NO840633L - time division multiplex - Google Patents

Description

Time multiplex system

The invention relates to a time multiplex system where several

64 kbit/s signals or 64 kbit/s signals converted from analog signals are combined into a 2048 kbit/s signal on the transmitter side and separated again on the receiver side

Such combinations and separations of data signals are realized with a data signal multiplex device DSMX 64 K/2 which is mentioned in the Siemens publication "Nachrichten-Ubertragungsein-richtungen fiir analoge und digitale Signale", Bestell-Nr. A 42020

- A 131 - A 1-2-75. A transformation of analogue telephone signals into corresponding digital signals is realized by a system PCMX 30 or a PCM system with a smaller number of channels. In a digital network, however, the bit rate of 2048 kbit/s in the lower network level, especially for private users, often constitutes too much transmission capacity.

The task of the invention is to realize mains feeders with less transmission capacity.

Based on a time multiplex system of the kind indicated at the outset, this task according to the invention is solved by

that multiplexers are arranged on the sending side within a first hierarchy step for combining thirty 64 kbit/s signals into several 384 or 384 and 768 or 1024 kbit/s signals,

that a multiplexer is arranged within another hierarchy step for combining the 284 or 768 or 1024 kbit/s signals into the 2048 kbit/s signal, and

that corresponding demultiplexers are arranged on the receiving side.

A bitrate of 384 kbit/s is known per se from the CCITT recommendation G.739 (COM XV-temp. 39-E, Geneva 23.11.-3.12. 1980, pages 12-21).

In the embodiment of the object of the invention, one or two multiplexers may be arranged on the transmitting side within an intermediate hierarchy step to combine two 384-kbit/s signals into a 768-kbit/s signal and on the receiving side one or two demultiplexers may be arranged within an intermediate hierarchy step for create-

Ice of two 384-kbit/s signals from a 768-kbit/s signal.

If the arriving 64-kbit/s signals are plesiochronous, it is advantageous if termination devices are arranged in the first hierarchy step on the sending side and termination-eliminating and beat-restoring devices on the receiving side. Other synchronization methods can also be used.

In a 384 kbit/s signal, five voice signals and one additional signal or one or two tone program signals from 15 or 7 kHz can be transmitted.

In a 768-kbit/s signal, there is room for ten voice signals and two additional signals or eleven voice signals and one additional signal or two or four tone program signals. Additional signals can form communication technical characteristics.

A combination of five and five voice or data signals forms, together with the additional signal, a unit capable of communication. The time slot in the 2048 kbit/s signal which is otherwise used for the transmission of the communication technical characters, namely the sixteenth time slot, is thus available for the transmission of other information.

The system according to the invention can form the basic building block for a larger system hierarchy.

In the following, the invention will be explained in more detail by way of examples. Fig. 1 shows a time multiplex system made in accordance with the invention with a sending and receiving side. Fig. 2 shows the sending side of a time multiplex system carried out in accordance with the invention with an intermediate stage of hierarchy, and

fig. 3 shows the transmission side of a time multiplex system carried out in accordance with the invention with a modified first hierarchy step.

The time multiplex system of fig. 1 has thirty inputs

1, multiplexers 2-6 and 7, a transmission line 9, demultiplexers 10, 12-16 and thirty outputs 17.

At the inputs 1, 64-kbit/s signals are supplied, specifically for each multiplexer 2-6 five main digital signals and one additional signal. At the outputs of the multiplexers 2, 384-kbit/s signals appear, which together with a further 64-kbit/s signal at the input 8 and an internally generated 64-kbit/s frame marking word or message word are fed to the multiplexer 7. Come -bination produces a 2048-kbit/s signal on the transmission path 9. On the receiving side, the demultiplexer 10 separates the received 2048-kbit/s signal into five 384-kbit/s signals and a 64-k-bit/s signal. The 384-kbit/s signals are fed to the demultiplexers 12-16, which separate the received signals into three 64-kbit/s signals.

The wires carrying 384-kbit/s signals can be short or connect two different places.

The main signals can be digital signals originating from digital sources, or coded analog voice or data signals. Fig. 2 shows the transmitter-side part of a time multiplex system according to the invention, comprising an intermediate hierarchy step. The reception section is structured in accordance with this. The device contains compared to fig. 1, multiplexers 18 and 19, which combine two and two 384-kbit/s signals into one and one 768-kbit/s signal. A multipixel 20 then has to combine two 768 kbit/s signals, one 384 kbit/s signal and two 64 kbit/s signals including the frame marking and message word. Fig. 3 shows the transmitting part of a further variant of the time multiplex system according to the invention. The reception side, not shown, is designed mirror-symmetrically. A difference from the device in fig. 1 consists in the multiplexers 2-5 in the first hierarchy step being replaced by two multiplexers 21 and 22 which have twelve inputs each and emit 768-kbit/s signals. A multipixel 23 then has to combine two 768 kbit/s signals, one 384 kbit/s signal, one 64 kbit/s signal and the frame marking or message word.

Claims (12)

1. Time multiplex system where several 64-kbit/s signals or 64-kbit/s signals converted from analogue signals on the sending side are combined into a 2048-kbit/s signal and separated again on the receiving side, characterized by that there are multiplexers on the sending side (2.6; 21, 22) within a first hierarchy step to combine thirty 64 kbit/s signals into several 384 or 384 and 368 or 1024 kbit/s signals, that on the receiving side a multiplexer (7; 20; 23) is arranged within another hierarchy step to combine the 384 or 368 or 1024 kbit/s signals into the 2048 kbit/s signal, and that corresponding demultiplexers (10, 12-16) are arranged on the receiving side. 2. Time multiplex system as stated in claim 1, characterized in that one or two multiplexers (18, 19) within a hierarchy step on the sending side are arranged to combine two 384-kbit/s signals into a 768-kbit/signal. 3. Time multiplex system as stated in claim 1, characterized in that one or two demultiplexers are arranged on the receiving side within a hierarchy step for forming two 384-kbit/s signals from a 768-kbit/s signal. 4. Time multiplex system as specified in claim 1, characterized in that within a first hierarchy step there are cut-out devices on the sending side and cut-out eliminating and beat-restoring devices on the receiving side. 5. Time multiplex system as stated in claim 1, characterized by the transmission of five voice or data signals and an additional signal in a 384-kbit/s signal. 6. Time multiplex system as stated in claim 1, characterized by transmission of one or two tone program signals in a 384-kbit/s signal. 7. Time multiplex signal as stated in claim 1, characterized by the transmission of ten voice or data signals and two additional signals in a 768 kbit/s signal. 8. Time multiplex system as stated in claim 1, characterized by the transmission of eleven voice or data signals and an additional signal in a 768 kbit/s signal. 9. Time multiplex system as stated in claim 1, characterized by the transmission of two or four tone program signals in a 768 kbit/s signal. 10. Time multiplex system as specified in claim 5, 7 or 8, characterized by the transmission of communication technical characteristics as additional signals. 11. Time multiplex system as specified in claim 5, 7 or 8, characterized in that the voice or data signal with its additional signals forms a communication technical unit. 12. Time multiplex system as specified in one of claims 1-11, characterized in that it is arranged multiple times to form a larger system hierarchy.