DE1271207B - Circuit arrangement for searching for free connection paths in multi-stage switching matrices in telecommunications, in particular telephone switching systems - Google Patents

Description

Circuit arrangement for looking for free connection paths in multi-stage Switching matrices in telecommunications, in particular telephone switching systems. The invention relates to a circuit arrangement for searching for free connection paths in multi-stage Switching matrices in telecommunications, in particular telephone switching systems, in the the coupling stages consisting of coupling points arranged in matrix form in the same way large sub-matrices are divided, so many are arranged in matrix form for testing Test circuits are provided, as each sub-matrix has elements to be tested, and in which the sub-matrix to be checked is arranged in a coordinate-like manner Column and row lines of a switching matrix assigned to the switching stage are connected Control potential is selectable.

The connection requests of the participants are processed in switching systems, in which the connection is established via multi-level switching matrices, generally with the help of a central marker, which via information and control lines is in connection with the switching matrices. It is his task to subordinate Taking into account the existing connections, the free connection paths determine, select a suitable one and switch it through. For the search process is usually a specific input and a specific output of the multi-stage switching network and those free line combinations are selected which from the designated input across all stages of the switching matrix to the designated Lead exit. A switching command then selects one of the possible connection paths selected switched through.

Because of the very large number of stretches of the path to be searched, they are complicated Testing and marking equipment required.

By the German patent 865 474 a circuit arrangement known, in which the operating state of the intermediate lines of the switching network, namely whether free or occupied, via information lines by means of time-shifted impulses the marker is communicated, which can be freely interconnected from this information Looks out and connects intermediate lines. Since with each pulse phase the information can be transmitted to a connecting line, although a proportionate suffices small number of information lines, but it must be used when establishing a connection a certain waiting time must be accepted, because only the occurrence of the coincidence possibilities of the different resulting in multi-level switching networks Pulse phases of the individual stages must be waited for. This waiting time and the required The effort involved in providing, generating and checking the coincidence of the many pulse phases outweighs the savings in information lines.

With the switching system described by the German Auslegeschrift 1048 956 the selection and combination of the intermediate lines does not take place in the marker, but by means of a route search network, which in its routing of those of the switching matrix. When looking for a route, it is both an entrance and a Marked the output of the route search network, the marking of the relevant Input and the relevant output assigned via free intermediate lines Route search veins propagated into the interior of the route search network until they are contiguous Routes are marked using the route search arteries. After choosing among these the marking is transferred to the connection path determined as free and the setting of the assigned crosspoint contacts made.

In this known method, the technical effort for the Markers are relatively small, but route search wires must be provided in the switching network which are connected to one another via special switching means, their number is proportional to the number of crosspoints. At the joints of these wires are Voters are provided, which are used for the selection of the sections of the road and the marking the setting switching means.

There is no special waiting time with this known arrangement, however, it must be viewed as disadvantageous be that special path search arteries and dialing facilities, the number of which is considerable in larger exchanges, required are.

The German Auslegeschrift 1191 430 discloses a circuit arrangement for testing circuits and / or lines for their occupancy status, in which the main matrix containing the circuits or lines in a cross-field arrangement is divided into sub-matrices of equal size, so many in matrix form for testing arranged test circuits are provided, as each sub-matrix has elements to be tested, and in which the sub-matrix to be tested can be selected by switches connected to the column and row lines of the main matrix.

It will be evident upon examination of this known arrangement of circuits or lines on their operational status a considerable saving of test arrangements, because the few test arrangements are achieved by means of a simple one Switching device can optionally be used for testing all sub-matrices.

The prior art given by the German Auslegeschrift 1191 430 suggests the task of saving switching means even when searching for free connecting paths by switching the path searching means to different sections of the coupling stages and thereby checking a whole such section at a time is extended.

The invention shows a way in which the existing test equipment, the number of which is only ever sufficient for testing a department, here in accordance with the above-mentioned German Auslegeschrift 1191 430 sub-matrix, is used for testing the existence of free connection paths in each coupling stage can. The selection of a usable path is easy. In addition to the considerable savings in test circuits in the case of larger systems, significant time savings are also achieved.

The invention is characterized in that switch sets are provided are each individual switch for the supply line of the operating status of each Coupling element to be tested is currently connected to the test circuits of a coupling stage connected sub-matrix containing characteristic potential, with the individual switch each switch set can all be switched on together or individually one after the other, so that the switching elements of each sub-matrix are used to search for free connection paths can optionally be tested all at the same time or individually one after the other.

The invention is explained using circuit diagrams.

F i g. 1 shows the structure of a three-stage switching network as a block diagram dar; F i g. Figure 2 shows a single switching stage with those for the relationship of the invention necessary details.

It is mentioned that the circuit diagrams only relate to the representation the control cores used for the route search. The speech arteries run in a known manner in the coupling stages to these control cores in parallel.

In Fig. 1 shows the switching stages A, B and C of a switching network. The crosspoints via which the connection paths can be switched through are arranged in the main matrices HM in the manner of a cross field. Each main matrix is divided into sub-matrices of equal size in a manner not shown here. The selection of a specific sub-matrix for your test is made by the switching matrix GM belonging to the main matrix. The test arrangements for determining the occupancy status of the crosspoints of a selected sub-matrix are summarized in the test matrix PM. In addition, an input marking matrix EM with a switch set Q and an output marking matrix KM are assigned to each coupling stage for the route search. Another set of switches Z is connected to the test matrix PM.

The coupling stages A, B and C are connected in series in a known manner. A distributor Vt is provided between two stages, which allows any changes to be made in the assignment of the connecting lines.

It will be shown below that if certain requirements are met for the first stage of a switching matrix, the input marking matrix EM, for the last stage the output marking matrix KAI and also some of the assemblies of the marking matrices provided between the stages can be saved; however, the explanations are initially based on the presence of this switching means.

In the case of the corresponding FIG. 1 coupling stages connected in series, marking signals can be fed to the inputs e of the input marking matrix EM of the first coupling stage A, depending on the occupancy status of the coupling elements of the main matrices HM and depending on the switching status of the switching matrices GM and the switch sets Q and Z, which are dependent on the here Central marker, not shown, are controlled from, at the outputs k of the output matrix KM of the last switching stage C are received. The received signal indicates that there is at least one free connection path from the pre-marked input to the receiving output. The existing switching status of the switching matrices GM and the switch sets Q and Z provides the marking for the switching through of the switching matrices.

In Fig. 2 shows the assignments and the signal flow in a coupling stage in more detail. The main matrix HM is also divided into the sub-matrices N 11 to N. Each sub-matrix N consists of a number of circuits Raa to Rzz. Accordingly, the sub-matrix N11 contains the circuits Raa11 to Rzz11. Each circuit consists, for example, of a number q coupling relays which are switched on one side in multiples so that they form a relay selector. The relay selector Rzz 11 has the connection bRzz 11 on one side and the connections aRzz11-1 to aRzz 11-q on the other side. The relay selector is considered occupied when its b-port is connected to one of the a-ports.

To initiate the test of all relay selectors in a sub-matrix, a call signal is applied to terminals g by the switching matrix GM in a manner known per se. In the case of the sub-matrix N11, the switching element G11 is activated in the switching matrix GM by means of the switching means Sxl and Sy1, which in parallel calls all the relay selectors Raa11 to R; cz 11 via the terminals g11. In the case of the assigned relay selectors, the potential that is present at the test terminals raa to rzz and characterizes the free state is suppressed.

An input marking circuit E arranged in the input marking matrix EM is provided for each connection aR. For example, the relay selectors Raa 11 of the sub-matrix N 11 are assigned the input marking circuits Eaa 11-1 to Eaa 11-q . These input marker circuits each consist of an AND circuit, the first input of which is assigned a signal line e-aall-1 to e-zzmn-q, which is connected via the circuit shown in FIG. 1 shown distributor Yt comes from the output marking matrix KM of the preceding coupling stage. The second input of each AND circuit is each connected to a call line g11. and g connected to the switching matrix GM through which the group code, is thus the assignment to the corresponding sub-matrix N11 to Nmn overall yields. The third input of each AND circuit is connected to an output 1 to q of the switch set Q , which determines the serial number of the connecting lines aRaa 11-1 to aRzz rnn-q of the relay selectors.

The outputs of all AND circuits have the same element identifier have, so in the example mentioned, the input marking circuits Eaall-1 bis Eaa11-q and all that have the element identifier aa are in an OR circuit, so summarized the OR circuit Daa. The outputs daa to dzz of these OR circuits are connected to inputs of the corresponding test circuits Paa to Pzz.

These assignments ensure that when a sub-matrix N is called up using a switch G of the switching matrix GM, precisely those input marking lines e-aall-1 to e-zz mh-q to the test matrix PM have access to the connecting lines aR ... of the relay selector R are assigned to this sub-matrix N, the switching state of the switch set Q then determining whether the connection lines of one, several or all of the order numbers 1 to q are permitted.

If the called sub-matrix contains N free voters R, they deliver at their test outputs raa to rzz the release signal to the test circuits Paa to Pzz. The test circuit, for example Paa, only gives paa at its output then a signal is sent to the output marking matrix KM if, in addition to the test output, raa also the assigned output daa of the input marker switch matrix and the switch zaa of the switch set Z deliver signals at the same time.

The Ausgangsmarkiermatrix KM consists of as many Ausgangsmarkierschaltungen Kaa 11 to kzz mn as to bRzz with are present in the main matrix selector terminals braa. 11 Each output marker circuit Kaa 11 to Kzz with consists of an AND circuit, to whose one input a signal line paa to pzz and to whose other input a switch line g11 to gmn is connected. Each of the signal lines paa to pzz is therefore routed to as many output marking circuits as the main matrix HM has sub-matrices N , an output marking circuit being selected in each case by the switching matrix GM by means of a switch line g. Each connection bR of a selector of the main matrix is therefore assigned an output kaa11 to kzzmn of the output marking matrix, and the idle signals of the test matrix PM on those output signal lines kaa 11 to kzz are also given to the input marking matrix EM of the subsequent switching stage which is connected to the connections bR of the voters correspond to the just called sub-matrix N.

For a chain of coupling stages constructed in the manner described the structure is made easier from the outset.

Since the first switching stage does not have to receive any input marking signals from a preceding stage, it is not necessary to connect an input marking matrix upstream of the test matrix PM. Depending on the design of the test circuits Paa to Pzz, the input marking can be carried out by applying a corresponding voltage or current to the relevant input daa to dzz of the test matrix PM. Together with its switch set Z, with the first switching matrix GM and with the first main matrix HM, the first test matrix PM acts like a signal source.

No output matrix KM is required for the last coupling stage in the chain. It is sufficient to combine the outputs paa to pzz of the last test matrix PM in an OR circuit (not shown) and to feed them to an identification amplifier. The amplifier acts as a receiver for the signals sent by the first stage and, if a free path is found, forwarded via the intermediate stages. When such an identification signal is received, it then intervenes via an output 1d (not shown) in the central control of the switching matrices GM and the switch sets Q and Z and causes, in a manner known per se, the identification of the connection path marked by their individual switch positions.

The row and column switch sets Sy and Sx of the switching matrices GM and the switch sets Q and Z of all coupling stages are also operated by a central controller. Depending on the route search to be made, either a switch from a set of switches Q or Z is switched on based on the information available, or a switch is switched on by a clock pulse and the previously operated switch is switched off, so that a step-by-step scanning takes place. Furthermore, the possibility is provided for the switch sets Q and Z to switch on not just one, but several switches at the same time.

The route search is generally carried out in two sections. The process is carried out on a three-stage switching network in accordance with FIG. 1, which however does not have an input marking matrix EM in the first stage A and only has an identification circuit instead of the output marking matrix KM of the last stage C.

It is assumed that a connection path from the third switching stage, namely from a connection terminal bRab 21 of the selector Rab 21, not shown, which is stored in the sub-matrix N21 of the main matrix FIM of the switching stage C, also not shown, to any free output, for example the Selector Raz 1 n of the sub-matrix N 1 n of the main matrix HM of the first switching stage A, is to be searched for and identified.

Information signals of the marker that characterize this task are now applied to the line daz of the test matrix PM of the coupling stage A for the determination of the selector Raz 1 n marking potential, namely the switch Zaz (not shown) from the switch set Z and the switch Gln in the switch matrix GM turned on by actuating the column and row selection switches Sx n and Sy 1 . To determine the other side of the connection path sought, namely the connection (not shown) bRab 21 of the selector Rab 21 of the main matrix HM of the coupling stage C, the switch Zab (not shown) of the switch set Z and the switch G21 of the switching matrix GM are activated by actuating the selection switches Sx1 and Sy2 switched on. In addition, the switch sets Q and Z of the coupling stage B and the switch Q of the coupling stage C receive the information "Switch on all stages" for the first section of the route search. The column and row selection switch sets Sx and Sy of the switching matrix GM of the coupling stage B are now caused by a step-by-step command to operate one of their switches after the other, so that all switches G11 to Gmn are switched on one after the other and, one after the other, all sub-matrices N11 to N with the Main matrix HM are searched for the possibility of a connection path. When a possible path is found, which is expressed by the generation of a free signal at a terminal raa to rzz of the test matrix, the free signal is forwarded from the test matrix PM via the output marker matrix KM of the coupling stage B via the third coupling stage to the identification circuit (not shown). The appearance of the identification signal causes the switch sets Sx and Sy of the switching matrix GM of the coupling stage B to be blocked, so that the switches that have just been operated remain in their switched-on state.

Through the search measures carried out in this first section of the route search all those sub-matrices of the three coupling stages were determined via the one free connection option exists.

In the second section of the route search, the exact Course of the way, so the voters themselves and their connection lines in the marked Sub-matrices, fixed.

This division of the route search into two sections, with first the path is searched roughly and then finely, reduces the number of those to be checked Connection combinations essential, so that the waiting time compared to the known Searching for coincidence possibilities by continuously combining line pieces is significantly reduced.

During the second section of the route search, the following reversals are carried out on switch sets Q and Z of coupling stage B and on switch set Q of coupling stage C: The signal "switch on all stages" is used for a switch set, for example for switch set Q of coupling stage C, turned off. Instead, the individual switches of this switch set are switched on one after the other. The identification signal received in the first section of the route search that the locking of the selection switches Sx and Sy of the switching matrix GM of the coupling stage B had caused, disappears again when reversing and is received again as soon as that switch of the switch set Q is operated, which according to its code number relevant voter, which can be used for the connection path, is assigned. The renewed reception of the identification signal causes the switch set Q to be shut down.

The search process is continued in the same way by means of the switch sets Q and Z of the coupling stage B , so that after the final reception of the identification signal a usable path is clearly determined by the actuated switch. The switching status of the switch sets established in the course of the route search is then used to switch through all the coupling relays marked.

Through the known grouping method of the connection lines in multi-stage switching networks there are multiple circuits under the switching points or between the selector inputs and outputs. These multiple circuits make significant Savings on the switching arrangements of the input and output marking matrices possible.

If, for example, the outputs of the voters are switched row by row in multiples in each sub-matrix, each sub-matrix only has as many outputs as the voters in a single column. Since an input marker circuit corresponds to each output aRaa11 ... aRzzmn, the number of input marker circuits is correspondingly reduced by the multiple circuit.

Significant savings can also be made in the input and output marking matrices when responding to the arrangement of distributors Vt between the individual coupling stages is dispensed with and a fixed wiring between the inputs and outputs. Namely, it leaves the interconnection of the Outputs of the downstream coupling stage with the inputs of the upstream Coupling stage in certain mutual assignment only prescribed routes so that the search for impossible paths can be omitted.

Claims (1)

Claims: 1. Circuit arrangement for searching for free connection paths in multi-stage switching matrices in telecommunications, in particular telephone switching systems, in which the switching stages consisting of coupling points arranged in matrix form are divided into sub-matrices of equal size, for the testing of which there are as many test circuits arranged in matrix form as each Sub-matrix has elements to be tested, and in which the sub-matrix to be tested can be selected by control potentials connected to the coordinate-like arranged column and row lines of a switching matrix assigned to the coupling stage, thereby characterized in that switch sets (Q and Z) are provided, each of which Individual switch (1 ... q or zaa ... zzz) for the supply of the operating status of each coupling element to be tested (Raall-1 ... Rzzll-q) to the test circuits (Paa ... Pzz) of a coupling stage connected sub-matrix (e.g. N11) containing characteristic potential n, whereby the individual switches of each set of switches can all be switched on together or individually one after the other, so that the coupling elements of each sub-matrix (N11 ... Nmn) can optionally be tested all simultaneously or one after the other to search for free connecting paths.