WO2001063877A1 - Method for managing mobility in a telecommunications network, and mobility server therefor - Google Patents

Abstract

The invention concerns a network comprising several sub-networks (11-13) equipped with mobility servers (8) operating in accordance with an application layer signalling protocol. For a specific mobile user, one of the sub-networks (11) constitutes a nominal sub-network (9) containing a first information locating the user. When the mobile user is located with an access point (7) connected to a visited sub-network (12), the first locating information designates the mobility server of said visited sub-network, the sub-network mobility server holds in a register of visitors (10) a second information locating the mobile user, enabling him to transmit data through said access point, and each flow of information addressed to or originating from the mobile user, in the context of communication with a remote correspondent, is addressed to the visited sub-network mobility server.

Description

 MOBILITY MANAGEMENT METHOD

IN A TELECOMMUNICATIONS NETWORK,

AND MOBILITY SERVER FOR IMPLEMENTING THE PROCESS

The present invention relates to user mobility services, and finds particular application in telecommunications networks comprising several interconnected subnetworks.

The user mobility in question here consists of the capacity offered to the user to communicate via the network by connecting to it at different access points. The user can take his terminal with him when he travels. This is the typical case of a radiocommunication network with mobiles, the access points being constituted by fixed relays. Without moving equipment, the user can also connect at different points by a registration procedure comprising the transmission, to a mobility management body, of identification data supplied by the user. Another possibility is that the user has a removable data medium which he presents at the visited access point equipped with an appropriate reader to automate the registration procedure.

We can distinguish two types of mobility, one called here micromobility consisting in allowing the user to change access point inside a sub-network, and the other called here macromobility by which the user can connect via access points belonging to separate subnets.

We also distinguish the ability of a user to change access point outside of a session, that is to say in the absence of active data flow ("roaming"), and the ability of a user equipped with a wireless terminal to change access point during a session ("handover").

For the purposes of network administration, each mobile user generally has a nominal sub-network to which is connected a body called here nominal location register, to which requests for the user are initially addressed and coming from sources which do not know their location. When moving in another subnetwork, another member connected to this visited subnetwork, called here visitor manager, can cooperate with the nominal location register for the implementation of mobility services. Application development on networks operating according to the IP protocol (J. Postel, “Internet Protocol”, Request For Comments (RFC) 791, IETF, September 1981), notably those for voice and data transport, contemporary to the development of communication systems with mobiles , naturally led to considering the question of mobility in IP networks, whether they are wide area networks (WAN, "Wide Area Network"), such as the Internet, or local area networks (LAN, " Local Area Network ”).

The Internet Engineering Task Force (IETF) has standardized a network layer protocol supporting mobility in an IP network (C. Perkins, "IP Mobility Support", RFC 2002, IETF, October 1996). After the mobile user has left his nominal subnetwork, his equipment addresses a body called a foreign agent, connected to the visited subnetwork, to send registration information to a body called nominal agent (“home agent”), connected to the nominal subnet. The identity of the visited subnet is also provided to the home agent. One of the main functions of the nominal agent is then to intercept the data intended for the mobile user in order to retransmit it, by an encapsulation mechanism, to a temporary address of the mobile user (called address c / o or "care-of address") provided by the foreign agent. Once arrived at this temporary address, the data can be delivered to their recipient.

This mobility scheme thus imposes a triangular path on the IP packets bound for the mobile user. On the other hand, the data originating from the mobile user is delivered to their destination via the usual IP routing mechanisms.

In addition, it assumes the use of a fixed address for the mobile user. Its implementation therefore poses difficulties in networks where address management is dynamic, which is the case for example when a DHCP server is used in the nominal subnet (see for example EP-A-0 938 217). The DHCP protocol is specified in RFC 2131 published by the IETF (R. Droms, “Dynamic Host Configuration Protocol”, March 1997).

A path optimization process, designed as an extension of the RFC 2002 protocol, has been proposed (C. Perkins, D. Johnson, “Route Optimization in Mobile IP”, Internet Draft, IETF, February 25, 1999) the disadvantages of the triangular routing mode. This process notably provides for the sending of update messages allowing possible correspondents of a mobile user to keep in memory the temporary c / o addresses of the latter. These can then send directly to the temporary address of the mobile user, thus avoiding the operations carried out on the data by the nominal agent. Some authors have criticized the complexity of implementing such a method, and have suggested supporting mobility under IP using an application layer signaling protocol such as the SIP protocol (M. Handley et al., “SIP: Session Initiation Protocol ”, RFC 2543, IETF, March 1999). SIP describes client and server entities, as well as procedures enabling them to communicate (see also HG Schulzrinne and JD Rosenberg, "The Session Initiation Protocol: Providing Advanced Telephony Services Across the Internet", Bell Labs Technical Journal, October-December 1998, pages 144-159). There are two types of SIP servers: proxy servers and redirect servers. On receipt of a request, a proxy server determines the next node on the path to the recipient and then transfers the request to this node, while a redirect server simply tells the client the next node to which it should address its request. .

SIP addresses are similar to e-mail addresses, that is, in the form user @ host, where the "user" field designates, for example, a user name or telephone number, and the " host ”a domain name or address in numeric form. The SIP protocol notably provides methods called INVITE, BYE, REGISTER, OPTIONS, ACK and CANCEL. The responses to messages sent within the framework of these methods are defined by code classes. The INVITE method is used to initiate a call session between two SIP users.

The SIP protocol provides personal mobility capabilities, and allows a user to obtain the same services regardless of their location or the terminal used, in particular thanks to the REGISTER methods.

It has been proposed (E. Wedlund, H. Schulzrinne, "Mobility Support using

SIP ", Proc. of the 2 ^nd ACM International Workshop on Wireléss Mobile

Multimedia, Seattle, August 20, 1999, pages 76-82) mobility methods using the SIP protocol in which wireless equipment connected to the network via an air interface can, after appropriate signaling exchanges, execute a handover, i.e. change network address (IP) by a DHCP mechanism while a communication is in progress. A SIP server connected to the user's nominal subnet manages the nominal location register for the latter. The SIP servers used in mobility management can be proxy servers or redirect servers. Any mobility gives rise to a registration with the nominal SIP server, which can then process requests from other SIP clients to the mobile user. When the wireless equipment determines the need to execute a handover (by detecting beacons emitted by the wireless access points), it obtains a dynamic address by a DHCP transaction, then it sends an INVITE message to its correspondent by indicating the reference of the call in progress and its new network address so that the correspondent updates the destination IP address of the packets which he sends. At the same time, the wireless equipment communicates its new address to its nominal SIP server, using the REGISTER method. One option provides for decentralization of the SIP servers used in mobility management: a proxy SIP server connected to the visited subnet manages micromobility, so that the REGISTER methods to the nominal SIP server, for redirection, can only concern macromobility (change of micromobility server). The main drawback of the process is the delay it can introduce in the execution of the handover. The INVITE method to the mobile user's correspondent requires significant routing time if this correspondent is far from the visited subnetwork. This delay can lead to a perceptible break in the communication in progress. It should be noted that a similar drawback exists within the framework of the IP mobility protocol of RFC 2002. When the mobile equipment is connected to a visited subnet remote from the nominal subnet, it is necessary to route a message location update to the home agent running the handover, which takes time. If the protocol is implemented with the aforementioned path optimization method, there is added the time necessary for the routing of a c / o address update packet to the user's correspondent. mobile.

An object of the present invention is to provide user mobility management which makes it possible to limit the delays due to signaling in the execution of handovers.

According to the invention, a mobility management method is proposed in a telecommunications network comprising several subnets respectively equipped with mobility servers operating according to an application layer signaling protocol, in which one of the subnets constitutes a nominal subnetwork for a mobile user and is equipped with a nominal register containing a first location information of said user. When the mobile user is located near an access point connected to a visited subnet, the first location information designates a mobility server of said visited subnet, said mobility server of the visited subnet is in a register of visitors a second location information of the mobile user, making it possible to transmit information to him through said access point, and each flow of information intended for or originating from the mobile user, within the framework of a communication with a remote correspondent is addressed to said mobility server of the visited subnetwork. Another aspect of the present invention relates to a mobility server adapted to the implementation of the above method. This mobility server is to be connected to a subnetwork belonging to a telecommunications network, and operates according to an application layer signaling protocol. It includes means for managing a visitor register containing, for at least one mobile user located near an access point connected to said subnet, information on the location of the mobile user, making it possible to transmit information to him. information through said access point, means for receiving information flows from the mobile user in the context of a communication with a remote correspondent and retransmitting them to the remote correspondent, and means for receiving information flow coming from the remote correspondent within the framework of said communication and retransmit them to the mobile user.

The mobility server of the visited subnet plays the role of proxy agent both for signaling flows, notably concerning user mobility, and for traffic flows (voice, images, data, etc.). ). Thus, during a handover, only local flows between the mobility server and the user are affected. The mobile user "sees" the proxy server as being his correspondent, so that he is the one to contact to report his change of access point. However, nothing is changed for exchanges between the server and the remote party. It is not necessary signaling information is sent remotely during the handover, to the nominal subnet or to the correspondent. As in general the routing of messages within a subnetwork is very fast, this results in an optimization of the execution time of the handover. This mobility management method does not in itself imply any particular adaptation at the level of the terminals communicating with the mobile equipment.

The method can be applied with various application layer signaling protocols. Currently, SIP is a preferred protocol because it constitutes a good compromise between functional richness and complexity of implementation, while having a good capacity of extension. Other examples, well known to those skilled in the art, are the H.225.0 ("Call signaling protocols and media stream packetization for packet-based multimedia communication Systems") and H.245 ("Control protocol for multimedia communication") protocols. ) specified by the International Telecommunications Union (ITU-T) within the framework of Recommendation H.323 (“Packet-based multimedia communications Systems”, February 1998), and the MGCP protocol (M. Arango et al., “ Media Gateway Controller Protocol (MGCP) ”, RFC 2705, IETF, October 1999) or its Megaco variant (F. Cuervo et al.,“ Megaco Protocol ”, Internet Draft, IETF, February 8, 2000).

The first location information stored in the nominal register of the user will typically be the IP address of the mobility server of the visited subnet, updated only when the movement of the user makes him change the visited subnet ( and possibly when the visited subnetwork includes several mobility servers and the mobile user changes the mobility server without changing the visited subnetwork). The mobility server of the nominal subnet can then be a redirection server to that of the visited subnet.

The second location information stored in the visitor register depends on the architecture of the visited subnetwork. It can consist of a physical MAC layer address (“Medium Access Control”), making it possible to reach the mobile user through the access point. It can also be an IP address of the mobile user in the visited subnet, for example a dynamic address obtained from a DHCP server of the visited subnet or a composite IP address (subnet + equipment address ) of version 6 of the IP protocol (IPv6). If the visited subnetwork is a LAN itself subdivided into subnetworks interconnected through routers, it is also possible to envisage using, within the visited subnetwork, a network layer mobility protocol such as that of RFC 2002, the mobility server playing the role of nominal agent for retransmitting the packets intended for the mobile user, by an encapsulation mechanism, to an address c / o provided by a foreign agent connected to the sub- subnetwork comprising the current access point of the mobile equipment, this c / o address of the mobile user then being recorded as second location information. The above method makes it possible to minimize the execution time of a handover not involving a change in the proxy server locally managing the mobility of the user. This is largely the most frequent case since we can often have only one mobility server per site (subnetwork) for visitors and handovers normally occur inside the same site. There may however be cases in which the same site is provided with several mobility servers, either because there are several subnets on the site, or because multiple servers are provided for reasons of load sharing . In such a case, when a mobile device detects during the session a new access point associated with a mobility server different from that which played the role of proxy before the handover, it remains necessary to exchange messages between the new mobility server and the remote correspondent, so that the latter takes into account a change of IP address where to send its packets. In the latter case, additional means must be used if one wishes to minimize the execution time of the handover.

One of these means consists in including, in a beacon signal emitted on an air interface by at least one access point near which the mobile user is likely to be located, and / or in at least one transmitted message. on the air interface by said access point to the mobile user as part of a procedure for registering a protocol specific to the air interface, a network address of a mobility server associated with said point access.

Thus, the first action of the mobile equipment after its ^' registration with the access point may be to send, to the mobility server from which it has obtained the network (IP) address, the message allowing it to update its location. The progress of the handover will not be delayed by additional exchanges aimed at obtaining this IP address. Other features and advantages of the present invention will appear in the following description of nonlimiting exemplary embodiments, with reference to the appended drawings, in which:

- Figure 1 is a diagram of a telecommunications network to which the invention is applied;

- Figures 2 to 4 are diagrams illustrating the exchange of messages involved in mobility management according to an embodiment of the invention;

- Figure 5 is a diagram of a subnetwork to which an embodiment of the invention can be applied;

- Figure 6 is a diagram illustrating the exchange of messages that can intervene in mobility management within a subnetwork according to Figure 5; and

- Figures 7 and 8 are diagrams showing examples of information blocks which can be transmitted by wireless access points in one embodiment of the invention. FIG. 1 schematically shows an Intranet network distributed over three sites 1, 2, 3. On each site, a sub-network 11, 12, 13 is installed to offer access to a certain number of users. These subnets 11-13 are for example of the Ethernet type (ISO standard 8802-3, “Local Area Networks, Part 3 - Carrier Sensé Multiple Access with Collision Detection - Access Method and Physical Layer Specifications”), and operate according to the protocol IP network. In the example shown, each subnet has an output router 4 connected to a backbone network 5 such as the Internet. The network can in particular be provided to support real-time signal communications, for example telephony, between users connected to it and / or with correspondents accessible by the backbone network 5. In this case, the terminals can use known manner the UDP transport layer protocol (J. Postel, “User Datagram Protocol”, RFC 768, IETF, August 1980) and the real-time protocol RTP (H. Schulzrinne et al., “RTP: A Transport Protocol for Real -Time Applications ”, RFC 1889, IETF, January 1996) for the transmission of coded speech or video. For call signaling, a preferred embodiment of the invention uses the SIP protocol, which also works with the UDP transport protocol. However, other signaling protocols (H.323, MGCP, ...) could be used, in addition to or instead of SIP. At least some of the network users are mobile users equipped with wireless terminals 6. To enable them to access the network, the latter includes radio access points 7 connected to the subnets 11-13. The radio access points 7 are for example DECT base stations (ETSI standard, “European Telecommunications Standards Institute”) or also according to the IEEE 802.11 standard, etc., depending on the type of wireless terminals used. Each of these radio access points 7 broadcasts a beacon signal on the air interface. On the basis of the beacon signals which it receives, an active terminal selects the access point which provides it with the best radio link. This access point is used for communications involving the terminal.

A wireless terminal thus has the possibility of connecting to the network via several access points 7 belonging to different sub-networks (macromobility) or to the same sub-network (micromobility). When the terminal has a communication in progress and moves around a site, it is possible for it to change the access point while maintaining the continuity of the communication (handover). When a communication of signals in real time, for example telephony, is in progress, it is desirable that these handovers are executed in a minimum time in order to avoid perceptible interruptions. For the management of mobility services, each subnetwork (at least those having wireless access points) has a mobility server 8 using the SIP protocol in the preferred embodiment of the invention.

Each mobile user has a nominal subnet. In the illustration of FIG. 1, the sub-network 11 is nominal for the holder of the wireless terminal 6. The SIP server 8 of this sub-network is associated with a location register 9 called the nominal register, which contains the IP address of the SIP server 8 of the subnet 12 visited by the mobile user. The SIP server 8 of the visited subnet 12 is itself associated with a location register 10 called the visitor register, which contains an address making it possible to reach the terminal 6 inside the visited subnet 12, for example an IP address associated with the terminal.

Each SIP server 8 can be associated with a nominal register 9 for the users attached to its subnet and with a visitor register for the users attached to other subnets, only the registers relating to the terminal 6 being represented on Figure 1. In practice, registers 9, 10 can be part of the same unit as the SIP server 8 to which they are associated, or they can be separate entities linked separately to the sub-network. On the other hand, it is possible to provide several SIP servers per subnet, for example in the case where the functions of nominal SIP server and of visited SIP server are provided by separate machines, or in the case where several SIP servers are provided to distribute the signaling load in the subnetwork.

FIG. 2 shows how the registration and the updating of the location of a visiting mobile user can take place in a subnet 12 different from its nominal subnet 11, and the initiation of a communication with this user at the initiative of a remote correspondent.

In the illustration of FIG. 1, the remote correspondent uses a fixed terminal 15 connected to a sub-network 13 different from the nominal sub-network 11 and from the visited sub-network 12. It will however be noted that a similar procedure applies also: - if this correspondent is another mobile user;

- if it is connected to the sub-network 11 or 12 or to the back-up network 5;

- if the connection with the correspondent passes through another network, for example a switched telephone network, for which the Intranet network is equipped with a gateway (in the latter case, it is this gateway which constitutes the SIP client relative to the correspondent shown in Figures 2 to 4).

With reference to FIG. 2, the wireless terminal 6 belonging to the nominal sub-network 11 first picks up on the air interface the beacon signal emitted by an access point 7 belonging to the visited sub-network 12. In response upon detection, it triggers a registration procedure for the MAC layer protocol used on the air interface, by sending a registration message to the access point. In response to this message, the access point 7 returns an acknowledgment (Register Ack) validating the registration of the wireless terminal with the access point. In the example of FIG. 2, the location information of the wireless terminal recorded in the visitor register 10 is a dynamic IP address obtained by the terminal after its registration with the access point 7. The subnet 12 is equipped with a DHCP server 16 which locally manages dynamic addresses. A classic DHCP transaction (DHCP_Discover, DHCP_Offer, DHCP_Request, DHCP_Ack messages) is executed between the roaming terminal 6 and the DHCP server 16, after which the terminal 6 has an IP address.

In another embodiment using the IPv6 protocol, the DHCP transaction is useless since the IPv6 address intrinsically allows a subnet / equipment hierarchy. The next step consists of the SIP client sending the terminal 6 with a SIP REGISTER message to the SIP server 8 of the visited subnet 12.

The IP address of the SIP server 8 was provided by the access point 7 in the beacon signal broadcast on the air interface, which allows the wireless terminal to have this IP address without having to carry out transactions for this purpose via the subnetwork 12. If the beacon signal broadcast on the air interface does not have an available field large enough to contain the IP address of the SIP server 8, this can be completed, or provided in full, in the Register Ack message validating the registration of the terminal on the air interface.

The SIP REGISTER message sent by the terminal 6 allows the visited SIP server 8 to determine the IP address of the terminal, obtained in the IP header of the packet containing the SIP REGISTER message, and to associate it with the SIP address (from the form user @ host) contained in the SIP REGISTER message. This association is recorded in register 10.

After having received this SIP REGISTER message, the visited SIP server 8, if it does not already manage the mobile user, transmits another SIP REGISTER message to the SIP server 8 of the nominal subnet 1 1. The latter sets up update the entry of the nominal register 9 concerning the mobile user identified in the SIP REGISTER message, by memorizing the IP address of the visited SIP server which sent this SIP REGISTER message. It then returns a validation message (code 200 OK) of the SIP protocol. The SIP server visited in turn sends the validation message 200 OK to the terminal 6, through the access point 7. At this stage, the wireless terminal 6 has registered with the access point 7, and updated its location with respect to the SIP servers 8.

When a call from the remote correspondent 15 is initialized, the latter sends the SIP server 8 of the nominal subnet 11 of the mobile user to a SIP INVITE message requesting the mobile user. The nominal SIP server being a redirection server in the example considered, it sends back to the remote correspondent a SIP message (code 302 Move) indicating to the latter that it must direct its INVITE method to the SIP server of the visited subnet 12 for which it provides the IP address. The correspondent again transmits the SIP INVITE message to this visited SIP server.

The visited SIP server then initiates another session with the mobile user, by transmitting to it a SIP INVITE message, which the wireless terminal acknowledges with a SIP 200 OK message if it is available for establishing communication. The session between the wireless terminal and the visited SIP server is opened when the latter has received the message 200 OK. It then retransmits another SIP 200 OK message to the remote correspondent to validate the opening of the session with it.

From this moment, the remote correspondent communicates with the visited SIP server as if the latter was the wireless terminal, and the wireless terminal communicates with the visited SIP server as if it were the terminal of the remote correspondent. In each session opened with the SIP server visited, data is exchanged, typically according to the RTP / UDP / IP protocol stack when it represents coded speech or video, and additional signaling can be provided. according to the SIP / UDP / IP protocol stack. The visited SIP server 8 passes on to the wireless terminal 6 the RTP / UDP flow received from the remote correspondent. Likewise, the RTP / UDP data stream received in the session established with the wireless terminal is passed on to the remote party. The visited SIP server also plays the role of proxy agent.

FIG. 3 illustrates the registration of the wireless terminal 6 with another access point 7 of the same visited subnetwork 12, and the location update carried out with the SIP server of this subnetwork. The registration of the wireless terminal with the new radio access point is carried out by a MAC layer transaction identical to that described with reference to FIG. 2. If necessary, a DHCP transaction (not shown) can be carried out for that the terminal acquire a new IP address. The wireless terminal then sends a SIP REGISTER message to the visited SIP server, whose address it obtained in the tag of the new access point and / or in the Register Ack message. Since the wireless terminal does not change the visited SIP server, it does not need to send a SIP REGISTER message to the SIP server of nominal subnet 11. After modifying the entry in the visitor register 10 relating to the mobile user, the SIP server visited validates its location update, by sending it a SIP 200 OK message. To initiate a call to a remote party (lower part of Figure 3), the wireless terminal sends a SIP INVITE message to its visited SIP server and the latter, which always acts as a proxy server, transmits another SIP message INVITE to the nominal SIP server of the called party. This nominal, redirecting SIP server returns a SIP 302 Move message indicating the IP address to which the correspondent can be reached. This IP address can be the address of the remote correspondent in its nominal subnet 13 or, as in the case of FIG. 2, the address of a SIP server visited if the remote correspondent uses a wireless terminal outside of its nominal subnet.

The establishment of the communication then ends as in the case of FIG. 2. SIP 200 OK messages are sent from the remote correspondent to the SIP server of the visited subnet 12, and from this SIP server to the wireless terminal 6 , after which the visited SIP server manages the two UDP streams as explained above to relay the communication.

FIG. 4 illustrates the handover procedure executed when the wireless terminal 6 has a communication in progress and changes radio access point 7 while moving inside the site visited 2. It is assumed here that the same SIP server visited 8 is associated with the two access points 7, that is to say that the IP address of this server 8 is indicated in the beacon signal of these access points and / or in the message Register Ack. The upper part of Figure 4 shows the data flows relayed by the SIP server visited as explained above.

After the wireless terminal 6 has detected the beacon of the new access point and decided to change the access point, the registration procedure with the new access point and location update with the SIP server visited is executed as in FIG. 3. When the wireless terminal has received acknowledgment of its location update (SIP message 200 OK), it sends an INVITE message to the visited SIP server, containing in particular a reference of the current call. After validation of the INVITE method (SIP 200 OK message returned to the wireless terminal by the SIP server visited), the data exchange resumes without any signaling from the SIP server visited to the nominal SIP server or the remote correspondent. Handover execution is particularly fast since the signaling messages exchanged remain inside the subnet visited 12 without having to be routed through the extended interconnection network 5.

On the other hand, the fact for the wireless terminal 6 to have the IP address of the visited SIP server directly, in the radio beacon or in the radio MAC layer signaling, makes it possible to save time by avoiding a search process of this address in the IP network.

FIG. 5 schematically shows another possible architecture of the subnetwork installed on the site visited 2, comprising several subnets 120, 121 interconnected by means of one or more routers. In the example drawn, the router 4 connected to the backbone network 5 also serves to interconnect the sub-subnets 120, 121.

The SIP server 129 of the visited subnet, which locally manages the mobility of the holder of the wireless terminal 6 in the manner previously explained, is connected to one of the subnets 120. It also acts as an agent nominal in an adaptation of the Mobile IP protocol which is the subject of RFC 2002. This adapted Mobile IP protocol is implemented inside the visited subnet in order to manage in the network layer the mobility of users between the sub- the subnets that make it up (but not at the scale of the grouping of subnets, where an application layer protocol is used, namely SIP in the example considered). Insofar as the agent 129 does not belong to the nominal subnet of the mobile user, we will call it agent "pseudo-nominal", and we will say that we implement a protocol "pseudo-mobile IP ".

In each sub-sub-network 121 different from that provided with the pseudo-nominal agent 129 and equipped with one or more radio access points 7, a routing module is provided as a foreign agent 130 in the sense of RFC 2002.

After the wireless terminal 6 has detected the beacon of a new access point 7 belonging to such a sub-sub-network 121 and decided to change the access point, the registration procedure with the new access point d 'access is executed as in the case of Figure 3 or 4 (upper part of Figure 6). Terminal 6 then sends a request to register the Mobile IP protocol (REGISTRATION REQUEST in the terminology of RFC 2002) to the foreign agent 130, which relays it to the pseudo-nominal agent 129. Terminal 6 places in the REGISTRATION REQUEST message, in addition to its own IP address, the IP address of the pseudo-nominal agent and the c / o address which was previously provided to him. This c / o address may have been obtained by the agent discovery mechanisms specified in RFC 2002. But in a preferred embodiment, the two IP addresses (that of the pseudo-nominal agent and the c / o address) are provided in the beacon signal broadcast by the access point 7, and / or in the Register Ack message. The c / o address is then an IP address of the foreign agent 130, and can be used as the destination address by the terminal for sending the REGISTRATION REQUEST message.

After acknowledgment of the registration request (REGISTRATION REPLY messages of FIG. 6), the mobile terminal transmits its SIP REGISTER message to update its location with respect to the SIP server visited 129. The SIP REGISTER message can be sent directly to the IP address of the visited SIP server 129. As this message is seen as data by the Mobile IP protocol, it can also be relayed by the foreign agent 130 to the visited SIP server / pseudo-nominal agent 129. For acknowledge the SIP REGISTER method (after an exchange with the SIP server of the nominal subnet 11 if there has been a change of visited subnet), the visited SIP server 129 uses two levels of IP header to transmit the SIP message 200 OK, the internal level having the IP address of the wireless terminal 6 and the external level having the c / o address which was supplied by the foreign agent 130. The foreign agent 130 removes the external level for retransmit the message 200 OK to the terminal.

The same encapsulation mechanism will be used for all the packets sent to terminal 6 by the visited SIP server 129 (SIP protocol or data from a remote correspondent). Similarly, the packets sent by the terminal 6 are relayed by the foreign agent 130 to their destination, namely the visited SIP server 129 since this is seen by the terminal as if it were its correspondent.

The location update executed according to FIG. 6 takes place in the same way in the case of “roaming” (FIGS. 2 and 3) and in the case of the “handover” (FIG. 4). The location information associated with the terminal 6 in the visitor register 10 then consists of the address c / o which allows the SIP server to route the data to their destination.

FIG. 7 illustrates a possible structure of the beacon signal broadcast by a wireless access point 7 connected to a subnetwork. This signal is formed by modulation of a digital data block B, and is transmitted in a radio signal frame, or possibly in a frame time interval if time division multiple access is used on the air interface.

The digital data of block B includes a predetermined synchronization pattern 20, the detection of which allows the wireless terminals located within range of the access point to synchronize in time and in frequency to demodulate the signal of the frame, and certain conventional fields 21-23 containing system information required by the physical layer and link layer protocols. This system information typically includes:

- an identification of the network to which the access point belongs (field 21);

- system synchronization information (field 22), identifying the position of the current frame in the temporal organization of the radio signal transmitted on the carrier of the beacon (frame index in a current superframe, superframe number, ...) ;

- other system information (field 23), such as for example a minimum received field level from which a wireless terminal is authorized to register with the access point, or even indications of the carrier frequencies of the beacon of some neighboring access points so that the terminals can monitor these carrier frequencies in order to determine the access point providing the best radio link.

Advantageously, the block B also comprises a field 24 in which the access point 7 places data describing its environment.

This data can represent the geographical environment where the access point is installed: location of the site visited 2, precise position of the access point (for example building, corridor, office, ...). As the network is based on the IP protocol in which there is no notion of physical connection, communication with a wireless terminal does not imply any knowledge, even implicit, of the geographic location of the terminal. Remote correspondents and the location register 9 does ^'' are "terminal as logically, through one or more IP addresses. However, a certain number of applications may need such geographic location information, for example to provide services differentiated according to the location of the terminal or for provide an indication of this location to the correspondents of the mobile user. By inserting this geographic location information (explicitly or in coded form) into the beacon signal, it is made available to wireless terminals which can then communicate it to the mobility server of the nominal subnetwork or to correspondents in the context apps like that.

The environmental data placed in field 24 of block B can also include one or more IP addresses of mobility management bodies, namely: - the IP address of the SIP server (or H.323, MGCP, Megaco, ...) visited in an embodiment according to Figures 1 to 4;

- in an embodiment according to FIGS. 5 and 6, the IP address of the SIP server (or H.323, MGCP, Megaco, ...) also playing the role of pseudonominal agent 129 and the IP address of the agent foreigner 130; - in an embodiment where mobility between the subnets is managed by a network layer protocol such as that of RFC 2002, the IP address of the foreign agent.

The environmental data of field 24 can also include a UDP or TCP port number used by the mobility server 8, 129 associated with the access point, if it is not a default port number. This allows the terminal to send requests to the application layer signaling protocol directly to the correct port number. It is also possible to include in the environment data a MAC (Ethernet) address of the mobility management unit 8, 129 connected to the same subnetwork or subnetwork as the access point.

If field 24 of block B does not provide enough space to insert all the planned environmental data into the beacon signal, it is possible to insert some (or all) of it in the Register Ack message of FIGS. 2, 3, 4 or 6. In the example illustrated by FIG. 8, this Register Ack message is formed from a block of digital data B 'comprising:

a field 25 identifying the previous registration request and / or the wireless terminal which sent it;

- a field 26 containing codes indicating the response to the registration request (access authorized, refused or conditioned, parameters, ...); - a possible field 27 to contain additional system information in addition to that provided in fields 21-23 of block B;

- a field 28 to repeat the environmental data or provide those which have not been in field 24 of block B.

Claims

1. Method for managing mobility in a telecommunications network comprising several subnets (11-13) respectively equipped with mobility servers (8) operating according to an application layer signaling protocol, in which one of the subnets (11 ) constitutes a nominal sub-network for a mobile user and is equipped with a nominal register (9) containing a first location information of said user, in which when the mobile user is located near an access point (7 ) connected to a visited sub-network (12), the first location information designates a mobility server of said visited sub-network, said mobility server of the visited sub-network maintains in a visitor register (10) a second information of location of the mobile user, allowing him to transmit information through said access point, and each information flow intended for or originating from the mob user ile, as part of a communication with a remote correspondent, is addressed to said mobility server of the visited subnet.

2. The method of claim 1, wherein the network operates according to the IP protocol.

3. The method of claim 2, wherein said application layer signaling protocol is SIP, H.323, MGCP or

Megaco.

4. The method of claim 2 or 3, wherein the first location information is an IP address of the mobility server (8) of the visited subnet (12).

5. The method of claim 2 or 3, wherein the second location information is an IP address of the mobile user in the visited subnet (12).

6. Method according to any one of claims 1 to 4, in which at least one sub-network comprises several interconnected sub-sub-networks (120, 121) respectively equipped with mobility agents (129, 130) used in a network layer mobility management protocol, wherein said subnet has a mobility server (129) connected to one of the subnets (120) and constituting a nominal mobility agent for mobile users visiting said subnetwork, and in which when a mobile user is located near an access point (7) connected to another of the subnetworks (121), said mobility server constituting a nominal mobility agent stores in the visitor register (10) a second location information of the mobile user, consisting of a network address, which said mobility server constituting a nominal mobility agent places in headers packets in which the information flows intended for the mobile user are retransmitted by an encapsulation mechanism.

7. Method according to any one of claims 1 to 6, in which at least one access point (7) with which the mobile user is likely to be located is associated with one of the mobility servers (8 ), and a network address of the mobility server (8) with which said access point is associated is included in a beacon signal transmitted on an air interface by said access point (7), and / or in at least a message transmitted on the air interface by said access point to the mobile user as part of a procedure for registering a protocol specific to the air interface.

8. The method of claim 7, wherein, at the end of the registration procedure with said access point (7), an update message for the location of the application layer signaling protocol is sent from the mobile user to said network address.

9. The method of claim 7 or 8, wherein at least one subnetwork comprises several interconnected subnetworks (120, 121) respectively equipped with mobility agents (129, 130) used in a management protocol for network layer mobility, wherein said subnet has a mobility server (129) connected to one of the subnets (120) and constituting a nominal mobility agent for mobile users visiting said subnet network, in which when a mobile user is located near an access point (7) connected to another of the sub-subnets (121), said mobility server constituting a nominal mobility agent stored in the register of visitors (10) a second information of location of the mobile user, consisting of a network address, which said mobility server constituting a nominal mobility agent places in packet headers in which the information flows intended for the mobile user are retransmitted by a encapsulation mechanism, and in which one also includes in the beacon signal emitted by said access point, and / or in at least one message transmitted on the air interface by said access point to the mobile user as part of the procedure for registering the protocol specific to the air interface, a network address of a foreign mobility agent (130) connected to the same sub-sub-network (121) as said access point and corresponding to the network address forming the second location information of the mobile user.

10. Mobility server to be connected to a subnetwork (12) belonging to a telecommunications network, operating according to an application layer signaling protocol and comprising means for managing a visitor register (10) containing, for at at least one mobile user located near an access point (7) connected to said subnet, information on the location of the mobile user, making it possible to transmit information to him through said access point, means for receiving information flows from the mobile user in the context of a communication with a remote correspondent and retransmit them to the remote correspondent, and means for receiving information flows from the remote correspondent within the framework of said remote communication and retransmit them to the mobile user.

11. The mobility server as claimed in claim 10, in which the network operates according to the IP protocol and said application layer signaling protocol is the SIP, H.323, MGCP or Megaco protocol.

12. Mobility server according to claim 10 or 11, wherein the second location information is an IP address of the mobile user in the visited subnet (12).

13. Mobility server according to claim 10 or 11, for a subnetwork comprising several interconnected subnetworks (120, 121) respectively equipped with mobility agents (129, 130) used in a mobility management protocol network layer, said mobility server being connected to one of the sub-networks (120) and constituting a nominal mobility agent for mobile users visiting said sub-network, in which the means for managing the visitor register (10) are arranged to memorize, for at least one mobile user located near an access point (7) connected to another of the sub-subnets (121), location information consisting of a network address, and the means for retransmitting mobile user information flows are arranged to encapsulate said flows in packets having a header comprising said network address stored in the visitor register for the mobile user.