SE517404C2 - Communication providing method between private telecommunication exchanges, involves using mapping function to obtain relation between specific sequence number and user information channel - Google Patents

Abstract

An user information channel is established in a call originating exchange, by establishing a sub-channel by giving a sequence number which is unique within each interconnecting link, to input of a selected multiplexer (65). A mapping function is used to obtain a relation between the sequence number and user information channel. The established channel is used for transmitting information to obtain an interconnecting link. A message comprising information about the relation obtained using the mapping function, is transmitted to another exchange, so as to create similar relation at that exchange.

Description

y .. 10 15 20 25 30 517 404 2 at the same time offer network services without having to rent wires. The carrier connection used is usually a call over the public network.

EP-A2-0667723, which is hereby incorporated by reference, describes a dynamic route assignment (DRA) method in a network interconnecting PBXs.

Between the PBXs there is a connected intermediate network, such as an ISDN, which serves as a transmission channel for conventional signaling information, as well as "in-band signaling", which is transparent to the network and also provides the functions intended for the PBXiama.

ECMA Technical Report TR / 65 “PTNX Functions for the Utilization of Intervening Networks in the Provision of Overlay Scenarios (Transparent Approach) -General Requirements”, June 1994, which is hereby incorporated by reference, describes what is needed to interconnect PBXIs. Furthermore, this document describes procedures, protocols, etc. that are applicable to almost all types of IVN and a reference configuration of a PBX that describes important functions, such as mapping, switching, call control, operation, etc. A conceptual point called a “Q "reference point" in each PBX, where channels and PTN call control signaling, such as Q-SIG are defined independently of the IVN type are described. The point where the PBX is physically connected to the IVN through an interface is called the “C reference reference”.

It is possible to design complex networks using a combination of leased lines, virtual private networks or public networks (using DRA) and sold to give the network specific characteristics, such as security aspects. For example, a private network may be based on leased lines but use virtual lines or DRA as backup in case the leased lines break. Another example is an international private network with PBXs in different time zones. The trace pattern in these examples indicates the possibility of sharing resources such as multiplexing units, by using a pool in a PBX when creating private networks by using channel speeds lower than 64 kbit / s. 10 15 20 25. -. 5a 317 3404 It is important to keep the characteristics of the operation of the user information channels at the Q reference point unchanged, even if new dynamic functions are introduced between the Q reference point and the C reference point. Internal functions of the PBX as well as the signaling (both for base calls and additional services) at the Q reference point are based on this characteristic. To achieve this, a mapping operation is required between the Q reference points and the C reference point, which must be able to identify a channel identity at the Q reference point.

However, prior art does not describe this mapping function.

Thus, there is a need for a method and associated device for PBX-PBX communication that can maintain the characteristics of handling user information channels at the Q reference point unchanged. Furthermore, there is also a need for an opportunity to share resources, for example multiplexing units, by using a pool of such units in a PBX.

Brief Description of the Invention An object of the present invention is to provide a method which allows the signaling at the Q reference point in a subscriber exchange device to be unchanged, which uses a mapping function to provide an interconnecting link between the Q points in at least two such devices. , thereby establishing user information channels.

A further object of the invention is to provide an exchange device for carrying out the method, in which device all functions using the characteristic at the Q reference point, such as the channel identity search order can be used as usual. Furthermore, due to the simplicity, hardware cosmads can be reduced by using a pool of multiplexing and compression devices. 10 15 20 25 30 517 404 4 Another object of the invention is to provide a communication protocol for controlling functions and information flows between interconnected switching devices in order to create a similar relationship in all devices.

The invention is exemplified in a switching device, and associated method, for providing communication between at least two subscriber switching devices interconnected by at least one IVN, wherein a channel for transmitting call control information and a channel for transmitting user information are established to obtain an interconnecting link between Qs. the reference points in the devices.

Each switching device comprises means for mapping functions, comprising mapping means, at least one multiplexing means with a number of inputs cooperating with the mapping means, any switching means connected to the multiplexing means and to the network, means for mapping monitoring cooperating with the mapping means, call control means cooperating with the switching means , any compression / decompression means cooperating with the multiplexing means and any means for carrier conditioning cooperating with the network. Each device comprises sequence number handling means which gives each input of the multiplexing means a unique sequence number, the mapping means creating a relationship between the sequence number and a channel for transmitting user information, the mapping monitoring means transmitting the information through a communication protocol to the second device for creating a similar relationship in the exchange.

As mentioned above, by giving each input of a selected multiplexer a sequence number which is unique in each interconnecting link, a "subchannel" is established, a mapping function being used to obtain a relationship between the sequence number and the user information channel. This is the core of recovery.

According to a more detailed embodiment of the invention, the call originating exchange device preferably starts with the user information channel with the lowest channel ID and is mapped to the lowest sequence number. However, the invention is not limited to mapping to the lowest sequence number, but any free sequence numbers in the IPL can be used. Furthermore, a subsequent call originating from the second exchange device starts with the user information channel with the highest channel ID, the next higher sequence numbers in the first exchange being used.

According to a more detailed embodiment of the invention, a new multiplexing unit is selected from a pool of units to obtain a new relationship between the user information channel and the sequence number.

According to another embodiment of the invention, this means a method for controlling the functions and information fates between interconnected devices, comprising the steps of: - requesting to establish / disconnect multiplexing unit (s) and assigning a sequence number to each one; - possibly confirming the establishment / disconnection of multiplexer unit resource; - request to establish / disconnect between user channel ID and sequence number; - if necessary, confirm the establishment or disconnection of the relationship between the dark channel identification and the sequence number.

It is thus obvious that the advantages of the invention result in a device, method and protocol which retains the characteristics of the operation of the user channels at the Q reference point unchanged and makes it possible to share resources such as multiplexing units by using a pool in a PBX.

The above-mentioned and other objects and functions according to the invention will now be described in more detail in the following detailed description of preferred embodiments with reference to the accompanying drawings, in which the same reference numerals indicate identical structures in all clocks. Fig. 1 is a simplified block diagram showing two switching devices interconnected by an intermediate network, comprising two network switches.

Fig. 2 schematically shows a PBX reference configuration as described in ISO 11579.

Fig. 3 shows an enlarged view of important units in the form of a block diagram of a preferred embodiment of one of the devices shown in Fig. 1 configured in accordance with the invention.

Figs. 4a-d are a block diagram of preferred embodiments of the devices according to the invention with a pool of multiplexing units and compression decomposition units.

Detailed Description of Preferred Embodiments of the Invention Referring to fig. 1 shows two subscriber exchange devices such as PBX or the like, 10A and 10B connected to each other by an IVN 20, comprising two network exchanges for providing the IPCiama. The devices 10A and 10B, may be connected to a terminal unit 80, such as telephones, LAN (Local Area Network) etc.

IVN 20 is preferably a public network or private network. F ig. 1 is primarily intended to show an entire system and is not described in more detail.

Fig. 2 shows a PBX reference configuration as described in ISO / IEC 11579. It shows a PBX 10, which can be connected to an IVN 20. The said PBX 10 comprises the following functional units which can, but need not, be the same as a physical unit: un ~ un 10 15 20 25 30 517 404 7 The MP 60 provides the functions necessary to adapt to the physical, electrical and procedural conditions of the boundary layer between the PBX 10 and the IVN 20. The MP 60 also provides the multiplexing functions required to separate or spread the information fates to or from the switching unit 30 from or to the user plane of the IVN 20 and between the Inter-PBX connection control group 50 and the control plane of the IVN 20.

Switching unit (SW) 30 SW 30 provides the switching functions for users and signaling information. Signaling information is switched between the call control unit 50 and MP 60.

Call Control Unit (CC) 50 CC 50 provides the functions necessary to control the call and the connection through a PTN. Inter-PTNS Connection Control Function Unit (ICC) 40 This unit provides the functions necessary to control the IPC through IVN 20.

Scenario Management Unit 70 Scenario Management Unit 70 coordinates the monitoring and use of the IPC by using the services of the ICC to establish and disconnect the IPC.

Reference points C reference point At each end, the IPCs terminate at an interface of the PBX 10, the so-called C reference point. An interface can also terminate your IPCs. Different IPCs terminated at the same interface can lead to the same pair of PBX 10 or to another PBX. 10 15 20 25 30 517 404 The number of available IPCs at the interface depends on the IVN services that the IPC uses and the type of interface. It is also possible to use different types of interfaces on both sides of IVN 20, for example ISDN on one interface and PSTN on the other side. It is also possible to use more than one interface at the C reference point.

In the case where IVN is a public ISDN, another reference point called T. g Q reference point is used. The Q reference point is defined as the interface between SW 30 and MP 60. The inter-PBX call control functions and the signals of signaling errors shall be specified therein. point.

One or more Iriter PBX larch (IPL) can be established between the Q reference points of two PBXIs. The Q reference point (a conceptual point) in PBX 10 defines channels and PTN call control signaling (eg Q-SIG) regardless of the type of IVN 20. An IPL consists of one or fl era channels and is defined by the IPL identity.

To facilitate the distinction between the C reference point and the Q reference point, the following concept is described in more detail: Inter PBX link (IPL) The IPL is established between the Q reference points of two pairs of PBXs. More than one IPL can be established between the same pair of PBXs, each IPL being created at a separate point at the Q reference point. An IPL consists of a call control channel DQ (also referred to as Dq channel) and its associated user information channels UQ (also referred to as UQ channel) at the Q reference point. The DQ channel transmits PTN call control information (eg Q-SIG). The UQ channels are added or removed from the IPL as desired. The DQ channel transmits call control information. The other channels 10 15 20 25 30 517 404 9 for user information, the so-called UQ channels can be added or removed as desired.

To fully describe a channel of an IPL, the following information is needed: - the IPL identity (ie the beginning of the Q reference point) - the channel identity (number) - channel usage - channel characteristics The channel identity is preferably expressed as a channel number that is unique within the IPL.

Reality between IPL and IPC The IPL occurs at the Q reference point in terms of channels, each channel being carried by an IPC. An IPC can carry more than one channel of an IPL, for example by using compression and multiplexing or the like.

Fig. 3 shows an enlarged view of a preferred embodiment of one of the devices 10A according to the invention, shown in Fig. 1, comprising the following main blocks, which will be briefly described below. When device 10A will be described, all reference numerals A are indexed. Fig. 3 does not show a complete switching device but only an enlarged view of the blocks corresponding to blocks 60 and 70 according to the PBX reference configuration shown in fi g. 2.

A. Mapping unit (MAP 61) B. Compression / decompression unit (COM 90) 90 C. Multiplexing unit (MUX) 65 D. Switching unit (SW) 68 (selectable) E. Mapping monitoring control unit (MMC) 72 o coon 10 15 20 25 30 n . oa nu on 517 404 10 F. Dynamic Router 71 (optional) Description of the functional units Mapping unit (MAP) 61 MAP 61 performs the mapping by relating the sequence number of user information channels at the Q reference point to the inputs of the selected MUX 65 as well such as checking the outputs of a MUX 65 to the IPC at the C reference point. MAP 61 is controlled by MMC 72 which will be described in more detail below.

B. Compression Jdecompression Unit (COM) 90 This unit is selectable and can be arranged on both sides of the Q reference point (as shown by a dashed line). Speech compression is an additional function that makes it possible to have your voice calls that are transmitted in a compressed format over a single and merged channel, which is realized, for example, by compressing / decompressing speech to a 64 kbit / s channel. Speech compression is preferably accomplished through the compression unit such as a VCU (speech compression unit) which includes the necessary program units.

Speech compression can, for example, be available at a compression rate of 4> l through an LD-CELP algorithm that makes it possible to transmit up to 4 speech channels in a 64 kbit / s channel. This is called the 4B configuration. The compression device can also be included in a pool of devices that serve your IPLs to save hardware resources.

C. Multiplexer Unit (MUX) 65 MUX 65 comprises at least one multiplexer 65. The MUX 65 is connected via the switching unit (SW) 68 to the IVN 20 at the C reference point or directly connected to the IVN. 404 11 MUX 65 provides the multiplexing frictions required to collect the information to the SW 68 and further to the IVN 20.

D. Switching unit (SW) 68 SW 68 provides the switching functions for user and signaling information. This unit is selectable and can be used if the IPC at the C reference point uses a switched connection in IVN.

E. Mapping Override Control Unit (MMC) 72 MMC provides sequence number monitoring (eg assignment, monitoring, selection), selection of MUX 65 from a pool 67 of MUX units 65. MMC 72 communicates with other MMC 72 through a protocol.

MMC 72 handles: - establishment / disconnection of MUX units 65; - Ethanization / disconnection of the relationship between user ID and sequence number.

The two MMCema 72 involved in a conversation are defined by a mutual relationship as master and slave. MMC 72 can function as a master / slave depending on the settings. This dependence checks the lPL on different traffic conditions depending on whether the inter-MMC message contains different information.

This is due to the fact that the master side MMC 72 always handles the process of selecting which MUX unit 65 and which input to use for an outgoing call, regardless of which side started the call.

G. Dynamic Router Control Unit (DRC) 71 This unit is selectable and used if DRA is used. If DRA is used, DRC 71 interacts with MMC 72.

DRC 71 contains control logic that handles connection, disconnection and traffic control of the dynamic routers in DlUl. DRC 71 is described in more detail below. 10 15 20 25 30 517 12 DRC handles: o Establishment / disconnection of a DQ channel 0 Control logic for the interface between the private and the public call.

DRA is a function that makes it possible to realize lines by using public connections over an overlying network. The idea is to connect different places in an organization to each other without having to lease lines.

In the following description, it will now be explained in a simplified manner without describing all the blocks, how a device 10 according to a preferred embodiment of the invention shown in Fig. 3 works.

The device 10A includes a monitoring unit 70 for establishing a DQ channel that is not part of the proposed solution. It is assumed that the DQ channel, eg 64 kbit / s or 16 kbit / s, is established before the sequence below. The DQ channel can be either static or dynamic, eg combined with the user information channels UQ.

Disconnection of the DQ channel can also be delayed by a command to prevent it from being set up and disconnected too often.

When a call is to be established at QA in the device 10A, a channel identification (ID) 1..n is used for a user information channel UQ. If there is no carrier connection, it must be established. The carrier connection over the intermediate network IVN 20 is normally a 64 kb / s (digitally leased line D64U without restrictions) transparent connection that can transmit compressed speech. Depending on the carrier characteristics required for the call at QA, the correct carrier connection is connected and additional equipment is reserved, such as a compression unit 90 and a MUX 65. The UQ channels are compressed by the speech compression unit 90, for example to 16 kbit / s if they are not data connections. 494 10 15 20 25 30 B Then, each selected input l ... n of the MUX unit 65 is given, by MMC 72, a sequence number s1 ... ,,, which gives each input 1 ... n of the MUX the unit 65 a unique sequence number s1, __ n_ thereby obtaining a "subchannel".

It is also possible to combine the compaction unit 90 and the MUX unit 65 in a single unit or a pool 67 of units. This is shown in Figs. 4a-d in the form of block diagrams of preferred embodiments of the devices according to the invention with a pool 67 of MUX units 65.

Thereafter, the mapping unit 61, which cooperates with the MUX unit 65, creates a relationship between the inputs 1 ... n of the MUX unit 65 with sequence number s1___ ,, and the user information channel UQ at Q. A relationship between the Q reference point and the C reference point will now be is established via the SW 68. At this point a temporary relationship is created between the selected channel ID and the sequence number.

MMC 72 transmits the information to the second device 10B to create a similar relationship in this device IOB. The sequence number sn is unique within the IPL.

This is signaled MMC-MMC in two steps by means of a communication protocol, which will be described in more detail below. The call at Q can then continue as usual.

An advantage is that the search order for channel ID at Q can be used as usual. A normal procedure is for device 10A to start with the lowest and device 10B with the highest. Thus, if 10 virtual channels are defined between device 10A and device 10B, the first call from A to B will use channel ID 1 and be mapped to sequence number 2. The mapping between channel ID and sequence number is only valid as long as the call at Q exists. The next call will establish a new mapping.

A further advantage is that the number of the carrier connection is determined by the traffic at Q and is independent of the algorithm used for selecting the channel ID. »Acc 10 20 25 30. . c Q now u 517 404 14 Depending on the topology of a particular PTN, a PBX may in practice have links to andra your other PBXs and may also have more than one link with the same PBX, ie more than one inter-PBX link may be present on a particular PBX. A PBX will then have a start for the Q reference point (Q1 ... Qn) for each IPL. This is not shown in Fig. 2.

If a device 10 has multiple groups of IPCIn, each leading to different devices 10, multiple Q reference points will appear. However, there is no relationship between the number of Q reference points and C reference points; ie multiple Q reference points can be mapped to a single physical interface at the C reference point. In the following description, it will now be further explained how different devices according to different preferred embodiments of the invention in the form of PBXs work. l.

Referring to Fig. 4, a route in PBX 10A has been initiated with a DQ channel and 12 UQ channels. All UQ channels will use dynamically established carrier connections. The channel identities are from 1 to 12. The PBX 10A will start selecting channels from channel 1 and up. A pool 67 of MUX units 65 is available. In this example, 16 kbps are used. An IVN between PBX 10A and PBX 10B (not shown) is available. It can be a public network or a private network. PBX 10A is defined as the master page for this IPL (in this case also route).

In PBX 10B, a route has been initiated with the same characteristics except that the channels are selected from channel 12 and down. PBX 10B are de fi nied as the slave side.

The first call from PBX 10A to PBX 10B will select channel 1. A 64 kb / s carrier connection is established between the PBXs at the C interface. A suitable MUX unit 65 is selected from the pool 67 in the PBX 10B. In this example based on 16 kb / s, ie 4 subchannels in the 64 kb / s connection. The 4 inputs of the MUX unit 65 are given the sequence numbers sm, s ”etc. in o unde 10 15 20 25 30 n. n a .n 517 404 ._ ;; - 15 l PBX 10A a relationship is created between channel 1 and sequence number sl and a message is sent to PBX IOB to establish a similar relationship. A confirmation is sent to PBX 10A. In PBX 10A, the call can then continue at QA as if it were a normal connection.

The message sequence above can also be combined in a request / confirmation message. These messages will be described in more detail below.

If the second call is established from the PBX IOB, channel 12 will be selected. A message requesting to create a relation to a sequence number is sent to the PBX 10A. In PBX 10A, a relationship is created between channel 12 and sequence number s2 (if the first call is still active). A message is sent to the PBX IOB with this information. A similar relationship is created in PBX IOB and the call at Q can continue.

When all four inputs are occupied in the unit 65 and a new call arrives at Q, a new unit 65 is selected from the pool 67 and a new carrier connection is established. The sequence numbers of this unit 65 will be s5 to sg.

When a call is disconnected at Q, the PBX 10A (master page) requests the slave page to release the relationship between the channel identity and the sequence number.

In order to have as few carrier connections established as possible, a search order is defined.

When new calls arrive at Q, a sequence number (input) in the unit 65 with the most frequently used sequence number or the unit 65 having a DQ channel established is selected.

If all inputs in a unit 65 are free (the unit is not used for any call), the unit will be disconnected. The master side decides that a device is to be realized and sends a message to the slave side with a request to disconnect the device 65.

A confirmation is sent to the master page. 10 15 20 25 30 517 404 16 L Same scenario as in 1, but DQ uses a 16 kb / s time slot in the first carrier connection. In this case, the first 3 inputs are available when DQ has been established.

These inputs will be given the sequence numbers 1 to 3.

This unit will always be the first in the search order. in the same scenario as above but with 8 kb / s subchannels instead. The principle is the same but the sequence numbers such as 1-8 or 2, 3, 5, 7, 9, 12, 17, 21 or any other free numbers will be used for the first unit 65. in Pool 67 may consist of a mixture of units 65 with different characteristics.

With reference to F ig. 3, it will now be explained how communication protocols between the MMC units 72 in the PBX 10 work according to a preferred embodiment of the invention. The protocol (a procedure for inter-MMC services) is created using the following: - address of sending and receiving entity; - transaction identifier; - type of service; - service event; - more information.

Each monitoring part must have a unique address. It is then possible to use any intermediate network (eg data network) between the PBXs to carry the protocol. An advantage of this is that the mapping functionality is used in combination with DRA, whereby the communication between the monitoring units does not depend on an established signaling channel DQ.

The Event Identifier is arranged to allow multiple Sessions.

Service types define the requested service, examples are: - request to establish MUX and assign sequence number - confirmation to establish MUX; - request to disconnect MUX; - confirmation to disconnect MUX; - request to create a relationship between channel ID and sequence number; - confirmation to create relationship; - refusing to create a relationship; - request to release relationship between user channel ID and sequence number; - confirmation of release of reaction; - data mismatch detected; - confirmation of data match detected.

The service effect is used to further specify the request for a certain type of service.

Furthermore, the protocol as described above preferably supports the following additional functions. Additional information includes for example: Additional information contains for example: - sequence number - type of MUX, eg 2B 32 kb / s, 4B 16 kb / s, 8B 8kb / s, 1B + D, 3B + D, 7B + D - compression type, eg ADPCM (2> 1), LD-CELP (4> 1) and CS-ACELP (8> l) (CS-ACELP, “Conjugate Structure Algebraic Code Exited Linear Prediction”) 517 404 18 It is therefore obvious that the benefits of The invention results in the signaling at the Q reference point in a subscriber exchange device being unchanged, which makes the method and the device according to the invention a very desirable improvement for subscriber exchanges.

It will be apparent to those skilled in the art that the invention may be practiced otherwise than as prescribed in the previously described embodiments, which are intended to illustrate the invention only, and are thus not limited to anything other than the claims which follow. . 10 15 20 25. . ; ø now 517 404 19 Some abbreviations used in the description ID Channel identity IPC Inter-PBX connection A connection given by an IVN between two C reference points used to transmit inter-PBX information from the PTN control plane and / or PTN the user plane.

IPL Inter-PBX Lecture at the Q Reference Point A link between the Q reference points of two PBXs that includes the entire signaling transmission and user information transmission means.

Q-SIG ISDN signaling via Q reference point Q-ref A conceptual point defined by ISO / IEC 11579 DRA Dynamic route assignment DRC Dynamic route controller DQ A signaling channel used to transmit call control information between the Q reference points of two pairs of PBXs.

UQ channel. A channel used to transmit user information between the Q reference point of two pairs of PBXs.

ISO Intemational Standards Organization C-ref A point defined by ISO / IEC 11579 PBX Subscriber Switch TE Terminal Equipment n ... n

Claims (17)

10 15 20 25 30 517 404 20 Patent claims A method for providing communication between at least two subscriber exchange devices (10A, 10B) interconnected by at least one intermediate network (20), the method comprising: - establishing a channel (DQ) for transmitting call control information, if not already established, and at least one channel (UQ) for transmitting user information to obtain an interconnecting link (IPL), characterized in that the establishment of user information channels (UQ) in a number originating exchange (10) comprises: - selecting a multiplexing means (65 ); - establishing a subchannel by giving each input (1.. .n) of at least one selected multiplexing means (65) a sequence number (s1-s ,,) which is unique within each interconnecting link (IPL); use a mapping function to obtain a relationship between the sequence number (s) and the user information channel (UQ), - transmit a message to the second exchange (IOB) including information about the relationship to create a similar relationship at the second exchange (IOB). A method according to claim 1, wherein said call origination exchange (10A) starts with the user information channel (UQ) with the lowest channel ID and a free sequence number, eg the lowest (S1). A method according to claim 2, wherein a next call originating from the second exchange (IOB) starts with the user information channel (UQ) with the highest channel ID, wherein another vacant sequence number, for example the next higher number (sn) in said first exchange ( l0A) is used. Method according to one of the preceding claims, characterized in that when all the inputs to the multiplexing means (65) are occupied, a new multiplexing means is selected. 517 404 21 ring means (65) from a pool (67) of units (65) to obtain a new relationship between the user information channel (UQ) and the sequence number, wherein another free sequence number, e.g. used. . Method according to claim 4, characterized in that the multiplexing means (65) having an established call control information channel (DQ) is selected first. . Method according to Claim 4 or 5, characterized in that the multiplexing means (65) are time-controlled. . Method according to any one of the preceding claims, characterized in that said first gear (IOA) is defined as master and said second gear (IOB) is defined as slave, the slave being controlled by the master who is always in charge of the method of selecting subchannel regardless of which side who originated the conversation. . Device (IOA) intended for use in a private telecommunication network (PTN) as a subscriber exchange device for interconnection with an intermediate network (IVN) to at least one other similar device (IOB), which device (10A) comprises: mapping means (61) ); at least one multiplexing means (65) having a plurality of inputs cooperating with the mapping means (61); switching means (68) connected to the multiplexing means (65) and to the intermediate network (20); mapping monitoring means (70) cooperating with the mapping means (61); any compression / decompression means (90) cooperating with the multiplexing means (65) and means for carrier conditioning cooperating with the network (20), characterized in that said device (10) comprises sequence number handling means arranged to provide each input (1.. .n) of the multiplexing means (65) a unique sequence number (sl-sn) and that the mapping means (61) are arranged to create a relationship between the sequence number (sn) and a channel (UQ) for transmitting user information wherein the means for mapping control (70) are arranged to transmit the information to the second device (10B). Device according to claim 8, characterized in that the device (10) comprises a pool (67) of multiplexing means (65). Device according to claim 8 or 9, characterized in that the pool (67) comprises multiplexing means (65) of different types, such as 8 kits / s, 16 kbit / s, etc. Device according to claim 9, characterized in that the multiplexing means (65) is a 16 kbit / s unit with four subchannels in a 64 kbit / s network connection. Device according to any one of claims 8-11, characterized by the means for mapping monitoring (70) comprising a dynamic route controller (71) and means for mapping monitoring control (72). A private telecommunication system comprising: - at least two devices according to any one of claims 8-12, interconnected by an intermediate network (20), such as a public network, a private network or leased lines. A method for controlling the fates of functional and information mellan between the means for monitoring (70) in interconnected devices (10) according to any one of claims 8-12, comprising the steps of: - requesting to establish / disconnect the multiplexing unit ( 65) and assign a sequence number sl-sn to each; - if necessary, confirm the establishment / disconnection of the multiplexing unit (65): - request to establish / disconnect the relationship between user channel ID and sequence number (s1-sn); - possibly confirm the establishment / disconnection of the relationship between user channel ID and sequence number sl-sn. The method of claim 14, wherein the two requesting steps are combined in one step. A method according to claim 14 or 15, wherein computer niche match is detected. A method according to claim 14 or 15, wherein additional messages such as departed messages are used.