NL8202135A - COUPLING DEVICE FOR A DIGITAL COMMUNICATION SYSTEM. - Google Patents

Description

3 * VO 3391

Subject: Coupling device for a digital communication system.

The invention relates to a coupling device for a digital communication system, in particular a tele-communication system, for which use is made of pulse-code modulation techniques.

Coupling device for digital communication systems are known.

Such coupling devices are arranged for simultaneous use of a number of devices, for example lines connected to telecommunication devices, over which digital signals are transported, such as data and / or digitized speech information, using pulse code modulation techniques (PCM) techniques . In the PCM-10 communication technique, two communication types are distinguished, namely time multiplex and space multiplex. In time-multiplexed communications, fixed time slots for transmitting and receiving information occurring within a periodic time frame are designated on a device for the duration of a connection. In the case of communication according to the spatial multiplex principle, the time frame of one of several line pairs is assigned to a respective device for the duration of a connection. Since the number of time slots occurring within the time frame is limited, with relatively large coupling devices, both network structures 20 are combined with one another, for example, a time-space-space-time structure for medium-sized digital communication systems is preferred.

The object of the invention is to provide a coupling device of the above structure, which offers the following possibilities for communication systems of different sizes: full accessibility and reliable, non-time-critical data transfer between time and space stages; economical manufacturing because the diversity of structure groups is limited; and simple, modular extension.

For this purpose, a coupling device according to the invention is characterized in that the parts of the coupling network required for the transmission of the data links are spatially added to each communication-technical structure group, in that several function units (0 ... 3) are connected to a coupling matrix (KM), which is arranged to couple in pairs the coupling points of space steps of transmission and reception lines characterized by identical addresses in pairs, elements (COD, FI, SLIC) 82 02 1 3 5 Γ>.

1 \ c -2- of the ... function units (0 ... 3) and the coupling matrix (KM) are under the control of a permanently added decentralized microprocessor (DMP); that the receive sync mark (FR) is lagged with respect to the transmit sync mark (FX) over a clock signal interval of the clock signal (CL) controlling the coupling device; and that between the transmit outputs of the function units (0 ... 3) and the coupling matrix (KM) an intermediate memory (ZS) is connected, which is controlled by the falling edges of the clock signal (CL).

Further preferred embodiments of the invention are further described in the subclaims.

For further explanation of the invention, by way of example, a telecommunication system as an embodiment thereof will be described, with reference to the drawing. In the drawing: Fig. 1 is a block diagram of a participant skehen; FIG. 2 is a schematic diagram of the triggering device. of the clock signals; and Fig. 3 is a diagram illustrating a connection between two chains.

The coupling device is designed as a divided coupling network.

This means that the digital communication system does not have a separate centralized single-stage or multi-stage coupling device. Each communication engineering structure group, such as, for example, a subscriber chain, a switchboard, an electoral chain, etc., has parts of the interconnection network which are necessary for the switching of data banks in the most general sense, ie those used for the speech path. as well as those which are necessary for the control path of the connection construction, have been added spatially. To this end, as shown in Fig. 1, several function units, for example four subscriber connection units 0 ... 3, are one unit. merged and combined with a common coupling matrix KM.

30 Each delegate connection unit is composed of a unit SLIC, which provides, among other things, a two-wire four-wire conversion, the power supply, the input of call pulses, tone frequency pulses and cost count pulses, a complex line simulation, as well as the loop monitoring, a filter FI and an analog-digital / digital analog converter COD. The converters COD 35 form the time steps in the time-space-space-time structure of the communication system.

The coupling matrix units KM form the space stack portion 8Z0 ~ 2T3 5 '~ -------------------- ~ ~' <, \ - 3 - a of the system. In the example shown, a torque matrix KM is applied for four subscriber connection units 0 ... 3. A coupling matrix KM consists in fibers of an address memory ADS for the coupling elements to be switched, an intermediate memory ZS, a demultiplexer 5 DMX, which acts as a coupling element in the transmission direction, a multiplexer MUX which acts as a coupling element in the receiving units, power outputs and receiving stages ST, which preferably include Schmitt tractors. With such an arrangement it is possible that the transmit outputs of the four digital-analog amzetters COD with eight unidirectional 10 transmission lines SL and the four receive inputs with eight unidirectional receive lines EL can be freely selected. cross-linked. Within the framework of a structure rack, which accommodates, for example, sixteen such communication-technical structure groups described above, the data reception paths and the data transmission paths for one-way transmission, ie separated, are housed in a manifold (bus system SL, EL). In the physically considered end portion of the structure group racks, whereby the unidirectional lines with transmitting and receiving elements, so-called transmit / receivers, are combined between the feed structure groups VL, the da-tabanes are formed in two-way PCM- pipes converted.

For the control of the time stacking part and the space stacking part of a communication engineering structure group, a decentralized microprocessor DMP is provided, which, among other things, has a one-time serial input of the time-slot information in the converter COD, and a one-time switching of introduce the required coupling points in the staircase at the beginning of the connection build-up.

The connection between a transmitting and a receiving circuit is shown in FIG. The centralized clock triggering chain link is shown schematically in FIG.

The frequency derived in a manner known per se from a quartz crystal is divided by means of a frequency divider FT such that different time signals whose respective periods are in a fixed relationship to each other are formed. Other 35 components TE, SY1 serve to trigger the OCM clock signal CL, produce the synchronizing chains FR and FX, and to fix their time relationships. Due to runtime effects in the coupler, the \ 8202135 \ k receive sync sign FR is trailing over a clock signal period relative to the transmit sync sign FX. The PCM clock signal CL and the synchronizing characters FE, and FX are distributed star-shaped via the drive circuits SM with respect to the structure group racks over the supply structure groups VL, which in turn further transmit the characters hus-shaped.

The PCM data track runs via 4-way and two-way lines. The feed structure groups VL are located at the transition points between the one-way and two-way lines. Thus, a connection, starting from a participant of the chain H with a participant of the chain N, has the form as shown schematically in Fig. 3.

As can be seen from Fig. 1, an intermediate memory ZS is connected between the transmit outputs of the converter COD and the demultiplexer DMX of the coupling matrix KM. This intermediate memory ZS, which is preferably designed as a bistable tipping chain (D-flip-flop), is directly controlled by the falling edges of the PCM clock signal CL. Such a falling edge is in a time interval in which the converter COD generates a data bit at its transmission output. Since the intermediate memory ZS is only reactivated at the next falling edge of the PCM clock signal CL 20, the data bit is present at the demultiplexer DMX for a sufficiently long time, irrespective of the tolerances of the converter COD.

The extension is required to compensate for the transit times and their tolerances between the sending and receiving converters COD, so that the receiving converter COD can take over the data bit stored in the cache on the next falling clock signal edge. Simultaneously take the coupling matrix. KM transfers the following data bit from the transmitting converter COD, as described above.

30 \ '82 0 2 1 3 5 “y

Claims (4)

1. A coupling device for a digital communication system, in particular the telecommunications system, using pulse-code modulation (PCM) techniques, with a mixture of a time-space-space e-time structure, characterized in that Each communication-technical structure group has been spatially added to the parts of the interconnection network required for the transfer of the data banks, because several function units (0 ... 3) are connected to a coupling matrix (KM), which transmit a paired interconnection of the establishes coupling points of the space stages for transmission and reception lines, which are characterized by equal addresses, whereby elements (COD, FI, SLIC) of the function units (0 ... 3) and the coupling matrix (KM) are a permanently added, decentralized microprocessor (DMP) that, to compensate for runtimes inherent in the digital data channels, the receive sync symbol (FR) over a clock signal interval of the clock signal (CL), whereby the coupling device is controlled, is trailing relative to the transmit synchronization mark (FX); and that an intermediate memory (ZS) is connected between the 2 end outputs of the function units (0 ... 3) and the coupling matrix (KM), which is controlled by the falling edges of the clock signal (CL). Coupling device according to claim 1, characterized in that the function units (¢ ... 3) form the time stages and the coupling matrix units (KM) form the space stages of the system. Coupling device according to claim 1 or 2, characterized in that a plurality of communication-technical structure groups are combined in structure racks, and are also coupled via supply structure groups (VL, transceiver elements). k. Coupling device according to one of Claims 1 to 3, characterized in that the transmission and reception lines (SL, EL) are arranged for one-way transmission within the framework of a structure group rack. Coupling device according to one of Claims 1 to 3, characterized in that a plurality of two pairs are used for connecting the structure group racks. installed in the direction of manifolds. ...... 82 0 2 1 35 --------------------------------- \