DE1817625B2 - Circuit arrangement for telecommunications, in particular telephone exchange systems, for searching, dialing and switching through connection paths in a multi-level switching network - Google Patents

Description

The invention relates to a circuit arrangement for telecommunications, in particular telephone switching systems, for searching, dialing and switching through Connection paths in a multi-stage switching network, which several are connected to one another by intermediate lines contains connected switching stages, each with a number of matrix switches with for each coupling point separate coupling relays are provided, with one winding of each coupling relay in series with one Decoupling rectifier inserted in a marker wire is switched on, which is on the output side of the crosspoint to the control wire of the line connected there and to one on the input side of the coupling point Input marker wire is connected, which is connected to a dialing device.

According to a known method (British Patent 7 39 905) for searching and selecting Connection paths in a multi-stage switching network are output as a marker signal fed, which is fan-like through the switching matrix via all possible free connection routes to the Inputs of the switching matrix and there inputs or matrix switches marked, from which or via which one or more: free connection paths to the marked switching matrix output are possible. In a known arrangement (French patent specification 14 54 234) for carrying out this method is any Input marker wire via a controllable, electronic switch to the control wire of the same Input like the input marker wire connected Intermediate line connected. In this circuit arrangement, after selecting a Coupling field input by suitable control of the controllable electronic switch reduces the marking signal transmission in such a way that the marking signal only is still being transmitted via a connection path. The remaining marking signal circuit contains the windings of the coupling relays in the connection path in series, which by increasing the marking current excites the coupling relays and the connection path

be switched through. This circuit arrangement has the disadvantage that the marker signal fed to the switching matrix output has a variable Number of paths branched, making the marking signal difficult to detect at the coupling matrix inputs is, and further that the leakage current of the controllable, electronic switches accumulate at the coupling network inputs and obscure the marking signal there can. It is known per se (British patent specification 7 79 236) to apply the marking signal in each switching stage regenerate, so that the detection of the marker signal at the switching matrix inputs with considerably greater Reliability can be done. However, it is not known to send the marking signal via a signal circuit transferred after choosing a free The connection path is used to energize the coupling relays can.

The invention is based on the object of creating a circuit arrangement of the type mentioned,

in using the principle of regeneration of the marker signal to search for and select one Connection path, the same switching means are used as for switching through the connection path.

The circuit arrangement according to the invention is characterized in that each intermediate line one connected to a voltage source in the operating state, to a high impedance and to a Low impedance adjustable marking circuit is connected, which in the operating state a marking signal ι ο with a low or high current level when searching for or switching through a connection path supplies to the intermediate line for marking an output of the preceding switching stage

The invention is explained in more detail with reference to the drawing. It shows

F i g. 1 the general structure of a 4-stage switching network,

F i g. 2 shows a first embodiment of a circuit arrangement according to the invention for the switching matrix according to FIG Fig. 1,

3 shows the general structure of a 3-stage switching network,

4 shows a second embodiment of a circuit arrangement according to the invention for the switching matrix according to FIG. 3.

Referring to FIG. 1, the general structure of a simple 4-stage switching network for use in a telephone exchange is first described. The switching network contains four switching stages A, B, C and D connected to one another by intermediate lines. The switching stage A contains the matrix switches A / to Ap, which are each provided with m inputs and q outputs. The coupling stage B contains the matrix switches Bl to Bq, which are each provided with ρ inputs and r outputs. The coupling stage Cent contains the matrix switches Cl to Cr, which are each provided with q inputs and s outputs, and the coupling stage D contains the matrix switches Dl to Ds, which are each provided with r inputs and π outputs. Each matrix switch is shown in FIG. 1 represented by a block this is to be understood in such a way that a coupling point is formed between each input and each output in each block. In Fig. 1, only the first, the second and the last matrix switch of each coupling stage are indicated, and the intermediate lines are also only partially shown. The inputs of the switching network are formed by the inputs of matrix switch Al to Ap, and they are in g F i. 1 labeled Eil to Epm. The outputs of the switching network are formed by the outputs of the matrix switches Dl to Ds, and they are designated in the figure with FIl to Fsn . The intermediate lines between each switching stage and the next switching stage are arranged systematically. The output (1) of the matrix switch Al is connected to the input (1) of the matrix switch B1 via an intermediate line (ABU) and the output (2) of the matrix switch Al is connected to the input (1) of the matrix switch B 2 etc. via an intermediate line. In general, the output (j), (j = 1, (> o 2 ... q) of the matrix switch Ai (i = 1, 2, ... p) is connected to the input (i) of the matrix switch via an intermediate line ABji Bj . The coupling stage B is connected to the coupling stage C and the coupling stage C is connected to the coupling stage D in a similar manner.

In the manner described, several possible connection paths are formed between each switching matrix input and each switching matrix output. Each connection path runs over a coupling point of each coupling stage and over an intermediate line between each coupling stage and the next following coupling stage. In Fig. 1 are in a possible connection path between the switching matrix input EU and the switching matrix output FIn lying intermediate lines ABU, BCRI and CD 2r by a thick line indicated This passageway extends further through the coupling point between the input (1) and the output (1) of the matrix switch Al , the coupling point between the input (1) and the output (r) of the matrix switch Bl, the coupling point between the input (1) and the output (2) of the matrix switch Cr and the coupling point between the input (r) and the output (n ) of the matrix switch D 2. The connections via the crosspoints are shown in FIG. 1 indicated by dashed lines. It should be noted that each in FIG. 1 intermediate line indicated by a line actually contains several wires. In a switching network for speech connections, which is chosen here as an example, these are the speech wires (a, b) and a control wire (c). Accordingly, each input and each output of a matrix switch contains three connection points. In addition, each input has a fourth connection point for connecting an input marker wire (d).

F i g. 2 shows in detail the in FIG. 1, the connecting path between the coupling field input EU and the coupling field output F2n, highlighted by a strong line. The matrix switches have separate coupling relays per coupling point, each coupling point relay being provided with only one winding, which is used both to switch on and to hold the relay. Four wires run above each crosspoint, ie an a-, b- and o-wire and a marker wire. The oAder and the marker wire are combined with each other at the exit of the coupling point. The winding of the coupling relay is switched on in the common part of the c- wire and the marker wire. The a, b and o wires contain coupling contacts that normally interrupt the wires, and the marker wire contains a decoupling rectifier. The winding Kahi the coupling relay is the cross point matrix switch Al shown in Figure 2. in the common part of the oAder running between input (1) and output (1) and the marker wire switched on, while in the a-, b- and c-wire the coupling contacts 1 era 111, 2ka \\\, and 3AaIIl are switched on and the marking wire contains the decoupling rectifier Ga 111.

Of the switching matrix input £ 11 of the connection path extends via the switching contacts 1 to 3ka 111 of the matrix switch Al via the intermediate line ABU, the coupling contacts 1 to 3Aröllr of the matrix switch B 1, the intermediate line BCr 1, the coupling contacts 1 to 3kort2 of the matrix switch Cr, the intermediate line CD 2r and the coupling contacts 1 to 3kd2rn of the matrix switch D 2 to the coupling network output F2n. The connection path is shown in the rest position, which is indicated by the open state of all coupling contacts.

Several sets of coupling contacts are connected to each matrix switch input and output, d. H. the same number of records as the number of outputs accessible from the input or such as the number of inputs accessible from the output. These input and output

Specialist connections are shown in FIG. 2 indicated by multiple characters, with the numbers in brackets indicating the number of sentences. There are z. B. connected to the input multiple connection of the input (1) of the matrix switch Al q sets that correspond to the q outputs of the matrix switch. In the coupling step A the Eingangsmarkieradern of the inputs (1) are connected together and the input selector WE to the output (1) while the Eingangsmarkieradern of the inputs (2) connected to one another and the selector WE are connected to the output (2), etc. In the coupling stage B , the input marking wires of the inputs (1) of the matrix switches B 1 to Bq are connected to each other and to the output (1) of the selector WA and the input marking wheels of the inputs (2) are connected to the output (2) of the selector WB , etc. In a similar way, the input marking wires of the matrix switches Ci to Cr are connected to the outputs of the selector WB and in the same way the input marking wires of the matrix switches D 1 to Ds are connected to the outputs of the selector WC . The c> wires of the lines connected to the outputs of the matrix switches D 1 to Ds are connected to separate outputs (1,1) to (s, n) of the output selector WF.

To initiate the search for a free connection path, a central control device or a marker M connects all input marker wires of switching stages B, C and D via lines 101, 102 and 103 to earth. Via the line 100 is a signal indicating the address of the desired coupling field output, in this case the switching matrix output F2n, the output selector WF supplied to the selector WF adjusts to the desired output and the wire leads of the switching matrix output F2n a search signal for causing the output is marked. The search signal consists of a positive DC voltage which is taken from a source of high internal resistance, so that the search signal can be briefly referred to as a high-impedance signal. The search signal source consists of the high-resistance voltage divider 104 connected between the positive pole (+) of the supply voltage and earth.

The matrix switch D 2 is assigned a separate OR gate PXD2, the inputs (1) to (n) of which are connected to the c-wires of the lines connected to the outputs of the matrix switch. The input (r) of the matrix switch D 2 is assigned an AND gate P2CD2r with a switching transistor TCD2r, its input (1) to the output of the OR gate PID2 and its input (2) to the input marker wire of the input (r) of the matrix switch D 2 are connected. The emitter of the transistor TCD2r is connected to the high-resistance voltage divider 105 and the collector is connected to the c wire of the intermediate line CD 2r connected to the input (r) of the matrix switch D 2. In general, each input j U = 1, ... r) is assigned an AND gate P2CD2J with a connected switching transistor TCD2J , which are connected in the same way as the AND gate P2CD2r and the transistor TCD2r . FIG. 2 also shows the AND gate P2CD21 with connected transistor TCD 21, which are assigned to input (1), and the AND gate P2CD22 with connected transistor TCD 22, which are assigned to input (2). The search signal of the marked switching matrix output F2n reaches the inputs (1) of the AND gates PCD 21 to PCD 2r via the OR gate P1D2. An AND gate is current-permeable when the input (2) is grounded, and supplies a control signal corresponding to the search signal, which makes the switching transistor conductive. If z. If, for example, the input marker wire of the input (r, is grounded, the input (2) of the AND gate P2CD2r is connected to ground, the search signal making the transistor TCD 2r conductive via the AND gate P2CD2r. As a result, a high-resistance voltage divider 105 taken from, regenerated search signal of the c-wire connected to the input (r) of the matrix switch D 2 intermediate line CD2R supplied generally, through the ground connection of the Eingangsmarkierader of receipt O) U = 1, ·· ■ r) a regenerated search signal of the Input (X) connected intermediate line. The marker M temporarily connects all input marker wires of the coupling stage D to earth, whereby a regenerated search signal leads to all intermediate lines that are connected to the inputs of the matrix switch D 2. A link is only actually marked by the search signal when it is free. When the intermediate line is occupied, as will be described further below, the c-wire between earth and the negative supply voltage is switched on via a relatively low series resistance practically does not change when the search signal is added. The regenerated search signal is transmitted to the coupling stage C via the free intermediate lines connected to the inputs of the matrix switch D 2 and marked by the search signal. In this coupling stage, the outputs of the matrix switch to which the marked intermediate lines are connected are marked by the search signal.

At each matrix switch of the switching stage C, the search signal is regenerated and transmitted through free intermediate lines in the direction of the switching network inputs in the same way and by the same means as with the matrix switch D 2. If at least one of the outputs of the matrix switch Cr is marked, the search signal goes through the OR -Tor PLCR and controlled before the marker M on the Eingangsmarkieradei, current-permeable and gates P2BCr \ to P2BCrq transistors TBCR and TBCrq becomes conductive Consequently, the high resistance Spannungsteilei 106 taken from regenerated search signal supplied to all intermediate lines connected to the inputs of the matrix switch Cr and Transfer the marked free intermediate lines to the coupling stage L. The same effect results with the other matrix switches of the coupling stage C. If at least one of the outputs of the matrix switch B1 is marked, then the search signal via the OR gate Plßl and that from the marker
electrically controlled AND gates P2ABW bii Ρ2ΛΒ Ip the transistors TABU to TAB Ip conductive. A regenerated search signal taken from the high-resistance voltage divider 107 is then fed to all intermediate lines connected to the inputs of the matrix switch Bi and transmitted to the coupling stage / via the marked free intermediate lines.

In the manner described, the search signal spreads from the switching matrix output FIn over there; Coupling field fan-shaped and then follows all possible free connection paths to the coupling

field inputs. The first phase of choosing a free connection path consists of selecting a matrix switch of coupling stage A. A matrix switch of coupling stage A is considered for the connection path if at least one of the outputs is marked. The matrix switch A 1 is assigned an OR gate P3A X whose inputs (1) to (q) are connected to the c-wires of the outputs of the matrix switch AX and whose output is connected to a separate input (1) of the selector WA . In general, each matrix switch Aj (J = \, ... p) is assigned an OR gate P3Aj , which is switched in the same way as the OR gate P3A 1. FIG. 2 also shows the OR assigned to the matrix switch / 4 2 -tor P3A2, whose output is connected to the input (2) of the selector WA, and the matrix switch Ap associated OR gate P3Ap whose output is connected to the input (p) of the selector WA. If at least one of the outputs of the matrix switch Al is selected, the search signal is the selected output via the OR gate P3A X to the input (1) is supplied to the selector WA, and this input is thus marked. In the same way, the corresponding input of the selector WA is marked for every other matrix switch of the coupling stage A, of which at least one of the outputs is marked. The selector WA selects a marked input in free or controlled selection and connects the corresponding output to earth. It is assumed that, inter alia, at least one of the outputs of the matrix switch AI is marked and, inter alia, the input (t) of the selector WB is marked accordingly. Further, assume that the voter WA selects the input (1) and, accordingly, connects the output (1) with soil The marker M lifts the ground connection of the Eingangsmarkierader the switching stage B, whereby only the to the output (1) of the selector WA connected input markers remain grounded. These are the marking wires of the inputs (1) of the matrix switches BX to Bq, ie the inputs to which the intermediate lines originating from the matrix switch AX are connected. For each matrix switch of the coupling stage B, of which at least one of the outputs is marked, a regenerated search signal is then only fed to the intermediate line coming from the matrix switch AX. In this way it is clearly established that the connection path runs through the matrix switch A 1.

The second phase of selecting a connection path consists in selecting a matrix switch of the switching stage B. As mentioned, for each matrix switch of the switching stage B, of which at least one of the outputs is marked, only the intermediate line coming from the selected matrix switch A 1 receives a regenerated search signal . This link is actually marked by the search signal when the link is free. A matrix switch of the coupling stage B can therefore be used for the connection path if one of the intermediate lines connected to the inputs is marked. bo

The matrix switch BX is assigned an OR gate P3B \ whose inputs (1) to (p) are connected to the c-wires of the intermediate lines that are connected to the inputs of the matrix switch, while the output of the gate is connected to a special input (1 ) of the selector WB is connected. In general, an OR gate P3Bj is assigned to each matrix switch Bj (J - 1, ... q) in the same way is switched like the OR gate P3Bi. 2 also shows the OR gate P3D2, which is assigned to the matrix switch B 2 and whose output is connected to the input (2) of the selector WB , and the OR gate P3Bq, which is assigned to the matrix switch Bq and its output the input (q) of the selector WB is connected. If one of the intermediate lines that are connected to the inputs of the matrix switch B 1 is marked, the search signal of the marked intermediate line is fed to the input (1) of the selector WB via the OR gate P3B \, whereby this input is marked. In a similar manner, the corresponding input of the selector WB is marked for every other matrix switch of the coupling stage B if one of the intermediate lines which are connected to the inputs of the matrix switch is marked. After setting of the selector WA, a signal is supplied to the selector WB via a line 108, which then selects a selected output and the corresponding output connected to ground connects It is assumed that, inter alia, the intermediate line ABW that to the input (1) of the Matrix switch Bi is connected, is marked, with the input (1) of the selector WB being marked accordingly. It is also assumed that the selector WB selects the input (1) and thus connects the output (1) to earth. The marker M interrupts the earth connection of the input marker wires of the coupling stage C, so that only the input marker wires connected to the output (1) of the selector WB remain earthed. The output (1) is connected to the input marker wire of the inputs (1) of the matrix switches CX to Cr; ie connected to the inputs to which the intermediate lines coming from the matrix switch BX are connected. At each matrix switch of the coupling stage C, of which at least one of the outputs is marked, a regenerated search signal is then only fed to the intermediate line coming from the matrix switch BX. In this way it is determined that the connection path will run through the matrix switch BX. In the coupling stage B , the matrix switch BX is then still the only one from which at least one of the outputs is marked. Thus, all from the matrix switcher Al upcoming intermediate lines only marks the device connected to the matrix switch BX intermediate line ABxx. As a result, it is clearly determined that the connection path is via the link AB XX.

The third phase of selecting a connection path consists of selecting a matrix switch for coupling stage C. This is done in exactly the same way as selecting a matrix switch for coupling stage B. The matrix switch Crist is assigned an OR gate P 3Cr, whose inputs (1) to (q ) are connected to the or the intermediate lines that are connected to the matrix switch Cr, while the output of the gate is connected to a special input (r) of the selector WC. In general, an OR gate P3Cj is assigned to each matrix switch Q '£ / - 1, ... r ^, which is connected in the same way as the OR gate PZCr. 2 also shows the OR gate P3CX, which is assigned to the matrix switch CX and whose output is connected to the input (1) of the selector WC , and the OR gate P3C2, which is assigned to the matrix switch Cl and whose output is connected to the Input (2) of the WC selector is connected. After the selector WB has been set , a signal is fed to the selector WC via a line 109, the

then selects a marked output and grounds the corresponding output. It is assumed that, inter alia, the intermediate line BCrI, which is connected to the input (1) of the matrix switch Cr , is marked and accordingly, inter alia, the input (r) of the selector WC is marked. It is also assumed that the selector WC selects the input (r) and grounds the output (r) The marker M interrupts the earth connection of the input marker wires of the coupling stage D, whereby only the input marker wires that are connected to the output (r) of the selector WC stay grounded. The output (r) is connected to the input marker wire of the inputs (r) of the matrix switches D 1 to Ds, ie the inputs to which the intermediate lines originating from the matrix switch Cr are connected. The matrix switch D 2 of the coupling stage D, with which the selected switching matrix output F2n is connected is a regenerated search signal now only coming from the matrix switch Cr intermediate line CD2R supplied Then that the communication path through the matrix switch, Cr and the intermediate line CD is run 2r is fixed, . In the coupling stage C, the matrix switch Cr is the only one from which at least one of the outputs is marked. It follows that the device connected to the matrix switch Cr intermediate line BCRI is marked by all originating from the matrix switch Bi intermediate lines only. This clearly establishes that the connection path will run via the link BCrI. The connection route is therefore completely fixed.

Before the connection path is switched through, the marker M leads a signal, which specifies the address of the desired switching matrix output ElI , via the line 110 to the input selector WE , which then adjusts itself to the desired switching matrix input and connects its input marker wire to ground. After the selector WC has been set, a signal is fed to the marker M via a line 111, which then connects the base of the switching transistors TFoo, TCDoo, TBCoo and TABoo to earth via a line 112. The switching transistors thereby become conductive, so that the low-resistance voltage dividers 113, 114, 115, 116 are each connected in parallel to the high-resistance voltage dividers 104, 105, 106 and 107, respectively. The high-resistance search signal, which marks the switching matrix output F2n and the intermediate lines CD2r, BCrI and ABU , is converted into a low-resistance switching signal by connecting the low-resistance voltage dividers in parallel with the high-resistance voltage dividers. In the manner described, separate excitation circuits are formed for the windings KD 2rn, KCrI 2, KBlIr and KA 111 of the coupling relays in the selected connection path, which run as follows:

1. Voltage divider 113, transistor TFoo, selector WF, coupling network output F2n, winding KD2rn, rectifier GD2m, input marker wire d of input (r), output ftf of selector WQ earth;

2. Voltage divider 114, transistor TDCoo, transistor TCD2r, intermediate line CDIr, output (2) of matrix switch Cr, winding KCrI 2, rectifier GCr 12, input marker wire c / of input (2), output (1) of selector WB, earth;

3. Voltage divider 115, transistor TBCoo, transistor TBCrI, intermediate line BCrI, output (r) of matrix switch Bi, winding KBHr, rectifier GBHr, input marker wire d of input (1), output (1) of selector WA, earth;
4. Voltage divider 116, transistor TABoo, transistor TABU, intermediate line ABU, output (1) of matrix switch A 1, winding KA 111, rectifier GA 111, input marker wire ei of network input E i 1 output (1) of selector WE, earth.
After the high-resistance search signal has been converted into the low-resistance switching signal, the coupling relays are in their separate excitation circuits

ίο switched on at the same time As a result of the closing of the coupling contacts, the connection path between the network input EH and the network output F2n is switched through. Between the c-core of each intermediate line and the c-core of the input of the

A rectifier is provided for the crossover switch to which the intermediate line is connected. It is Z. B. switched on between the c-wire of the intermediate line CD 2r and the c-wire of the input (r) of the matrix switch D2 of the rectifier GCDIr. This rectifier is used to decouple the excitation circuit (2) from the excitation circuit (1) after the coupling contact 3kd2rn is closed. F i g. 2 also shows the rectifier GABH provided between the intermediate line ABU and the input (1) of the matrix switch Bi in the c wire and the rectifier GBCr 1 provided between the intermediate line BCr 1 and the input (1) of the matrix switch Cr in the ii wire These rectifiers serve the same purpose.

The c-wire of the coupling network output F2n is connected in series with the connection indicated by dashed lines to earth via a rectifier G2n , in which connection devices for monitoring the connection path and the like can be present.

Furthermore, the c-wire of the coupling field input £ 11 is connected to the negative pole of the supply voltage (-) via a connection indicated by dashed lines, which can contain the winding of an isolating relay and the like. After the coupling contacts 3ka 111 3jH> llr, 3Jtcrl2 and 3kd2rn have been closed, a series holding circuit is then formed for the windings KAiU, KBUr, KCr 12 and KD2rn, in which the coupling relays are held after the switching signal has been switched off. The resistance of the high-impedance voltage divider is chosen so large compared to the total series resistance of the series holding circuit that the voltage of the series holding circuit is selected so high that the voltage of the series holding circuit is not noticeably influenced if the search signal is fed to an existing connection path when a connection path is selected.

3 shows the assembly of a simple three-stage switching network, which provides only one possible connection path between each switching network input and each switching network output. The in F i g. 3, the connection path between the switching matrix input £ 111 and the switching matrix output Fiqn , highlighted by a strong line, is shown in detail in FIG. 4 used. In the circuit arrangement according to FIG. 4, compared to the circuit arrangement according to FIG. 2 different simplifications provided. These simplifications are due to the existence of only one possible connection path between each switching matrix input and every switching matrix output.

to return. The connection diagram of the intermediate lines according to FIG. 3 is based on the description of FIG. 1 easily understandable. As shown in FIG. 4 is indicated, the input marking wires of the matrix switches AXX to Asp are multiple switched and connected to the outputs (1) to (m) of the input selector 2WE. The input marking wires of the matrix switches BIi to Bsq are switched multiple times and are connected to the outputs (1) to (p) of the selector HT; the input marking wires of the matrix switches CIl to Crq are multiple switched and connected to the outputs (1) to (s) of the selector WH . The c-cores of the coupling network outputs Fill to Frqn are connected to separate outputs (1,1,1) to (r, q, n) of the output selector 2 IVF.

The c-wire of the intermediate line BCq 11 connected to the input (1) of the matrix switch C \ q is connected to the collector of a separate transistor TBCq 11, the base of which is connected to the input marker wire of the input (1). In the same way, a transistor is attached for every other intermediate line connected to an input of the matrix switch CXq. The emitters of these transistors are connected to the collector of a transistor TBCq 10 assigned to the matrix switch C \ q , the base of which is connected to a separate output (1, </ j of a selector 2IVC. The emitter of transistor TBCg 10 is connected to one between the positive Pole (+) of the supply voltage and earth connected high-impedance voltage divider 200. In the same way, a transistor for each intermediate line connected to an input and one transistor per matrix switch is provided for each additional matrix switch of the coupling stage C. In the coupling stage B , the oAder is provided connected to the input (1) of the matrix switch B Xq intermediate line ABXqX connected to the collector of a separate transistor TABXqX whose base is connected to the Eingangsmarkierader of the input (1). in the same manner of the matrix switch BXq is connected to each other to an input Intermediate line a transistor attached. The Em Itter of these transistors are connected to the collector of a transistor TABXqO assigned to the matrix switch BXq , the base of which is connected to a separate input (1, q) of a selector 2WB . The emitter of the transistor TAB XqC is connected to a high-resistance voltage divider 201. In every other matrix switch of the coupling stage B , one transistor is provided in the same way for each intermediate line connected to an input and one transistor per matrix switch.

Only one connection path is possible between the switching matrix input £ 111 and the switching matrix output FXqn , namely that in FIG. 4 shown. If a connection is to be established between the switching matrix input EHl and the switching matrix output FXqn , it is first checked whether the connection path is free. The selector IVH is set to the output (1) and connects the input marker wire of the inputs (1) of the matrix switches CXX to Crq with ground, ie the inputs to which the intermediate lines coming from the group of matrix switches ßll to BXq are connected. The selector 2WC is set to the output (1, q) and then connects the base of the transistor TBCq 10 associated with the matrix switch CXq to ground. As a result, the transistors TBCq 10 and TBCqXX become conductive in series, whereby a search signal taken from the voltage divider 200 is fed to the intermediate line BCqXX . The selector WT is set to the output (1) and then connects the input marking wire of the inputs (1) of the matrix switches BX 1 to Bsq to earth, ie the inputs to which the matrix switch AjX (J = \, 2, .. .s) originating intermediate lines are connected. The selector 2WB is set to the output (1, (1, q) and connects the base of the transistor TABXqO assigned to the matrix switch 81 q to ground. As a result, the transistors TABXqo and TABXqX become conductive in series, whereby a search signal of the intermediate line AB \ qX is fed.

The intermediate lines between the switching stages B and C are connected to the inputs of an OR gate 202 and the intermediate lines between the switching stages A and B are connected to the inputs of an OR gate 203. The output of the OR gate 202 is connected to the input (1) of an AND gate 204 and the output of the OR gate 203 is connected to the input (2) of the AND gate 204. If the intermediate line BCq 1 is free, the search signal is fed to the input (1) of the AND gate 204 via the OR gate 202, and if the intermediate line ABXqX is free, the search signal is fed to the input (2 ) of the AND gate 204 is supplied. If both intermediate lines are free, coincidence of the search signals occurs at the inputs of the AND gate 204, and a signal is fed via a line 205 to a marker (not shown).

The marker then sets the selector 2 WF to the output (1, q, n) , whereby a switching signal taken from the low-resistance voltage divider 206 is fed to the c wire of the switching network output FXqn. Furthermore, the marker sets the selector 2 '»VE to the output (1), whereby the input marker wire of the coupling field input EIlI is connected to earth. Finally, the marker connects a line 207 to ground, making the transistors TBCoo and TABooo conductive. Via the transistor TBCooo a low-impedance voltage divider 208 is supplied to the high-resistance voltage divider 200 and through the transistor TABooo the low-voltage divider 209 is connected in parallel to the high-resistance voltage divider 201 in parallel. In the manner described, separate excitation circuits are formed for the windings KC 1 q X n, KB 1 q XX and KAXXXq of the coupling relay in the connection path, the course of which is as follows:

1. Voltage divider 206, selector 2 WF, switching matrix output FXqn, winding KCXqXn, rectifier GCXqXn, input marker wire of input (1), output (1) of selector WH, earth;

2. Voltage divider 208, transistor TBCooo, transistor TBCq 10, transistor TBCqXX, intermediate line BCqXX, output (1) of matrix switch BXq, winding KBXqXX, rectifier GBXqXX, input marker wire of input (1), output (1) of selector WT, earth;

3. Voltage divider 209, transistor TABooo, transistor TABXqO, transistor TABXqX, intermediate line ABXqX, output (q) of matrix switch A XX, winding KA XXXq, rectifier GA XXXq, input marker wire of input (1), output (1) of selector 2 WE, Earth.

The coupling relays are excited in this excitation circuit and switch when they close Contacts continue the connection path. This creates a series holding circuit for the coupling relays,

which runs from earth at the coupling network output F \ qn via the rectifier G \ qn over the ο wire of the connection path to the minus potential on the c wire at the coupling network input £ "11. The rectifiers GBCq 11 and GAB Iq 1 are also used to decouple the Excitation circuits similar to the corresponding rectifiers according to Fig. 2.

For this purpose 4 sheets of drawings

Claims (6)

Patent claims: 1.Circuit arrangement for telecommunications, in particular telephone switching systems, for searching, Selecting and switching through connection paths in a multi-level switching network that has several contains coupling stages interconnected by intermediate lines, each with a number of matrix switches are provided with separate coupling relays for each coupling point, one Winding of each coupling relay in series with a decoupling rectifier in a marker wire is switched on, which is on the output side of the crosspoint to the control wire of the line connected there and on the input side of the Crosspoint is connected to an input marker wire with a dialing device is connected, characterized in that each intermediate line is connected to a voltage source in the operating state a high impedance and marker circuit adjustable to a low impedance is connected, the in the operating state, a marking signal with a low or high current level when searching for or switching through a connection path to the Intermediate line for marking an output of the preceding switching stage supplies 2. Circuit arrangement according to claim 1, characterized in that in at least one of the Coupling stages for each matrix switch a marking signal detection device connected to its outputs and connected to this Control organs are provided to switch on the marking circuits connected to the inputs of the Matrix switch to prevent connected intermediate lines when the marking signal is a activated marking circuit is missing at at least one of the outputs of the matrix switch. 3. Circuit arrangement according to claim 2, characterized in that the control elements consist of AND gates and the marker circuit is one on An intermediate line connected to an input of the matrix switch to the output of an AND gate is connected, of which a first input is connected to the input marker wire of the last-mentioned input of the matrix switch, and of which a second input is connected to the marking signal detection device. 4. Circuit arrangement according to claim 1, characterized in that the marking circuit has a contains the first transistor whose emitter-collector path between the intermediate line and a high-resistance potential source is switched on, as well as a second transistor whose emitter-collector path between the high-resistance potential source and a low-resistance potential source is connected. 5. Circuit arrangement according to claim 1, characterized in that the marking circuit has a contains first and second transistor whose emitter-collector runs in series between the Intermediate line and a high-resistance potential source, as well as a third transistor whose Emitter-collector path is connected between the high-resistance potential source and a low-resistance potential source. 6. Circuit arrangement according to claim 5, characterized in that the base of the first transistor is connected to the input marker wire of the input of the matrix switch to which the Intermediate line is present, and the base of the second transistor to a dialing device for dialing of the matrix switch is connected