DE1487900C - Circuit arrangement for telecommunications, in particular telephone switching systems, with multi-stage switching matrices - Google Patents

Description

In telecommunications switching systems with switching matrices, it is in the interest of the highest possible Utilization of the lines and coupling switching means provided that connections are essential over the switching matrix, z. B. of inputs, can only be switched through to outputs that have both are free as well as verifiable, the z. B. are connected to a free line. There are now Switching systems for telephone purposes known, in which this is to switch through a connection first one of its inputs via a switching matrix after an incoming occupancy of one of its inputs Outputs is determined in accordance with a direction desired by the calling party a free line leading in this direction is selected; then are through a route finding process free switching means, e.g. B. Crosspoints, in couplers of the various Switching stages and free intermediate lines in the switching network determined that lead to a through-connection

can be used, and then via a certain path through the switching matrix a corresponding connection switched through.

Since it can happen that after preselecting a free line in the desired direction, a Through-connection in the switching network due to internal blocking of the same not to this free line is possible and that a connection to other free lines would be possible, that is one per se possible connection cannot be established, a circuit arrangement that has meanwhile become known has become known (German Auslegeschrift 1 062 761) for the control of switching matrices developed in the search for a route between a certain, incoming occupied entrance and several exits, to which lines leading in the desired direction are connected, all free paths in Switching matrix from this input to the outputs determined by the choice with regard to it checks and selects whether the respective exit to which a path leads is also free. the Route search and route selection in the switching matrix thus includes all routes in the switching matrix, those of the particular one Incoming occupied input lead to outputs, which are determined by the choice as are also verifiable. By selecting certain outputs are marked for this purpose. This well-known Circuit arrangement contains a route search selector through which a first search selection process Path between on the one hand the coupler of the first coupling stage to which the incoming occupied input is connected, and on the other hand a coupler of the last coupling stage is selected, at its outputs at least one free, marked line, i.e. one line of the selected direction, connected. This selection of the ones leading to the coupler of the last coupling stage Intermediate line, this becomes a coupler for the through-connection and one of the to its outputs connected outgoing, free lines intended for assignment for this connection. Further contains the said, known circuit arrangement a so-called "place selector", i. H. a search dial, that in a second search selection process from the outputs of the selected in the first search selection process Coupler selects a line switched with a free marked line. Known by this Circuit arrangement, it is possible, if there is a brokerage order, both all free To take into account lines of the desired switching direction as well as all paths in the switching network, which somehow lead to these lines.

There are a number of switching systems in a switched telephone network, such as those described Type, provided, and connections between subscribers on telecommunications switching systems different locations (e.g. districts, localities) can be connected via cables between two telecommunications switching systems are produced each time. The lines between telecommunications switching systems form a bundle of lines which, viewed from each of them, corresponds to one direction. Multiple telecommunications exchanges at multiple locations are through a number of trunk groups connected with each other. The bundles of lines form a network, the structure of which is star-shaped, mesh-shaped and also mixed star-shaped / mesh-shaped. Networks with a mixed Structure adapt optimally to the individual traffic needs.

For connections between subscribers of telephone exchanges in different locations there are usually various transport options. A connection can be made through an or Several trunk groups (one after the other in the case of through connections via several lines in series

ίο telephone exchanges), which are preferred for a connection can also be established via other trunk groups that represent a detour that should only be used if the trunk group that represent the direct route, are busy. For a traffic relationship (connections required between two switching systems at different locations) often apart from the direct route also several detours via different line

special bundle provided. The use of detours is only possible if the direct route is occupied he wishes; the detours with regard to the occupancy of a line between each other are also to be preferred. As is well known, aspects of economic efficiency play an essential role here.

In a network that is organized based on a pure star network and that a hidden mesh network is superimposed, one speaks of the direct route mentioned above as the first cross-line bundle and in the case of the detours according to the order in which they are occupied preferred are from the second, third, etc. trunking bundle; the last detour is in usually the so-called key figure path or the main direction.

Can connect to many others from the central office in one location Locations, also referred to as destinations, are each established via several trunk groups, so usually leads a specific trunk group on the direct route to the desired one Destination; lead one or more other trunk groups, e.g. B. via switching systems to several other places in through traffic, via more or less economically favorable detours.

To control each of the destinations from a switching system, a few specific of all connected trunk groups come into question. In the interest of optimal economic efficiency, there is a ranking order also determined by the destination, according to which they are each to be used for selection, among the line bundles that come into question for each destination. For example, three locations A, B and C can be reached from one location X via three assigned trunk groups 1, 2 and 3; furthermore, the locations A, B and C are connected to one another by a mesh network. For connections from location X to location A , the following trunk groups can be used for selection in the following order of priority: 1, 2, 3. For connections from location X to location B, on the other hand, the following trunk groups can be used for selection in the following order of priority: 2, 1. For connections from location X to location C, however, the following trunk groups can be used for selection in the following order of priority: 3, 1, 2. For a circuit arrangement for telecommunications switching systems, in particular telephone exchanges

Auxiliary systems with multi-level switching matrices, in which the outputs of couplers of a last switching level connected to lines (e.g. local and long-distance lines) can each be reached via different routes from the switching matrix inputs, which can be selected alternatively by means of a route search, and in which one specific Coupling network input connected path search potential in particular, spreading like a fan, marked all couplers accessible via free intermediate lines and in which, after selecting one of these couplers of the last coupling stage and a single path from the specific coupling network input to this coupler, a corresponding connection is switched through from the switching network input via the last-mentioned coupler to a switching network output and with bundles of lines that combine the lines, in particular depending on the direction, and of which the lines suitable for reaching a specific destination, in a ranking order dependent on this, for the purpose of B. elegung a free line are available, the possibility was supported by the Patent 1226 165 provided already in the routing choice in a switching matrix, the respective rank order, 'in which the bundles _a5 of devices connected to the outputs of the switching network lines in response to the respectively to be driven destination for a connection establishment come into question, thereby decisively taking into account that a route selection is made with a single route search process, the result of which already includes the result of the routing. The connection of lines to the outputs of the switching matrix could thus be designed freely, so that lines of the same bundle can be connected to the outputs of different couplers of the switching matrix as desired.

The subject of patent 1 226 165 is a circuit arrangement of the type just described, which is designed in such a way that all trunk groups suitable for reaching a respectively selected destination are marked by a central marker at the same time and that on the basis of coincidence formation between the route search markings and the line bundle markings and on the ground the order of precedence determined by the destination, the free lines for all to reach one each selected destination suitable trunk group are available at the same time, whereupon a free line is selected from that of the said line bundle, which with regard to this Precedence is the first in which at least one free line is available.

In the circuit arrangement according to patent 1226165, said coincidence formation carried out jointly for each trunk group or part of the trunk group. For this purpose are for each switching matrix output individually provided contacts for transferring the route search marking with contacts provided for each line bundle or bundle part joint transmission of the line bundle marking can be interconnected. Both of these Contacts can be interconnected to form coincidence circuits, each with a plurality of Coupling network outputs (trunk group or bundle part) are common.

The object of the invention is to provide the circuit arrangement according to patent 1,226,165 to that effect to improve and further develop that a change in scope or a rearrangement the connection position of the bundle of lines does not necessarily mean an internal change in the for said coincidence formation provided interconnection of the contacts of both types according to themselves pulls.

This object is achieved in that one per output of the last switching stage of the switching network Coincidence gate is provided, the gate output of which is used to mark the switching matrix output, provided that one connected to the coupler of the last coupling stage corresponding to the coupling network output first gate input receives path search potential and one with the to the switching matrix output connected line connected second gate input a voltage potential indicating their free state receives and via a third gate input one of the identification of all For reaching the selected destination, suitable lines serving to mark potential are switched on is, and that one of the marked switching network outputs corresponds to the order of precedence is selected.

The mentioned coincidence formation between the possibly multiple criterion of the successful Route search and the markings of the controlled line bundle is according to the invention made individually for each line connected to a switching matrix output. Changes with regard to the scope or a rearrangement of the connection position of the trunk groups are only by a correspondingly changed connection of the inputs of the coincidence gates according to the invention to undertake. Changes are made much clearer because they are individually per Line can be run. Furthermore, the line selection aims directly at a single free reachable Management of the most suitable bundle of cables to reach the selected destination. Since the selection process no longer extends to line bundle and line selection, it is no longer affected by the changes and rearrangements mentioned. The invention creates the possibility of a telephone exchange system designed accordingly at any time and without much Adjust effort to new traffic conditions in the telephone exchange network. Through an according Execution variant multi-stage selection among the lines mentioned is the one mentioned The selection process is much clearer and faster.

In the figures, an embodiment of the invention is only essential for their understanding contributing components shown.

In Fig. 1 shows a switching network whose couplers are arranged in four switching stages KA, KB, KC and KD . The individual couplers are shown as broad, vertical lines. The number of inputs of a coupler is shown on the left and the number of outputs to the right of each coupler. Its ordinal number is given below each coupler. The switching matrix shown in Fig. 1 is intended for an expansion of 1000 inputs and 1000 outputs. It is divided into input coupling groups with 100 inputs each and output coupling groups with 100 outputs each.

A coupler in the coupling stage KA has 10 inputs and 16 outputs. These 16 outputs lead as intermediate lines to inputs of the 16 couplers in the switching stage KB of the same coupling group. The couplers in the coupling stage KB also have 10 inputs, corresponding to the 10 couplers in the coupling stage KA that belong to an input coupling group. Intermediate lines lead to 10 different output coupling groups via each of the 10 outputs of the couplers of the coupling stage £ 5. The input coupling groups and the output coupling groups are constructed symmetrically. Each of the outputs of a coupler in the coupling stage KB leads into a different output coupling group to a coupler in the coupling stage KC with the same ordinal number.

Even with partial expansion, all outputs of the couplers in the coupling stage KB must be connected to the inputs of the couplers in the coupling stage KC in order to avoid major internal blockages of the coupling network. This results in parallel routing of intermediate lines. This means that several intermediate lines lead from a coupler in the coupling stage KB to one and the same coupler in the coupling stage KC . With a partial expansion of z. B. only two input coupling groups and output coupling groups lead five intermediate lines from each coupler of the switching stage KB to one and the same coupler in the switching stage KC in one coupling group and five other intermediate lines to one and the same coupler of the switching stage KC in the other output coupling group. Each time an input coupling group and / or output coupling group is added, the number of intermediate lines to be routed in parallel changes. The then necessary rearrangements are carried out at a marshalling distributor labeled RV , which is arranged between the coupling stages KB and KC.

By using this mesh-like grouping in the switching matrix, each input can reach each output in 16 different ways, the result is negligibly smaller internal blocking an almost complete accessibility and thus a good use of the outgoing expensive trunk lines. Each outgoing line is only sent to a single output of the Connected switching network. The high load of each output makes any mixing in the unnecessary Switching matrix.

In Fig. FIG. 2 shows an overview of a telephone exchange in which the system shown in FIG. 1 is shown switching matrix is reproduced in a simplified manner. It is represented by four vertical lines drawn next to one another, which are named with the coupling stage designations KA, KB, KC and KD . In the course of establishing a connection, an AZIG counting pulse generator is initially assigned. It is connected to a registering for outgoing traffic via a two-stage relay search selector RSW. The dialing information running into the register via the counting pulse generator is saved there. After a sufficient number of digits has been saved to establish a connection, these are transmitted to an AUM corrector. Using the digits entered, the operator recognizes the desired destination, which is also referred to as the “destination”, and marks a destination point in a marker AMK assigned to him. The destination point identifies all of the outputs of the switching matrix that come into question for the relevant destination.

At the same time, an occupancy potential acts from the marker AMK via the corrector A UM, the register ARg, the search selector RSW and the counting pulse generator AZIG at the input of the coupling matrix to which the counting pulse generator is connected. With the help of this occupancy potential, this input is first marked in preparation for the connection. In addition, the occupancy potential has the effect that path search potential is applied to the relevant coupler of the coupling stage KA. In Fig. 3, a corresponding part of a routing network is shown schematically for an input coupling group and an output coupling group. Anyone who is shown in FIG. The coupler shown in FIG. 1 corresponds to a path search node shown in FIG. 3. The path search node of a coupler of the coupling stage KA can receive path search potential via any of the 10 inputs of the corresponding coupler. This arrives via the 16 path search wires of the coupler of the coupling stage KA to the path search node of the 16 couplers of the coupling stage KB of the same input coupling group, provided the path search wires belong to free intermediate conductors. In the course of each route search artery there is a contact, for example Ia , Ib, Ic, of an intermediate line relay assigned to this respective intermediate line, for example LA, LB, LC (FIG. 3). Contact 1 α of a link relay interrupts the corresponding route searcher if the link in question is occupied. In Fig. 3 the intermediate line relay contacts are indicated by vertical lines that cross the associated path search cores. Each achievable by routing potential routing node in the switching stage KB is the potential on the routing wire whose intermediate line relay contacts 1b are at rest, corresponding to the couplers of the coupling stage KC routing node on. This process is repeated at these, so that finally all path search nodes of the couplers of the coupling stage KD that can be reached via free intermediate lines from the marked input receive path search potential.

In the route search network in FIG. 3, a coincidence gate with three gate inputs is assigned to each of the 10 outputs of each coupler of the coupling stage KD. A first, d, of these gate inputs receives path search potential if the path search node of the corresponding coupler of the coupling stage KD carries path search potential. A second gate input c receives a control potential when the line associated with the relevant output of the coupler of the coupling stage KD is free. A third gate input r receives a marking potential from the marker AMK if the output belongs to a line bundle which is identified by the above-mentioned marked target point. The coincidence gate has an output signal when the three input signals described are present at the gate inputs.

A single one of all coincidence gates marked in this way is selected by the AMK marker. The selection process takes place in three phases. In the first phase, if coincidence gates from different output coupling groups, an output

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signal, a single output coupling group selected. In the second phase, a coupler of the coupling stage KD is selected in this output coupling group if AND gates have output potential that correspond to outputs at different couplers of a coupling group in the coupling stage KD. In the third phase, a single one of the outputs of the selected coupler of the coupling stage KD is selected and marked in preparation for the connection. With the marking of the input of the switching matrix and the selection of an output of the switching matrix, the path through the switching matrix is not yet clearly determined. However, it is ensured that with the selection of one output of the switching matrix, at least one path can be switched through via the switching matrix. In total, depending on the occupied state of the intermediate lines, there are a maximum of 16 possible routes, of which a single route must be determined in a further selection process.

In the above-mentioned second phase of selecting an output, a coupler of the coupling stage KD was selected. As a result of this selection, one of several relays Z , described in greater detail below, is energized, which is individually assigned to this coupler of the coupling stage KD. With a total of 16 contacts, it connects the 16 path search wires leading from the coupling stage KC to a path search node of the coupling stage KD to the marker AMK . In the 16 lines leading to the AMK marker, the path search potential appears on those whose corresponding couplers of the coupling stage KC can be reached from the marked input and whose intermediate lines to the selected coupler of the coupling stage KD are free.

One of the maximum 16 possible intermediate lines is selected by the marker and thus a coupler of the coupling stage KC via which the connection is to be switched through. This selection is made in the AMK marker with the aid of a viewfinder SU1 . Since with full expansion between the last-mentioned coupler of the coupling stage KC and the coupler of the coupling stage KA, whose input has been occupied, only a single path can be switched through via a single coupler of the coupling stage KB , by marking the response circuits of the inputs of the last-mentioned coupler of the coupling stage C corresponding intermediate lines of the connection path to be switched through via the switching matrix are completely marked. In Fig. 5, the marking is indicated by a contact g 16 for a single one of the intermediate lines. The occupied input of the switching matrix and the selected output of the switching matrix are marked by negative potential. The couplers are set in a known manner. The response coils of the coupling relays of the couplers are combined in a known manner in a control matrix constructed like kreuzfei and decoupled from one another with the aid of decoupling rectifiers. The coupling relays form, via their own contacts, in a known manner a holding circuit which runs over the coupling field and in which their holding windings are kept energized for the duration of a connection. The relay coils of the aforementioned intermediate line relays are also included in this holding circuit in a manner known per se. The circuit details previously referred to as known and only partially shown and described can be found in German Patent 1,062,761.

After an overview of the entire functionality of the switching system shown in the figures and a description of details of the control of the 4-stage switching network has been given by the above explanations, the functionality of the marker AMK , which explains the present invention in particular, is then shown.

Each output coupling group (coupling stages KC, KD) is assigned an auxiliary setting set with connection coupler. From the marker AMK (Fig. 2, 6 and 7) a line manifold, hereinafter referred to as marker cable MRK , leads to all auxiliary setting sets EH (Fig. 6) of the output coupling groups of the switching network. These can be connected to this marking cable with the aid of the auxiliary setting sets and the connection couplers assigned to them. The auxiliary setting kit and the connection coupler are shown together in FIG. 6.

As previously with reference to FIG. 3, a coincidence gate KG is assigned to each output of the switching matrix. One of these coincidence gates KG is also shown in FIG. 6 shown. From this representation it is particularly evident how the marking potential used to identify all lines suitable for reaching the selected destination reaches the third gate input r of the coincidence gate KG.

The third gate input r of the coincidence gate KG thus receives marking potential when the relevant output of the coupler is connected to an outgoing trunk line that belongs to the selected direction. In order to be able to arrange the outputs of an output coupling group on the lines of the various traffic directions clearly and freely, a jumper field RF is provided in the auxiliary setting set EH , which has as many jumper points on one side (the upper side in FIG. 6) as there are outputs in the output coupling group are available. It is assumed that there are a total of 100 outputs per output coupling group, ie also 100 routing points in the routing field RF. These jumper points are permanently connected to the third gate inputs of the 100 coincidence gates KG. On the other side of the patch panel RF another number is provided from the second shunting that can be freely connected together with the first-mentioned shunting rl to rlOO. To select an output of the switching matrix, the marker AMK provides one of the points B ... and thus all points r ... assigned by the routing with marking potential.

The gate outputs / all coincidence gates KG are connected to rectifiers (G 1) and contacts (17 z 1). Said rectifier, e.g. B. Gl to GlO, form a mixer that is permanently assigned to the first coupler of a relevant coupling group. Such a series of rectifiers, eg Gl to GlO or G 91 to GlOO, is permanently assigned to each coupler in a coupling group.

If, as previously described, one of the directional points, e.g. B. Bl, marked, so all those lead

11 12

Points IAl to 10 ^ 410 to select a corresponding line and the corresponding

value potential whose associated switching matrix outputs to mark the corresponding output of the switching matrix,

are connected with lines that lead to the desired- In addition, there is a choice from a maximum of 16 routes

leading traffic direction and also to meet freely and in the coupling network; after all is how to

via the switching matrix from the occupied input. 5 already shown after selection

are reachable. From the amplifiers Vl to FlO, a single path via the switching network of these

each for a coupler in the coupling stage KD upstream (contact g 16) on a response wire of an intermediate

are seen, all those are opened, interconnection between the switching stages KB and KC

to mark the at least one of the gate inputs i the.

associated coincidence gate an evaluation potential io . Among other things, the AMK marker (FIG. 7) has been preserved. If at least one of the above-mentioned groups of a bundle selector BW is indicated, which is controlled to select stronger Vl to FlO, a criterion is sent via the marker cable via one of a maximum of five possible traffic directions and the wire h , which is used to control the selected HRC to the marker AMK, which indicates this, destination come into question. The outputs that lead in this output coupling group at least one trunk selector BW (shown on its upper side), output of the desired traffic direction to the five steps and one busy step, is available. If this criterion in the markers of several AMK Einstellhilfs- to five vertical Ordinatenleitungen a kosätzen EH single ordinatenförmig built Überlaufrangierfeldes hits, as detailed below described UR. The abscissa lines shown horizontally ben, a single one of the several output coupling 20 lead to the inputs 1 of the z. B. total groups selected by the marker AMK . As 38 direction coincidence gate RKG. The inputs 2 result of this selection is with one of these one of these are marked with further abscissa lines of an auxiliary setting set EH, the wire H , which is connected in the target point routing field ZR , whose lower right ordinate lines for the destination marking gates UZl to UZlO are activated are connected to the corrector A UM . In both ordered amplifiers Fl to FlO on controlled wor- patch panels UR and ZR can be ordinates. From the marking cable cores ζ 1 to ζ 10 lines and abscissa lines through in detail all those are connected to an evaluable rectifier, not designated. Potential through the coincidence gates UZl to UZlO In the destination routing field ZR , the one destination is supplied whose coupler numbered with the same number in the ordinate coupling stage KD corresponding to that shown vertically in the ordinate coupling stage KD for a further selection escapes with those traffic directions. As a result of this selection, a single line is connected by the speaking, horizontally displayed ordinate marker AMK in the auxiliary setting set EH , via which the selected destination of the individually assigned to the couplers can be reached. In the overflow routing field UR , contacting relays Zl to ZlO are energized, with rectifiers (not designated), the search row outputs i of the coincidence gates KG of the - as previously defined by a corresponding insertion of a total of 10 contacts shown in FIG. 6 , to which the various traffic descriptions - selected coupler of the coupling directions are subjected. Since a traffic level KD via the wires el to elO of the marking direction in each case several trunk groups corresponding to kabeis MRK switches through to the marker AMK , which can 40, a bundle routing field BR is also a single one of the possible views, in which the corresponding assignment outputs of this coupler of the coupling stage KD from bundles to traffic directions through dials in by causing that unmarked rectifiers fixed to the response points, the circuit of the relevant output is negative.

tial to the marking is switched on. This minus 45 The bundle selector BW is at the beginning of the Marpotential is in FIG. 5 at the lowest output of a kier process is set to its step 1. When coupler indicated. A corrector simultaneously by a UM-Zielortsinfor was then reference to FIG. 7, the working mation is given zil via the line, so as the marker AMK receives explained. As can already be seen from the jumper balancing shown in FIG. 2, the corrector 5 ° direct the direction coincidence gate RKG1 to A UM and the marker AMK work closely with one another to its two inputs 1 and 2 control potential. If the corrector of elected partial The output of the direction coincidence gate RKG participants the choice of information about the registry ARG provides a control potential on the beam receiving, it is a destination information to the ranking BR, namely the corresponding direct-marker on. With this information, richter knows which bundle amplifier BV has reached. Which the marker, which target the desired connection bundle amplifier BV delivers via the marker cable should reach. This goal can optionally be achieved MRK a marking potential to the coincidence gates via different traffic directions of all those exits (FIG. 6), which have a single direction with the line of preference belonging to the lines belonging to the marker in a certain corresponding bundle are switched. These lines can be found on couplers. A traffic direction selected by different output coupling groups is therefore preferably to be checked first. First be switched. If at least one of the marked exits in this traffic direction does not have at least one free line and the busy input line is free or accessible, one can be reached via the switching matrix, 65 line h of the respective auxiliary setting set EH is used for checking the second traffic direction will. If a certain traffic direction has been selected in the AMK marker, seeker SU1 (FIG. 7), then this traffic is allowed. If this is not done because there is no corresponding bundle of cables and no aisle is accessible, the bundle is

13 14

selector BW advanced by one step. After the connection selected output of the coupling

the one shown in FIG. 7 shown example of the routing is defined in the field.

then the bundle ß2 via the bundle amplifier BV 2 The searchers -5171, SUl and SU2> have one of

marked. Assignment to assignment moving starting position,

If none of the maximum 5 outputs of the directional coupler in relation to a destination are possible

times five possible trunk groups to be controlled evenly and to use in the event of a fault

can be, the bundle selector BW is based on its in the initial search the effective range of this disturbance

Occupied step GS set, which keeps the corrector low.

AUM and the AMK marker are triggered. Finally, it should be mentioned that with the help

whereupon the dialing subscriber is busy io the contacts of the relay Z ..., z. B. the contacts

character is sent out. IzI to 16ζ 1, the route search arteries with the help of the

During a marking process, seeker SU 2 selected coupler of the coupling stage usually has several output coupling groups, in KD of its inputs to one of the seekers SU 1 until at least one exit is free, accessible and St / 3 similar seekers are switched through to control the selected destination suitable 15 This viewfinder, in Fig. 4 with AMK / SU4 is symbolic. Each of these output coupling groups transmits indicated, takes a signal from a cable MRK via the line h of the marker route search cores assigned to it, which carry route search potential. This multiple signals selection before, by which a single coupler is marked via the lines hl to hlO the same output coupling group in the coupling stage speaking of the maximum of 10 steps of the searcher 20 KC . To the contacts of the SUl. This takes a selection of the offer input-side intermediate lines of this coupler before and featuring one of the lines Hl up as shown in Fig. 5, g to the contact H reasonable 16 40 over which indicated the respectively assigned output, connected to ground potential, whereby the Coupling group marked as the selected one, the occupied entrance to the selected exit. 25 connection to be switched through clearly

It has already been described that this criterion is identified and marked. Now the terium is switched through via the wire H in the setting aid EH entire connection.
(Fig. 6) arrives and here the coincidence gates UZl As described above, UZlO are reached for the training. Some of these coincidence selections of a free accessible line and gates give an output signal that is provided via the bundle selector as well as the searcher. The speaking lines ez 1 to et 10 of the marker bundle selector has the task of reaching the marker AMK via its outputs kabeis MRK . Submit marks. If a first exit is thereby started, the searcher SU2 , which is marked as each, then all those switching fields around which a selection is made and outputs marked with regard to an association of the lines EZ Ibis EZ 10 are marked accordingly. As a result, the connection request in the first rank for the promise in the connection switching selected by the searcher SU1 come into question. The so setting aid egg? one of the relays Zl to ZlO on. With this selection, a single coupler of the named searchers is each a signal, provided they can be reached via the out- coupling network already selected by the searcher SU1 and the particular coupling group via which the connected line is free is determined . Hits when marking is to be switched through. No signal was sent to the viewfinders F i g by means of the bundle selector. 4 explains how, on the basis of this selection, the bundle selector switches its marking one step further to the route search in the switching matrix, because the further selection processes marked first are ongoing. With the help of line at least either not free or not contacts, for example 17ζ 1 to 26ζ 1, one of the addressed 45 was accessible.

nen, z. B. Zl, these relays are the gate- The selection process is thus handled by

outputs of the bundle selector and the viewfinder correspond to the selected coupler. The marking

corresponding coincidence gate KG via the cables, routed via the patch panels UR, ZR,

el to elO of the marking cable MRK to the marker BR and RF (Fig. 6 and 7) on the one hand and the search

AMK switched through. 50 and selection boards e. .., h ..., H ..., ez ■ ■ ■

The inputs of the viewfinder SU3 are connected to the and EZ ... (FIGS. 6 and 7) on the other hand, are each connected for cores el to elO of the marking cable MRK . This means that each switching matrix output can use the. Those coincidence gates KG of the selected coupler with the line connected to it in the selected output reference to each controlled destination individually coupling group, whose assigned outputs are free 55 of the order of preference when selecting a line accessible via the coupling matrix and subject to the establishment of a free line will. The number of connections that are suitable send a signal via the lines el to elO that are to be used for checking during a selection process, the respective lines being switched on by the viewfinder SU 3 and a marker AMK and the setting aid set EH Makes selection among them. One of the cores El 60 is not specified in a restrictive manner. It is also possible to mark it ElO, whereby the corresponding borrowed, the lines of line bundles in completely marked output and the c-wire of this output is used freely distributed over the switching network outputs. Thus, the one for the through-connection has to be connected to this in a scattered manner.

For this purpose 2 sheets of drawings

Claims (7)

Patent claims: 1.Circuit arrangement for telecommunication switching systems, in particular telephone switching systems, with multi-stage switching matrices, in which the outputs of couplers of a last switching stage connected to lines (e.g. local and long-distance lines) can be reached via different routes from the switching matrix inputs that can be selected alternatively by a route search and in which path search potential connected to a specific switching network input, in particular, spreading like a fan, marks all couplers accessible via free intermediate lines and in which, after selecting one of these couplers of the last switching stage and a single path from the specific switching network input to this coupler, a corresponding connection is made from the switching network input the last-mentioned coupler is switched through to a switching network output, and with bundles of lines which combine the lines, in particular depending on the direction, and of which the lines to be exited each b A certain destination suitable, in a ranking sequence dependent on this, are available for selection for the purpose of occupying a free line, with all line bundles suitable for reaching a respectively selected destination being marked by a central marker at the same time, and based on the formation of coincidences between the route search markings and the line bundle markings and on Because of the ranking order determined by the destination, the free lines of all trunk groups suitable for reaching a respective selected destination are available for selection at the same time, whereupon a free line is selected from that of the above-mentioned trunk group that is the first in terms of this ranking order in which at least one free line is selected is available, according to patent 1226 165, characterized in that per output (e.g. B. Ue in FIG. 2) the last switching stage (KD) of the switching network is provided with a coincidence gate (e.g. KG) , via whose gate output (/) the switching network output is marked, provided that a first gate input connected to the coupler of the last switching stage (KD) that corresponds to the switching network output (d) receives path search potential and a second gate input (c) connected to the line connected to the switching matrix output picks up a voltage potential indicating its free state and via a third gate input (r) a marking potential serving to identify all lines suitable for reaching the selected destination is connected , and that a single one of the marked switching network outputs is selected according to the order of precedence. 2. Circuit arrangement according to claim 1, characterized in that the outputs gate outputs corresponding to a coupler (i) are combined via a mixing gate (e.g. Gl to GlO) assigned to the coupler. 3. Circuit arrangement according to claim 2, characterized in that outputs (Fl) of the Mixing gates assigned to the couplers (e.g. Gl to GlO) via additional, multiple couplers jointly assigned mixing gates (GlOl to GIlO) are combined. 4. A circuit arrangement according to claim 3, characterized in that in a multi-stage selection process (5171, 5t72, 5i73) first a selection among the multiple couplers common mixing gates (GlOl to GIlO and others) and then among the mixing gates each assigned to a coupler (Eq to GlO, ..., G 91 to GlOO) and then under the coincidence gates (KG, ... ) assigned to each coupler output. 5. Circuit arrangement according to claim 4, characterized in that several central search selectors (SU 1, 5172, 5i73) are provided in a corresponding number for the multi-stage selection process. 6. Circuit arrangement according to claim 1, characterized in that when a destination is selected (e.g. marking zi 1) according to the order of precedence, the identifications of lines of different line bundles step by step one after the other and for each level at the same time on the lines connected to the switching matrix corresponding third gate inputs ( r) can be switched on. 7. Circuit arrangement according to claims 5 and 6, characterized in that the markings by a marker switch, for. B. a bundle selector (BW) can be switched on, which is switched from marking step to marking step as a function of time, provided that no marking is issued via any of the outputs (/) of the marked gates (KG) and is received by one of the searchers as a search stimulus.