DE1267725B - Circuit arrangement for crossbar switch - Google Patents

Description

Circuit arrangement for crossbar switches The invention relates to a circuit arrangement for crossbar switches with a matrix at the cross points differentially wound ferreed relays arranged in rows and columns. Such Coordinate switches are used in message switching systems for optional manufacture used by connections and releasing them when they are no longer needed.

Differentially wound Ferreed relays are known. You are with equipped with two control windings. When both windings end through at the same time Current pulses are excited with essentially the same amplitude, close the Contacts of the relay and lock magnetically. But if only one of the two windings is excited or when the current pulses do not have substantially the same amplitude or if the current pulses do not end at the same time, the contacts of the relay open. This mode of operation is called differential excitation.

Relays of this type are particularly suitable for a coordinate arrangement. A known arrangement of this type is described in U.S. Patent 3,037,085 . In this arrangement, to form a column control conductor, one winding of each relay in a particular column is connected in series with one winding of all other relays in the same column, and to form a row control conductor, the other winding of each relay in a particular row is connected to the other winding of all other relays in the same row connected in series. A selected cross-point relay is closed by applying coincident current pulses of the same amplitude to those row and column control conductors whose intersection point defines the selected cross-point relay. In this way, both windings of the selected relay are energized at the same time and the contacts are closed. For each unselected relay whose windings are in series with either the energized row control conductor or the energized column control conductor, only one winding will be energized. As a result, according to the mode of operation of this type of Ferreed relay, the contacts of each unselected relay are opened if they were previously latched in the closed state.

From the operational characteristics of a matrix with differential energized Ferreed relay results in that critical requirements in terms of temporal assignment and the waveform of the control current pulses exist. Any essential Amplitude difference or any deviation from the simultaneous termination of the two control pulses leads to a failure when closing the contacts of a chosen one Relay or causes the previously closed contacts of a relay to open, whose permanent closing is required. It is obvious that extensive and complicated synchronizing circuits for the control pulse sources are required are to meet the critical requirements for the optional control of such Matrix to suffice.

The invention provides a solution to the problem outlined above. She goes to based on a circuit arrangement of crossbar switch comprising a matrix of at the intersections of rows and columns arranged, differentially wound Ferreedrelais, which at the same time ending current pulses actuated by each their row coil and depending on its columns coil and locked, and at a pulse of current through each only one its coils are released, in which the line coils are connected each to one row and column coils per one column via a respective row or column control conductor electrically in series, and with Markierschaltungen, create the optional Markierspannungen to each one end of a row and column control conductor.

The invention proposes that in a known manner a bus bar the other ends of the row control conductors and the column control conductors for formation a series current path between the applied marking voltages connects the work together in such a way that a current pulse over the series current path flows and that Ferreed relay is actuated and latched, its rows and column coils via the selected row control conductor and the selected column control conductor in series are switched.

The invention facilitates the elimination in an advantageous manner essential of all previous silent restrictions regarding synchronization the control current pulses. Practically any curve shape is then usable, and the only restriction concerns the flux reversal in the magnetic circuit of a Ferreed relay required electricity. Furthermore, there is an absolutely exact time correspondence the control pulses through the series connection of the two windings of the selected Crosspoint Ferreed relay reached. As a result, regardless of the waveform of a current pulse the required equality of the pulse amplitude and the necessary Simultaneity of the pulse termination by supplying the same, through the applied Marking voltages generated a current pulse on both windings of the selected Ferreed relay ensured.

From the German Auslegeschrift 1060 445 a coordinate arrangement of non-latching crosspoint relays is already known, in which a series current path leads between marking voltages via the row and column windings of the relays. However, since magnetically non-latching reed relays (protective tube armature contact relays) are used in the known arrangement, an additional holding winding is required for each relay in order to keep the relay attracted after the actuation currents have ceased.

The task relating to these holding windings at the known arrangement deviates completely from the problem solved here away. On the one hand, there are no problems with the circuit arrangement according to the invention to the effect that cross points are attracted to after switching off the actuating currents hold, because the differentially wound Ferreed relays are magnetically attracted Remain locked in the state until a current pulse through only one their windings are brought to waste. On the other hand, however, the above-mentioned play critical operating conditions of Ferreed relays with the known arrangement none Role. For the solution proposed here resulting from these critical operating conditions The known arrangement does not provide any stimulus for the problem arising, especially the advantages of the solution proposed here with the known arrangement cannot be realized.

In a switching system, monitoring of the input circuits of a switching network is necessary in order to indicate an operating request and to initiate suitable measures. In many known systems, this monitoring is achieved by periodically polling bistable scanning elements which are connected to the connections of the switching network and which reproduce the monitoring states of the input circuits connected to the network connections. These bistable elements adversely affect the transmission properties if they remain connected to an occupied network connection, or they interfere with the connection in some other way. Therefore, selective disconnection of the bistable sensing elements from the ports of the network when the ports are in use is desirable. , According to a development of the invention it is proposed that in series with each column control conductor coil of a bipolar Ferreedrelais is actuated with a current pulse of a polarity across its coil and is locked and released at a current pulse of opposite polarity.

The bipolar ones used in the embodiment of the invention Ferreed relays are also called isolating relays because their contacts open the Separation or disconnection of the sensing element or other circuits from the associated one Effect network connection.

Since the control winding of a bipolar isolating relay is in series with each Column control conductor of the matrix is located, the corresponding isolating relays are through optional application of a marking voltage pulse from one of the two marking circuits to a selected column or row control conductor and by optional application another marking voltage from the other marking circuit to a selected one Column or row control ladder controlled. Generate the applied marking voltages together a current pulse whose polarity is related to the desired control of the one Isolation relay leads to whose winding the pulse is applied. The chosen polarity the applied marking voltage determines whether the contacts of the isolating relay are open or closed.

Most switching networks contain more than one dial level. During normal maintenance and in the event of a breakdown, it is desirable to use the various To be able to optionally check message transmission paths through the switching network, without the input circuits connected to the output (first or last) selection stages to influence.

According to a further development of the invention, it is proposed that that a further marking circuit optionally one of the two marking voltages the busbar creates that a selected one of the marking circuits optionally the other of the marking voltages applies and that the applied marking voltages such cooperate that a current pulse through only one selected column control conductor or flows over only one selected row control conductor and that thereby those Ferreed relays drop out, their column or row coil in series with the selected one Column or row control ladder lies.

In this way, an arrangement is created for the selective control of the crosspoint relays of a multi-stage switching network such that selected test connections can be established through this which do not extend through the last selection stage of the switching network to an input circuit. This arrangement also enables the optional control of the isolating Ferreed relay without disturbing the cross-point Ferreed relay in other selection levels. This is based on the fact that the current pulse generated by the cooperating marking voltages, which is sent to the busbar of a matrix in a first or last selection level (for example the first selection level) of the switching network and to a selected column control conductor of a matrix in the (first or last) selection level of the switching network is applied, passes through only one coordinate of the matrix on whose busbar the marking potential has been applied. When the current pulse traverses the column control conductor of a matrix of the first selection level, the crosspoint relays of that column drop out and the isolating relay of the column picks up or drops out depending on the polarity of the current pulse.

On the other hand, if the current pulse is only one column control conductor one First-level matrix, but both rows and columns control lines from Passes through the matrices of the following elective levels, the crosspoint relays fall into the Line of the first option level, the crosspoint relays in the following option levels are actuated and their isolating relays are not influenced.

By optionally applying certain combinations of marking voltages from three marking circuits, various switching functions can be achieved in the connection network. This includes: 1. Opening of those previously closed crosspoint relays in a selected line of a first or last selection level and simultaneous closing of a selected crosspoint relay in all other selection levels; 2. Opening of a selected isolating relay and simultaneous closing of selected crosspoint relays in all selection levels; 3. Closing of a selected isolating relay and simultaneous opening of those previously closed cross-point relays of a selected column of a first or last selection level, without influencing cross-point relays of another selection level; 4. Opening of a selected isolating relay and simultaneous opening of those previously closed cross-point relays of a selected column of a first or last selection level and finally 5. Simultaneous closing of a selected isolating relay and selected cross-point relay in all selection levels.

Most switching networks contain, in addition to several dial levels, more than one relay matrix in each dial level. As is known, the outlay for the network access circuits can be kept to a minimum if common marking circuits can be used for all matrices of an election level.

According to a further development of the invention, it is proposed for this purpose that that a selectively operable switch in series in the busbar between the other ends of the column control line and the other ends of the row control line is switched on to selectively the series current path between the applied marking voltages to switch through.

This creates a preferred arrangement for selecting a particular one Matrix created from a multitude of similar matrices in which the contacts of a selected crosspoint relay are to be closed or opened. Except if the optionally actuatable switch, for example a relay contact or may be another gate device, is closed and the common busbar therefore remains continuous, the row current path is via the row and column control conductors interrupted. Then the crosspoint relays and the isolating relays become a matrix by applying current pulses to the row or column control conductors of the Matrix not affected. However, if by selectively closing the switch the series current path is switched through in a matrix as such, the controller can of the various relays of this matrix selected can be carried out, such as described above. In this way one of a variety of matrices, e.g. B. the matrices of an optional level, for the relay control by closing the switch selected in series with the common busbar of the selected matrix.

The invention is described using an exemplary embodiment shown in the drawings. F i g. 1 schematically shows a circuit arrangement according to the invention for a multi-stage connection network, with differentially wound ferreed relays, and FIG . Figure 2 is a table illustrating some of the various network switching control functions that can be performed with the invention.

F i g. Figure 1 shows a plurality of matrices, such as 0-0 and N-0, arranged in N levels of choice. For the sake of simplicity, only the first option level 0 and the last option level N of the multi-level switching network are shown.

The matrix 0-0 of the first selection level 0 contains a coordinate arrangement of differentially actuable Ferreed relays or crosspoint switches 09, which are arranged at the crosspoints of, for example , three columns A, B, C and rows X, Y, Z each. For example, the crosspoint switch 09 CX is in column C and in row X. Each switch 09 has two windings W1 and W2 in a known manner. For example, the winding Wl of the crosspoint switch 09 CX is connected in series with the corresponding winding of all the other crosspoint switches 09AX, 09BX of the row X, so that a row control conductor 07X is formed. The other winding W2 of the cross point switch 09 CX is connected in series with the respective other winding of all other crosspoint switch 09 CY, CZ 09 of the C column to a voltage control conductor to form 06 C.

Each column control conductor 06 of the matrix 0-0 and each column control conductor 016 of the other matrices, not shown, of the optional level 0 is connected in a known manner with its beginning to a marking circuit 01. This applies either a positive current pulse 4 or ground potential 5 to a selected column control conductor in accordance with supplied, suitable address information. Since the marking circuit is not the subject of the invention and such access circuits are known, it is not described further here. The other end of each column control conductor 06 is connected to a common busbar 010 in a known manner.

One end of each row control conductor 07 is connected to an intermediate line 50 in a pattern to be described later. The other end of each row control conductor 07 is led to the busbar 010 . In this, a contact 011 of a matrix selection relay 012 is connected in series between the connection of the column control conductor 06 to the busbar 010 and the connection of the row control conductor 07 to the busbar 010 .

The matrix selection relay 012 is controlled by the marking circuit 01 on the basis of the optional application of earth potential 5 to its matrix selection conductor 013.

Another marker circuit 02 is connected to the busbar 010 via a matrix control conductor 014, which is also assigned to the matrix 0-0. The marking circuit 02 applies either a positive current pulse 4 or ground potential 5 to a selected matrix control conductor 014 or 017 in accordance with supplied address information.

The control winding of a bipolar Ferreed relay or isolating relay 08 is also connected in series with each column control conductor 06. For example, the winding W3 of the isolating relay 08 C is connected in series with the column control conductor 06 C. The contacts of the bipolar isolating relay 08 C are not shown, but they can each connect a scanning element to the connection of the transmission path that is assigned to the column control conductor 06C which contains the winding of the isolating relay 08 .

The column control conductors 016 of every other matrix are connected multiple times with the respective column control conductor 06 of the same name of the matrix 0-0. Common bus lines of every other matrix are separately connected to the second marking circuit 02 via their individual matrix control conductor 017. The matrix selection relays of every other matrix correspond to the matrix selection relay 012 and are controlled separately via individual matrix selection conductors 015 similar to the matrix selection conductor 013 described above.

The illustrated matrix N-0 of the selector stage N is analogously a coordinate arrangement with differentially actuable Ferreed relays or crosspoint switches N9. .. Analogously, it has column control conductor N6 ", row control conductor N7, a common busbar N10, a matrix selection relay N12 and a marking circuit N10.

The matrices of option levels 0 and N are connected via intermediate lines 50 of a known regular link arrangement in which one end of each row control conductor of each matrix of the first option level 0 is connected via an intermediate line 50 to one end of a row control conductor of a separate matrix in the last option level N. For example, row control conductor 07X of matrix 0-0 of the first stage is connectable to row control conductor N7X of matrix N-0 of the last stage via link 51 (and other links and select stages, if any). Row control conductor 07X is the only row control conductor of matrix 0-0 that is connected to any row control conductor of matrix N-0 . The other row control conductors of the matrix 0-0, such as 07 Y and 07Z, are correspondingly connected to other separate matrices (not shown) in the last selection level N. Similarly, every other row control conductor of the last dial matrix N-0 , such as N7 Y and N7 Z, is connected to one on that matrix other than matrix 0-0 in the first dial 0 .

As a result of this known method of matrix connections, the selection of a particular matrix of the last elective level determines a particular row control conductor in a selected matrix of the first elective level. For example, the selection of the matrix N-0 of the last elective level determines the row control conductor 07X of the matrix 0-0 of the first elective level. Network control With the in F i g. 1 , various types of switching functions can be performed. The explanation relates to the establishment of a number of connections and their release with reference to an exemplary message transmission path through the connection network in FIG. 1 input circuits, not shown, are correspondingly connected to connections, not shown, of the network, which are individually assigned to the corresponding column control conductors 06 .. and N6 .. of the matrices 0-0 and N-0 . Each input circuit selecting level 0 associated (not shown) can monitor sensing through the closed contact of an isolation relay 08 .. are connected to the network ports. The contacts of the isolating relay 08 are individually assigned to the network connections whose assigned column control conductors 06 .. contain the winding of the isolating relay 08 ...

F i g. 2 is a table of the various switching functions described here in relation to the contact positions of the corresponding switches resulting from the corresponding switching functions and the output signals of the corresponding marking circuits which initiate the switching functions. Initial state The initial state of the network is the state in which the network connection of a free input circuit is connected to its associated sensing element and in which no connection is established through the network to the network connection. In this state, as in FIG. 2 indicated, the contacts of the isolating relay 08 assigned to the network connection closed, the contacts of the crosspoint switch 09 of the first selection level open, the windings of which comprise the column control conductor 06 assigned to the input circuit, and the contacts of the crosspoint switch N9 of the last selection level can be either open or closed.

For example, the sensing element for a free input circuit via the closed contact of the isolating relay 08C is connected to the column control conductors 06 C associated network terminal in the initial state, and the contacts of the crosspoint switch 09CX, 09CY and 09CZ, each of which turned a winding in series in the column control conductor 06C is, are open. The contact state of the crosspoint switches N9 of the last selection level is not critical and these contacts can be either open or closed.

Operations during connection If a connection is to be established between selected input circuits, the sensing element connected to the network connection of the monitored input circuit is switched off in order to avoid a disturbance in the transmission of night light. As in Fig. 2, the contacts of a selected isolating relay 08 are opened, the contacts of a selected crosspoint switch 09 of the first selection level, selected crosspoint switch of any further selection levels (not shown), and a selected crosspoint switch N9 of the last selection level are closed. In this way, a connection is established through the network between a selected connection of the last dialing level and a selected connection of the first dialing level and the corresponding scanning element is disconnected from the selected connection of the first dialing level.

The establishment of a connection between the connections associated with the column control conductor N6C of the last selection stage and the connection associated with the column control conductor 06C of the first selection stage will now be described. The matrices 0-0 and N-0 of the first and last selection level are selected by the marking circuits 01 and Nl by optionally applying ground potential 5 to the matrix selection conductors 013 and N13 , respectively. The matrix selection relays 012 and N12 pick up , and their contacts 011 and N11 switch the busbars 010 and N10 through. This creates a number of control paths between the marking circuit 01 and the marking circuit Nl, each of which can be selected by the marking circuit. To establish the desired connection, the control path is selected, which is via the column control conductor 06C of the first selection level, the busbar 010 of the matrix 0-0, the row control conductor 07X of the first selection level, the intermediate line 51, possibly further intermediate lines and selection levels, the row control conductor N7X of the last Elective level, leads the busbar N10 of the matrix N-0 and the column control conductor N6C of the last electoral level.

The selected control path contains only one winding each of the crosspoint switches 09CZ, 09CY, 09AX and 09BX of the first selection level and the crosspoint switches N9BX, N9AZ, N9CY and N9CZ of the last selection level. However, it leads over both windings of the crosspoint switch 09CX of the first selection level and the crosspoint switch N9CX of the last selection level and also contains the winding of the isolating relay 08C To establish the desired connection, the marking circuit Nl applies earth potential 5 to the column control conductor N6 C, and the marking circuit 01 applies one positive current pulse 4 to the column control conductor 06 C. The current pulse 4 runs through both windings of the crosspoint switches 09 CX and N9 CX and through one winding each of the crosspoint switches 09CZ, 09CY, 09AX, 09BX, N9BX, N9AX, N9CY and N9CZ to the column control conductor N6C. This causes the contacts of the crosspoint switches 09CX and N9CX to close or remain closed and the contacts of the crosspoint switches 09CZ, 09CY, 09AX, 09BX, N9BX, N9AX, N9CY and N9CZ to open or remain open. When the contacts of the selected crosspoint switches 09CX and N9CX close, the contacts of the unselected crosspoint switches 09CZ, 09CY, N9AX, 09BX, N9BX, N9AX, N9 C Y, N9 CZ in the same row X or column C as the selected crosspoint switches open at the same time. All previously existing connections that contain the unselected crosspoint switches are released so that the desired connection cannot be disturbed.

The pulse 4 applied to the column control conductor 06C also passes over the winding of the isolating relay 08C and, when it flows in this direction, opens its contacts. This agreement with regard to the direction of current for the bipolar control of the isolating relays is maintained throughout the following. In this way, the sensing element is separated from the network connection associated with the column control relay 06C. As in Fig. 2, the marker circuit 02 is not energized during a connection process and does not perform any functions.

Operations during disconnection If an existing connection that has previously been established to the network connection of a selected input circuit is to be disconnected, the sensing element must be reconnected to the network connection and the contacts of the crosspoint switch 09 of the first selection stage, via which the connection runs, must be opened . Since subsequent connection processes, as described above, or subsequent test processes, as described below, cause the opening of crosspoint contacts of unneeded intermediate selection levels and the last selection level, opening during a disconnection process is not necessary. As in Fig. 2, the contacts of a selected cut-off relay 08... closed and the contacts of a selected crosspoint switch 09.. the first step is opened, but the contact position of the crosspoint switch N9 .. of the last selection step or any intermediate selection steps that may be present is not affected.

The release of a connection which has previously been established to the network connection assigned to the column control conductor 06 .. of the first dialing stage will now be described. The matrix 0-0 of the first selection level is selected by the marking circuit 01 by applying ground potential 5 to the matrix selection conductor 013 . Then the matrix selection relay 012 picks up, its contact 011 is closed and the busbar 010 is electrically connected. This creates a number of control paths between the marking circuit 01 and the marking circuit 02, each of which can be selected by the marking circuits 01 and 02. Such a control path contains the column control conductor 06C, the busbar 010 and the matrix control conductor 014. This is the path selected by the marking circuits 01 and 02 to achieve the desired release of the existing connection.

The selected control path contains only one winding each of the crosspoint switches 09CZ, 09CY and 09 CX of the first selection level. The selected path does not contain any windings of other crosspoint switches 09 of the matrix 0-0 of the first selection level or the crosspoint switch N9 of the last selection level. The selected control path also leads via the control winding of the isolating relay 08 C.

A separation process is carried out by applying ground potential 5 from the marking circuit 01 to a column control conductor 06 of the first selection level and by applying a positive current pulse 4 from the marking circuit 02 to a selected matrix control conductor 014, 017 . In the present case, the marker circuit 01 applies ground potential 5 to the column control conductor 06 C, and the marker circuit 02 applies a positive current pulse 4 to the matrix control conductor 014. The current pulse 4 is on the selected control path via a single winding of the crosspoint switches 09 CY, 09 CY and 09 CZ and the winding of the isolating relay 08 C to earth potential 5 , which is applied to the column control conductor 06 C. As a result, the contacts of all previously closed crosspoint switches 09CX, 09CY and 09 CZ in column C are opened. If the connection to be released is that which was established during the connection process described above, this would be the contacts of the crosspoint switch 09CX. As a result of the disconnection process, these contacts are now opened and disconnect the network connection assigned to the column control conductor 06C.

The pulse 4 applied by the marking circuit 02 to the matrix control conductor 014 also runs through the winding of the isolating relay 08C, in the opposite direction as the current pulse 4 previously applied by the marking circuit 01 during the connection process described above 08 C closed, and the sensing element is in turn connected to the column control conductor 06C associated network terminal.

As in Fig. As shown in FIG. 2, the marker circuit NI is not energized during the separation process and does not perform any function. Switching off the monitoring function If, for the purpose of testing or for other reasons, it is desirable to switch off the monitoring of a free input circuit, the sensing element assigned to the network connection of the input circuit is disconnected. As in Fig. 2, when the monitoring function is switched off, the contacts of a selected isolating relay 08 .. are opened and the contacts of the crosspoint switch 09 .. whose windings are in series with a selected column control conductor 06 are opened.

The disconnection of the monitoring for the network connection assigned to the column control conductor 06C will now be described. The mode of operation when switching off the monitoring is identical to the isolating function described above, with the exception of the direction in which the current pulse 4 is applied to the selected switch control path. The monitoring is switched off by applying ground potential 5 from the selector circuit 02 to a selected matrix control conductor 014, 017 and by applying a positive current pulse 4 from the selector circuit 01 to a selected column control conductor 06 .. of the first stage. In the present case, the marking circuit 02 applies ground potential 5 to the matrix control conductor 014 and the marking circuit 01 applies a current pulse 4 to the column control conductor 06C . The current pulse 4 runs on the selected control path through a single winding of all crosspoint switches 09CX, 09BX, 09AX in column C and through the winding of the isolating relay 08C to the column control conductor 06C. This opens the contacts of the isolating switch 08C, and the sensing element is disconnected from the network connection associated with the column control conductor 06C. In addition, the contacts of all crosspoint switches 09CX, 09BX or 09AX in column C, which were previously closed, are opened. i As in F i g. 2 indicated, the marker circuit Nl is not energized while the monitoring is switched off and does not perform any function.

Operation of Pre-Monitoring If the monitoring of a selected input circuit is to be checked through a connection through the switching network, the sensing element must be connected to the network connection of the selected input circuit. As in Fig. 2, the contacts of a selected isolating relay 08 .., the contacts of a selected crosspoint switch 09 .. of the first selection level and selected crosspoint switch of any intermediate selection levels and the contacts of a selected crosspoint switch N9 .. of the last selection level are closed during test monitoring. In this way, a connection is established through the network between a selected last dial port from which the desired test can be performed and a selected first dial port with the sensing element connected to the selected first dial port.

The establishment of a test monitoring connection between the network connection assigned to the column control conductor N6C of the last dialing level and the network connection assigned to the column control conductor 06C of the first dialing level will now be described. The work process for a test monitoring is identical to the connection process described above with the exception of the direction in which the current pulse 4 is applied to the selected control path. During a test monitoring, earth potential 5 from the marking circuit 01 is applied to a selected column control conductor 06 .. of the first selection level and a positive current pulse from the marking circuit NI is applied to a selected column control conductor 1V6 of the last selection level. In the present case, the marking circuit 01 applies ground potential 5 to the column control conductor 06C and the marking circuit Nl applies a positive current pulse 4 to the column control conductor N6C. The current pulse 4 runs on the selected control path through both windings of the crosspoint switches 09 CY and N9 CX, through a single winding of the crosspoint switches 09CZ, 09CY, 09AX, 09BX, N9BX, N9AX, N9CY, N9CZ and through the winding of the isolating relay 08C to the column control conductor 06C As a result, the contacts of the crosspoint switches 09CX and N9CX are closed or remain closed, and the contacts of the crosspoint switches 09CZ, 09CY, 09AX, 09BX, N9BX, N9AX, N9CY, N9CZ are opened or remain open.

The direction in which the pulse 4 runs through the winding of the isolating relay 06C during the test monitoring is opposite to that in the connection process explained above. Due to the properties of the isolating relay OSC, its contacts are closed, and the sensing element is connected to the network connection assigned to the column conductor 06C or remains connected to it.

As in Fig. 2, the marker circuit 02 is not energized during the test monitoring and does not perform any functions. Network test procedure If, during normal maintenance or in the event of a fault, it is desired to test the various communication paths through the switching network, a test connection is established through all dial levels of the network with the exception of the first dial level 0 . Such a test connection simplifies the optional testing of the various communication paths without influencing the input circuits connected to the first selection stage 0. As indicated in FIG. 2, a network test process leaves the contacts of a selected isolating relay 08 .. closed, ensures that the contacts of a selected crosspoint switch 09 .. of the first selection stage are open, and closes the contacts of a selected crosspoint switch N9 of the last Optional level and, if applicable, crosspoint switch of intermediate selection levels. In this way, a non-terminated connection path through the network is established from a selected network connection of the last dialing level, from which tests can be carried out without exerting undue effects on the level 0 input circuits.

The purpose of this is to describe the establishment of a network test connection from the network connection assigned to the column conductor N6 C of the last dial stage, which contains the transmission path assigned to the row control conductor 07X of the matrix 0-0. The matrix N-0 is selected by the marking circuit Nl by applying ground potential 5 to the matrix selection conductor N13 . The matrix selection relay N12 picks up , its contact Nll is closed and the busbar NIO is switched through. This results in a number of control paths between the marker circuit N1 and the marker circuit 02, each of which can be selected by the marker circuits N1 and 02. Such a control path contains the column control conductor N6 C of the last selection level, the busbar N10 of the matrix N-0, the row control conductor N7X of the last selection level, the intermediate line 51, possibly further intermediate lines and selection levels, the row control conductor 07X of the first selection level, the busbar 010 of the matrix 0 -0 and the matrix control conductor 014. This is the control path which has been selected by the marking circuits N1 and 02 in order to establish the desired network test connection.

The selected control path contains only a single turn of the crosspoint switches N9CZ, N9CY, N9AX and N9BX of the last selection level and the crosspoint switches 09CX, 09BX and 09AX of the first selection level. The selected control path, however, leads over both windings of the crosspoint switch N9CX of the last selection level. It should be noted that the path chosen does not cover both windings of any cross-point switch 09.. the first selection stage or the winding of any isolating relay 08 .. contains.

During a network test process, ground potential 5 is applied from the marking circuit Nl to a selected column control conductor N6 of the last selection stage and a positive current pulse 4 from the marking circuit 02 is applied to a selected matrix control conductor 014, 017 . In the present case, the marker circuit Nl applies ground potential 5 to the column control conductor N6 C, and the marker circuit 02 applies a positive current pulse 4 to the matrix control conductor 014. The current pulse 4 runs on the selected control path through both windings of the crosspoint switch N9 CX and through a single one Winding of the crosspoint switches 09 AX, 09 BX, 09 CY, N9 BX, N9AX, N9CY and N9CZ to the column control conductor N6C. This causes the contacts of the crosspoint switch N9CX to close or remain closed, and the contacts of the crosspoint switches 09AX, 09BX, 09CX, N9BX, N9AX, N9CY and N9CZ to open or remain open.

The connection established via the contacts of the selected crosspoint switches of the intermediate selection levels and the last selection level can now be selected without affecting any of the input circuits connected to the matrix 0-0 of the first selection level.

As in Fig. 2, the marker circuit 01 is not energized during a network test process and does not perform any function at this point in time.

Claims (2)

CLAIMS disposed 1. A circuit arrangement for crossbar switch comprising a matrix of at the intersections of rows and columns, differentially wound Ferreedrelais, which at the same time ending current pulses actuated by each their row coil and depending on its columns coil and locked, and at a pulse of current through each only one of its coils are released, in which the line coils are connected each to one row and column coils per one column via a respective row or column control conductor electrically in series and with Markierschaltungen, create the optional Markierspannungen to each one end of a row and column control conductor, i.e. a d urch g e hen k -zeichnet that in known manner, a bus bar, the other ends of the row control conductors (07.) and the column control conductors (06.) (010) to form a series current path between the applied Markierspannungen (4, 5) connecting , which cooperate in such a way that a current pulse flows through the series current path u nd that Ferreed relay (09 CX) is actuated and locked, the row and column coils (W1, W2) of which are connected in series via the selected row control conductor (07 X) and the selected column control conductor (06 C). 2. Circuit arrangement according to claim 1, characterized in that in series with each column control conductor (06th.) The coil (W3) of a bipolar Ferreed relay (08 ..) is located, which is actuated by a current pulse of one polarity via its coil (W3) and latched and released when a current pulse of opposite polarity occurs. 3. Circuit arrangement according to claim 1 or 2, characterized in that a further marking circuit (02) optionally applies one of the two marking voltages (4 or 5) to the busbar (010) , that a selected one of the marking circuits (01 or N1) optionally applies the other of the marking voltages (5 or 4) and that these applied marking voltages (4, 5) work together in such a way that a current pulse flows over only one selected column control conductor (06) or over only one selected row control conductor (07) and that as a result those Ferreed relays (09) drop, whose column or row coil (W2 or Wl) is in series with the selected column or row control conductor (06 or 07) . 4. Circuit arrangement according to claim 1, 2 or 3, characterized in that an optionally operable switch (011) is switched on in series in the busbar (010) between the other ends of the column control conductor (06) and the other ends of the row control conductor (07) in order to optionally switch through the series current path between the applied marking voltages (4, 5) . Considered publications: German Auslegeschriften No. 1060 445, 1091 160; French Patent Nos. 1186 451, 1268 138; U.S. Patent No. 3,037,085.