DE1238964B - Circuit arrangement for telecommunication switching systems, in particular telephone switching systems, with multi-stage switching networks - Google Patents

Description

Circuit arrangement for telecommunications switching systems, in particular Telephone exchanges, with multi-stage switching networks The invention relates on a circuit arrangement for telecommunications switching systems, in particular Telephone exchanges in which connections are made via multi-stage switching arrangements and their connection paths (intermediate lines) are switched through and in which parallel to all signal wires that can be interconnected in coupling points and coupling stages (e.g. speech wires) of the connection paths setting circuits for in the crosspoints individually provided coupling switching means are arranged.

It is known that in such arrangements there is a multiplicity of connection paths between the couplers in each case of two successive coupling stages. These connection paths are also known as intermediate lines. In general, individual couplers are combined into coupling groups in such coupling arrangements. Several switching groups form a switching matrix. In a z. B. four-stage switching matrix are a first and second or third and fourth switching stage within each of these two switching stages comprising coupling groups through intermediate lines connected to each coupler. Likewise, from the second to the third coupling stage, the couplers of all coupling groups are connected to one another by bundles of intermediate lines.

In such coupling arrangements there is the task of establishing connections to a specific input (or output) of a coupler of the first (or last) coupling stage across all coupling stages with a specific or yet to be determined output (or input) of a coupler the last (or first) coupling stage. Here arises as another object, depending on a suitable free to select from a plurality of paths between two switching stages, thereafter to make a through connection over a plurality of such series-connection paths. The well-known methods developed for this purpose are also referred to as "route search methods".

A known circuit arrangement for route search now provides a route search network which represents a structural image of the switching matrix. One switching point corresponds to each coupler in the coupling network. Corresponding to the connections of the couplers by intermediate lines, the switching points are connected to one another by route search wires in such a way that a route search wire is always provided for each intermediate line. In the respective intermediate lines Wegesuchadem contacts of relays are connected intermediate line corresponding to the Z, state of the intermediate line, whether free or occupied by their switching state - addressed or not addressed - labeled. The selection of a suitable one of several free through-connection paths through the entire switching network is then carried out by a central marker, which has insight into the respective switching state of the Cresamten path search network, depending on this switching state. Accordingly, the marker switches through a connection via the response circuits of the coupling relays.

A derartiae arrangement has the disadvantage that it must be used in a switching matrix for each existing intermediate line per line an intermediate relay. To avoid this effort, circuits for switching matrices have already been proposed that the state of the intermediate lines (whether free or occupied) electrically, z. B. by the presence or absence of certain potentials, at certain points of the intermediate lines, such as the holding wire, and in which test relays of a central marker are switched on for a connection possibly coming into question intermediate lines, through which the status of the intermediate lines in question from the marker is checked. To determine suitable free intermediate lines located between every two of all coupling stages, which are each connected to one and the same coupler in successive coupling stages, the contacts of the test relays in the marker form a coincidence circuit according to the structure of the switching network, by means of which, firstly, those free intermediate lines are determined which can be switched through with one another and, secondly, those coupling points (e.g. coupling relays) are marked via which the switching is to be carried out. Such a circuit arrangement for central markers proves to be particularly advantageous because the effort of a link relay for each link can be saved by reproducing the structure of a large coupling field in the coincidence circuit formed from the test relay contacts, i.e. only one compared to the number of links requires a much smaller number of test relays in the central marker.

Since now the structure of a switching network is analogous in the coincidence circuit of test relay contacts concentrated in the marker, drag changes changes in the marker in the structure of the switching matrix. these can may cause considerable difficulty if there is a possibility of changes of the switching matrix has not been taken into account from the outset in the structure of the marker is. Furthermore, an in itself easy to overlook, to be carried out by the maintenance personnel Change in the switching network, its intermediate lines provided between two switching stages z. B. over # eir a marshalling distributor are necessary in such a way through additionally changes in the marker that are going to be analogous, but completely different that the involvement of special forces will be necessary.

It is also undesirable to make changes in a central marker to be carried out, as switching errors can easily occur due to changes and any change temporarily pulls this out of operation in central sections.

The object now is to avoid the described disadvantages of known arrangements, namely to specify a circuit arrangement which does not require any changes in the marker when there are changes in the switching network. This object is achieved according to the invention in that by means of the state, d. H. Whether free or occupied, the connection paths (intermediate lines) indicating circuits of the same individually connectable test switching means, the occupancy status of each of the connection paths can be determined, that the pre-switching means can be effectively switched analogously into the setting circuits of the coupling switching means assigned to the connection paths for connecting the connection to mark the respective occupancy status of a connection path, and that a route search can be carried out via the setting circuits in which the test switching means are effectively switched. The invention thus advantageously uses the setting network (response circuits in all switching stages) of a switching matrix as a route search network, after which, for the purpose of determining which connection paths (e.g. intermediate lines) of successive coupling stages allow a connection to a specific output (or input) in coincidence , the occupancy states (whether free or occupied) of the connection paths have been determined by central test switching means of the marker and have been marked by them in the corresponding setting circuits of the same connection paths. Then the running over several successive coupling stages setting circuits are switched to low resistance, so that the corresponding coupling switching means are effective, that is, for. B., coupling relays respond.

This invention can be used in a particularly advantageous manner in switching networks are used in which i firstly a path search only after determining a single free output to be connected to a specific occupied input and in which, secondly, a grouping is provided by the one Interface with the same coupling level as seen through the response and stopping network, clearly only ever one single path from a point of this interface (e.g. an intermediate line or a crosspoint) to a specific input or output of the switching matrix can be switched through. The route search carried out at this interface then establishes the points at the interface from which the particular input or output can be reached via intermediate lines of several coupling stages, and selects then select one of these points, which clearly creates a switchable connection referred to from this point to the particular input or output in question is. If the route search at the interface is carried out by a coincidence check with regard to made of the definite entrance and the definite exit, so can thereby the point of the interface selected and designated over which a unique Switching through the entire switching network is possible.

According to a further embodiment of the invention, the holding wires lead unused connection paths no potential and the holding wires of occupied connection paths a potential over which the test switching means are excited when they are connected to them will. This makes it possible to save any switching means per retaining wire, through which a potential that characterizes their free state is attached to the holding wires in their Free state would have to be switched on, as it is, for. B. in known circuit arrangements It is customary to use high-ohmic resistances for each holding wire to have a characteristic of its free state To connect potential to this.

According to a further embodiment of the invention, the test switch means at the same time also serve as route search switching means.

In the F i g. 1 and 2, an exemplary embodiment of the invention is shown in components that only contribute significantly to the understanding of the invention, to which, however, the same is in no way restricted.

In Fig. 1 shows an overview of a switching network that is constructed in four switching stages KA to KD. Couplers K 111 to K 4 n 0 are connected to one another by intermediate lines in a known manner, so that through-connections from each input to each output of the switching network are possible. In Fig. 2 shows some circuits of a connection path running through the entire switching network, with the aid of which a path search, a path selection and a through connection can be made. Furthermore, some circuits of a central marker are shown, through which a route search, route selection and setting of coupling relays in the entire coupling network is possible.

The structure of a switching network according to FIG. 1 is known per se. The couplers of a 1st to 4th coupling stage are combined into coupling groups on the one hand in the 1st and 2nd coupling stage and on the other hand in the 3rd and 4th coupling stage. So belong z. B. the couplers K111 to K110 and K211 to K210 to form a coupling group. All couplers of the 1st switching stage of this switching group are connected to couplers of the 2nd switching stage of this switching group via intermediate lines in the intermediate line field Z l. The same applies to the other coupling groups. To connect the various coupling groups to one another, their couplers in the 2nd and 3rd stage of the coupler are connected to one another by intermediate lines in the intermediate line field Z2. Between the intermediate line box Z 2 and the 3rd switching stage KC a marshalling Rg is provided, can be changed via the interconnection of the couplers of coupling stage 2 and 3 according to need. So it can be B. happen that for certain traffic relationships stronger trunk groups are required. Is z. If, for example, there is particularly heavy traffic between the couplers KM and K411, the bundle of intermediate lines that is between ZL1 and ZL10 in FIG. 1 can be reinforced at the expense of other intermediate line bundles.

The grouping in the switching arrangement according to FIG. 1 is chosen so that when searching for a route on the intermediate lines in the intermediate line field Z2, after a single input and a single output have been previously determined by identifying an intermediate line in the intermediate line field Z2, the entire connection path is clearly defined. If, for example, the intermediate line ZLIO is determined by the route search to be used for a connection between a certain input on the coupler KM and a certain output on the coupler K411, then it is determined that the desired connection via the couplers 210 and 310 of the 2nd or 3. Coupling stage is to be switched through. Furthermore, since the couplers KM and K411 of the 1st and 4th coupling stage are designated by the specific input and the specific output, and since only a single intermediate line is provided between each coupler of the 1st and 2nd or 3rd and 4th coupling stage is, by selecting an intermediate line in the intermediate line field Z 2 when searching for a route, a through connection with regard to all couplers and intermediate lines can be clearly determined. For the determination of an intermediate line in the intermediate line field Z 2 when searching for a route, it is essential which of these intermediate lines can be switched through via free intermediate lines in the intermediate line fields Z 1 and Z 3 to a specific input and to a specific output.

The principle of the route search is based on FIG . 2, a grouping according to FIG. 1 being assumed.

It is now assumed that in FIG. 1 , subscribers TN are connected on the input side and relay connection sets RS are connected on the output side. If a subscriber wishes a connection, he must first be connected to a free relay connection set, which is initially determined in a manner not described in detail here. Since the calling subscriber is also a specific connection, so, as already mentioned, its input and output, which are to be interconnected, are already established in the switching matrix before the route is searched. For the route search based on this, many different, but not all routes are available in the switching matrix; for a connection between a particular input and a particular output of the switching matrix may firstly in the 1st and 4th switching stage only depending on a particular coupler, namely only on the on which this input or output is turned on, and secondly in the 2nd and 3rd coupling stage can only be switched through via couplers that belong to the same coupling group as the respective couplers of the 1st and 4th coupling stage. Thus, a connection from a subscriber (TN) connected to the coupler KM to a relay connection set (RS) connected to the coupler 411 can only be established via these couplers in the 1st and 4th coupling stages KA and KC and only via the couplers K 211 bis KZIO or K311 to K310 in the 2nd or 3rd coupling stage (KB and KQ and consequently in the second intermediate line field Z2 can only be switched through via one of the intermediate lines ZL1 to ZL10.

Simultaneously with the marking order to switch through a certain subscriber with a certain relay connection set via the switching network, the marker M (Fig . 2) receives the information from a corrector (not shown) about which couplers and intermediate lines of the various coupling stages KA to KD and the different ones Intermediate line fields Z1 to Z3 this through-connection can only take place. An example of this has already been described above. If the marker now receives the marking order, based on the information mentioned, it only connects to those intermediate lines that are between the specific couplers. For this purpose, the marker contains connection relays An (not shown), of which the corresponding ones connect the marker M to the specific intermediate lines. These connection relays are thus selectively excited; they can also be combined to form a separate interface coupler which is controlled as a function of the information about the particular coupler and intermediate lines to be used.

Contacts of these connection relays are shown in FIG. 2 and denoted by an 1 to an 11 (numbered consecutively).

The in Fig. The switching matrix shown in FIG. 1 thus has couplers KM to K4n0 with inputs and outputs, as well as intermediate lines connected to them and a jumper distributor Rg. The intermediate lines in the intermediate line fields C Z 1 to Z 3 are shown in FIG. 1 each only represented by a single line. In Fig. 2 is shown in more detail that the intermediate lines and the coupling points connected to them via the inputs and outputs (formed by coupling relays A to D of the coupler) C all have several circuits, namely signal wires Ad 1/2, z. B. speech wires whose through-connection is of the entire arrangement via the switching network of meaning, further one each Ansprechader A d4 and j e a retaining wire A d 3. These designations A d 1/2, A d 3, A d 4 in the intermediate line box Z 2 apply through-C continuously for the entire switching network from a subscriber TN to a relay connection set RS. The in F i g. 2 are thus provided in the coupling stages KA to KD per coupling point (that is, several times in a coupler) and in the intermediate line fields Z1 to Z3 per individual intermediate line.

C, In order to carry out the route search through the marker, the marker switches itself on, as described above, selectively to certain intermediate lines that are eligible for switching. The marker for this purpose has per inter-line box Z 1, Z 2 and Z 3 each such a large number (eg. 10) of Zwischenleitungsprüfrelais (ZPL; ZP2, ZP3), as intermediate lines come in each intermediate line box in each case for a connection through-connection in question. In Fig. 2, only one of these link relays is shown per link field. If the intermediate line relays ZP1, ZP2, ZP3 are now connected to their holding wires to check the occupancy status (whether free or occupied) of the intermediate lines, the intermediate line test relays respond in the free state of the tested intermediate line, since the holding wires Ad 3 of the intermediate lines are potential-free when the intermediate lines are free ; on the other hand, link test relays respond if the checked link is busy, since the holding wire then carries a partial voltage potential that is not equal to ground potential in all link fields Z1 to Z3. The link test relays have a corresponding response sensitivity and are so high-resistance that they do not noticeably affect existing holding circuits. They are preferably designed as electronic assemblies.

The response wires Ad4 of all intermediate lines that are considered for a through-connection and therefore connected to the marker are switched through via zp ... As a result, speak of the relays WP in the marker . . ., of which only one (WP 1) is shown, those that find current-permeable response circuits across all coupling stages and in the intermediate line fields ZPl to ZP3 via closed zp ...- normally closed contacts. For this purpose, the participant TN and the relay set RS to be connected to it were previously marked by the marker on the response circuits via the contacts mt and mr. It is now assumed that of the relays WP 1 ... the relay shown WP 1 and the relays WP2 and WPn respond, of which the latter only the contacts 1 wp 2, 2 wp 2, 1 wp n and 2, nlpn are shown . These relays WP1 ... are also so highly resistive that their response current does not effectively excite the coupling relays in their response circuits via their coupling relay windings A (1), B (I), C (I), D (I) can. If the relays WP1, IVP2, WPn have responded and this indicates that through-connection is possible via the corresponding intermediate lines of the second intermediate line field, this means that in all switching stages and intermediate line fields, coupling points and intermediate lines for a through-connection via the relevant intermediate line in the intermediate line field Z 2 are ready. A selection is made via the contacts 1 wp 1, 2wp 1, lwp2, 2wp2, lwpn, 2wpn of the addressed path search relay WP1 ... in that one of the relays G 1 to G n responds, in this case relay Eq. Via its contact gl, the response circuit (response wire AD 4) of a single intermediate line suitable for connection in the intermediate line field Z 2 is switched through with low resistance across all coupling stages. In the circuit earth, mt, an1, v, TN1A (I), A (I), GL1, an2, zpl, an4, B (I), GL2, an5, gl, zp2, an7, (RG), C ( I), GL3, an8, zp3, an10, D (1), GL 4, RS 1 A (1), u, an 11, mr, - now the coupling relays A, B, C and D speak, as well as a relay TN1A in the subscriber circuit TNI of the calling subscriber and a relay RS 1 A , which is the occupancy relay in the marked relay connection set RS1. These relays A, B, C, D, TN 1 A and RSIA form a holding circuit Ad 3 via their own contacts, in which they remain held for the duration of the connected connection until this holding circuit is switched by switching means (not shown) in the subscriber circuit TN1 or in the relay connection set RSlA , e.g. as a result of tripping, is disconnected. The marker is disconnected from the coupling matrix after the coupling relay has responded and its holding circuit has been formed. By forming the holding circuit, the holding wires in the relevant intermediate lines are also identified as occupied in the manner described above. The test result of each of the link relays is fixed in the marker in a manner not shown, so that the response of the coupling relays A to D can not subsequently have any influence on the route search and route selection.

Through the coupling relays, the desired connection is switched through via their coupling contacts a112, b1 / 2, c1 / 2, d1 / 2 , which can be one-, two- or multi-wire.

By marking the occupancy states of the intermediate lines located in the intermediate line fields Z 1 and Z 3 in their address cores, the route search can be carried out on the intermediate lines of the intermediate line field Z2, whereby the occupancy of intermediate lines in the intermediate line fields Z 1 and Z3 is also evaluated. This route search principle allows changes to be made in the switching matrix d without them being changed in the marker z. B. need to be taken into account by an analogous change; because the marker uses the response route network as a route search network, into which the occupancy states of the intermediate lines are marked. Changes in the coupling matrix also always relate to the address wires - because they belong to the intermediate lines - they inevitably relate to the circuits used by the marker to search for a route.

Thus in FIG. 1 a jumper distributor Rg is provided between the second link field Z2 and the third switching stage KC. At this, without interventions in the marker are necessary, changes in the routing can be made by the maintenance staff of a telephone system, through the z. B. the bundle strength of intermediate lines can be adapted to the requirements according to the traffic load of the individual components of the switching system.

Instead of the method used here for marking the free state of Intermediate lines through floating holding wires can be used to implement the invention the condition of intermediate lines is also marked and checked differently on the holding wires will. However, the method of marking used here and exam and the status of the link (whether free or busy) can, as already suggested, additionally secured against the creation of double connections. That is achieved in that a final route search and switching through has been carried out Switching through the connection is still prevented until a Acknowledgment is given that the switched through in the switching network, before the through-connection as free checked paths are now occupied.

Claims (2)

Claims: 1. Circuit arrangement for telecommunication switching systems, in particular telephone switching systems, in which connections via multi-stage coupling arrangements and their connecting paths (intermediate lines) are switched through and in which parallel to all signal cores (e.g. speech wires) of the connection paths that can be interconnected in the coupling points of the coupling stages, setting circuits for the Coupling points individually provided coupling switching means are arranged, characterized in that by means of the state, d. H. whether free or occupied, the connection paths (intermediate lines) indicating circuits of the same individually connectable test switching means (relays Zp 1, Zp 2, Zp 3 with their contacts zp 1, zp 2, zp 3) the occupancy status of each of the connection paths can be determined that the test switching means, (Zpl, Zp2, Zp3) can be switched into the setting circuits (Ad4) of the coupling switching means (A, B, C, D) assigned to the connection routes for the connection through-connection to mark the respective occupancy status of a connection route and that a route search via the setting circuits (Ad4 ), in which the pre-switching means are effectively switched, can be carried out. 2. Circuit arrangement according to claim 1, characterized in that the test switching means (M, ZP2, ZP3) can be connected to the holding wires (Ad3) of the connecting paths. 3. Circuit arrangement according to spoke 2, characterized in that the holding wires (AD 3) of unoccupied connection paths have no potential and the holding wires of occupied connection paths carry a potential via which the test switching means (ZPI, ZP2, ZP3) are effectively energized when they are connected to them. 4. Circuit arrangement according to claim 1, characterized in that in the setting circuits (Ad4) of the connecting paths between the coupling stages (KA, KB, KD, KC) contacts of the test switching means, in particular relay row contacts (zpl, zp2, zp3), can be switched on. 5. Circuit arrangement according to spoke 4, characterized in that the setting circuits (Ad4) free connection paths from the test switching means (ZPI, ZP2, ZP3) can be switched to be current-permeable. 6. Circuit arrangement according to claim 1, characterized in that the setting circuits (Ad4) path search switching means (WP1, ...) can be switched on and that the coupling switching means (KA, KR, KC, KD) are thereby not effectively excited. 7. Circuit arrangement according to claim 6, characterized in that the path search switching means (z. B. WP 1), which are particularly high-resistance, can be connected in series with the coupling switching means (KA, KB, KC, KD) in the setting circuits (Ad4). 8. Circuit arrangement according to claim 6, characterized in that the route search switching means (WP1, ... ) bring about a selection of one of these by means of selection switching means (G1, G2, ... Gn) and in the selected connection route in the presence of several connection paths suitable for switching through switch through the setting circuit (Ad 4) with low resistance. 9. Circuit arrangement according to spoke 6, characterized in that the test switching means also serve as path search switching means. 10. Circuit arrangement according to claim 6, characterized in that the route search switching means (WPI, ...) recognize the availability of connection paths of several subsequent coupling stages (KA, KB, KC, KD) during the route search via the setting circuits (Ad4). 11. Circuit arrangement according to claim 1, characterized in that the route search relates to already fixed end points (input and / or output) of the switching network. 12. Circuit arrangement according to spoke 11, characterized in that the selection of one of several possible free paths for switching through a connection between the two end points in a certain switching stage or on the connection paths (e.g. hu intermediate line field Z2) between two certain coupling stations is made by there is a certain cross point or connection path is selected, and in that only each is a single path to each of the endpoints of this coupling point or connection path.