CH659927A5 - SUBSCRIBER LINE FINAL EQUIPMENT. - Google Patents

Description

The present invention relates to subscriber line end equipment for use on the subscriber side of a telecommunications system. In the case of an integrated information transmission system, different data sources, including the telephone, have to be connected to a single subscriber letting, the information being sent in digital form to the subscriber's equipment. The end equipment in such a transmission system must be able to serve at least two sources of information without mutual interference, e.g. Language and screen text. In such a case there is a main channel with 64 kbit / s for speech, the speech being transmitted with 8-bit words at a sampling frequency of 8 kHz, and an auxiliary channel with e.g. 16 kbit / s.

The means for controlling such connections must be designed so that they do not influence the information transmitted on them. In one embodiment, signals in a frame format are used for this purpose, which are transmitted in the auxiliary channel and are based on the principles of high-level data link control. So if signals are transmitted on the information channel, they must be extracted and offered to the switching system on the auxiliary channel with the appropriate data rate and in the appropriate format. Furthermore, the sources of information other than speech do not necessarily provide data at a rate appropriate for the channel used.

It is obvious that the data interface circuits involved have to perform essential functions, each different data source requiring a different interface circuit in order to bring the data to the common denominator, which is necessary for the channel used.

It is therefore an object of the present invention to provide subscriber line end equipment which meets the above requirements and is of relatively simple construction.

This object is achieved by the features mentioned in the characterizing part of the first claim. Advantageous further developments can be found in the dependent claims.

Embodiments of the invention will now be explained in more detail with reference to the drawing. The drawing shows:

1 shows a block diagram of a subscriber line terminal equipment for an integrated information transmission system;

2 shows a circuit diagram of a subscriber line end equipment in which one of the various information sources can be excluded by means of a selector switch;

3 is a circuit diagram of a subscriber line end equipment in which the operated data sources can be twisted with a set of data busbars;

Figures 4 and 5 show details of the circuit of Figure 3; and FIG. 6 shows a subscriber line terminal equipment in which the operated data sources can each be connected to a set of ring lines.

The local distribution of the interface circuit in an integrated information transmission system was determined by CCITT (Ref. COM XVIII Temp. 105E). The corresponding interface positions for the interfaces A, B and C are shown in FIG. 1. Interface B is a reference point for the design and the type of interface C depends on the type of transmission.

As can be seen from FIG. 1, the voice source 1 is connected via the uppermost interface circuit A with a codec in the subscriber line interface circuit (SLIC) 2. The codec could also be part of the subscriber set, in which case the voice signals would already be delivered in digital form by the subscriber set. This would advantageously be done at 64 kbit / s, so that a direct connection to other 64 kbit / s channels b would be possible. Two of the other sources, three of which are shown, are connected to the corresponding interface circuit A via an adapter, which converts the information from this source to the bit stream used for the latter, the latter being connected to the SLIC 2 circuit.

An important recent CEPT decision says that the line termination equipment LT, which is the interface to the line to the center, provides the bit clock and frame alignment for the subscriber equipment CTE. However, the most important interfaces for the subscriber are the interfaces A. This should be universally usable for all data, but is inevitably different for speech if the codec is arranged in the subscriber terminal equipment CTE. This can make sense for telephone subscriber sets connected in parallel, which are best connected in an analog manner, the signaling being suitably multiplied.

As already mentioned, the data sources require adapter

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Circuits if their output signals do not fully meet the requirements of interface A. Such adapter circuits deliver the data at a rate appropriate for the peripheral device while receiving data from that device in order to convert it to the requirements of the interface A. The adapter circuits also convert the signaling information into one that is suitable for forming frame mode signals and vice versa. Thus, although certain data sources do not require adaptation, existing data arrangements can be made acceptable for the requirements of an integrated information transmission system. These adapter circuits can be provided either with any peripheral device or in the subscriber terminal equipment CTE. If the latter is chosen, of course, each peripheral device requires its own subscriber terminal equipment, while in the first variant a single subscriber terminal equipment CTE can serve any peripheral device.

The nature of the interface circuit A is very much dependent on the way in which the subscriber terminal equipment CTE has access to the peripheral devices. There are three solution principles, namely the switched selection, busbars and ring lines. These three principles are described below.

When switched, the subscriber equipment can switch on the required peripheral device via a circuit that is suitable for the data rate used. The switch is set either at the request of the peripheral device or the subscriber who uses it or on the basis of the dialing data received. 2 shows such an arrangement. Data rates of 64 kbit / s, 8 kbit / s and 8 or 16 kbit / s are assumed, with individual switches being available for each data rate, which allow simultaneous processing. Signals for controlling the connections are routed to a signaling circuit 5 on lines that are individual for each peripheral device or in a multiplex, and depending on such signals, the signaling circuit 5 sets up the corresponding signaling frames. Circuit 5 also returns control signals to the peripheral devices. A MUX / DEMUX circuit 6 combines and mixes the data streams from up to three peripheral devices, as indicated by the connections from the switches, and delivers the result to the line termination equipment 3 as an 80 kbit bit stream. In the opposite direction, the circuit 3 dissolves the multiplex of the incoming bit stream and routes the various parts to the corresponding peripheral devices. In the SLIC2 circuit, the outgoing information from the three channels is combined into an 80 kbit / s data stream and applied to the line termination equipment. The incoming 80 kbit / s data stream is divided into the corresponding sub-streams in order to apply these via the switches to the peripheral devices or directly to the signaling circuit 5, which in turn applies the signals to the corresponding peripheral devices.

With this arrangement, telemetry signals can be treated in the same way as signaling signals, or then by using the (d '+ tm) A channel.

Fig. 3 shows the version with data busbars. The circuit is somewhat similar to that of FIG. 2. The main difference is that a set of data busbars 10 with corresponding bit rates is used, with which the peripheral circuits are connected via conductors and gates 11, these gates being bidirectional. Gates are. As in FIG. 2, a control circuit 12 is also present, which, as before, receives instructions from the signaling circuit as to which peripheral devices should be connected, the peripheral devices being adapted to the standards of the data busbars by individual adapter circuits, which adapter circuits also adapt the signaling information extracted to the Deliver signaling circuit 5 via individual lines per peripheral device or receive such signals from the signaling circuit 5. Telemetry signals are treated in a similar manner as is done in the circuit of FIG. 2.

Fig. 4 shows part of the circuit of Fig. 3 in more detail. Each data interface circuit 15, 16 has a detector 17 for its own peripheral code. With an 8-bit input in parallel, the signals «1» and «0», which describe this code and enable easy access to any of 255 peripheral devices, are applied to the 8 + 8 conductors to the detector. As FIG. 5 shows in detail, this detector is connected to the corresponding conductors for “1” and “0” in order to activate the corresponding peripheral device. In Fig. 5, the peripheral number is in binary 01011001, which corresponds to number 89 in decimal.

When a peripheral device is activated by the terminal equipment CTE, an acknowledgment signal is sent back to the equipment CTE and the gates for the reception of data by the data interface and / or the transmission of data from the data interface are activated. If in-band signals are contained in the data from the peripheral device, these are detected and converted into the signaling format of the network and sent to the terminal equipment CTE.

Similarly, signals contained in the information received from the equipment CTE are extracted and routed to the appropriate peripheral.

In the above description, a particular form of parallel code transmission and detection was used, but it is clear that other forms using serial transmission would result in the same result if the number of lines were reduced.

Fig. 6 shows an arrangement with ring lines. Here too, the design of the subscriber terminal equipment CTE is little influenced. 3 are replaced by ring lines 20, 21 and 22 with corresponding bit rates. A ring line is also available for signaling, so that signals to and from the individual peripheral devices can be processed with a minimum number of lines. The signaling loop is shown separately to take into account the CEPT version b + Ai + A2 if Ai and A2 are each operated at 8 kbit / s but are separate. If the (b + A) version is used, where Ä is 16 kbit / s, the signaling ring line and the ring line for slower data are combined into a single ring. This then has the advantage that the signals with a lower data rate can be switched dynamically from one peripheral device to another. With the 64 kbit ring line, this can only be done on the basis of a switched line, because dynamic switching is not possible.

The blocks with broken lines in FIG. 6 have the following functions:

a) Interface for peripheral devices that enable the data to be compiled in a format suitable for interface A, a format that is identical to that used for the frame mode data and the signaling channels in the network of the integrated information transmission system. This allows the network to be transparent down to the frame if desired.

b) extraction of the received data and signals.

c) Regeneration of (b) or insertion of original frames if desired. The possibility of inserting a frame depends on the detection of a free space of suitable frame length in the shared channel used.

It can be seen that a separate path is shown for signals, for data and for telemetry plus additional paths for higher rate data and for 8 kbit / s data. The latter would not be necessary if all data with a low bit rate on the

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(s + d '+ tm) channel would be processed. It should be noted that the ring line can use the same protocol as the subscriber line, so that the need for implementation is avoided.

A comparison of the different connection methods shows that the main advantage of the ring lines is that only a small number of lines is required. This is particularly useful in applications where distances need to be considered. On the other hand, their characteristics are similar to those of the signal distribution with busbars, both are limited only by the code for the selection and by the physical limitations of the characteristics of the busbar or ring line interfaces in the number of peripheral devices that can be operated. When the distribution is switched, there must be a corresponding number of gates, although the simplest arrangement has been chosen. This could be a burden for the user of the very simple end equipment.

Therefore, the two methods with busbars and ring lines are currently preferred over the switched method 5. The busbar method requires less equipment than the ring system, but there is little difference in the cost of the two systems or even all three systems. Where the distances are greater, the ring line is most suitable and could therefore be the first choice for a universally applicable solution. It has the advantage of dynamic use and the use of the same format as the integrated information transmission system. The security of the ring line can be improved by using a double ring 15, which allows a faulty interface device of a peripheral device to be avoided.

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Claims (5)

659 927 2nd PATENT CLAIMS 1. Subscriber line terminal equipment in a telecommunication system in which the telecommunication information is transmitted in digital form between the subscriber station and the headquarters, characterized in that the various services offered have those for which the digital bit rates are different, that connections for information sources (1 ) for a number of these services to the terminal equipment (CTE), the number of information sources exceeds the number of different digital bit streams to which the subscriber is entitled, and control means (SLIC) are provided to selectively connect information sources to corresponding physical paths, on which the mentioned bit streams are carried. 2. Terminal equipment according to claim 1, characterized in that it has a multiplexer (6) in which the bit streams from the various information sources (1), from which a transmission is to be carried out, are combined into a single bit stream for transmission to the central office. it can be summarized that a demultiplexer (6) is present in which the bit stream is divided by the control center in order to route it to different peripheral devices for which it is intended, whereby different bit streams on different physical paths (d, d ', tm ) before the merging in the multiplexer and after the separation in the demultiplexer, and that control means (5, 12) are present in order to connect the information sources to be connected with corresponding physical paths on which the bit streams before the merging in the multiplexer and after the separation in the demultiplexer. 3. Terminal equipment according to claim 2, characterized in that each of said physical paths (d, d ', tm) is connected to a multi-position switch which gives access to a number of different services. 4. Terminal equipment according to claim 2, characterized in that each of said physical paths (d, d ', tm) is connected to a set (10) of data busbars, each busbar having access to a number of said busbars (11) Services. 5. terminal equipment according to claim 2, characterized in that each of said physical paths (d, d ', tm) is connected to at least one ring line (20-22), which ring lines are designed so that any of the services to which the Ring line has access, can be activated.