge of the SIP-URI makes it possible to obtain the IP address of a device of the network of the operator managing this correspondent. According to the state of the art, this routing process is performed for each of the SUBSCRIBE requests generated by the RLS server each time the application of Presence of the client device is started. In this context, during the normal operation of a SIP network, the latter receives requests for initial registration and initial subscription, as well as registration refresh and subscription requests, as the users of the SIP network network, initialize and then renew their registration and subscriptions after the respective refresh periods. Each SIP network operator must obviously provide the processing capacity of the nodes of his network so as to be able to cope with the corresponding request frequency, in particular according to the usual number of users of the network. But predicting the required capacity is a difficult problem. Indeed, the 3GPP standards for SIP architectures simply provide that the call routing is provided by the core network, without ever taking into account the synergistic effects of this routing with a particular IP service, whose definition is provided independently by a specific standard. With regard in particular to the Presence service, the architecture and the protocol mechanisms of the OMA pose serious problems of scalability on the equipment of the core network SIP as soon as an interconnection with one or more other operators is setup. Indeed, the traditional implementation of the Presence service implies, for all SIP core network equipment located on the Presence flow path, a significant workload, and which is constantly increasing as as the use of Presence services increases. This issue of scalability is for example described in the "draft" IETF http: //tools.ietf. org / html / draft-ietf-simpleinterdomain-scaling-analysis-08. It is particularly related to the fact that, for a user of a given SIP network, any desire to retrieve the presence information of a correspondent belonging to another SIP network generates a SIP dialogue type SUBSCRIBE / NOTIFY to the interconnection between the respective networks of the two users. This dialog is established as long as the user wishes to be notified of changes in the presence status of this external correspondent; in addition, as illustrated in FIG. 1, if the list of correspondents of a user belonging to a given operator network 1 contains several correspondents belonging to third-party networks (operator networks 2 and 3 in the figure), he There will be several dialogues of this type established simultaneously during interconnection. The present invention therefore relates to a method for processing Presence flows in a SIP network. This method is remarkable in that, when a user A belonging to a first SIP network has requested to be notified of changes in the presence status of a correspondent B external to said first SIP network and identified by such a URI containing its telephone number, said method comprises the following steps: identification, in a database contained in an RLS server of the first SIP network or associated with said RLS server, of a presumed SIP-URI of said correspondent B stored as a alias of said tel-URI, and - sending to a second SIP network containing said presumed SIP-URI a subscription request to the state of presence of the correspondent B.

Thus, the present invention applies to Presence service implementations in which the correspondents are known only by their telephone number. Indeed, the authors of the present invention have realized that, according to the state of the art, these Presence services rely on the SIP core network to exploit its routing function. They concluded that it was sufficient to remedy (at least partially) this single problem of routing by the core network, to relieve it in the implementation of Presence services, which are among the most consumer-intensive services. resources for the core network.

It is clear, however, that the solution according to the invention alone makes it possible to subscribe effectively to the presence state of a correspondent only if the presumed SIP-URI of this correspondent is correct. Indeed, the authors of the present invention have realized that, for a given correspondent, the SIP-URI associated with his telephone number is information which, admittedly, may occasionally change when the correspondent changes operator (portability) or SIP network by keeping the same operator (for example in case of evolution or reorganization of the network of the operator), but without these changes are, all things considered, very common. The inventors having found means, as explained in detail below, to manage the SIP-URI change situations, the invention advantageously makes it possible to reduce the number of processing operations, as well as the number of invocations of the functions required for allow the core of the first network to route Presence requests to the SIP network and the Presence server managing the correspondent concerned. The workload of the core equipment of the SIP networks is thus considerably reduced. According to particular features, said alias was obtained beforehand by means of the following steps: discovery of the SIP-URI of the correspondent B by means of said tel-URI of the correspondent B, and storage in said database of this SIP -URI as an alias of the tel-URI of the correspondent B. Thanks to these provisions, one can obtain the required alias for the implementation of the invention, by means of any discovery procedure, conventional or not. It should be noted in this regard that, while it is conventional to use static databases supplied by the service providers and making it possible to store the SIP-URI associated with a telephone number, it is contrary to the habits of the service providers. SIP network specialists to create such a database based on information dynamically discovered during SIP exchanges, as is the case here. According to other particular features, in case, in response to said subscription request, said RLS server receives a notification from said second SIP network that said SIP-URI is unknown, the storage in said database of this SIP-URI as an alias of said tel-URI of the corresponding B is deleted. Thanks to these provisions, coupled with the repetition of the steps, briefly described above, of discovery and storage of the SIPURI of the correspondent B, one can advantageously handle SIP-URI change situations, as announced above. Correlatively, the invention relates to a device for processing Presence flows in a SIP network. Said device is remarkable in that, when a user A belonging to a first SIP network has requested to be notified of changes in the presence status of a correspondent B external to said first SIP network and identified by such a URI containing its telephone number, said device comprises means for: identifying, in a database contained in an RLS server of the first SIP network or associated with said RLS server, an assumed SIP-URI of said correspondent B stored as an alias of said tel-URI, and - send to a second SIP network containing said presumed SIP-URI a subscription request to the presence state of the correspondent B. According to particular characteristics, to obtain said alias, said device comprises means for : - discover the SIP-URI of the correspondent B by means of said tel-30 URI of the corresponding B, and - store in said database this SIP-URI as alias of the tel-U RI of the correspondent B. According to other particular characteristics, in case, in response to said subscription request, said RLS server receives a notification from said SIP network according to which said SIP-URI is unknown, said device comprises means to delete in said database the storage of this SIP-URI as an alias of said tel-URI of the correspondent B. According to another aspect, the invention relates to an RLS server comprising a device as briefly described below. above. The advantages offered by these devices and this RLS server are essentially the same as those offered by the correlative methods briefly described above. Note that it is possible to realize these devices in the context of software instructions and / or in the context of electronic circuits. The invention also relates to a computer program downloadable from a communication network and / or stored on a computer readable medium and / or executable by a microprocessor. This computer program is notable in that it includes instructions for performing the steps of the Presence flow processing method succinctly set forth above, when executed on a computer. The advantages offered by this computer program are essentially the same as those offered by said method. Other aspects and advantages of the invention will appear on reading the detailed description below of particular embodiments, given by way of non-limiting examples. The description refers to the figures which accompany it, in which: FIG. 1, already described, schematically represents the topography of Presence flows in a telecommunications system comprising SIP networks, FIG. 2 schematically represents the structure of an IMS network; FIG. 3 represents, according to an embodiment of the invention, a procedure for discovering a SIP-URI and for storing this SIPURI as an alias for such a URI; FIG. , according to one embodiment of the invention, the use of a SIP-URI aka such a URI, and - Figure 5 represents, according to one embodiment of the invention, the deletion of a SIP-URI aka of such-URI. Although the present invention relates to SIP networks in general, an exemplary embodiment will now be considered an IMS network architecture as briefly described above. This architecture is illustrated in FIG. 2. The multimedia services offered by this IMS network 1 may comprise services of telephony, video telephony, content-sharing ("content-sharing" in English), presence, instant messaging , or television. These services are available to the user A of a UE client device belonging to the network 1, which enables the client device 10 to exchange multimedia streams and session control in accordance with the SIP protocol, in particular with the client device UE 11 (not shown) of a user B belonging to a SIP network 2 (not shown) connected to the network 1. Each of the client devices 10 and 11 can be a fixed or mobile terminal, or a home or enterprise gateway, having SIP signaling means and which may include means for rendering audiovisual content.

As shown in FIG. 2, this IMS network 1 comprises: an IP transport infrastructure (not represented); one or more I / S-CSCF call servers; a USCSCF call server 22 manages in particular the procedure for registering the devices connected to the network 20; the I / S-CSCF server 22 also manages the routing of the signaling between the client device 10 and the voicemail servers VM 25, Presence PS 26, Resource Lists RLS 27, and telephony TAS 29, as well as routing to other terminals managed by the same IMS network and the routing of the signaling between this IMS network 1 and other networks (not shown); one (or more) server (s) P-CSCF (initials of the words "Proxy-Gall Server Control Function" meaning "Control Function of the Proxy Call Server"); the P-CSCF server 21 is the SIP contact point of the client device 10 in the IMS network; thus, all the SIP signaling exchanged between the client device 10 and the I / S-CSCF call server 22 passes through this server PCSCF 21; one or more database servers, of the HSS type; an HSS server 24 contains the profile of the user A of the client device 10 in terms of authentication data, location and subscribed services; optionally, a server of the SLF type (for "Subscriber Location Function") 23; an SLF server is used in IP networks comprising several HSS servers; more specifically, this SLF server 23 is interrogated by the functions I-CSCF and S-CSCF to find the address of the HSS server 24 hosting the data concerning the user A of the client device 10; one (or more) server (s) VM 25 voicemail ("message-summary" in English); a VM server 25 manages the subscription of the client device 10 to the message deposit / retrieval events for the user A, and notifies the client device 10 at the occurrence of these events; - one (or more) PS Presence server (s) 26; a PS server 26 receives, stores and distributes the Presence information of the user A of the client device 10; - one or more server (s) of Resource Lists RLS 27; an RLS server 27 (moreover often often physically combined with a Presence server) manages the subscriptions to lists of correspondents of the user A, and is responsible for subscribing to the presence information of each of the correspondents present in these lists; and one (or more) TAS 29 telephony server (s); a TAS server manages the telephone services to which the user of the terminal 10 has subscribed with his operator, such as the presentation of the number or call forwarding. The voicemail servers VM 25, Presence PS 26, Resource Lists RLS 27 and telephony TAS 29 are examples of so-called AS (initials of the English words "Application Servers" meaning "Servers"). Applications "). Certain services such as those of the server VM 25, the server PS 26 and the server RLS 27 rely on the subscription of the terminal 10 to predetermined events. The initial subscription procedure of the terminal 10 with the network 1 is normally executed when the terminal (or an application installed on this terminal) is started by the user just after the initial registration procedure. An initial subscription procedure is performed for each type of event subscribed (for example, the initial subscription to the mailing / viewing events is done independently of the initial subscription to Presence events). A subscription has a limited duration in time. This duration may be different for each type of event subscribed, and it is also independent of the recording lease duration. Under normal operating conditions, the client device 10 must renew its subscription (s) automatically and periodically. As part of the SIP protocol, event subscription procedures use a request called "SUBSCRIBE". The present embodiment of the invention can be broken down into several phases: the discovery of a SIP-URI associated with a correspondent, and the storage of this SIP-URI as an alias of the known tel-URI of the RLS server, the use of this SIP-URI as long as it makes it possible to join the presence server of this correspondent, and the deletion of this SIP-URI when it no longer makes it possible to join the presence server of the correspondent, for example when the correspondent changes operator or SIP network. The procedure can then be repeated: discovery, storage, use, and so on. These different phases are described below. FIG. 3 illustrates, according to an embodiment of the invention, a procedure for discovering a SIP-URI and storing this SIP-URI as an alias for such a URI. It is assumed here that when the RLS server 27 of a user A, belonging to the IMS network 1 wishes to be notified, on behalf of the latter, changes in the presence status of an external correspondent B belonging to the an external SIP network, the RLS server initially only knows the tel-URI of this external correspondent (for example such as: +33123456789). Not knowing the SIP network 2 to which this external correspondent B belongs, the RLS server 27 sends its Presence request (SUBSCRIBE) to its IMS network 1, which is then responsible for routing it to the SIP network 2 of the correspondent B. This request will then be transmitted to the presence server of correspondent B.

The response 200 OK indicating the acceptance of the subscription and received from the SIP network 2 then makes it possible to recover a SIPURI (for example, sip: bob @ domain2) from the external correspondent B; indeed, the SIP header called "P-Asserted-Identity" contained in this response to the SUBSCRIBE request makes it possible to convey a SIP-URI identifying the recipient B of the initial request. In the present embodiment, this SIP-URI is then stored, in the RLS server 27 of the user A or in an associated database, as an alias of the tel-URI of the external correspondent B.

It should be noted that other SIP-URI discovery procedures can also be used. The RLS server 27 of the user A could for example rely on a routing based on wafers of telephone numbers, similar to the routing carried out in the RTCP networks (Public Switched Telephone Networks), but implemented here by the heart The IMS network 1. The RLS server 27 could also recover a SIP-URI by directly querying the ENUM server (which supposes the setting up of a non-standard interface). The RLS server 27 could also retrieve a SIP-URI used as GRUU (initials of the Globally Routable User Agent URI words meaning "Globally Routable User Agent URI"), as defined in RFC 5627, which would be inserted by the presence server of the external correspondent B in the response 200 OK to the request SUBSCRIBE. Whenever, subsequently, the Presence application of user A will be started again, its RLS server 27 will again need to be notified of changes in the presence status of external correspondent B. As shown in FIG. FIG. 4, the second phase of the present embodiment of the invention consists of using the SIP-URI previously stored as an alias of the tel-URI of B. The SIP-URI makes it possible to identify the SIP network hosting the external correspondent B (network 2 here), and allows the RLS server 27 to route its request to this network 2, either directly by using the I-CSCF function of the network 2, or indirectly by sending the request to an interconnection function of the type 2. IBCF (initials of the English words "Interconnection Border Control Function" meaning "Interconnection Border Control Function"). This request will then be transmitted to the presence server of the correspondent B. Thus, the RLS server 27 of the user A does not need to send its request to the S-CSCF server 22 of its own IMS network 1, which avoids to have to invoke the routing functions of the core network IMS. The SIP-URI of the correspondent B stored as an alias is temporary insofar as it functions only as long as the correspondent does not change SIP-URI. If the correspondent changes operator, or SIP network dependent on the same operator, the RLS server receives an appropriate SIP error message (for example a SIP error message "404 Not Found") indicating that the resource does not. could not be found. FIG. 5 illustrates this case according to one embodiment of the invention. The SIP-URI sip: bob @ domain2 stored as alias of the tel- URI of B then no longer allows to reach the correspondent B since it is no longer in the SIP network 2, but in a SIP network 3. The RLS server thus deletes this SIP-URI, then it uses again the tel-URI of the correspondent B to discover the new SIP-URI sip: bobby @ domain3 to which the correspondent B can now be joined.

This mechanism makes it possible to cover situations where a correspondent B would change operator or service provider, while keeping his telephone number. The above description of an embodiment of the invention has, for the sake of simplicity, made reference to a unique correspondent B for a given user A. But it is of course easy to generalize this embodiment to a set of correspondents of the user A, as illustrated in FIG. 1. It is also possible, conversely, to pool the implementation of the invention for a plurality of users. Al, A2, ..., which would share the same RLS server 27 and wish to know the presence status of the same remote correspondent B. The invention can be implemented within the nodes, for example RLS servers, SIP networks, using software and / or hardware components. The software components can be integrated into a typical network node management computer program. Therefore, as indicated above, the present invention also relates to a computer system. This computer system conventionally comprises a central processing unit controlling signals by a memory, as well as an input unit and an output unit. In addition, this computer system may be used to execute a computer program having instructions for implementing any of the Presence flow processing methods of the invention. Indeed, the invention also relates to a downloadable computer program from a communication network comprising instructions for executing the steps of a Presence flow processing method according to the invention, when it is executed on a network. computer.

This computer program may be stored on a computer readable medium and may be executable by a microprocessor. This program can use any programming language, and be in the form of source code, object code, or intermediate code between source code and object code, such as in a partially compiled form, or in any another desirable form. The invention is also directed to a computer-readable information carrier having instructions of a computer program as mentioned above. The information carrier may be any entity or device capable of storing the program. For example, the medium may comprise storage means, such as a ROM, for example a CD ROM or a microelectronic circuit ROM, or a magnetic recording means, for example a diskette ("floppy disc" in English) or a hard drive. On the other hand, the information medium may be a transmissible medium such as an electrical or optical signal, which may be conveyed via an electrical or optical cable, by radio or by other means. The computer program according to the invention can in particular be downloaded to an Internet type network. Alternatively, the information carrier may be an integrated circuit in which the program is embedded, the circuit being adapted to execute or to be used in the execution of any of the Presence flow processing methods according to the present invention. 'invention.

Claims (9)

REVENDICATIONS1. Method for processing presence flows in a SIP network, characterized in that, when a user A belonging to a first SIP network (1) has requested to be notified of changes in the presence status of an external correspondent B at said first SIP network (1) and identified by such a URI containing its telephone number, said method comprises the following steps: - identification, in a database contained in an RLS server (27) of the first SIP network (1) or associated with said RLS server (27), a presumed SIP-URI of said correspondent B stored as an alias of said tel-URI, and - sending to a second SIP network (2) containing said presumed SIP-URI of a subscription request to the state of presence of the correspondent B. 2. Method of processing Presence flows according to claim 1, characterized in that said alias was obtained beforehand by means of the following steps: - discovery of the SIP-URI of the correspondent B by means of said tel-URI corresponding B and storage in said database of this SIP-URI as aliases of the tel-URI of the correspondent B. A method for processing presence flows according to claim 1 or claim 2, characterized in that, in response to said subscription request, said RLS server (27) receives a notification from said SIP network. (2) according to which said SIPURI is unknown, the storage in said database of this SIPURI as an alias of said tel-URI of the corresponding B is deleted. 4. Device for processing Presence flows in a SIP network, characterized in that, when a user A belonging to a first SIP network (1) has requested to be notified of changes in the presence status of a correspondent B external to said first SIP network (1) and identified by such a URI containing its telephone number, said device comprises means for: - identifying, in a database contained in an RLS server (27) of the first SIP network (1 ) or associated with said RLS server (27), an assumed SIP-URI of said correspondent B stored as an alias of said tel-URI, and - sending to a second SIP network (2) containing said presumed SIP-URI a request under the Presence status of correspondent B. 5. Presence flow processing device according to claim 4, characterized in that, to obtain said alias, said device comprises means for: - discovering the SIP-URI of the correspondent B by means of said URI of the corresponding B, and - store in said database this SIP-URI as an alias of the tel-URI of the correspondent B. 6. Presence flow processing device according to claim 4 or claim 5, characterized in that, in response to said subscription request, said RLS server (27) receives a notification from said network SIP (2) according to which said SIPURI is unknown, said device comprises means for deleting from said database the storage of this SIP-URI as an alias 25 of said tel-URI of the correspondent B. 7. EPIRB server (27), characterized in that it comprises a device according to any one of claims 4 to 6. An immovable, or partially or totally removable, data storage means having computer program code instructions for performing the steps of a Presence flow processing method according to any one of claims 1 to 3. 9. Computer program downloadable from a communication network and / or stored on a computer-readable medium and / or executable by a microprocessor, characterized in that it comprises instructions for the execution of the steps of a method of processing Presence flows according to any one of claims 1 to 3 when executed on a computer.