NO180220B - Method of transmitting data signals - Google Patents

Abstract

The method is designed to increase the available transmission capacity of the line. The control channels reserved on such a line in multiplex frames for the transmission of control signals, but unused, can additionally be employed for the transmission of data signals. The method can be used, for example, for the transmission of data signals according to CCITT Recommendation X.51. <IMAGE>

Description

The invention relates to a switching device for the transmission of data signals which are received and/or transmitted by a number of data transmission devices where the transmission takes place over a transmission line used in time multiplex operation to which for the transmission of the data signals for each of the data transmission devices and correspondingly that of the transmission device ML in each in the case of a fixed transmission rate, at least one time channel of a number of time channels is assigned with in each case cyclically repeated time slots occurring in successive multiplex frames, so that of the total available time channels a fixed number is reserved as control channels for the transmission of control signals, and the control channels not used for the transmission of the control signals can be used for the transmission of data signals.

Such a coupling device is already known from US-PS no.

4245 340. With this known switching device, signaling information is transmitted in every sixth frame. For the identification of each of these signaling frames, a frame channel with one bit position per frame. In this frame channel, every second frame a bit of a fixed bit pattern is transmitted in the bit position fixed for this. In this connection, an additional data channel is obtained in that the bit positions of this frame channel not used for the transmission of this bit pattern are used for the transmission of data bits.

Furthermore, it is already known from US-PS no. 4 467 469 to use unused data bits in a PCM data stream for the transmission of control signals.

Finally, CCITT recommendation X.51, for example, defines multiplex frames that consist of subframes, each with a total of 640 time slots. Of these time slots, 600 are intended for the transmission of data signals, while the other 40 time slots are reserved for the transmission of control signals, such as synchronization signals and of national and internationally used organizational signals. Of the latter time slots, a portion is thus exclusively used for the transmission of the control signals.

The purpose of the present invention is to provide a solution with which a switching device of the kind mentioned in the introduction can be made to be able to transmit data signals that are received and/or transmitted by data transmission devices over a transmission line used in time multiplex operation with a low control cost and switching technical cost.

This purpose is achieved with a connection device of the kind mentioned in the introduction which, according to the present invention, is characterized by the fact that a number of channel group devices are arranged which are connected by connection lines and which each have a number of memory areas corresponding to the number of connection lines available over a channel memory. that the data signals which are respectively to be received and transmitted on the respective connection line can be stored in the respective memory area, that the channel group devices are connected together via a bus line system with a central processor which on the one hand forms the multiplex frames to be transmitted over the transmission line and on the other side dissolves the multiplex frames received over the transmission line, that an assignment memory is arranged in the central processor in which the assignments are stored between the time channels determined in the multiplex frames and the channel group devices as well as the connection lines connected to the channel group devices, that the central processor has a first counting device which is used in the creation of multiplex frames and another counting device which is used in the resolution of multiplex frames, the counter values of the counting devices being assigned to the time slots within a multiplex frame, that according to the value of the counter value of a first counting device and the information stored in the state memory can the individual channel group devices are controlled to emit the data signals to be inserted into the multiplex frames, and that according to the value of the counter reading of the other counting device and the information stored in the state memory, the individual channel group devices can be supplied with the data signals accommodated in the multiplex frames.

The invention entails the advantage that the control sequences necessary for the creation and resolution of the multiplex frames take place exclusively in the central processor and that the channel group devices are controlled solely on the basis of the information added to the allocation memory and the counter readings of the counting devices are controlled for the reception and transmission of data signals, so that in these channel group devices there is neither necessary with control engineering or connection engineering measures for the formation and dissolution of the multiplex frames. A further advantage of the invention is that by exclusively changing the information contained in the allocation memory, the switching device can be flexibly adapted to changed requirements regarding the allocation of the data channels and the free control channels to the data transmission devices.

An appropriate design of the channel group devices consists in that these respectively have a microprocessor device, that the microprocessor device's bus line system is connected on the one hand to the channel memory and on the other hand to an interface device, and that the connection lines connected to the respective channel group device are led to the interface device.

In the following, the invention will be explained in more detail in connection with the drawing. Fig. 1 shows a timing diagram of a multiplex frame according to CCITT Recommendation X.51. Fig. 2 shows a multiplex device where the invention is used.

In fig. 1 (la-lc) a timing diagram for a multiplex frame according to CCITT Recommendation X.51 is shown. This multiplex frame, whose duration is 40 ms, is according to fig. la divided into four subframes with a duration of 10 ms each. In each of these subframes, 640 time slots are set for the transmission of data signals and control signals. Thus, a multiplex frame has a total of 2560 time slots. At these time slots, which cyclically repeat in successive multiplex frames, 2560 time channels are determined. Thus, e.g. the time channel "1" formed by the first time slot appearing in successive multiplex frames. In similar ways, the last time slot appearing in successive multiplex frames forms the time channel "2560".

In each of the aforementioned sub-frames, 600 time slots are set for the transmission of data signals. The data signals are thereby transmitted in the form of so-called "envelopes", each of which is formed by eight data bits and two control bits added to these (a synchronization bit and a status bit). Consequently, it is possible to transfer 60 envelopes per wonder frame (fig. lb). After every fifteenth of the time slots used for the transmission of the data signals, i.e. after 1.5 envelopes, a time slot is arranged for the transmission of the control signals. This gives per subframe 40 time slots as in fig. lb is denoted by Pl to P40. In fig. lc, the occurring time slots distributed within a subframe are produced combined. These time slots define 40 control channels with the corresponding time slots repeatedly occurring in successive subframes. These 40 control channels are reserved for the transmission of control signals. These control signals fall under, e.g. synchronization signals and for national as well as for international needs used organizational signals. These organizational signals are termed "housekeeping information". For the transmission of the national organizational signals, e.g. reserved the control channels corresponding to time slots P9 to P20 (fig. lc).

According to CCITT recommendation X.51, the aforementioned 40 control channels are exclusively used for the transmission of control signals. According to the present invention, it is now ensured that the unused control channels can be used for the transmission of data signals. Thus, it is e.g. possible to transmit data signals that occur at a transmission rate of 50 bit/s in time channels formed by those in subframes 1 and 3 resp. 2 and 4 of successive multiplex frames occurring in time slots P9 to P20. In this way, a further 24 50 bit/s time channels are then available to the time channels reserved for the transmission of the data signals. In addition to this, there is e.g. when forming other subframe combinations, it is also possible to determine time slots where data signals that occur with a transmission rate deviating from 50 bit/s can be transmitted. E.g. the time channels formed by time slots P9 to P20 for successive subframes can be used for the transmission of 100 bit/s data signals. A mixture of time channels for the transmission of 50 bit/s and 100 bit/s data signals is also possible.

In fig. 2 shows a multiplex device for transmitting data signals over a multiplex transmission line ML. This multiplex device has a number of identically constructed channel groups KG1 to KGn. Each of these channel groups constitutes a microprocessor device which is shown in section for the channel group KG1. This microprocessor device has a microprocessor MP1 which is connected via a bus system BUS1 to an input/output device E/A. This input/output device thereby forms the interface of a number of transmission lines LI to Lm over which e.g. the subscriber device receives resp. transmits to the multiplex device data signals in the form of the aforementioned envelopes. However, it is also possible to set up the channel groups so that to the transmission lines LI to Lm it is possible to connect subscriber devices that receive or emits data signals in the form of start-stop data signals. In this case, the channel groups will carry out a corresponding signal transformation.

A channel memory KSP is also connected to the mentioned bus system BUS1. This channel memory has for each of the transmission lines connected to the channel group in question, here to the channel group KG1, a storage area in which data signals to be transmitted or received on each transmission line can be stored.

The aforementioned channel groups KG1 to KGn are connected to a central processor ZP via a central bus line system BUS2. This central processor, on the one hand, generates the multiplex signals in accordance with CCITT recommendation X.51 and passes these multiplex signals on via a multiplex group MG which is also connected to the central bus line system BUS2, to the already mentioned multiplex transmission line ML. On the other hand, it dissolves the multiplex signals supplied above the multiplex group into individual data signals and passes these on to the previously mentioned channel groups. The multiplex group MG also serves to adapt the one in fig. 2 showed multiplexing arrangement for the multiplex transmission line ML.

The central processor ZP has a microprocessor device which in fig. 2 is shown in section. A microprocessor MP2 belongs to this microprocessor device and is connected via a bus system BUS3 to an allocation memory ZSP. In this allocation memory, it is to generate resp. dissolve the multiplex frames stored a table which gives the assignment between the time slots determined in the multiplex frames and the individual channel groups as well as the transmission lines connected to the channel groups. In addition to this, the microprocessor MP2 has two in fig. 2 not shown in further detail, counter devices that each cycle with a counting period corresponding to one of the number of time slots determined in a multiplex frame.

One of the counter devices is used by the microprocessor MP2 to generate multiplex signals. In connection with the count level of this counter device and which corresponds to the time slots in the multiplex frames to be formed, and the table stored in the allocation memory ZSP, the microprocessor receives the data signal bits stored in the channel memories of the individual channel groups KG1 to KGn to be transmitted in each time slot and combines these into the multiplex frame with the control signal bits generated by the microprocessor itself. In this connection, the data signal bits which are to be transmitted are also received in those of the control channel's time slots which are not used for the transmission of control signal bits. According to the example described above, these are time slots P9 to P20.

The second counter device is used by the microprocessor MP2 to resolve multiplex signals which have been received over the multiplex group MG. This counter device is synchronized by the control signals which are transmitted in these multiplex signals and which are used for the synchronization. Determined by the counter level of this counter device and the already mentioned table stored in the allocation memory ZSP, the data signal bits occurring in the individual time slots are transferred to each of the relevant channel memories KSP in the channel groups KG1 to KGn. These data signal bits also include those that were previously transmitted in time slots in the control channels not used for the transmission of control signals.

Above, the present invention is explained exclusively with the transmission of data signals according to a multiplex transmission principle according to CCITT recommendation X.51 as an example. However, the invention is generally always applicable when multiplex frames are determined for the transmission of data signals where the time channels reserved for control purposes are only partially used for the transmission of control signals.

Claims (2)

1. Coupling device for the transmission of data signals that are received and/or transmitted by a number of data transmission devices where the transmission takes place over a transmission line (ML) used in time multiplex operation to which the transmission of the data signals for each of the data transmission devices corresponds to that of the transmission line (ML) in each case fixed transmission rate is assigned to at least one time channel of a number of time channels with in each case cyclically repeated time slots appearing in successive multiplex frames, so that of the total available time channels a fixed number is reserved as control channels for the transmission of control signals, and those for transmission control channels not used by the control signals can be used for the transmission of data signals, characterized by the fact that a number of channel group devices (KG1, ..., KGn) are arranged which are connected by connection lines (LI, ..., Lm) and which each have a channel memory (KSP) has at its disposal a number of memory areas corresponding to the number of connection lines, that the data signals that are respectively to be received and transmitted on the respective connection line can be stored in the respective memory area, that the channel group devices (KG1, ..., KGn) are connected together via a bus line system (BUS2) with a central processor (ZP), which on the one hand forms the multiplex frames to be transmitted over the transmission line (ML) and on the other hand dissolves the multiplex frames received over the transmission line, that an allocation memory (ZSP) is arranged in the central processor (ZP) in which is stored the assignments between the time channels defined in the multiplex frames and the channel group devices as well as the connection lines (LI, ..., Lm) connected to the channel group devices, that the central processor (ZP) has a first counting device that is used when creating multiplex frames and a second counting device that is used when resolving multiplex frames , as the counters of the counting devices are assigned t the time slots within a multiplex frame, that according to the value of the counter reading of the first counting device and the information stored in the state memory (ZSP), the individual channel group devices (KG1, ..., KGn) can be controlled to emit the data signals to be inserted into the multiplex frames, and that according to the value of the counter reading of the other counting device and the information stored in the state memory can be supplied to the individual channel group devices with the data signals accommodated in the multiplex frames. 2. Connection device according to claim 1, characterized in that each of the channel group devices (KG1, ..., KGn) respectively has a microprocessor device (MP1), that the microprocessor device's bus line system (BUS1) is connected on the one hand to the channel memory (KSP) and on the other hand with an interface device (E/A), and that the connection lines (LI, ..., Lm) connected to the respective channel group device are led to the interface device.