LU84165A1 - COUPLING FOR A DIGITAL SWITCHING SYSTEM - Google Patents

Description

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Coupling arrangement for a digital switching system

The invention relates to a coupling arrangement for a digital switching system, in particular a telecommunications switching system using the pulse code modulation method.

5 coupling arrangements for digital switching systems are known. These serve the simultaneous use of a number of facilities such. B. lines of telecommunications systems that forward digital signals, such as data and / or digitized voice information according to the pulse code 10 modulation method (PCM). In PCM switching technology, two types of switching are distinguished: the

Multiple times and the Eaumlagen. When switching in the time slot multiple, fixed time slots for sending and receiving information are assigned to a device for the duration of a connection within a periodically recurring time frame. In contrast, when switching in the multiple location, the device is assigned the time frame of one of several line pairs for the duration of the connection. Since the number of time slots 20 is limited within a time frame, the two network structures are combined with one another in the case of larger switching arrangements. B. a time-space-space-time structure is preferred for medium-sized digital switching systems.

25 The invention has for its object to provide a coupling arrangement of the structure mentioned, which ensures full accessibility and secure time-uncritical data transmission between time and space levels as well as economical production by reducing the variety of assemblies and a simple modular expansion for different sized switching systems.

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This object is achieved by the invention as set out in the characterizing part of the first claim. The subclaims show further advantageous developments of the invention.

5 Using a drawing consisting of three figures, the invention is illustrated using the example of a telecommunications *

Systems described in more detail below. In the drawing they show

Fig. 1 shows the block diagram of a subscriber set, the 10 Fig. 2 schematically shows the clock supply and

Fig. 3 shows the example of a connection between two sets.

The coupling arrangement is designed as a distributed coupling network. This means that the digital switching system Ί5 has no separate central one or multi-stage coupling arrangement. Any switching assembly, such as. B. the subscriber set, official sentence, elective sentence, etc., are all for data path switching, d. H. the 20 parts of the switching network required for the speech path and the control path of the connection establishment are spatially assigned. For this purpose, as shown in Fig. 1, several functional units, for. B. four subscriber line units 0 ... 3 to a «

Summary summarized and fed to a common coupling matrix KK. Each subscriber line unit consists of 25 a unit SLIC, which u. a. a two / four-wire conversion »which includes the feed, the Euf-, Ton-, fees pulse feed, a complex line simulation and the loop monitoring, filter FI and an analog-digital / digital-analog converter COD together. The converters CQD 30 form the time stages in the time-Eaum-Kaum-Zeit structure of the switching system.

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The spatial matrix of the system is represented by the coupling matrices EM. In the example shown, a coupling matrix KM is provided for four subscriber line units 0 ... 3. A coupling matrix KM "essentially 5 consists of an address memory ADS for the switching elements to be switched, a buffer ZS, a demultiplexer DMX as a coupling element in the transmission direction, a multiplexer KUX as a coupling element in the receiving direction, driver outputs TS and receiver stages ST, preferably Schmitt trigger .

10 With this arrangement, an optional link between the transmit outputs of the four digital-to-analog converters COD and eight uni is direct! onal en transmission lines SL and the four receive inputs with eight unidirectional receive lines EL. Within a module frame, 15 of the z. B. sixteen such described switching technology modules, the receive and transmit data paths are unidirectional, d. H. separately, as a collective line (BUS system, SL, EL). At the physical end of the module frame, the unidirectional lines with transmit and receive modules, so-called

Transceivers, to summarize, between the VL supply modules, the data paths are routed to the PCK line.

A decentralized microprocessor DKP is provided in each case for controlling the time slot multiple and the spatial position .25 diversity of a switching module. a. a single serial loading of the time slot information into the converter COD or a single switching of the required double points in the Baun stage to 3C causes the connection to be established.

The connection between a sending and a receiving sentence is in the big. 3 shown. The central clock supply is schematically in the Big. 2 indicated.

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The frequency taken from a quartz in a known manner is subdivided into a frequency divider FT into various time cycles which are in a fixed relationship to one another. Other blocks TE, SYN are used to generate the 5 PCM clock CL, the synchronization characters FE, FX and

Fixing their time allocation. For the sake of running time in the coupling arrangement, the receive synchronization symbol FE is delayed by a clock interval against the transmission synchronization symbol FX. The PCM clock CL 10 and the synchronization characters FE, FX are distributed in a star shape via driver SM to the module frames via the supply modules VL, which in turn pass on the characters in a BUS shape.

The PCM data path runs over unidirectional and bidirectional 15 lines. The VL supply modules are connected to the

Interfaces between the unidirectional and bidirectional lines. This results in a connection from a subscriber of the set H to a subscriber of the set M, as is shown schematically in FIG. 3.

From Fig. 1 it can be seen that an intermediate memory ZS is connected between the transmit outputs of the converter COD and the demultiplexer DMX of the coupling matrix KM. This buffer ZS, preferably a bistable flip-flop (D flip-flop), is controlled directly with the falling edge of the PCK clock CL. The falling edge lies in a time interval in which the converter COD applies the data bit to its transmit output. Since the buffer store ZS is only triggered again with the next falling edge of the PCK clock CL, the data bit 30 is present at the demultiplexer DMX for a sufficient time regardless of the tolerances of the converter COD. The extension is necessary to split the terms and their tolerances. \ m · · ~ 5 - to compensate the sending and receiving converter COD so that the receiving converter COD can take over the temporarily stored data bit with the next falling clock edge. At the same time, the Koppel-5 matrix KM takes over the next data bit of the sending converter COD as previously described.

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Claims (5)

1. Coupling arrangement for a digital switching system, in particular telecommunications switching system, using the pulse code modulation method (PCM), 5 with a mixed time-space-space-time structure, thereby. characterized in that each switching technology construction group required for switching the data paths. parts of the coupling network are spatially assigned. are by connecting several puncture units (0 ... 3) to 10 a coupling matrix (KM), which allows a couple of switching through of the coupling points of the spatial stages of equally addressing transmission and reception lines, elements (COD, FI, SLIC) of the functional units ( 0 ... 3) and the coupling matrix (KM) are controlled by a permanently assigned 13 decentralized microprocessor (DMP) that the receive synchronization symbol (FR) by a clock interval of the clock controlling the coupling arrangement (time delay compensation on the digital data paths ( GL) is lagging behind the send synchronization character (Fl) 20 and that between the send outputs of the functional units (0 ... 3) and the coupling matrix (KM) an intermediate memory (ZS) is connected, which is due to the falling edge of the clock (CL) is controlled. 2. Coupling arrangement according to claim 1, characterized in that the functional units (0 ... 3) represent the time levels and the coupling matrices (KM) the spatial levels of the system · '. »’ • «» - 7 - 3 «coupling arrangement according to claim 1 and 2, characterized in that several mediating assemblies are combined in assembly frames and 5 are coupled via supply unit groups (VL, transceiver modules). . 4. Coupling arrangement according to claim 1 to 3t characterized in that the transmission and reception lines (SL, EL) uni directly within a module frame! are managed online. X / ^ 10 5- coupling arrangement according to claim 1 to 3 »characterized in that a plurality of bidirectional busbars are provided for connecting the module. / '' ..... 1 i i | • · ·