DE1191001B - Method for route search and selection of free connection routes in a multi-level field of crosspoints - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. CL:

H04m

German class: 21 a3 - 38

Number:
File number:
Registration date:
Display day:

S 86947 VIII a / 21 a3
August 28, 1963
April 15, 1965

The invention enables the selection of connection routes, also known as route searches, in multiple stages Fields of crosspoints in telecommunications, in particular telephone exchanges in particular expedient way to make.

In order to facilitate the understanding of the route search and selection according to the invention, first the structure, known per se, of fields of crosspoints, briefly referred to as crosspoints, is described. The crosspoints are in the individual stages of the switching network, also called switching stages, arranged like a cross field. Crosspoints which are switched multiple times in rows and columns form a switching matrix.

Coordinate selectors such as crossbar selectors or relay couplers can be used to implement it. At each coupling point there is a coupling element which enters its working state when a connection path leading via this coupling point is established. Here, ao z. B. several so-called crosspoint contacts are operated. A switching matrix has several inputs and outputs, each of which can be differentiated according to its location. Corresponding inputs or outputs of different switching matrices of the same switching stage then have the same space. The switching matrices at which the inputs of the switching matrix are located are also called input switching matrices, and those at which the outputs are located are also called output switching matrices. The individual switching stages of the switching network can contain several switching matrices and are connected via intermediate lines that each have several wires, e.g. B. speech cores and occupancy cores, may have connected to each other in a certain way. The arrangement of these intermediate lines and the associated switching matrices is determined by the grouping plan, which results from considerations of traffic theory. If the intermediate lines are arranged between two neighboring switching stages in such a way that certain switching matrices of one switching stage are exclusively connected to certain switching matrices of the other switching stage via intermediate lines and vice versa, these switching matrices form a so-called switching group which extends over two adjacent switching stages. Several coupling groups are then available within adjacent coupling stages. The intermediate lines are primarily arranged in the switching groups in such a way that at least one intermediate line from each switching matrix of the one switching stage to each switching matrix derbe method for path search and selection of
free connection paths in a multi-level field of crosspoints

Applicant:

Siemens & Halske Aktiengesellschaft,

Berlin and Munich,

Munich 2, Wittelsbacherplatz 2

Named as inventor:

Dipl.-Ing. Ulrich Körber, Munich

adjacent coupling stage leads. In a switching network, several simultaneous connection requests are expediently processed one after the other, so that undesired connections do not come about. The handling of connection requests usually takes place with the help of a central device, which is called a marker here. The marker is connected to the switching matrix, among other things, via information lines. There must also be memory available to store connection orders prior to dispatch to record. There are now inevitably waiting times until the stored connection orders are processed will. Since in telephone exchange systems, the waiting time is partly the duration of a Intermediate voting time must not exceed a quick search and selection process and establishing the connection paths required. The invention now shows a way by which the Route search and selection of connection routes and thus also the establishment and connection of the Connection paths in switching matrices for certain purposes can be carried out faster than before can. Accordingly, it relates to a method for searching for routes and selecting free connecting routes between the input side and the output side of a switching network containing several switching stages Help with applied markings in telecommunication systems, in particular telephone switching systems. These Path search and selection is characterized by the input and output markings supplemented by the additional marking of certain sections of the route lying in the coupling field are which the routing, which is otherwise separated across the entire switching network, is there in each case

509 539/100

in such a way that the route search leads to connecting routes over the additionally marked route sections results, so that with the selected connection path leading via the switching matrix a device connected to an additional path is also connected.

As will be explained in detail, connection paths are often to be established by one first device connected to the input side of the switching matrix via a second device have to lead to a third device connected to the output side of the switching matrix. When using the route search and selection according to the invention, the mentioned second device be connected to a section of the route lying in the switching network, so that because of the additional Marking this part of the way inevitably when processing the relevant connection requests is immediately taken into account. So a connection path is found that immediately connects three institutions connects with each other, i.e. not just two institutions, as is usually the case. Without application the route search according to the invention would be a connecting route between the first and the second Device and separately therefrom a connection path between the second and third device search for and select, for which purpose each time for the purpose of creating markings and switching through the The connection paths found by the markers would have to be used, i.e. in this case as a whole twice. By combining these route searches into a single route search according to the Invention, the marker is now to be claimed only once, so that an advantageous Reduction of the time required to process the connection request under consideration Time span results. The saving of the time span for the separate has a particularly favorable effect The first connection path found is switched through. Shortening the time required is therefore even particularly advantageous, since it is precisely those connection requirements for which three facilities are to be connected, can be processed very quickly, as will be described later will.

If not just a single second in the handling of the connection requests in question Institution comes into question, but one of several similar second institutions, see above you can also mark all of the sections of the path belonging to these facilities at the same time will. This has the advantage that those looking for a route are immediately among the second facilities certainly take into account which of both the first and the third facility can be reached via free stretches of path. Without using the route search according to the invention would be however, this is not ensured. When searching for a route, connections could then result that cannot be continued to the desired first or third facility. This would result in further delays in processing the relevant connection requests to have. To avoid this, special measures would have to be taken, such as a special one Increase in the distances between the facilities and thus those belonging to the coupling field Crosspoints would be. This increase can, however, when using the invention Procedure can be saved.

Even if in the handling of the relevant connection requests instead of a single third party Establishment of several devices connected to outputs of the switching matrix in question come, they can all be taken into account at the same time when searching for a route. They are all then mark at the same time. Several inputs of the switching matrix can be connected in the same way connected facilities are taken into account when searching for a route.

The whole scope and the resulting advantages of the route search according to the invention and The selection can be seen even more clearly in the description of the applications below. The description is carried out with reference to FIGS. 1 to 6. In detail shows

1 shows an example of a grouping plan for a six-stage switching network,

F i g. 2 shows the course of the speech wires α and b in the switching matrix for a connection path between an input and an output of this switching matrix, which leads via a device connected to a path section in between;

F i g. 3 shows an example of a routing network assigned to the six-stage switching network and the associated voting facilities;

F i g. 4 shows a section from the one in FIG. 3 route search network shown for illustration purposes serves a variant;

F i g. 5 and 6 show the circuitry required for actuating crosspoint contacts Setting wires, relay couplers being used as coordinate selectors;

Fig. 7 also shows how the related F i g. 1 to 6 are to be arranged. The brands M must lie together.

The first step is the one shown in FIG. 1 structure of a switching matrix shown and that shown in FIG Representation of the speech veins explained in more detail.

1 shows a six-stage switching network with the switching stages A to F. Each switching stage contains several switching matrices, each switching matrix being implemented by a coordinate selector. So contains z. B. the switching stage A, the switching matrices A 1 to AI, the switching stage B , the switching matrices B 1 to BI, the switching stage C, the switching matrices Cl to Cl etc. The switching matrices of each stage are the same in this example. The inputs of the switching matrix are at switching stage A and are at the same time the inputs of the switching matrix of this switching stage. Each switching matrix of the switching stage A has / inputs and ρ outputs. A part of the switching matrix of this switching stage is connected to a part of the switching matrix of switching stage B via an intermediate line. The switching matrices connected to one another together form a switching group. The coupling stages A and B contain several such coupling groups. Each switching matrix of switching stage B is connected to each switching matrix of switching stage C via an intermediate line. This means that every input of the switching matrix can be connected to every switching matrix of the switching stage C. The switching stages C and D contain, similar to the switching stages A and B, several coupling groups. The outputs of the switching matrices of switching stage D.

are now still connected to the switching matrices El to En of the switching stage E via intermediate lines. From there, intermediate lines lead in a corresponding manner to the switching matrices F 1 to Fo of the switching stage F. The outputs of the switching matrices of this switching stage are at the same time the outputs of the switching matrix. The coupling matrices are only indicated schematically in the illustration, and the intermediate lines are only partially drawn. At the crossing points of the rows, i.e. the rows (horizontal) and the columns (vertical) of the coupling matrices, there are contacts in the coordinate selectors that are assigned to the coupling points located there and are therefore also called coupling point contacts.

So is z. B. in the switching matrix A 1 at the intersection of the / th column and the first row of the crosspoint a IjI, to which the crosspoint contacts Ika 1/1 ... are assigned. Correspondingly, the crosspoint contacts Ikbllm ... are assigned to the crosspoint 511 m in the switching matrix B 1, etc. These crosspoint contacts are looped into the networks of speech cores α and b and the occupancy cores, while certain other switching elements are present at these points in the networks of the other cores are.

The in F i g. 1 represents the scheme according to which the switching matrices or marking nodes assigned to them are connected to one another via the intermediate lines in the networks of the various line cores. The speech wires α and b of the switching matrix are routed via the crosspoint contacts that are located at the crossing points in the switching matrices. The F i g. 2 shows the course of the speech cores α and b between an input and an output, namely a very specific one has been picked out of the many possible connection paths in the switching network. He is z. B. determined by the fact that after the route search, the cross point contacts located in it actuated, that is, are closed. In FIG. 2, however, these crosspoint contacts are shown in the idle state and therefore as open. In this example, this connection path leads from the switching matrix input Tl / to the switching matrix output Z11. The switching matrix input TIj is at the / th input of the switching matrix A 1 of the switching stage A, and the switching matrix output Z11 is at the first output of the switching matrix Fl of the switching stage F. From the switching matrix input TIj , the connection path in this example leads via the coupling point contact 1 ka 1/1 to Output 1 of the switching matrix A1. The multiple circuit symbols drawn to the right and left of the crosspoint contact 1 ka 1/1 indicate that several crosspoint contacts are connected at the same time in the columns and in the rows of the coupling multiple. The left multiple circuit symbol indicates the ρ crosspoint contacts connected to one column, and the right multiple circuit symbol indicates the / crosspoint contacts connected to each row. An intermediate line wire leads from the coupling point contact lkaljl to the input 1 of the coupling matrix B 1 of the coupling stage B. Here the coupling point contact lkbUm is in the connection path. Here, too, two multiple circuit symbols are shown. An intermediate line leads from the m-th output of the coupling matrix Bl to the first input of the coupling matrix Cm of the coupling stage C. The connection path continues via the coupling point contact lkc m Iq , and it goes through the coupling point contacts Ikdmrn, Ikenml and lkflnl to the output ZIl. The first of the devices connected by the connection path considered above is at the switching matrix input TIj, the second is connected to the intermediate line leading from the coupling point contact Ikdmrn of the coupling matrix Dm to the coupling point contact Ikenml of the switching matrix En and is designated W mn. The third facility is located at the switching matrix output ZIl.

The route search and selection in a switching matrix, such as the one described above or in one Switching matrix that is structured differently can be implemented in various ways. There are for this already known several possibilities.

So this z. B. via information lines the operating status of the intermediate lines to Markers are transmitted, in which then the intermediate lines suitable for the connection establishment can be selected and combined, possibly including several possible connection paths one is selected. The marker then effects actuation via command lines the crosspoint contacts located at the respective crosspoints.

But it can also z. B. choosing and combining the intermediate lines not in the marker, but by means of special networks for finding and setting routes, their Line routing corresponds to that of the switching network and which is superimposed on this as a part of the same are. With the help of switching means that are looped into these networks, the actuation of the Crosspoint contacts made for a connection path. Since these switching means individually the Are assigned to crosspoints or intermediate lines, they are to be understood as belonging to the switching network (see German patent specification 1 048 956).

In the route searches mentioned above, connections between the input side and searched and selected the output side of the switching matrix in question, for this purpose there Markings can be created by a marker. These path searches can now according to the invention be designed by these markings by the additional marking of certain im Coupling area lying sections of the route can be added, which would otherwise be across the entire switching area close separated routing there. The ones to the switching matrix on the input side and on the output side created markings are transferred according to the existing routing, which only includes the sections of the road for which they are no longer separated due to the marking of these sections of the road, but is closed. This has the consequence that only such connection paths between marked Inputs and outputs of the coupling matrix are taken into account when searching for and selecting a route, which lead over additionally marked sections of the path. With the selected one leading over the switching matrix The connecting path is then also one that is connected to an additional marked section of the path Establishment connected. So the overall result is a connection path that not only has two facilities, but connects three institutions.

The creation of the additional marking can relate to sections of the road of various types. So can she z. B. be applied to intermediate lines located between two coupling stages, which are im unmarked state are interrupted. However, it can also be applied to switching matrices belonging to a switching stage, where in the unmarked state the routing is interrupted.

First, an example of a route search is described in which the additional marking is applied to intermediate lines and which is carried out with the help of a route search network. In Fig. 3, the associated selection devices and excerpts of the route search network required for this are shown. Only a section of the route search network is shown, namely only the route search arteries belonging to a connection route. There are two wires in each case. The one shown wire, the / -wire, leads over the marker nodes fA 1, / Bl, fDm, fEn and / Fl. ao the other core shown, the g-core, leads from the selection device KVB via the selection devices KVD, KVE and KVF to the selection device PKVF. It also leads over the marking node gCm. The route search network used to search for free route sections suitable for the connecting routes has a structure that corresponds to the route guidance. The markings created are transmitted via this route search network. The wires of this route search network are assigned to the intermediate lines and connected to one another via the marking nodes assigned to the switching matrices. The marker node fA 1 corresponds to the switching matrix A1, the marker node fB 1 to the switching matrix Bl, the marker node gCm to the switching matrix Cm etc.

The already mentioned elective facilities KVB, KVC. .. KVF are located at so-called interfaces that run across the switching network. A section of the route to be used is selected there. So many such interfaces are provided here in parallel to switching stages that a connection path is clearly defined by the selection of these sections of the route. The selected path sections each represent switching matrices. The selection devices are therefore referred to below as switching matrix selectors. First, a section of the route is selected from the marked connecting routes at a first arbitrary intersection and then marked. This interface is located in the coupling stage C. The switching matrix selector KVC is used for selection and marking. The marking provided by it is transmitted in the opposite direction to the original marking in the route search network to other interfaces that are offset in the direction of the input side or output side of the switching matrix. At these offset interfaces, with the aid of the markings that now coincide here, a further possible route segment is selected from the connecting routes containing the selected route segment. For this purpose, among other things, the switching multiple selectors KVB and KVD provided for the switching stages B and D , which each select and mark a further section of the route, are used. The switching matrix selector KVB has as many inputs as there are switching matrices in the switching stage B, i.e. / inputs. Correspondingly, I intermediate lines also lead from the switching matrix Cm to the switching stage B. On the other hand, only q intermediate lines lead from the switching matrix Cm to the switching stage D _1, that is to say fewer than there are switching matrices. This is related to the fact that in the switching stages C and D the switching matrices are arranged to form switching groups. A maximum of q switching matrices of the switching stage D are therefore also possible, via which the connection path can be continued. It is therefore sufficient if the switching matrix selector KVD has q inputs, i.e. fewer than the switching stage D has switching matrices. In this case, however, a switching device (not shown) is to be provided for this switching matrix so that it is connected to the switching matrices of switching stage D of the switching group in question before a selection process. If this switching device is not provided, then as many inputs must be provided in this switching matrix selector as there are switching matrices in the switching stage D , that is to say m inputs. There are now selected and marked more route sections in other switching stages, namely, as already mentioned, so many until the routing in the route search network is established by the opposing markings transmitted from interface to interface and the respective selection of route sections, which is from the input side of the switching matrix leads via a section of the path that is located in the switching matrix and is provided with additional marking to the output side of the switching matrix and determines those crosspoint contacts with whose confirmation the connection path is switched through. For this purpose, the coupling multiple selectors KVE and KVF are required. By selecting one switching matrix in each of the switching stages in question, the connection path is determined if only one intermediate line leads from one switching matrix to a switching matrix of the adjacent switching stage. If not only one output but several outputs of the switching matrix have been marked at the same time, a further selection device is required which determines the output to be actually used. This dialing device is called the PKVF place selector. The additionally marked section of the route is represented here by the intermediate line leading from the switching matrix Dm to the switching matrix En , which is represented in FIG. 3 by the parts of the route search cores leading from the marker node / D / n to the marker node fEn. There two working contacts are inserted, which are designated with lwmn and 2 wmn and which are closed when the additional marking is applied. The device Wmn (see FIG. 1) is connected to the associated intermediate line.

The nature of the route search method provided here, for example, was specified above. Now a few more detailed explanations about that shown in detail in FIG. 3 will first be given Route search network is given, and then associated examples of how to do it are given the route search and selection described in which the measures according to the invention are provided are.

As already indicated, FIG. 3 shows a part of the network of the / and g cores superimposed on the switching matrix, i.e. the route search cores.

9 10

The network of these route search cores is marked after the marking node is set up using the grouping scheme shown in FIG. 1. g-cores are transmitted to the other interfaces. First of all, the marking nodes belonging to the g-cores, except coupling matrices, are replaced by so-called marking nodes 5 the other switching matrix already mentioned, which each consist of a node, in which coincidence gates are also inserted, of which the path search cores connect the coincidence gates UbI, Udm, Ueη and are bound, which are shown in the relevant coupling UfI. These coincidence gates are each associated with multiple intermediate lines connected to an input of the relevant coupling matrix. The shown io lers belonging to the / cores are connected upstream. One input of one of these marker nodes is labeled fAl ... fFl . In the case of coincidence gates, the coincidence gate Ucm is inserted in each case at the relevant mar a marking node, which is not specifically designated kierknoten is connected to the outgoing g-wire there. To the sen. The other input, on the other hand, is at the associated marking node anten gCm belonging to the g-cores, among other things, the marking node / cores. There are still further marking nodes 15 closed. The Mardazu transmitted via a g-vein , which are not specially designated. In this kierpotential therefore only reaches the associated marking node are the switching multiple selectors KVB, gene switching multiple selectors, even if they are inserted on the associated KVD, KVE and KVF. Allocation contacts have been inserted into the / cores and the marking nodes belonging to the / cores and the g cores. Marking potential is. The effect is that they are closed when the associated intermediate line is free when selecting sections of the route on this intersection, and open when it is occupied. You provide only such sections of the route to be taken into account, the presence of which means that created mar- kets lie in connection paths that are selected at the first intersection for the section of the route already selected to be transmitted only over free sections of the route. Into the / -veins that lead to the intermediate line. Were If between the considered section belong, that of the 25 point from the coupling point contact lkbUm and the first interface nor the other coupling multiple Bl lie to the coupling point contact interfaces in which paths pieces excluded Ikcmlq leads of the switching matrix Cm is the loading selected, they will be automatically belegungskontaktlö & clm looped in. The occupancy contact 2 bbclm selected section of the path is also inserted in a connection in the fact that the g-wire belonging to the interface under consideration is taken into account. These two associated movements are in the same operating position via the laying contacts in between. Interfaces leading to selected sections of the route.
In a corresponding manner, the route search and selection for one or more other occupancy contacts are now inserted, describing the connection route through which three already belong together in twos and each have the same pre-determined facilities with one another. In addition, there are people who are looking for the way. This may be one of the decoupling directional conductors looped into the coupling field. The gangway TIj, one at the switching network output are in series with the above-mentioned BeZIl and the one between the coupling stages D laying contacts. The directional decoupling conductor and E connected to an intermediate line are in series with the occupancy contact 1 bbclm in the direction of Wmn (see FIG. 1). The corresponding input and the occupancy contact 2bbclm are connected to the path and the decoupling directional ladder Rbclm in series with the search network. This decoupling associated output is marked. This is done by light guides which are each polarized in such a way that the marking potential applied when closing is applied via them into the coupling field of the contacts IiI / and Iz 11 (see FIG. 3). The contransfer is. But they prevent the Martakt Ixi from also being closed. Its function kierpotential also from the marker nodes via 45 will be explained later. The closure of the other path search cores going out there in inadmissible-mentioned contacts is effected by the backwards in activity to other points of the coupling marker, which is transmitted field not shown here, where it is occupied and therefore is. The open on the input side of the coupling by programming contacts broken field-scale Markierpotential is free intermediate lines improperly bypassed 50 trails assigned / veinlets up to the switching stage E are would. transfer. Since the coincidence gate Ucm has already been inserted into the / wires leading from there to the coupling stage D , which are inserted into a Mar- belonging to the / wires that is inserted into the node in question for the connection. In this coupling stage C, the devices are assigned, for which purpose the first interface is used. Corresponding 55 takt Iwmn heard, it cannot easily get to further coupling stages until coincidence gates are also with the other ones. This is because the routing is inserted transversely marking nodes through these working contacts to the switching matrices of this switching stage. Their outputs are separated over the entire switching network. In addition, the inputs of the coupling multiple selector KVC also indicate the working contacts that are included in the g-wires, which therefore has as many inputs as 60 are added, including the working contact 2wmn . Coupling matrix present in coupling stage C The marking potential can now be from the coupling. It also has just as many exits and only then connects one of these to further coupling stages if one or more of its long, if at least one of the mentioned ones, has been marked in the entrances. At its outputs / wires inserted working contacts are closed, which the coupling multiples of the coupling stage C will pull. There are now connected to the associated marking nodes described here, which belong to the game for the route search and selection through additional network of the g-wires, of which the Mar- borrowed marking the device W mn zugekierknoten gCm is shown. A working contacts Iwmn and 2wmn assigned to such a

closed. Then the marking potential applied on the output side also reaches the coupling stage D, namely to the associated marking node / D m, and from there to coincidence gates at the coupling stage C, provided intermediate lines leading there from the marking node fDm are free. At least the intermediate line may be free here, via the / wire of which the coincidence gate Uc m is reached. If the marking potential applied on the input side is also transmitted there, it also reaches the associated input of the switching matrix selector KVC. This now carries out a selection process in which its marked inputs are taken into account, and marks one of its outputs, here z. B. the output to which the marking node gCm is connected. From this marking node, the marking potential reaches the marking nodes of the coupling stages B and D, in which the coupling multiple selectors KVB and KVD are inserted, via the outgoing and free intermediate lines associated with the g-wires. In the coupling stage B , this includes the marking node into which the coincidence gate UbI is inserted. In this coincidence gate, the original mark and the mark applied afterwards, which emanates from the switching matrix selector KVC , meet. The marking potential is therefore fed to both inputs of this coincidence gate, so that it also reaches the associated input of the switching matrix selector KVB . If the relevant intermediate lines are free, it can also reach other entrances. The switching matrix selector KVB carries out its selection process and marks its output, here z. B. the output associated with the switching matrix Sl. A suitable part of the entire connection path, which leads from the switching matrix input TIj to the switching matrix Cm of the switching stage C , has thus already been determined. This is because the switching matrix Al, at which the switching matrix input TIj is located, is also already determined from the start.

The marking potential applied to the marking node gCm also reaches the marking nodes assigned to coupling matrices of the switching stage D , including at least the marking node assigned to the switching matrix Dm , since the intermediate line leading there is free. In this switching stage, this switching matrix Dm comes into question as a section of the path for the connection path, since the intermediate line to which the device W mn is connected extends from there. The marking potential is also only fed to the coincidence gate Ud m assigned to this switching matrix at both inputs. Namely, as already mentioned, of the marking nodes inserted in the / -wires in the coupling stage D , only the marking node fDm is supplied with marking potential, so that it is only transmitted from there to the coincidence gate Ud m. When the switching matrix selector KVD carries out its selection process, the switching matrix Dm is therefore inevitably selected as the path segment to be used. The assigned output of the switching matrix selector KVD is marked, whereupon this marking potential reaches the coincidence gate Ue η , which is connected upstream of the switching multiplier KVE, via the g-wire going from there into which the closed normally open contact 2 wmn is inserted. The marking potential is now fed to both inputs of this coincidence gate, since it also arrives there from the marking node fEn , to which the intermediate line leads to which the device W mn is connected. Corresponding to the switching matrix D m in the switching stage D , the coupling multiple En is now also selected in the switching stage E as the path segment to be used for the connection path to be sought.

If there is more than one more between the switching stage E and the outputs of the switching matrix

ίο there is a coupling stage, apart from the latter switching stage, further selection processes through the switching matrix provided there take place in order to define the sections of the route to be used for the connection route.

This happens in each case as before the selection of a switching matrix in switching stage B by the switching matrix selector KVB. If, on the other hand, as is the case here in the arrangement according to FIG. 3 is provided, there is only one switching stage, namely the switching stage F, and also only a single output has been marked, then a further selection of path pieces is no longer necessary, since the switching matrix to be used in the coupling stage F as a path piece is already through the only marked output, namely the output ZIl is set. It is the coupling element Fl here. In the arrangement according to FIG. 3 switching multiple selector KVF , which is still provided, is therefore not required this time, nor is the location selector PKVF.

Since all switching matrices over which the connection path is established by switching through the associated Connection route completely determined by itself. The way in which, for example, a connection path can be established by switching through the associated crosspoint contacts, is even later on the basis of FIG. 5 and 6 will be described. It should be noted that the route search handled accordingly if the first interface instead of the coupling stage C is at another coupling stage.

An example for route search and selection will now be dealt with in which, instead of a single device connected to an intermediate line of the switching matrix, several such devices are taken into account, which are accordingly connected to several intermediate lines. When the additional marking is applied, instead of a pair of make contacts inserted in intermediate lines, such as the make contacts lwmn and 2 wmn, now several such pairs of make contacts belonging to the relevant intermediate lines are closed. Accordingly, the marking potential transmitted from the output side of the switching network is not only transmitted from the switching stage E to the coupling stage D via an intermediate line, but also via several intermediate lines. From there it reaches the coincidence gates inserted at the marking nodes of the coupling stage C via free intermediate lines. The coupling multiple selectors KVC and KVB carry out their selection processes in the same way as otherwise, with more coupling multiples being taken into account than in the first example if necessary. The switching matrix selector KVD this time has to carry out a real selection process, provided that the markings have been applied to intermediate lines that arrive at different switching matrices of the switching stage D. Also go from different coupling matrices

the marking potential is applied to several coupling network outputs. In the case of the in FIG. For this purpose, the arrangement shown in FIG. 3 closes the contact lxi, which is connected to several switching matrix outputs. This is indicated by the multiple circuit symbol i . Via other contacts, not shown, which correspond to the contact lxi , several other switching matrix outputs can be marked together. Are belonging to the same switching matrix

the coupling stage E , a corresponding selection process must also be carried out using the coupling multiple selector KVE. The last two selection processes specified at the same time determine an intermediate line which lies between the two selected switching matrices, and thus also the device connected to the selected connection path.

If the intermediate lines to be marked are each connected to the same switching matrix of the coupling matrix outputs to several such contacts level E , this marking can be connected at the same time still insert decoupling directional conductor, this coupling stage of the inserted working contact, to which the decoupling directional conductor Gv 11 belongs. These are taken. However, the otherwise used Arbeitskon- decoupling directional conductors can be omitted if the clocks Iwmn, 2wmn etc. can then be replaced by short-circuit connections belonging to the same switching matrix. The in F i g. 4 outputs shown only with a single such contact cut from the route search network according to FIG. 3 are connected. One-type working contacts connected to via such a contact shows how in the marking nodes of the coupling stage E marked coupling network outputs are to be arranged. It is directions are inserted through this marking as for there at the marking node fEn the normally open contact 20 the connection to the connection path in question wn. All upcoming facilities are designated in a corresponding manner. The availability of other marking nodes, which in this coupling stage or the occupancy of these facilities can be located between the / wires, adds working contacts into their assigned contacts additionally taken into account. Now just come for a connection. So the contact Iz 11 is in question in this case as devices that are assigned to intermediate lines 25 occupancy contact of the device that are connected to the switching matrix output IZ11 in the same switching matrix. the switching stage E come off, so is the additional When this facility is occupied, the contact mark of the associated paths pieces, ie the Iz 11 is open.

The relevant intermediate lines, especially the working The previous description of the route contact is now closed, which is inserted in the associated search and selection by the description of the pre-order node. It is therefore then added to the inputs that are also processed, the output side of the switching matrix applied when several switching matrix outputs are marked at the same time marking potential just over the outgoing there. You can also transmit to coupling stage D on different / wires. Since the switching multiples of the switching stage F are. Provided that the relevant working contact is inserted like all the other corresponding corresponding outputs with free Einricheeintriche inserted at the different coupling matrices at the same time marked in such a way that it is connected before the branching of the lines from there, in this case from a wire leading to a coincidence gate If the output side of the switching network is open, according to Schlie- (see FIG. 4), only the relevant coincidence of the contact lxi becomes the marking potential to the avoidance gate of the switching stage E from the output side 4 ° reren marking nodes of the switching stage F and thus the switching matrix, also to several Markierknoten of the coupling stage e has her supplied with Markierpotential what the result that the switching matrix voters, etc. the way search and selection wrap at KVE only candidate switching matrices of all switching stages, except for the coupling stage F, just switch stage I? in its selection process as usual, it is therefore only included in the coupling process. With the help of the occupancy contacts, which are inserted into the 45 stage F by a selection process of the coupling selection intermediate lines, to which a switching matrix is also connected in this coupling gene, the KVF can also be selected into account. The switching matrix selector KVF will determine whether the devices connected to the additionally marked interconnects as well as the other corresponding switching lines are free multiple selectors in the marking nodes of the associated or occupied. In the case of occupied devices, the coupling stage, here the coupling stage F, is inserted and also lent the associated intermediate line occupied, and carries out a selection process accordingly, so that the occupancy contacts inserted there are carried out in the given case.

opened. In general, it is to be expected that no markings will be transmitted via these intermediate lines, and there will be several couplers that are not marked when searching for a route and selecting field exits for which the free facility is not taken into account. Several can easily be connected. In this case there is now even more switching matrices outgoing links
can also be marked by closing the contacts inserted at the associated marking nodes. Corresponding working contacts have 60 because outputs. Its inputs are also connected to the rest of the arrangement in the case of those between the wires. Marking nodes of the coupling stage D -be provided, where they have appropriate functions.

When searching for and choosing a route, you can not only

several specific paths in the switching network 65 of the switching stage F are connected. So is z. B. the first

pieces and thus the setup input connected there with the first output of each of these

lines, but also at the same time several switching matrix switching matrices connected, namely with the one there

outputs are taken into account. In this case, each lying / -wire. Besides, each is the

select one of these switching matrix outputs. In addition
the PKVF place selector is used. It has as many inputs as a switching matrix of the switching stage F

Each input is via a coincidence gate,
of which the coincidence gate £ 7/11 is shown with
an assigned output of each switching matrix

15 16

mentioned coincidence gates via a g-core with which belong to telephone switching systems. There those output of the switching matrix selector KVF are z. B. in the following operating case, three differently connected, which is assigned to that switching matrix of the Kop- dene devices at the same time to connect with each other to pelstufe F, at which the output is located, bind. From a subscriber station already provided with a keyboard selection device with its / -wire the coincidence gate 5 are connected via which is connected. One input of the in FIG. 3 associated subscriber circuit dialing information in the coincidence gate shown UfU is therefore sent with the development belonging to the form of multi-frequency code characters to the transmission of the coupling multiple Fl, which is initially received there and / -wires and the other input via a g-wire in the form of number switch pulse series a line leading to another office with the output associated with the switching matrix F1 is connected to the switching multiple selector KVF . are to be admitted, which goes from one in the exchange itself its output is with an input of the place-lying line termination circuit. The voter connected to PKVF. Corresponding multi-frequency code characters are to be implemented at this input in further correspondingly switched coincidence number switch pulse series, for which a gate is connected, namely as many as coupling multiples, referred to below as signal converters, are present in coupling stage F. This contributes to the direction. Such a conversion is indicated by the multiple circuit symbol ο. mostly required. In general, it is not to be expected at the other inputs that dialing information in the course of the place selector PKVF will not be displayed in the form of multi-frequency code characters connected to a coincidence gate set. (This part can also be processed in other offices, since the arrangement shown in FIG. 3 is also set up in German patent 1062 761 for most offices still in conventional technology. Such offices are only for the purpose of writing.) Processing of Number switch pulse series on - The PKVF place selector guides its selection device. In the operation considered above, after the switching matrix selector KVF 95 case, three devices have selected a switching matrix in the exchange. At its to be connected to each other, namely the mentioned partial matching output, the marking potential receiving circuit, the signal converter and the line, which all the line termination circuit upstream of the place selector, occur. Thus, taking into account coincidence gates are supplied which are also assigned to the three different devices of this switching matrix. There are 30 ways to look for and choose. If now all s coincidence gates, since a switching matrix has these devices in an expedient manner at the switching stage F in each case s outputs. If the same switching network are connected upstream, this s coincidence gate is done by the multiple circuit symbol s drawn in by the invention there, that is, interpreted by means of a single path search. One of the inputs of this 35 and selection are therefore used, as a result of which the suitable connection s coincidence gate is supplied with marking potential. away is found very quickly. It is only with those coincidence gates that a line termination circuit to serve the other inputs is generally also supplied with marking potential, from which a line is connected in a certain direction with / -wires that go out in these th direction, the by previously arrived switching matrices marked outputs with free 40 dialing information that belong in the facilities. These coincidence gates provide apt mediation that has been processed by itself. the marking potential to the associated inputs. The dialing information that arrives afterwards must be passed on to the PKVF place selector , who then immediately forwarded it so that it does not carry out the selection process. The inputs and outputs are lost. Appropriately, therefore, the gears of this place selector are sorted by place from the path search and selection for the connection of the entered subscriber circuit of the switching matrices of the switching stage C with a subscriber circuit in question, as has already been mentioned. Among the line termination circuits and a possible place here, an out-signal converter is now selected by the marker preferably in the, which also defines the one for the connection path to compare to the path search and selection for output that is used differently. 50 like connection requests are handled. Therefore, the device connected there by the type of different connection requirements then serve the connection path established with the an- z. B. to connect a dial tone source connected to one of its two facilities. If a subscriber circuit is also provided, in the associated part of which at coupling stage A a switching multiple selector and subscriber station just lifted a place selector, then at 55 is. A longer waiting time is permitted here, since the person who is searching for a route may also select several participants in a corresponding manner only after the arrival of the other or even all inputs instead of just one dial-in tone. The preferred dispatch of the switching network are taken into account. The low route search and selection, on the other hand, must be handled in the marking on the input side of the switching matrix of the intermediate dialing time, which can therefore also be applied to part of the 60 located there where the dialing of two digits through the relevant inputs. The same goes for those who lie to the participant.

The subscriber circuits to be applied to the output side of the switching network are

Marking as already described. Also connected wisely to inputs of the switching matrix. The signal converters to be additionally applied to sections of the route in the coupling matrix, each for the relevant Marking can each have to be taken into account on a part of the connection requirement for this, designated sections of the path are laid out. are then connected to the outputs of the switching matrix

The route search described above and excluded during the line termination switching is particularly recommended for switching matrices. at the intermediate between two coupling steps

interconnections are connected. Usually there are several outgoing lines in the same direction with associated line termination circuits available, so that each for a connection request several line termination circuits must also be taken into account. So it's a connection establish a subscriber circuit for the input side of the switching network, furthermore all free signal converters connected to the relevant outputs of the coupling matrix and all Free line termination circuits are to be taken into account, of which lines in the desired Going off direction. If only a signal converter and only a suitable line termination circuit are free, only three individual facilities need to be taken into account when requesting the connection. In all cases, the route search and selection according to the invention can be advantageous be applied.

When the delivery of the dialing information via the subscriber circuit is finished, the occupied Signal converter no longer required. It is very useful then that of the line termination circuit to separate the signal converter leading part of the switching path, which with the help of Marker can be carried out. This makes the previously assigned signal converter available for other assignments free. Likewise, the intermediate lines, etc. leading there are free and can be used by others Purposes. The one leading from the subscriber circuit to the line termination circuit On the other hand, part of the connection path is only to be disconnected after the end of the associated call.

When searching for a route and selecting it, as well as with other processes mentioned, a was not specified explained marker used. The mode of action of such markers is already known, so that it does not need to be discussed further. The marker to use here also ensures that the connection requests are processed one after the other, by temporarily applying marking potential to certain points in the route search network. Then the crosspoint contacts belonging to the connection path found are to be actuated, whereby this connection path is switched through. As already mentioned, the switching matrix realized by different types of coordinate selectors, such as crossbar selectors or relay couplers will. The way in which the selected connection path was switched through depends on the type of coordinate selector used. In the German patent specification 1 048 956 are already several examples of how to search for a route and select the relevant one Route sections to switch through the connection route when using coordinate selectors is described in detail. The one for actuating the relevant crosspoint contacts provided switching means are in a network of so-called setting wires superimposed on the switching matrix looped in. To hold the actuated crosspoint contacts, switching means may have to be provided, which are connected to a network of so-called assignment cores.

The F i g. 5 and 6 show details of examples of networks that are required for actuating crosspoint contacts when relay couplers are used as coordinate selectors. These networks and the processes that take place in them to connect a connection path are described below. The network shown in FIG. 5 is constructed according to the grouping plan shown in FIG. 1. However, there are marker nodes instead of the switching matrices. Decoupling directional conductors and special auxiliary setting relays are looped into the intermediate lines. In Fig. 5, the relays Hbc Im, Hcdmn, Hde mn and Hefnl are shown. No auxiliary setting relays are looped into the intermediate lines between coupling stages A and B. Contacts of the relevant switching matrix are connected to the marker nodes which are located in the switching stages in which switching matrixes are present in the route search network. Of these contacts, the contacts kvb 1, kvcm, kv dm, kv en and kvf 1 are shown in FIG. Each switching matrix selector activates a contact when searching for a route.In the example already described, the switching matrix selector KVC, which is located at the first interface, first activates contact kvcm, and then the two neighboring switching multiples KVB and KVD activate contacts kvb 1 and kv dm. Furthermore, the contact kve η by the switching multiple selector KVE and possibly also the contacts kve η and kvfl are actuated by the switching multiple selector KVE and / CFF. In addition, the marker closes the contact 2 ti j. The actuation of all these contacts has the consequence that the auxiliary setting relays required in each case are energized. These auxiliary setting relays are located in the individual intermediate lines and are therefore assigned to them. They have contacts with the aid of which the relevant intermediate lines can be energized in the network shown in detail in FIG. 6. The setting windings of the coupling relays, from which the relay couplers are built, are looped into this network. When the auxiliary setting relays operate their contacts, here the contacts hbclm, hcdmn, hdemn and possibly the contact ran η 1 and at the same time from the marker the contacts 3 ti j and the contact 3 ζ 11 belonging to the switching network output in question or the one belonging to the place selector Contact pkvfl are closed, the coupling relays belonging to the selected connection path are energized. These coupling relays then operate their associated contacts, including the coupling point contacts. As a result, among other things, the speech wires of the selected connection path are switched through. In addition, the coupling point contacts inserted there are also actuated in the associated occupancy wires, not shown here.

Claims (9)

Patent claims: 1. Method for route search and selection of free connection routes between the input side and the output side of a number of coupling stages containing switching matrix with the help of applied Markings in telecommunications, in particular telephone switching systems, thereby 509 539/100 characterized in that the input-side and output-side markings by the additional marking of certain sections of the route lying in the coupling field are added, which close the routing, which is otherwise separated across the entire switching network, in such a way that that the route search via the additionally marked sections of the route leading connection routes results, so that with the selected, leading via the switching matrix connection path also one connected to an additionally marked section of the path. 2. The method according to claim 1, characterized in that the additional marking is applied to intermediate lines between two coupling stages (Cl-C mlD 1-Dm) which are interrupted in the unmarked state. 3. The method according to claim 1, characterized in that the additional marking is applied to switching matrices (El .. .En) belonging to a switching stage, in which the routing is interrupted in the unmarked state. 4. The method according to any one of the preceding claims, characterized in that the as search for free, suitable for the connecting path sections by means of a route corresponding to the routing and the markings applied over free path sections transmitting path search network, the veins (/ veins and g- Cores) are assigned to the intermediate lines as well as marking nodes (jA 1 ... / Fl; ... gCm ...) assigned to the switching matrices (A 1 ... Fl) are connected to one another and through which so many interfaces are placed parallel to coupling stages , on each of which a section of the route to be used is determined that a connection path is clearly defined by selecting a section of the route (Cm) from the connection paths marked on both sides to determine these sections of the route at a first arbitrary interface (coupling stage C) and then marking it, this latter marking opposite to the original marking in the route search network to w Further interfaces (switching stages B, D, E, F) are transmitted, which are offset in the direction of the input side or output side of the switching matrix, after which at these offset interfaces with the help of the markings that coincide here from the connection paths containing the selected path segment, another in each case in The route section (B 1, Dm, En, Fl) that is coming into question is selected until the routing in the route search network is determined by the opposing markings transmitted from interface to interface and the respective selection of route sections, which is from the input side of the switching matrix via a and in the switching matrix A section of the path provided with additional marking (intermediate line from Dm to En) leads to the output side of the switching matrix and determines those coupling point contacts whose actuation switches the connection path through. 5. The method according to any one of the preceding claims in the switching network of a telephone switching system, characterized in that it is used to connect a subscriber circuit connected on the input side to the switching network (at TIj) with a line termination circuit (Wmn) connected in the desired direction to the path section provided with additional marking a signal converter connected on the output side to the switching matrix (at ZIl) for dialing information arriving via the subscriber circuit. 6. The method according to claim 5 for connection requests, each using a Markers are dispatched, characterized in that it is compared to the route search and Select for different connection requirements, such as connecting a dial tone source with the relevant subscriber circuit, is preferably carried out. 7. The method according to claim 5 or 6, characterized in that, after the delivery of dialing information on the subscriber circuit has ended, the part of the connection path leading from the line termination circuit (Wmn) to the signal converter (at ZIl) is disconnected, while that of the subscriber circuit (at TIj) to the line termination circuit (Wmn) leading part of the connection path is only disconnected after the end of the associated call. 8. The method according to any one of the preceding claims, characterized in that the additional Marking to be applied to the route section in the coupling matrix only on a part of the relevant route sections lying in the coupling matrix is created. 9. The method according to any one of the preceding claims, characterized in that the Marking on the input side and / or the output side of the switching matrix only to one Part of the inputs / outputs located there is applied to the available facilities are connected. 1 sheet of drawings 509 539/100 4.65 © Bundesdruckerei Berlin