DE19746721A1 - Integrated services digital network telecommunications installation - Google Patents

Abstract

The telecommunications installation (3) has an interface on the exchange side for connection to a network terminator basic access device (1), or for direct connection to a digital exchange (2) and an interface on the subscriber side for connection to a number of subscriber devices (4,5), with a coupling field and a transcoder for bit rate conversion inserted between the opposing interfaces, each provided with a memory for temporary storage of data. OF DLRAWING - The drawing shows an integrated services digital network telecommunications installation. Network terminator basic access, 1. Digital exchange, 2. Telecommunications exchange, 3. Subscriber devices, 4, 5.

Description

The invention relates to an ISDN telecommunications system and a subscriber terminal for connection to a such ISDN telecommunications system according to the main patent . . . (German patent application 197 39 516.3).

This ISDN telecommunication system enables the operation of several ISDN terminals on one ISDN base connection. For this purpose, the ISDN telecommunications system is connected via a 4-wire line to the S ₀ interface of a network termination device (NTBA - network terminator basic access), which is installed in the user's premises and provides the ISDN basic connection. On the official side, this network termination device has a U _K0 interface and is connected to the responsible local exchange (DIVO - digital exchange local network) via a conventional 2-wire line. On the subscriber side, the ISDN telecommunications system also has an S ₀ interface to which several ISDN terminals can be connected via 4-wire lines.

On the one hand, such an ISDN telecommunications offers a variety of comfort and mediation functions, such as internal connections between the to the ISDN telecommunication system closed end devices, without a fee-based Ver to have to build a connection to the local exchange.  

On the other hand, the ISDN telecommunications system enables the simultaneous operation of more than two ISDN terminals despite the restriction by only two B channels on the internal S ₀ bus. For this purpose, bit rate-reduced coding is used on the internal S ₀ bus by nesting several data words of the end devices into the individual data words of the B channels. Each data word in the ISDN transmission standard with a transmission rate of 64 kBit / s contains eight bits, while for example the transmission standard DECT with cordless telephones with a transmission rate of 32 kBit / s contains only 4 bits in each data word (English nibble). provides for the data words of two DECT terminals to be nested in a data word of a B channel. In the ISDN tele communication system, the data streams originating from the terminal devices operating at reduced bit rates and summarized in bytes are then broken down into the original bit groups and then converted by a transcoder into the ISDN transmission standard with a transmission rate of 64 kbit / s.

The disadvantage here is that so-called DC balancing errors can occur on the internal S ₀ bus, ie the transmission is not free of DC voltage. Normally, the DC voltage freedom of data transmission on the internal S ₀ bus is achieved by using a pseudo ternary code that encodes a logical one with a zero level and a logical zero when it first occurs with a pulse of negative polarity and then with pulses of alternating polarity. In the case of a data word with an even number of logical zeros, the data word is therefore free of DC voltage. With an odd number of zeros, however, there is an overhang pulse with negative polarity, which is compensated by a subsequent DC voltage compensation bit (DC balancing bit) with positive polarity, so that the data transmission is DC-free in this case too .

In the ISDN telecommunications system described at the beginning with bit rate-reduced DECT terminals, the two nibbles of a data word on the B channel can come from different terminals, with the first logical zero being encoded with a pulse of negative polarity in each nibble. If both nibbles now contain an odd number of logical zeros, the entire data word contains two overhang pulses with negative polarity, only one of which can be compensated for by the subsequent DC voltage compensation bit, so that the data transmission in this case is not DC-free is. The DC voltage component on the internal S ₀ bus therefore stems from the fact that the terminal devices operating at reduced bit rates independently encode the first logical zero of the nibble assigned to them on the B channel with a pulse of negative polarity, which in the case of odd numbers of logical zeros in both Nibbles leads to two overhang pulses.

The invention is therefore based on the object of creating an ISDN telecommunications system of the type described at the outset as well as bit rate-reduced terminals for which the data transmission on the internal S ₀ bus is DC-free in any case.

The task is based on an ISDN telecommunications tion system according to the preamble of claim 1, by the characterizing features of claim 1 and resp Lich the correspondingly adapted subscriber terminal solved by the features of claim 6.

The invention includes the technical teaching of coupling several successive data words of the same terminal into the individual data words of the B channels on the internal S ₀ bus instead of the data words of different bit rate-reduced working terminals.

If, for example, four DECT terminals are operated simultaneously on the internal S ₀ bus, the first two nibbles of the first terminal are coupled into the first byte of the B1 channel within an S ₀ frame of 48 bits. Two consecutive nibbles of the third terminal are then coupled into the first B2 channel byte of the S ₀ frame. The second byte of the B1 channel then contains two successive nibbles of the second terminal and the second byte of the B2 channel within the S ₀ frame finally contains two nibbles of the fourth terminal. Of course, the individual terminals can occupy the bytes within an S ₀ frame in a different order.

The only important thing is that a byte only contains the data device.

When coupling two successive bit groups of the bit rate-reduced terminals into a B channel of the internal S ₀ bus, it is important that the coding of the two bit groups must not follow each other independently in order to have a DC voltage component on the internal S ₀ -Bus to prevent. Rather, the first logical zero of the second nibble must be encoded opposite to the last logical zero of the first nibble. This ensures that the logical zeros within a data word on the B channel are always coded with alternating polarity, so that within a data word of the B channel a maximum overhang pulse with negative polarity can occur, which can be caused by the subsequent DC voltage Compensation bit is compensated.

On the one hand, this joint coupling of several, time-sequential bit groups of the same terminal into a data word of a B channel advantageously ensures a DC-free data transmission on the internal S ₀ bus. On the other hand, this leads to a temporal distortion, since the bit groups of the terminal devices, which normally occur at regular time intervals, are transmitted in a different rhythm. A buffer memory is therefore provided both in the ISDN telecommunications system according to the invention and in the subscriber terminal device according to the invention, which stores a bit group when sending data via the internal S ₀ bus until the next bit group arrives. These two successive bit groups are then coupled together through a coupling field in the terminal or in the telecommunications system into a B channel of the internal S ₀ bus. Accordingly, when receiving data via the internal S ₀ bus, the buffer memory is used for the temporary storage of a complete data word of a B channel, the individual bit groups being read out from the buffer memory by the end devices in the correct chronological rhythm.

In a variant of the invention, two ISDN data frames, each with a length of 48 bits or 250 microseconds, are combined to form a superframe with a length of 96 bits or 500 microseconds. On the subscriber side, end devices with a reduced transmission rate of 16 kbit / s are used, the data of the end devices present in bit pairs being coupled into the B channels of the internal S ₀ bus. Each of the eight bytes of the superframe contains four bit pairs of a terminal here, so that a total of eight bit rate-reduced terminals can be operated simultaneously on the internal S ₀ bus.

The invention was explained above in connection with an ISDN base connection which provides an S ₀ bus with two B channels with a transmission rate of 64 kbit / s each and a D channel for control purposes with a transmission rate of 16 kbit / s . However, the invention can be implemented in the same way with an ISDN primary multiplex connection or with corresponding digital interfaces.

Also, the invention is not based on the coupling of ever because there are two nibbles in a data word of a B channel limits. Rather, it is also possible to have more than two successive bit groups of a terminal in a data word of a B channel. So with a da transmission rate of 8 kbit / s, for example four consecutive pairs of bits in a byte of a B- Channel can be coupled.

The switching matrix described above can for example integrated in software on the hardware platform ISDN processor VNS 80000 from the US manufacturer VLSI reali be used, which is particularly suitable for this. It is ever but it is also possible to use the switching matrix specifically for this to develop developing hardware components.

Other advantageous developments of the invention are in the subclaims or are identified below along with the description of the preferred embodiment the invention with reference to the figures. It shows gene:

Fig. 1 as a preferred embodiment of the OF INVENTION dung an ISDN telecommunication system with a plurality of subscriber terminals in a block diagram,

Fig. 2, the DECT radio base station of FIG. 1 detail lines in a block diagram,

Fig. 3, the ISDN telecommunication system of FIG. 1 in detail as a block diagram,

Fig. 4 shows the frame structure of the data transmission of the ISDN telecommunications system shown in Fig. 1 and

Fig. 5a, 5b, the frame structure on the internal _S0 bus for various embodiments of the invention.

The system configuration shown in Fig. 1 enables the connection of a large number of terminals to an ISDN basic connection, which is provided on a network termination device (NTBA - net work terminator basic access) 1 , the network termination device 1 being installed in the rooms of the user and has a U _K0 interface on the office side, which is connected via a conventional 2-wire line to a local exchange (DIVO - digital local exchange) 2 . The local exchange 2 enables the connection to be established to other subscribers and is integrated into the public ISDN network for this purpose. On the subscriber side, the network termination device 1 has an S ₀ interface, which is connected via a 4-wire line to an ISDN telecommunications system 3 according to the invention, which is shown in detail in FIG. 3 and will be described in detail below.

In addition to the S ₀ interface (s) at the office, the ISDN telecommunication system 3 has at least one further S ₀ interface which provides an internal S ₀ bus and on the subscriber side the connection of the individual subscriber terminals 4 , 5 , 6 enables. For this purpose, several ISDN connection units (ISDN-AE) 7 , 8 , 9 are distributed in the rooms of the user, each of which enables the connection to a subscriber terminal 4 , 5 or 6 and are connected to the internal S ₀ bus, whereby the internal S ₀ bus is looped through the individual ISDN connecting units 7 , 8 , 9 and is connected at its end to a terminating resistor 10 which prevents line reflections on the internal S ₀ bus.

The subscriber terminals 4 , 5 are ISDN telephones which use both the ISDN transmission standard with a data transmission rate of 64 kbit / s in accordance with ITU (formerly CCITT) Rec. G.711 and the DECT transmission standard in accordance with ITU Rec. Support G.711 with a transmission rate of 32 kbit / s. In the following description, to explain the function of the ISDN telecommunication system 3 according to the invention, it is assumed that the ISDN telephones 4 , 5 work in DECT mode.

Furthermore, a DECT radio base station 6 with four cordless telephones 11.1 to 11.4 is connected as the subscriber terminal device, which is shown in detail in FIG. 2 and enables simultaneous operation of two of the cordless telephones 11.1 to 11.4 . For this purpose, the DECT radio base station 6 has a conventional DECT transceiver station 12 which is connected to an antenna 13 and communicates with the cordless telephones 11.1 to 11.4 in accordance with the transmission standard ETS 300175 defined by the ETSI, which enables a Data transmission rate of 32 kbit / s according to ITU (formerly CCITT) Rec. G.726.

In the following, the case is first described that the active cordless telephones 11.1 , 11.2 transmit data to the ISDN telecommunication system 3 via the internal S ₀ bus. In this case, the DECT transmitting / receiving station 12 delivers at regular time intervals bit groups with four bits (English nibbles), which are first buffered in a buffer memory 14.1 or 14.2 , in order to subsequently enable a common transmission of two successive nibbles . The buffer memory 14.1 serves to receive the nibbles originating from the cordless telephone 11.1 , while the buffer memory 14.2 buffers the nibbles of the telephone 11.2 . When the next nibble arrives at the buffer memories 14.1 or 14.2 , this is fed together with the last nibble cached in the buffer memory 14.1 , 14.2 to a header field 15.1 or 15.2 which couples the two nibbles together into a data word of a B channel. Each data word on a B channel of the internal S ₀ bus thus contains only the nibbles of a terminal 11.1 or 11.2 . This is important for the subsequent coding in accordance with the ISDN transmission standard G.711 with a data transmission rate of 64 kbit / s, which is carried out by a downstream S ₀ interface 16 . To code the data, a pseudo-ternary code is used in accordance with the ISDN transmission standard, which encodes a logical one with a zero level and a logical zero when it first occurs with a pulse of negative polarity and then with pulses of alternating polarity. In the case of a data word with an even number of logical zeros, the data word is therefore free of DC voltage. With an odd number of zeros, on the other hand, there is an overhang pulse with negative polarity, which is compensated by a subsequent DC balancing bit with positive polarity, so that the data transmission on the internal S ₀ bus also is DC-free in this case.

The inventive coupling of two successive nibbles of the same terminal 11.1 or 11.2 in a Da word of a B channel offers the advantage that the above-described coding of logical zeros with changing polarities can be maintained within the entire data word, so that a maximum overhang pulse with negative polarity can occur, which is compensated by the subsequent DC voltage compensation bit. In the known arrangement described at the outset, on the other hand, this coding rule can be violated, since the two nibbles of a data word on a B channel originate from different terminals which independently code the first logical zero within their nibbles with negative polarity.

In the following, the case is described that the active cordless telephones 11.1 , 11.2 receive data from the ISDN telecommunication system 3 via the internal S ₀ bus. It is assumed here that the data for the telephone 11.1 be contained within an S ₀ frame in each case in the first byte of the B1 channel, while the data intended for the telephone 11.2 are each transmitted with the first byte of the B2 channel , as is also shown in Fig. 4 Darge. The S ₀ interface 16 then passes these two bytes on receipt of an S ₀ frame to the switching matrixes 15.1 , 15.2 , which break the bytes into two nibbles, which are stored in parallel in the buffer memories 14.1 , 14.2 . Subsequently, the two nibbles are pushed out one after the other from the buffer memories 14.1 , 14.2 and passed on to the DECT transceiver station 12 , the stored nibbles being released periodically in order to achieve a time equalization of the jointly transmitted nibbles. The DECT radio base station 6 therefore has a control device, which is not shown here for simplification and controls the buffer memory 14.1 , 14.2 accordingly.

In the following the operation of the ISDN telecommunications system 3 according to the invention is described, which is shown in detail in FIG. 3. On the subscriber side, the ISDN telecommunications system 3 has an S ₀ interface 17 which provides the internal S ₀ bus and enables the subscriber terminals 4 , 5 , 6 to be connected. The S ₀ interface 17 has the task of controlling the data transmission on the internal S ₀ bus in accordance with the ISDN transmission standard G.711, the S ₀ interface 17 transmitting the control data transmitted in the D channel to a control unit 18 , which controls the switching technical data transmission. The control unit 18 evaluates the control data arriving on the D channel on the subscriber side and determines therefrom whether the data coming in on the B channel originate from an ISDN terminal or contain two of the "subchannels" described above, which of the End devices 11.1 to 11.4 or the telephones 4 , 5 originate that work with the bit rate-reduced coding G.726. Furthermore, the ISDN telecommunications system has two further S ₀ interfaces 19.1 , 19.2 , which enable connection to a network termination device 1 .

Both the control unit 18 and the DECT radio base station 6 shown in FIG. 2 have coordinated proprietary extensions of the standardized DSS1 protocol in order to be able to handle the handling of end devices with "subchanneling".

The incoming B-channel data are then fed to a switching matrix 20 , which is controlled by the control unit 18 and is connected to an office-side white switching matrix 21 . The switching network 20 forwards the incoming B-channel data to the exchange switching office 21 if the B-channel data originate from an ISDN terminal, since in this case no further conversion is required. Correspondingly, the exchange on the exchange side 21 forwards the incoming B-channel data directly to the exchange 20 on the subscriber side if a conventional ISDN terminal is addressed on the internal S ₀ bus, since no conversion is required in this case either.

In the following, on the other hand, the case is described that the evaluation of the D-channel data arriving on the subscriber side at the S ₀ interface 17 by the control unit 18 indicates that the B-channel data from a DECT terminal 11.1 , 11.2 , 4th or 5 , which works according to a bit rate-reduced transmission standard. In this case, the coupling field 20 forwards the incoming B-channel data to two switching fields 22.1 , 22.2 , which each break down the bytes of the B channels into two nibbles. Each of these nibbles represents the data supplied by one of the terminals 11.1 , 11.2 , 4 , 5 at two successive times. The two nibbles are then temporarily stored in a Puf ferspeicher 23.1, 23.2 and then, in a predetermined time sequence from the buffer memory 23.1, pushed out 23.2 and a transcoder 24.1, supplied 24.2, that of the subscriber-side over transmission standard according to ITU Rec. G.726 with a transmission rate of 32 kbit / s in the ISDN transmission standard according to ITU-Rec. G.711 implemented with a transmission rate of 64 kbit / s. It is important here that the nibbles are pushed out of the buffer memory 23.1 , 23.2 in a predetermined time interval of 125 microseconds , which corresponds to half a S ₀ frame. In this way, a time equalization is achieved and the original time sequence of the nibbles is restored.

In the following, the case is described that the evaluation of the D-channel data received by the office by the control unit 18 shows that a DECT end device 11.1 , 11.2 , 4 or 5 is addressed on the subscriber side. In this case, the switching matrix 21 forwards the B-channel data arriving at the office to the two transcoders 24.1 , 24.2 , which convert the ISDN transmission standard according to ITU-Rec. G.711 with a transmission rate of 64 kbit / s into the DECT transmission standard according to ITU-Rec. Carry out G.726 with a transmission rate of 32 kbit / s.

The B-channel data converted in this way and present in the form of nibbles are then written successively into a buffer memory 23.1 , 23.2 , the content of which can be read out in parallel by the switching matrix 22.1 , 22.2 . The switching matrix 22.1 , 22.2 therefore reads two successive nibbles from the buffer memory 23.1 , 23.2 and merges them into a byte, which is then fed to the switching matrix 20 and coupled into a B channel of the internal S ₀ bus.

Fig. 4 shows the frame structure in the data transmission from the DECT terminals 11.1 , 11.2 , 4 , 5 to the ISDN telecommunications system 3 , the frame structure being shown on the internal S ₀ bus in the center of the picture, while above and below the frame structure on the external S ₀ buses between the ISDN telecommunications system 3 and the network termination device 1 is reproduced.

From the illustration it can be seen that frames with a length of 48 bits are transmitted via the S ₀ bus, which in addition to control information contain two bytes of the B1 channel and two bytes of the B2 channel. At the beginning of a frame there is initially a frame bit F (framing bit) with logic "0" and positive pulse polarity, followed by a DC voltage compensation bit L. (DC balancing bit) with logic "0", but negative pulse polarity. This is followed by the first byte of the B1 channel, which contains two nibbles that were generated by the cordless telephone 11.1 . The first byte of the B1 channel is followed by a further DC voltage compensation bit L. (DC balancing bit), which is intended to compensate for any DC voltage component of the B1 channel that may occur. The DC voltage compensation bit L. is therefore set to a logical "0" with positive pulse polarity if an odd number of logic zeros occurs in the associated byte, since in this case the byte contains a DC voltage component.

This is followed by a D channel bit D, a logi "0" of the D-channel bit with negative pulse polarity ko is dated. In this case, the following contains  DC equalization bit L. a logical "0" with po sitative pulse polarity.

After the D channel bit D with the associated DC voltage compensation bit L., a frame bit F is then transmitted with an associated DC voltage compensation bit L. Both the frame bit F and the DC voltage compensation bit L. are set to a logical "0" with negative pulse polarity by the associated terminal in order to indicate to the ISDN telecommunications system 3 that the ISDN frame has been successfully synchronized.

Next, the first eight bits of the B2 channel generated by the cordless telephone 11.2 are transmitted, the first logical "0" within the B2 channel byte with a negative pulse polarity and all subsequent logical zeros within the entire B2 -Channel bytes are alternately encoded with positive and negative pulse polarity, so that any DC component that may be present can be completely compensated for by the following DC voltage compensation bit L.

Within the ISDN frame, the next B1 channel byte follows with two nibbles, which were generated by the ISDN telephone 4 working in DECT mode, followed by a DC equalization bit L. and a D channel Bit with the associated DC voltage compensation bit L..

This is followed by the next B2 channel byte with two nibbles, which come from the ISDN telephone 5 , which also works in DECT mode. The second byte of the B2 channel is in turn followed by a DC voltage compensation bit L., which compensates for any DC voltage component of this byte.

At the end of the ISDN frame there is finally a D-channel Bit D followed by a DC equalization bit L.

From the illustration in Fig. 4 continue to show how the ISDN telecommunications system according to the invention 3 converts the frame structure to the exchange side to connect with conventional ISDN terminal union to made despite the subscriber-side operation of DECT terminals 4, 5, 11.1, 11.2.

In the following, the conversion is first described for the case that four DECT terminals 11.1 , 11.2 , 4 , 5 are operated simultaneously on the internal S ₀ bus and transmit the data to the ISDN telecommunications system 3 .

In this case, the first byte of the B1 channel contains two nibbles of the cordless telephone 11.1 , which were generated one after the other in time. These two nibbles are transcoder 24.1 from the transmission standard according to ITU-Rec. G.726 with a transmission rate of 32 kbit / s into the ISDN transmission standard according to ITU-Rec. G.711 implemented with a transmission rate of 64 kbit / s and then form two complete bytes, which are coupled into an S ₀ frame of the external S ₀ interface 19.2 , as the curved arrows in FIG. 4 illustrate. The byte resulting from the first nibble is coupled into the first byte of the B1 channel within a S ₀ frame of the external S ₀ interface 19.2 , while the byte resulting from the second nibble forms the second byte of the B1 channel.

The first byte of the B2 channel of the internal S ₀ bus, on the other hand, contains two nibbles that were generated in succession by the cordless telephone 11.2 . These nibbles are implemented by the transcoder 24.2 and then form two complete bytes, which are coupled into the two bytes of the B2 channel at the external S ₀ interface 19.2 with a time delay.

Accordingly, the second byte of the B1 channel of the internal S ₀ bus comes from the telephone 4 operating in DECT mode. This byte also contains two nibbles, which correspond to successive sampling times and each form a complete byte after implementation by the transcoder 24.1 . These bytes are then coupled into the two bytes of the B1 channel at the external S ₀ interface 19.1 , as can be seen from the curved arrows.

Finally, the second byte of the B2 channel of the internal S ₀ bus contains two nibbles which originate from the telephone 5 operating in DECT mode. These two nibbles are in turn converted by the transcoder 24.2 into complete bytes and then coupled into the two bytes of the B2 channel at the external S ₀ interface 19.1 .

Fig. 5a shows the frame structure described above for clarification in a clearer view, from which it can be seen that each byte of a B-channel contains only the data of a telecommunications terminal TE1, TE2, TE3 or TE4, the data of the Telekommuni cation terminals are in the form of nibbles.

Fig. 5b for the two shows a further possible frame structure, ISDN frame with a length of 48 bits or 250 microseconds to a superframe having a length of 96 bits or 500 microseconds will be summarized. The terminals work with a bit rate reduction at a transmission rate of 16 kbit / s, so that the data of the individual terminals TE1,. . ., TE8 are in the form of bit pairs. Each B-channel byte thus contains four bit pairs of a terminal, so that a maximum of eight terminals can be operated simultaneously on the internal S ₀ bus.

The invention is not limited in its execution the preferred embodiments given above le. Rather, a number of variants are conceivable, which fundamentally different from the solution shown makes use of any type.

Claims (7)

1. ISDN telecommunications system ( 3 ) with an official S or U interface ( 19.1 , 19.2 ) for connection to a network termination device ( 1 ) or for direct connection to a digital switching center ( 2 ) and with a participant-side S- Interface ( 17 ) for providing an internal S-bus and for connecting ISDN terminals ( 4 , 5 , 11.1 , 11.2 ) to the internal S-bus, characterized in that
that on the subscriber side a first switching matrix ( 20 , 22.1 , 22.2 ) is provided which, when data is received from the terminals ( 4 , 5 , 11.1 , 11.2 ), the data words arriving on a B channel of the internal S-bus on the subscriber side each in several Bit groups broken down and when sending data to the terminals ( 4 , 5 , 11.1 , 11.2 ), several bit groups are coupled into a data word of a B channel, the bit groups contained in a data word being assigned to the same terminal ( 4 , 5 , 11.1 , 11.2 ) are working according to a bit rate reduced transmission standard,
that a transcoder ( 24.1 , 24.2 ) is provided for the conversion between the transmission standard, which is reduced at the subscriber end, and the ISDN transmission standard,
that the first switching network ( 20 , 22.1 , 22.2 ) and the Tran scoder ( 24.1 , 24.3 ) a buffer memory ( 23.1 , 23.2 ) is interposed between the bit groups when receiving data from the terminals ( 4 , 5 , 11.1 , 11.2 ) One data word each is buffered and periodically passed on to the transcoder ( 24.1 , 24.2 ) with a corresponding time delay and, when data is sent to the terminals ( 4 , 5 , 11.1 , 11.2 ), the bit groups supplied periodically by the transcoder ( 24.1 , 24.2 ) are temporarily stored in order to be able to couple several consecutive bit groups into the same data word of a B channel. 2. ISDN telecommunications system ( 3 ) according to claim 1, characterized in that the transcoder ( 24.1 , 24.2 ) and the office-side S interface ( 19.1 , 19.2 ) with the subscriber-side S interface ( 17 ) connected to a second switching matrix ( 21 ) is connected, which connects the official B-channels either with the transcoder ( 24.1 , 24.2 ) or bypassing the transcoder ( 24.1 , 24.2 ) with the subscriber-side S-interface ( 17 ). 3. ISDN telecommunications system ( 3 ) according to claim 2, characterized in that for controlling the first and / or second switching matrix ( 20 , 22.1 , 22.2 , 21 ) and / or the read / write behavior of the buffer memory ( 23.1 , 23.2 ) Control unit ( 18 ) is provided, which is connected to the office-side S interface ( 19.1 , 19.2 ) and the subscriber-side S interface ( 17 ) for evaluating the D-channel protocol data. 4. ISDN telecommunications system ( 3 ) according to one of the preceding claims, characterized in that he ste switching network ( 20 , 22.1 , 22.2 ) the subscriber side strikes a byte of the B channels each in two nibbles zer. 5. ISDN telecommunications system ( 3 ) according to one of the preceding claims, characterized in that the bit rate-reduced transmission standard follows the ITU recommendation G.726 and / or the ISDN transmission standard follows the ITU recommendation G.711. 6. Digital subscriber terminal ( 6 ) for connection to an ISDN telecommunications system ( 3 ) according to one of the preceding claims,
with at least one digital telecommunications terminal ( 11.1 to 11.4 ) operating in accordance with the bit rate-reduced transmission standard and an S-interface ( 16 ) for connection to the internal S-bus of the ISDN telecommunications system ( 3 ), characterized in that
that on the interface side a switching matrix ( 15.1 , 15.2 ) is provided which, when sending data, couples several bit groups of a terminal ( 11.1 to 11.4 ) into the same data word of a B channel on the internal S-bus and when data is received which on the internal S-Bus incoming data words broken down into several bit groups,
that the switching network ( 15.1 , 15.2 ) is preceded by a buffer memory ( 14.1 , 14.2 ), which temporarily stores the bit groups of one data word each when receiving data via the internal S-Bus and periodically forwards them to the terminal ( 11.1 to 11.4 ) with a corresponding time delay and When sending data to the ISDN telecommunication system ( 3 ), the bit groups that are periodically buffered by the terminal ( 11.1 to 11.4 ) temporarily, in order to enable a common coupling of several successive bit groups into the same data word. 7. subscriber terminal ( 6 ) according to claim 6, characterized by the training as a DECT radio base station ( 6 ), the telecommunications terminals are mobile parts ( 11.1 to 11.4 ) of the DECT radio base station ( 6 ) and the bit rate-reduced transmission standard of the ITU recommendation G.726 follows.