DE2916413C2 - - Google Patents

Description

The invention relates to a circuit arrangement for Telecommunications systems, in particular telephone switching plants, with control devices for in larger An number of switching elements provided for control arranged in a coordinate system and at intersection score from coordinated control lines gen individually connected to this, one on the one hand with a control line a plurality of Switching elements is connected and on the other hand the the switching elements are interconnected Control lines are decoupled from one another, and their Identity when controlled by the respective Combination of certain control lines clearly is determined  and with three groups of control lines that form a three-coordinate form nate system, in which the switching elements each three of Control serving connections, and in which the three Connections of a switching element with one control line each that of the three groups are connected, whereby the identity ei nes to be controlled switching element by the individual the three control lines belonging to different groups.

Circuit arrangements of this type are by the specialist  book "Computer-controlled switching systems" by Peter R. Gerke (Springer-Verlag Berlin / Heidelberg / New York 1972) already known and under the keyword "Signal distribution" shown and be detailed wrote. Hereafter it is known for control of switching elements, e.g. B. electromagnetic relays, the principle of the contact pyramid or that of a person tax matrix (page 131 ff). Besides, will also noted that these two drive principles can be used in combination can. As is well known, it is in a control matrix required that over those provided in the matrix Switching elements interconnected control lines decouple the matrix from each other. This is not just to consider the circuitry effort, but also the problem of susceptibility to failure as a result a loss of lockability of one of the Ent coupling diodes. In this context, however, is not only the possibility of such an occurrence In the event of an error, acts z. B. DE-PS 11 62 883 the problem that out there are limits to the size of tax matrices are. This results from the fact that the decoupling diodes in the reverse direction a finally great resistance have, and that by summing a larger number through the decoupling diodes in the reverse direction blocking currents malfunction in such a Tax matrix can occur.

In DE-PS 17 62 055 in connection with the Bil extension of so-called submatrices to save Mar  Kierkontakte indicated on the matrix control lines. At the same time, this means a saving on control lines This saving is relative through education extensive matrix arrangements possible. This one however, as mentioned above, there are also hints limits to the decoupling problems.

The object of the invention is to avoid Contact pyramids and the time involved for the control processes the effort on control lines and marking contacts (or corresponding non-mechanical switching means) or the same Effort on control lines is the number of over them controllable switching elements to increase.

According to the invention, this object is achieved by  that the switching elements each have a three-pole semiconductor switch, especially a transistor, and one as an electromagnetic sches relay trained two-pole controllable switch point, and that ent the control path of the semiconductor switch speaking two terminals, each with a control line from two control line groups and the third terminal of the Semiconductor switch over which its current path runs, with egg Nem is connected to the first winding terminal of the relay, the second winding connection with a control line of the third Control line group is connected.

The invention ensures that the number of control lines and marker switches can be significantly reduced. This is illustrated by a numerical example. Is it z. B. by a number of 4096 switching elements to be controlled via control lines, 64 row lines and 64 column lines, ie a total of 128 control lines, are required in conventional matrix arrangements. In contrast, when using the invention, three groups of 16 control lines each, that is to say only 48 control lines in total, are required.

In the drawing is an embodiment of the He with only essentially to their understanding load-bearing components.

The drawing shows a three-dimensional arrangement of control lines for controlling a larger number of switching elements 1 k 11 to mkkn . This three-dimensional arrangement has several levels K 1 , K 2,. . . and Km , in each of which a group of switching elements, for. B. 1 k 11 to 1 kkn , is included. These levels are therefore to be understood as arranged one above the other. The control lines x 1 to xk are thus routed to each of the different levels. From the Steuerleitun gene y 1 to ym each leads only to one of the levels, for. B. the control line y 1 in the level K 1 . This control line leads to all crossing points on this level. The control lines z 1 through zn penetrate the multiple levels, as it were, if one assumes that the level K 2 is arranged above the level K 1 , and if the other levels are arranged in layers above it, so that the level Km is the top level . Within each of these levels, the control line x 1 leads to the switching elements of a first line. The same applies to the control lines x 2 to xk . Control line y 1 leads to all switching elements of level K 1 . The same applies to the control lines y 2 to ym and the other levels K 2 to Km . The control line z 1 leads to all switching elements of a first column in each of the levels. This corresponds to the control lines z 2 to zn and the switching elements in the other columns of the different levels.

The control lines x 1 to zn are therefore assigned to three groups x, y and z of control lines. Each of these group of control lines is brought up to a control device, not shown. To control a switching element, one control line is activated in each of the three groups of control lines. How this happens and how the control of a switching element electrically influences it is described in more detail below. - The control devices can be expediently designed as counting chains, so three counting chains are required for the switching elements partially shown in the drawing. To control a switching element, three setting information is issued in a manner known per se from a central control device to the control devices mentioned, in each case one piece of information to one of the control devices. Each of this information can e.g. B. from a pulse series or from a coded, for. B. binary coded, signal exist. The three control devices can receive their information via a common information multiple. In this case, the three pieces of information must be delivered to the three control devices in succession. One after the other, one of the three control devices for receiving the information intended for each of them is controlled ready to receive. This is done in a known manner.

The identity of each switching element thus results from the respective combination of specific control lines, namely one control line for each of the three groups of control lines. The control lines form a three-coordinate system. Each of the switching elements has - as is shown in detail for the switching element 1 k 22 - three inputs a, b and c . Each of these three inputs is connected to a control line of each of the three groups of control lines. The identity of a switching element to be controlled, e.g. B. 1 k 22 , is determined by the three control lines x 2 , y 1 and z 2 belonging to the three different groups x, y and z of control lines.

The switching elements mentioned can be designed in various ways. So it is z. B. possible to construct each of the switching elements as a triple coincidence circuit, which has the effect of a flip-flop. As shown in the drawing, the switching elements can each be designed so that they each have a three-pole semiconductor switch and a two-pole controllable switch. The three-pole semiconductor switch can be a transistor, a thyristor or - as shown - a triac T. There are also many versatile implementation options for the two-pole controllable switch. In the illustrated embodiment, the provided per switching element bipolar controllable switch is an electromagnetic relay R. The electromagnetic relays provided in the switching elements can be the coupling relays in relay coupling multiples, that is to say relays which not only form circuits with regard to their control circuits, but also with regard to the circuits to be switched by means of their contacts, in the form of arrangements having a coordinate structure. So z. B. the total unit of the switching elements of level K 1 often belong to a relay coupling. The switching elements provided in the several levels would then form multiple relay contacts with their coupling relay contacts per level. Deviating from this, however, it is also possible to use the relays provided in the switching elements as subscriber relays in subscriber line circuits. The relays mentioned can be bistable and / or polarized relays.

To control one of these relays, one of the control lines of the three groups x, y and z of control lines is activated, as has already been stated. Should z. B. the switching element 1 k 22 can be controlled with the relay R on, then the control line x 2 plus potential and the control line z 2 minus potential is switched on. Furthermore, a potential suitable for controlling the triac T is connected to the control line y 1 . By this, the triac T via the input b in a manner known per se permeable controls for the voltage applied to the inputs a and c . As a result, the relay R receives an input voltage at its two winding ends, through which it is connected, for. B. is excited. As a result, its relay contacts move from the rest position to the working position. If this relay is a bistable polarized relay, its contacts remain in the working position even after the potentials mentioned have been switched off. The relay R is thus brought into its working position by briefly connecting the potentials mentioned to the control lines x 2 , y 1 and z 2 . Then these potentials are switched off again. In the same way, corresponding bi-stable polarized relays can be activated in any other switching elements. If the contacts of a relay, which have been brought into the working position in the manner described, are brought back into the rest position, then a voltage with the opposite polarity is switched on to the two control lines in question in groups x and z . If it is again the relay R in the switching element 1 k 22 , this voltage, which serves to reset the relay, is applied to the control lines x 2 and z 2 . Furthermore, a potential suitable for controlling the triac T is applied to the control line y 1 . - In this description the mode of operation of Triacs is assumed to be known, as is the selection of the potentials suitable for controlling Triacs.

The triac T has two main electrodes over which its current path runs. One main electrode is connected to the input a of the switching element 1 k 22 . The other main electrode is connected to one of the two winding ends of the relay R. In addition, the triac T has a control path which is connected to the input b of the switching element 1 k 22 . It has already been pointed out that the current path of the triac T is bidirectional in a manner known per se.

Claims (6)

1.Circuit arrangement for telecommunications systems, in particular telephone switching systems, with control devices for switching elements provided in large numbers, which are arranged for control in a coordinate system and are individually connected to these at crossing points of control lines designed in a coordinated manner, with on the one hand a plurality of switching elements with one control line each is connected and, on the other hand, the control lines connected to one another via the switching elements are decoupled from one another, and their identity is clearly defined in the case of activation by the respective combination of specific control lines, and with three groups of control lines which form a three-coordinate system in which the switching elements each have three connections serving for the control, and in which the three connections of a switching element are connected to a control line of each of the three groups, whereby the identity of a nzusteuerenden switching element is determined by the control lines belonging individually to the three different groups, characterized in that the switching elements each have a three-pole semiconductor switch, in particular a transistor, and a two-pole controllable switch designed as an electromagnetic relay, and that the control path of the Semiconductor switch speaking two terminals, each with a control line from two control line groups and the third terminal of the semi-conductor switch, over which its current path runs, is connected to a first winding terminal of the relay, the second winding terminal is connected to a control line of the third Steuerlei line group. 2. Circuit arrangement according to claim 1, characterized characterized in that the switching elements each have a three-pole semiconductor switch, in particular a transistor, and a two-pole controllable Switches, especially an electromagnetic relay, and that the control path of the semiconductor switch corresponding two terminals one control line each from two control line groups and the third terminal of the semiconductor switch,  over which its current path runs, with a first Connection of the two-pole controllable switch ver is bound, the second connection with a tax line of the third control line group is connected. 3. Circuit arrangement according to claim 2, characterized characterized in that the three-pole Semiconductor switch both in terms of its control path and its current path bidirectional and is designed in particular as a thyristor, and that the electromagnetic relay as a polarized relay, especially as a polarized bistable relay is formed. 4. Circuit arrangement according to claim 2, characterized characterized that the relay coupling relays in relay coupling multiples of in particular more tiered switching fields are. 5. Circuit arrangement according to claim 2, characterized characterized that the relays individually Subscriber line circuits are assigned. 6. Circuit arrangement according to claim 2, characterized characterized in that the semiconductor scarf ter a the tax linked through it lines of the different groups from each other have a coupling effect.