FR2799324A1 - Switching system to establish communication between terminals in a communication network without using the Internet network involves tasks associated with each terminal - Google Patents

Abstract

Method involves : creation of a task for the terminal calling stocked in its reference unit; task send a signal through the network carrying information such as number of the calling terminal and type of connection to the network; called terminal creates task in response, which interacts with the configuration control unit to determine which gateway must be used to link both terminals without using the Internet network. Switching system comprises controlling unit (11-13,21-25,30) controlling many terminals (32-36,40-43). An Independent claim is also included for the switching system using the method previously described.

Description

 METHOD OF ESTABLISHING <U> OF COMMUNICATION </ U> <U> BETWEEN TERMINALS CONNECTED TO A </ U> SYSTEM <U> OF SWITCHING </ U> <U> AND </ U> SYSTEM <U> OF The present invention relates to a method for establishing communications between terminals in a switching system. The invention applies more particularly to a switching system in which: FIG. access points (lines to terminals or terminals connected to networks or dedicated lines) are organized into clusters, each managed by a cluster control unit (UCG). Each cluster control unit has some autonomy to manage communications or other service supplies involving access points that depend on them. In particular, the UCG includes a memory where are stored tables containing various related terminal data which are connected to it and in particular to manage the faculties of which the terminals have.

This hardware architecture induces the half-call software concept. Signaling processes for establishing a common ion (or other service provision) through an access point include access point control tasks for identifying events (off-hook, on-hook, numbering, occupation ...) coming from the access point and translate them into messages of the switching system and to address various commands to the access point (ringing, display tones ..., and on the other hand management tasks to process requests relating to the access point (in particular according to the rights defined in the tables) and to supervise the access point control tasks .The signaling relating to a communication between several access points proceeds from exchange of messages between the half-calls concerned Advantageously, the call management tasks use messages in standardized formats and protocols in the switching system. Ndis access point control tasks provide the necessary translations to take into account the specificities of different types of terminals or networks that can be connected.

The above architecture is well adapted to the case of fixed terminals connected to the UCGs to invariable addresses. The half-call for such a terminal can be fully executed at the UCG to which it is connected (reference UCG). The patent application EP-A-0 748 describes a way of adapting it to the case of mobile radio terminals that are able to communicate via radio terminals connected to visited UCGs that are distinct from their reference UCGs. I UCG reference of a terminal is generally one where are stored the relevant data concerning this terminal.

The success of Internet Protocol (IP) -based networks has led to the development of real-time protocols (RTP, Real Time Protocol, and Real Time Control Protocol (RTCP) capable of supporting telephony traffic. These IP terminals can in particular take the form of conventional telephones associated with appropriate adapters, telephone terminals connectable directly to the IP network (for example Webphone), or even equipped microcomputers. telephony software (for example Netmeeting marketed by Microsoft).

The success of IP networks on the other hand suggests to use them in the field of enterprise switching, to link together different entities of the switching system. The IP network of an enterprise (Intranet) can thus be used to interconnect separate PBXs. In addition, it can advantageously provide a connection means for IP terminals managed by the system.

In the architecture mentioned above, some of the UCGs are then equipped with gateway interfaces with the IP network, and can serve as a reference UCG for IP terminals connected to this network. A terminal knows a priori only the IP address of the reference UCG gateway interface, and it addresses its requests to this UCG, which then relays the signals to the destination. This process uses resources from the Gateway UCG during communication.

An object of the present invention is to optimize; in a switching system, the use of resources mobilized by communications involving IP terminals connected to the system by a local network.

According to the invention, there is provided a method of establishing communication between terminals connected to a switching system, the switching system comprising a plurality of interconnected cluster control units each providing access points to the system. Each terminal is respectively associated, among the cluster control units, with a reference unit which stores data specific to said terminal; used to carry out signaling treatments concerning him. At least some of the cluster control units are gateway units respectively equipped with gateway interfaces with an IP network. Some of the terminals are IP type terminals connected to the system via the IP network. The switching system comprises at least one call configuration manager arranged to deliver call configuration data in response to two sets of parameters relating to calling terminals and called, respectively, said set of parameters relating to a terminal including an indication of the type of connection of the terminal, which differs according to whether the terminal is IP type or not. The method according to the invention comprises the following steps for establishing a communication between first and second terminals comprising calling and called terminals - creation of a first call processing task in the reference unit of the calling terminal - training, by the first call processing task, an establishment message including at least the called terminal number and the connection type indication of the calling terminal; in response to receiving said establishment message, creating a second call processing task in the reference unit of the called terminal; querying the configuration manager by the second call processing task, on the basis of a set of parameters relating to the calling termi extracted from the establishment message and from a set of parameters relating to the called terminal deduced by the second call processing task from the number received in the setup message; and when the call configuration data returned by configuration manager corresponds to an opportunity to exchange, directly across the IP network, traffic between said first terminal and at least one gateway interface from which said second terminal is accessible without through the IP network, signaling exchange between the first and second call processing tasks and a management task of a gateway interface, in order to establish between the said gateway interface and the second terminal a communication path that does not by the IP network, providing said gateway interface with addressing data of the first terminal in the IP network, and providing the first terminal with addressing data of said gateway interface in the IP network.

The method minimizes the resources required in the switching system to support communication between a type terminal and a conventional terminal (which is not IP type). By distinguishing different call configurations, the system can in each case behave appropriately and make the most of the routing capabilities of the IP network when possible.

Thus, when the call configuration data returned the configuration manager correspond to an exchange possibility; directly through the IP network, traffic between said first and second terminals, the method may include a signaling exchange between the first and second call processing tasks. to provide the second terminal addressing data of the first terminal in the IP network, and to provide the first terminal address data of the second terminal in the IP network. In this case, the two terminals communicate directly with the IP network, maintaining the link with their reference units only as regards the signaling functions.

In an advantageous embodiment of the method, the set of parameters relating to an IP type terminal, taken into account by the configuration manager, includes information on coding capabilities of said terminal, and preferably a location information enabling to identify a subnet of the IP network to which said terminal is connected. The configuration manager then acts as a topology server for the IP network. The choice of how to set up the voice path by the configuration manager is based on the IP terminal coding capabilities and the available bit rate resources in the IP network (for technical reasons only and / or given choices made by the network administrator). The configuration manager can also take into account the state of charge of the IP network to favor the use of a minimum rate coding for voice communications to use this network while it is relatively congested.

Another aspect of the present invention relates to a switching system comprising a plurality of interconnected cluster control units each providing access points to the system, at least some of the cluster control units being gateway units respectively equipped with interfaces. gateways with an IP network, the system being arranged to implement a method as defined above to establish communication between terminals connected thereto.

Other features and advantages of the invention will appear in the following description of nonlimiting embodiments, with reference to the accompanying drawings; Figure 1 is a block diagram of a cluster control unit of the system of Figure 1; FIGS. 3 to 6 are diagrams illustrating examples of call signaling in the system of FIG. 1; respectively between two conventional terminals; from an IP terminal to a conventional terminal; from a conventional terminal to an IP terminal, and between two IP terminals.

Figure 1 shows, for illustrative purposes, an example of a switching system constructed from three PBXs 10. 20; 30. Each PBX has a cluster organization. It thus comprises one or more cluster control units (UCG) 11-13; 21-25, 30 each having a set of access points to the system. The access points can interface with different types of lines, depending on the desired system compatibilities. In particular, it is possible to provide access points for the connection of conventional 32-35 telephone terminals, analog (simple terminals S63 or "intelligent" terminals) or digital terminals (terminals X.25, ISDN, etc.). For external communications, at least some of the UCGs 13, 22 have access keys connected for example to lines of the Public Switched Telephone Network (PSTN) 50 of an Integrated Services Digital Network (ISDN) and / or a packet-switched digital network (X.25). To possibly allow communication with mobile terminals 36 (for example CT2 or DECT), some of the UCGs may comprise radio access poles connected to respective radio terminals 37, 38.

Each UCG has sufficient resources to support communications between its own access points.

Each PABX 10, 20 comprising several UCGs is equipped with a transport loop 18, 28, allowing inter-UCG exchanges so as to support communications between several access points belonging to this PABX. As an example, the loop 18, 28 may be a 40 megabyte digital line organized in time-sharing to support 512 circuit-switched channels ("channel circuits") and 70 packet-switched channels ("packet channels") . The circuit channels are provided for access points whose operation requires the reservation of a circuit resource, while the packet channels are provided for the access points used by packet switched communications and for the exchange of commands. specific to the switching system (including signaling functions). Unrepresented control units are provided in PABX 10 to supervise the operation of the transport loops 1 28.

When the system comprises several PBXs, inter-PABX lines 52 (for example private PCM lines or leased to a public operator) are possibly provided between some of their UCG 25, 30.

The switching system cooperates with an information network supporting the IP protocol. In the example of FIG. 1, this network incorporates two local area networks (LAN) 54, 55 interconnected via a wide area network (WAN) 56. The ANN 56 plays the role of interconnection between the subnetworks. networks formed by the LANs 54, 55. The PABX 10 is connected to the LAN by an access point of its UCG 11. The PABX 20 is connected to the LAN 55 by access point of its UCG 21. The PABX 30 consisting of in a single UCG is connected to the LAN 55 by one of its access points. These UCGs 11, 21, 30 provided with IP interfaces are hereinafter referred to as UCG gateways.

 Some of the terminals managed by one or more of the PBXs are terminals of type IP 40-43, which are connected to the system via the IP network. Such a terminal 40 may be a conventional telephone 47 associated with an adapter 48 for connection to the network. It can also be a telephone terminal 41, 42 (VVebphone for example) incorporating an IP interface, or a microcomputer 43 executing a telephony application (Netmeetïng for example).

In the embodiment considered here by way of example, the reference UCG of each IP terminal is a gateway UCG. Without being mandatory, this simplifies the architecture of the system. In the case represented in the figure, the UCG 11 is for example the reference UCG of the IP terminals 40 and 41 connected to the LAN 54, while the UCG 21 is the reference UCG of the IP terminals 42 and 43 Connected to the LAN 55. Each IP terminal stores the address in the IP network of a gateway interface of its reference UCG, to which it addresses all its requests.

FIG. 2 is a block diagram of a UCG 11 having, for example, access points for analog terminals 32 for connecting radio terminals 37 and a gateway access point for connection to LAN 54. UCG 11 comprises an interface 60 with the transport loop 18 of the PABX. consisting, for example, of repeaters for retransmitting the frames circulating on the loop 18 associated with a packet-type separation automaton and the circuit and buffer channels for extracting and inserting signals concerning the UCG.

Each access point of the UCG consists of a physical interface 61, 62; 63, which provides the physical functions of signaling (event detection, commands ...); translation and formatting necessary for the compatibility of the organs connected to the access points with the formats used in the switching system.

With respect to IP terminals, the interface 63 with the 54 can provide signaling and formatting functions according to the ITU-T H.225, H.245, and H.323 ITU-T Recommendations. Another possibility is to code display patterns defined for the switching system by means of a page description language such as XML (eXtended Markup Language), as described in the French patent application 99 06159. If the terminal is adapted for this type of presentation, it displays the system-specific patterns described in the XML messages built by its gateway interface, and it can provide the signaling information required in response to these messages. performs according to Transmission Control Protocol (TCP) transport protocol sessions established between two gateway UCGs or between an IP terminal and its gateway UCG.

For transmission of the speech encoded on the network I, the UDP transport protocol (User Datagram Protocol and the real-time protocols RTP and RTCP) is used as usual, so the Passerel 63 interfaces are capable of constructing and retrieving datagrams. UDPIIP according to the RTP and RTCP protocols.

Different speech coding / decoding modes may be used by the IP terminals 40-43 and the gateway interfaces 63. In the case of H.323, the audio coding may be in accordance with one of the Recommendations G.711, G .722, 723.1, G.728 and G.729 of the IT-T.

In the remainder of the present description, it is assumed, but not limited to, that an IP terminal can transmit and receive G.711 coded speech (64 kbit / s PCM coding), and possibly G.723. (predictive coding compression at 6.4 or 5; 3 kbit / s), and that the speech transmission within the PABXs, between the PABXs and the conventional terminals 32 and between the PABXs and the radio terminals 37, 38 is in the form G.711. Thus, the gateway interface is arranged to perform a G.711 /G.723.1 transcoding when it is required for an IP terminal operating in G.723.1.

The different interfaces 60-63 are connected to a switching matrix 64 which ensures the routing of the signals.

The operation of the UCG 11 is controlled by a processor 65 associated with a memory 66. The processor 65 controls the interfaces 60-63 via its bus 67 @ either directly (interfaces 60, 62, 63 in the example of Figure 2) or through the switching matrix 64 (interfaces 61). The processor 65 notably supports the signaling processes concerning the access points of the UCG: it is informed of the events detected by the interfaces 60-63 and performs the appropriate processes to configure the switching matrix 64. to send signaling messages to the interface 60 and commands to the physical interfaces 61-63.

For the PABX transport loop interface, the processor 65 has two software utilities: the Inter Communications Manager (GIC) which manages the packet channels and the Multisite Time Interval Manager (GIM) which manages the channels circuits. For the transmission and reception of its messages, the call processing is addressed to the GIC in the form of primitives. By the choice of a directed message or a broadcast message, it is possible to address a UCG or all the UCG of a PABX. In connection with the operational system, the ICG manages the routing of messages. For the taking / releasing and the connection / disconnection of the voice path, the call processing is addressed to the GIM also in the form of primitives. When it comes to reserving a path, the GIM utilities of the two half-calls dialogue directly with each other.

Different types of software modules are used by the processor 65 to perform the signaling processes. A half-call concerning a terminal thus entails the creation of the following tasks - the (Organ Manager) playing the role of controller of the terminal, subdivided into an MGO and an IGO. The MGO (Organ Management Monitor) more specifically performs the interface functions with the higher level (MAS level), while the Organ Management interface (1G0) holds account details specific to each type of terminal. It detects the elementary events generated by the terminal, processes them and translates them into telephone events transmitted to the MAS by messages conforming to the standard of the internal signaling of the system. It passes back to the terminal the commands expressed by the MAS in messages conforming to the standard internal signaling system.

- the Simple Call Monitor (MAS) which performs all the functions of analysis and decision (call routing, request for faculty ....) involved in call management. For these functions, the MAS consults tables stored in the memory 66 and defining in particular the its of the user and the faculties accessible by the terminal. MAS disguises the Organ Manager The organ manager is adapted to the type of organ that it controls; the MAS is independent of the organ type. This independence preserved by the interface MASIMGO whose formats are standardized in the system. MGO is common to a family of applications so 1'1G0 is more specific.

In the diagrams of FIGS. 3 to 6, each half-call concerning a terminal is managed by a call processing task (TAP) executed by the processor 65 of the reference UCG of the terminal. This TAP task groups together the tasks MAS and MGOIIGO mentioned above; between which the distinction is not made to simplify the representation of the call scenarios. The left part of each diagram corresponds to the requesting half-call, and the right part to the half-call requested.

Each represented call scenario begins with an exchange of information between the calling terminal 70. 170 and the corresponding call processing task 71, 171. This task 71, 171 has for example been created by the processor 65 of the reference UCG of the calling terminal 70. 170 to receive a message signaling the line taken by this terminal. It sends to the terminal the patterns coding the information to present to the user (displays, tones, ...). and retrieves the data provided by the user to define his request (choice of functions, numbering, ...). When it has sufficient information. the UCG broadcasts in the system a set-up message (SET_UP), comprising in particular the following elements: the directory number of the called terminal 80; 180, defined directly or indirectly by the user of the calling terminal 70, 170; the location of the calling terminal 70, 170 in the system, namely the reference UCG site number (a site which may correspond to a PABX 10, 20, 30) and the reference UCG number in the site ; the type of connection of the calling terminal, contained in the tables of its reference UCG executing the task TAP 71; 171; this element makes it possible in particular to distinguish the conventional terminals from the IP terminals; for a calling terminal of conventional type, a corresponding physical device number designating the PABX interface to which the terminal is connected for an IP type calling terminal, an indication of the codings and data rates with which it is compatible (in the simplified example mentioned previously, G.711 only or G.711 + G.723.1); for an IP type calling terminal; the IP address of the terminal in the network 54-56, a UDP port number which it devotes to the speech transmission according to the RTP protocol and another UDP port number for the transmission of the control information according to the RTCP protocol.

The UCGs to which this message is broadcast analyze the number of the called terminal. The only UCG that takes the message into account, by creating a TAP job 81, 181, is the reference UCG of the called terminal. This task 81, 181 queries a topology server 90 to determine a configuration of the call.

In the example shown in FIG. 1, the system comprises two topology servers 90; one connected to an access point of the UCG 13 PABX 10, and the other connected to an access point of the UCG 25 PABX 20. These two servers contain essentially the same data; either being queried according to YUCG where task 81, 181 is performed. It will be noted that many other implementations would be possible, for example to provide a single or more topology server, to connect a topology server to the IP network, or to make the topology server in the form of simply stored tables in each UCG capable of question.

The topology server 90 is interrogated on the basis of two sets of parameters, one relating to the calling terminal 70, 170 and the other relating to the called terminal 80, 180. Each set of parameters relating to a terminal comprises - the type terminal connection - the location in the system (reference UCG site numbers and reference UCG number in the site); for an IP type terminal, an indication of the codings and rates with which it is compatible.

For the calling terminal, these parameters are obtained by the TAP task 81 181 in the received setup message. For the called terminal, they are read from the terminal-specific data stored in the UCG by means of the directory number obtained in the received establishment message.

In the case of a call between two terminals 70, 80 of conventional type (non-IP), the call configuration designated by the topology server 90 in response to its interrogation corresponds to the diagram of FIG. of the GIM utility, the TAP 81 task of the incoming half-call, executed in the reference UCG of the called terminal 80, controls the establishment of a communication path between the access points of the calling and called terminals 70 , 80. If necessary (multi-site call), this communication path can partly borrow the IP network between two gateway UCGs. TAP task 81 sends directly to the called terminal 80, if it is available. I mire indicating the incoming call, and it returns to the TAP 71 task of the originating half-call an alert message to signal the start of ringing the called terminal. This alert message is retransmitted in the form of a pattern to the calling terminal 70, via the line connecting this terminal to its reference UCG, which is the one that executes the task TAP 71. When the called terminal takes the line. the event is signaled to the TAP task 81 which informs the TAP task 71 in a connection message retransmitted as a pattern to the calling terminal 70. The communication can then proceed conventionally. When one of the terminals is hung up, the other is informed by the TAP tasks 71, 81 before they withdraw.

In the case of a call from an IP terminal 170 to a conventional type terminal 80, the call configuration designated by the topology server 90 in response to its interrogation may correspond to the diagram of FIG. 4. The TAP task 81 on the arrival side does not immediately have physical device number for the calling terminal, since it is connected by an IP network in which there is no notion of connection. It then sends the TAP 171 task of the other half-call an event request message, in which it indicates the current call configuration as well as the location (UCG site) of the terminal called 80. Received of this message, the task 171 consults a gateway designation table 92 to identify the UCG of at least one gateway interface from which the called terminal 80 is accessible without going through the IP network.

The tabl 92 is constructed during the configuration of the system. It maps to each cluster control unit 11-13, 21-25, more than 30 gateway units, the gateway interface of which, according to the system configuration, can link with the access points of said unit. cluster control without going through the IP network. The table 92 may for example be stored in each gateway UCG, so that it can be consulted in the processing of each half-call concerning an IP terminal. When setting up a new gateway to the network; it broadcasts on the IP network; to all UCGs with gateways; its location (site, UCG) as well as the location (site; UCG) of each UCG to which it has access inside the PABX system without going through the IP network. As a variant, the gateway table 92 could be stored in a server accessible within the PABXs or on the IP network.

Thus, in the call scenario of Figure 4; when it receives an event request message indicating the location (site, UCG) of a called terminal of conventional type, the task TAP <B> 171 </ B> can obtain in the table 92 the localization (site, UCG) of each appropriate gateway. <B> El </ B> then issues a second set-up message, which it directs to the UCG I designated by table 92, including the IP address of the calling terminal. and the UDP port numbers it uses for the RTP and RTCP protocols. Upon receipt of message, the Gateway Manager Management Task 95 (GO-P) executed by the processor of a gateway UCG concerned examines whether the gateway interface has resources for the communication being established. If so, it reserves two UDP port numbers for the RTP and RTCP links, and responds to task 171 by returning the physical number of the available gateway interface, its IP address in the network and both numbers. UDP port reserved. Task 171 can then respond to task 81 by providing the physical device number of a gateway interface. Having two physical equipment numbers (that of the gateway interface to rent, and that of the called terminal 80 which knows from the tables stored in the UCG), the task 81 command, with the help of the utility GIM, the establishment of a communication path, which does not pass through the IP network, between the gateway interface and the access point of the called terminal 80. It sends to terminal 80, if available, the target indicating the incoming call, and it returns to the TAP 171 task of the originating half-call the alert message signaling the start of ringing the called terminal. This alert message is retransmitted in the form of a pattern to the calling terminal 170, in one or more TCPIIP segments addressed to the terminal by its reference UCG; with the IP address of the gateway interface to use and the reserved UDP ports in it for communication. When the called terminal 80 takes the line, the event is reported to the TAP task 81 which informs a TAP task 171 in a connection message retransmitted as a pattern to the calling terminal 170. The communication can then take place - the IP terminal 170 sends its coded speech in the form of RTP packets to the UDPIIP port indicated to it with the alert pattern, and the recipient gateway interface reconstructs the coded speech signal stream; if necessary performs a transcoding, and retransmits the speech coded in G.711 to the conventional terminal 80; the speech coded in G.711 transmitted by the conventional terminal 80 is routed to the gateway interface within one or more PABXs, possibly transcoded, and then sent over the IP network to the UDP port that has been specified in the second setup message - TAP tasks 171 and 81 (more specifically GO tasks) remain in effect until the end of the communication, as well as the TCPIIP session carrying the signaling between the IP terminal 170 and its reference UCG.

In the case of a call from a conventional type terminal 70 to an IP terminal 180, the call configuration designated by the topology server 90 in response to its interrogation may correspond to the diagram of FIG. 5. The TAP task 181 executed in the gateway UCG on the arriving side does not immediately have a physical device number for the called terminal. It then consults the gateway designation table 92 based on the location (site, UCG) of the calling terminal 70 that it has obtained in the setup message, to identify the UCG of at least one gateway interface. from which the calling terminal 70 can be accessed without going through the IP network. The TAP task 181 then sends a second set-up message, which directs to the UCG (s) designated by the table 92, including the IP address of the called terminal 180 and the UDP port numbers that it uses for the calls. RTP and RTCP protocols (the UCG executing task 181 has these addresses and port numbers in the memory it stores about the called terminal whose number was in the first establishment message) Upon receipt of this message, the gateway management module (GO-P) executed by the processor of a gateway UCG concerned examines whether the gateway interface has resources for the communication being established. In the affirmative, it reserves two UDP port numbers for the RTP and RTCP links, and responds to task 181 by returning the physical device number of the available gateway interface, its IP address in the network, and both numbers. UDP port reserved. Having two physical equipment numbers (that of the gateway interface to be used, and that of the calling terminal 70 that it obtained in the first establishment message), task 181 command, using the utility GIM, the communication path establishment, which does not pass through the IP network, between the gateway interface and the access point of the terminating terminal 70. It sends to the IP address of the called terminal 180, where it is available, the pattern indicating the incoming call, with the IP address of the gateway interface to be used and the UDP ports reserved therein for the communication, and it returns to the TAP task of the half-call starting on alert message signaling the beginning of the called terminal ring. This alert message is retransmitted in the form of a pattern to the calling terminal 70. When the called terminal 180 takes the line, the event is reported to the task TAP 181 which informs the task TAP 71 in connection message retransmitted under The communication can then take place - the G.711 coded speech transmitted by the conventional terminal 70 is routed to the gateway interface in one or more PABXs, possibly transcoded; then sent over the IP UDP port network that was specified in the second setup message; the IP terminal 180 sends its coded speech in the form of RTP packets destined for the UDPIIP port which has been indicated to it with the incoming call pattern, and the recipient gateway interface reconstitutes the coded speech if I stream, operates the case transcoding, and retransmits the speech encoded in G.711 to the conventional terminal 70; TAP tasks 71 and 181 (specifically GO tasks) remain in effect until the end of the communication, as well as the TCPIIP session carrying the signaling between the IP terminal 180 and its reference UCG.

In the case of a call between two IP terminals 170; 180; the call configuration designated by the topology server 90 in response to its interrogation may correspond to the diagram of FIG. 6. In this configuration, the coded speech is exchanged between the terminals directly on the IP network 54-56. The TAP task 181, executed in the gateway UCG on the arriving side, sends to the IP address of the called terminal 180, if it is available. the target indicating the incoming call, with the IP address of the calling terminal 170 and the UDP ports used by it for the communication, it obtained in the establishment message. In addition; it returns to the TAP task 171 of the half-call starting the alert message signaling the start of ringing the called terminal; with the IP address of the called terminal 180 and the UDP ports used by it for communication. This alert message is retransmitted as a pattern to the calling terminal 170, with the IP address of the called terminal 180 and the UDP ports used. When the called terminal 180 takes the line, the event is reported to the TAP task 181 which informs the TAP task 171 in a connection message retransmitted as a pattern to the calling terminal 70. The communication can then take place, directly between the UDP ports for the traffic part, and in the context of TCPIIP sessions between I terminals and their reference UCGs for the signaling part.

In the case where the LANs 54, 55 and WAN 56 are still able to support any bit rate and where the IP terminals are all compatible with each other, the decision between the four call configurations illustrated in FIGS. to be taken by the topology server 90 on the sole basis of the connection types of the calling and called terminals.

A refinement consists in taking into account the coding capabilities of IP terminals. The configuration data returned by the server 90 may thus include instructions to use this or that type of coding in the IP terminals, which the call processing tasks transmit to the terminals and gateway interfaces concerned. The system administrator can thus privilege the low-speed transmissions (for example G.723.1 rather than G.711) over the IP network to limit the congestion of the latter by the telephone traffic. It can also possibly avoid transcoding at the level of the gateways if there are constraints on the computing capacities thereof (favor the use of G.711 by the terminals if the size of the network allows). The configuration chosen by the server for each call may depend on dynamic parameters on the congestion of the IP network or the load of the interfaces.

Taking into account the IP terminal coding capabilities can furthermore intervene in the choice of the coding scenario in FIG. 4, 5 or 6. particularly in the case where the location of the terminals is also taken into account. This location information makes it possible, for an IP terminal, to identify a subnet of the IP network. that is, one of the LANs 54, 55 to which this terminal is connected.

Consider for example the case where there would be no congestion problem to transmit the speech coded at 64 kbitls (G.711) on the LANs 54, 55, but where it would be desired to minimize the bit rate on the WAN 56. for billing reasons by an operator managing the WAN. To establish a communication involving a calling or called IP terminal, not equipped with the G.723.1 codec (which appears in the parameter sets supplied to the server 90), the topology server 90 may control the implementation of the configuration 4 or 5 as long as communication can take place without going through the WAN. But if the other terminal involved is on another site and requires a passage through the WAN 56, a transcoding G.7111G.723.1 should be performed, which requires a different call configuration.

For example, if the IP terminal 41 of FIG. 1 is the calling terminal that supports G.711 only and if the IP terminal 42 is the called terminal that supports G.711 and G.723.1, the topology server 90 responds to the games. parameters that are presented to him by controlling the configuration according to Figure 5 (and not according to Figure 6, although the two terminals are IP type). The gateway interface of the reference UCG 11 of the terminal 41 will play the same role as the connection interface of a conventional terminal: during the communication, it will perform a transcoding, and dialogue in G.711 with the terminal 41 and in <B> G, 723.1 </ B> with the terminal 42 across the IP network. same, if the conventional terminal 34 is the terminal called by the terminal 41. I topology server 90 controls the configuration according to Figure 3. and not according to Figure 4.

Symmetrically, if the IP terminal 43 of FIG. 1 is the called terminal that supports G.711 only and if the IP terminal 40 is the calling terminal that supports G.711 and G.723.1. the topology server 90 responds to sets of parameters presented to it by controlling the configuration according to FIG. 4 (and not according to FIG. 6, although both terminals are IP type). Similarly; if the conventional terminal 32 is the terminal calling terminal I, the topology server 90 controls the configuration according to FIG. 3 and not according to FIG.

To make this type of decision, the server 90 includes tables constructed by integrating knowledge of the topology of the switching system and the IP network: which make it possible to associate the appropriate configuration data with each pair of sets of parameters terminating I terminal called.

Claims (9)

A method of establishing a communication between terminals (32-36, 40-43) connected to a switching system, the switching system comprising a plurality of interconnected cluster control units (11-13; 21-25, 30) each providing access points to the system, wherein each terminal is respectively associated; among the cluster control units, a reference unit which stores data specific to said terminal, for performing signaling processing concerning it. wherein at least some of the cluster control units are gateway units (11, 21, 30) respectively provided with gateway interfaces with an IP network. (54-56). and some of the terminals are P terminals (40-43) connected to the system via the IP network. and wherein the switching system comprises at least one call configuration manager (90) arranged to provide call configuration data in response to two sets of lative parameters to calling terminals and called, respectively, said set of parameters relating to a terminal including an indication of the type of connection of the terminal, which differs depending on whether the terminal is IP type or not, the method comprising the following steps for establishing a communication between first and second terminals comprising calling terminals and called - creating a first call processing task (71, 171) in the calling terminal's reference unit (70, 170); - training, by the first call processing task; an establishment message including at least the called terminal number and the call type indication of the calling terminal - in response to receiving said setup message; creating a second call processing task (81, 181) in the called terminal reference unit (80, 180) - querying the configuration manager by the second call processing task, based on a set of parameters relating to the calling terminal extracted from the establishment message and from a set of parameters relating to the called terminal deduced by the second call processing task from the number received in the establishment message; and when the call configuration data returned by the configuration manager corresponds to an opportunity to exchange, directly across the IP network, traffic between said first terminal and at least one gateway interface from which said second terminal is accessible without passing by the IP network. signaling exchange between the first and second call processing tasks and a gateway interface management task, in order to establish between the said gateway interface and the second terminal a communication path that does not pass through the IP network; providing said gateway interface with address data of the first termina; in the IP network. and providing to the first terminal addressing data of said gateway interface in the IP network. The method of claim 1, comprising the next step when the call configuration data returned by the configuration manager (90) corresponds to an opportunity to exchange, directly across the IP network, traffic between said first and second terminals (170, 180) - signaling exchange between the first and second call processing tasks (171, 181). in order to provide the second terminal with addressing data of the first terminal in the network, and to provide to the first terminal addressing data of the second terminal in the IP network. The method of claim 1 or 2 wherein said set of parameters relating to a terminal of type IP 40-431 includes information on coding capabilities of said terminal. The method of claim 3, wherein the call configuration data returned by the configuration manager (90) for communication involving an IP type terminal (40-43) includes an instruction to use a coding particular. 5. Method according to claim 3 or 4. wherein said set of parameters relating to a terminal includes a localisati information enabling, in the case of a terminal type iP (40-43); identifying a subnet (54, 55) of the IP network to which said terminal is connected. 6. Method according to any one of the preceding claims. wherein each IP type terminal (40-43) has as its reference unit a cluster control unit (11, 21, 30) equipped with a gateway interface with the IP network (54-56). A method according to any one of the preceding claims, wherein each gateway unit (11; 21, 30) has a gate designation table (92) matching each cluster control unit (11-13). 21-25, 30) at least one gateway unit whose gateway interface can, according to the system configuration, bind to the access points of said cluster control unit without going through the IP network. The method of claim 7 wherein, when the call configuration data returned by the configuration manager (90) corresponds to an opportunity to exchange. directly through the network I (54-56), traffic between said first terminal and at least one gateway interface from which said second terminal is accessible without passing through the IP network, said first terminal (170) being the calling terminal of the type IP, and said second terminal (80) being the called terminus which is not IP type, said signaling exchange has the following steps - the second call processing task (81) sends a request message to the first task method (170), including identification of the called terminal reference cluster control unit - the first call processing task consults the gate designation table (92) on the basis of the unit cluster control device identified in the request message, for determining a gateway unit from which the called terminal is accessible without going through the IP network; the first call processing task sends a message, including an IP address and at least one UDP port number of the calling terminal, to a task (95) for managing a gateway interface of the determined gateway unit; gateway interface management task reserves at least one UDP port number for communication and returns to the first call processing task an equipment number and an IP address of the gateway interface and each UDP port number reserved - the first call processing task communicates to the second call processing task the equipment number and the IP address of the gateway interface and each reserved UDP port number; the second call processing task controls the establishment of a communication path that does not pass through the IP network between said gateway interface and the link-point of access of the calling terminal sends to the called terminal (80 B>) </ B> a call signaling including the IP address and each UDP port number of the calling terminal, obtained in the setup message., And return an alert message to the first processing task d. call: and - the first call processing task sends the calling terminal (170) an alert message with the IP address of the gateway interface and each reserved UDP port number. The method of claim 7 or 8, wherein when the call configuration data returned by the configuration manager (90) corresponds to an opportunity to exchange; directly over the IP network (54-56), traffic between said first termi I and at least one gateway interface from which said second terminal is accessible without passing through the IP network, said first terminal (70) being the called terminal of IP type, and said second terminal <B> (</ B> 180) being the calling terminal which is not IP type, said signaling exchange comprises the following steps - the second call processing task (181) consults the gateway naming table (92) based on the called terminal's reference cluster control uni to determine a gateway unit from which the calling terminal is accessible without going through the IP network - the second task of call processing addresses a message, including an IP address and at least one called terminal UDP port number; <tb> for <SEP> to establish <SEP> a <SEP> communication <SEP> between <SEP> of <SEP> terminals <SEP> which <SEP> it <SEP> are <SEP> connected. <tb> work <SEP> a <SEP> process <SEP> according to <SEP> <SEP> any <SEP> <SEP> previous <SEP> claims <tb> <SEP> gateways with <SEP> a <SEP> network <SEP> (54-56). <SEP> the <SEP> system <SEP> being <SEP> arranged <SEP> for <SEP> setting <SEP> in <tb> <SEP> units <SEP> <SEP> gateways (11, <SEP> 21, <SEP> 30) <SEP> respectively <SEP> equipped with <SEP> interfaces <SE> <SEP> access to <SEP> system, <SEP> <SEP> <SEP> <SEP> <SEP> <SEP> <SEP> <SEP> <SEP> <SEP> <SEP> <SEP> <SEP> <SEP> <SEP> <SEP> cluster <SEP> being <SEP> <SEP> Cluster Interconnected <SEP> 1-13, <SEP> 21-25; <SEP> 30) <SEP> providing <SEP> each <SEP> of <SEP> points <tb> 10. <SEP> <SEP> <SEP> Switching <SEP> System Comprising <SEP> Multiple <SEP> <SEP> Units of <SEP> Control <tb> terminal <SEP> calling <SEP> (70). <tb> - <SEP> The <SEP> First <SEP> <SEP> Task <SEP> <SEP> Call Processing <SEP> <SEP> Address A <SEP> <SEP> Alert <SEP Message > to <tb> a <SEP> <SEP> alert <SEP> @ <SEP> message the <SEP> first <SEP> <SEP> task of <SEP> <SEP> call processing <SEP>; <SEP> and <tb> interface <SEP> gateway <SEP> each <SEP> number <SEP> of <SEP> reserved <SEP> UDP <SEP> port, <SEP> and <SEP> returns <tb> the <SEP> terminal <SEP> called <SEP> (1 <SEP> a <SEP> signaling <SEP> calling <SEP> including <SEP> the <SEP> IP <SEP> address of <tb> interface <SEP> gateway <SEP> and <SEP> the <SEP> <SEP> <SEP> access point of the calling <SEP> terminal <SEP>, <SEP> sends <SEP> to <tb> path <SEP> of <SEP> communication <SEP> not <SEP> passing <SEP> not <SEP> with <SEP> the <SEP> network <SEP> IP <SEP> between <SEP> said <tb> - <SEP> The <SEP> Second <SEP> task <SEP> of <SEP> <SEP> processing <SEP> calling <SEP> command the <SEP> establishment of a <tb> interface <SEP> gateway <SEP> and <SEP> each <SEP> number <SEP> of <SEP> port <SEP> UDP <SEP> reserved <SEP>; <tb> <SEP> Call Processing <SEP> A <SEP> <SEP> Equipment Number <SEP> and <SEP> a <SEP> <SEP> IP <SEP> Address of <tb> <SEP> port <SEP> UDP <SEP> for <SEP> I <SEP> communication <SEP> and <SEP> returns <SEP> to <SEP> <SEP> seconds <SEP> task <SEP > from <tb> - <SEP> The <SEP> task <SEP> of <SEP> management <SEP> interface <SEP> gateway <SEP> reserves <SEP> at <SEP> less than <SEP> a <SEP> number <tb> gateway <SEP> determined     at <SEP> a <SEP> task <SEP> (96) <SEP> management <SEP> of a <SEP> interface <SEP> gateway <SEP> of <SEP> the unit