DE2553411B2 - Circuit arrangement for telecommunications switching systems, in particular telephone switching systems, with switching matrices with reverse grouping - Google Patents

Description

The main patent relates to a circuit arrangement for telecommunications switching systems, in particular telephone switching systems, with a switching matrix, which consists of switching matrices in several over interconnection lines interconnected switching stages is built, and at the inputs of its first switching stage all lines (e.g. subscriber lines, local and trunk lines) and all inputs and Outputs of necessary for connection establishment and connection monitoring per connection Switch elements (z. B. dial receivers, connection sets and the like) are switched on, and in which Outputs of the switching matrix of the first to penultimate switching stage to the inputs of the switching matrix each downstream coupling stage is switched on and can be interconnected in pairs in this, and which is divided into switching matrix parts, at the inputs of which the subscriber lines, connecting lines and the switching elements required for each connection are connected, and in which the switching matrix parts are each assigned their own sub-control units and in which the switching matrix parts with their outputs in the Way are connected in parallel, so that all have the same name with regard to the switching matrix parameters Coupling network outputs of the various coupling network parts individually with one another in one of the number of KoDDel

Field outputs per switching network part the same number of multiple circuits are connected.

Circuit arrangements according to the main patent allow a very simple expansion of switching systems. For this purpose, only the outputs of a switching matrix part that is to be additionally provided for an expansion need to be connected to an already existing group of multiple circuits. The individual assignment of sub-control units to the switching matrix parts creates the possibility, with a suitable size limitation of the latter, to dispense with a doubling of the common sub-control units, which is usually carried out in known cases for safety reasons. A duplication of common control devices for safety reasons is known to be necessary in those cases in which a malfunction- related failure of the common control would make a switching system as a whole or an impermissibly large part of the switching system temporarily inoperable. Due to a suitably dimensioned size limitation of the switching matrix parts, a doubling of each of the subcontrol units common to each switching matrix part can be dispensed with. The number of multiple circuits mentioned, provided for parallel switching of the switching matrix parts on the output side in the smallest expansion state, is dimensioned so that these are sufficient up to a specified maximum number of switching matrix parts for the traffic load occurring therein.

The object of the invention is to provide a circuit arrangement according to the main patent to improve and further develop that a number of switching network connections are provided can, which is greater than the product of the one hand due to the size limitation of the switching matrix parts conditional number! of switching network connections per switching network part and on the other hand the maximum number of switching matrix parts is.

This object is achieved in that the number of the multiple circuits one Switching matrix of the connected switching matrix parts is smaller than the number of switching matrix parts, which from the maximum traffic load capacity of the multiple circuits of a switching network results, and that in one Switching system a plurality of switching matrices is provided, the several groups of switching matrices are assigned, with one switching matrix belonging to different groups and the switching matrices each belonging to a group at the same time different other groups, each group being a different one Combination of switching matrices includes, and that of the multiple circuits in each case a group of Switching matrices each have an identical part per switching matrix connected by individual multiple connections are, each only between the multiple circuits of the switching matrices of the group in question run by adding a multiple connection to each of the multiple circuits of the various switching matrices this group connects with each other. bo

The invention makes it possible to increase the number of switching network connections. Since the number of switching matrix parts connected to the multiple circuits of a switching matrix is smaller than the number of switching matrix parts resulting from the maximum traffic load capacity of these multiple circuits, these multiple circuits can in turn be interconnected in the manner according to the invention through the multiple connections between the multiple circuits of the various switching matrices without the traffic load of multiple circuits and multiple connections being exceeded in an inadmissible manner. If one were to connect all multiple circuits of all switching matrices individually to one another, and only ever those with switching matrix parameters of the same name, one would again obtain an arrangement corresponding to the subject matter of the main patent. However, the invention differs from this in that, on the one hand, the multiple connections connect the multiple circuits of several switching matrices with one another, but on the other hand not each of the multiple connections is routed to the multiple circuits of all switching matrices. The principle of the Staff one is shown in Fig. 3 of DE-AS 15 62 133 and explained with reference to this diagram. Because each of the multiple connections runs only to a part of the multiple circuits of the plurality of coupling springs, significantly more multiple connections can be provided in the present case than can be provided for multiple circuits in the case of the main patent. For this reason, and since the traffic load is also distributed over a total of more multiple connections, a total of more switching matrices can also be provided. As a result, the number of switching network connections can consequently be increased in their entirety. - It is expedient here to maintain the size of each of the switching matrix parts with regard to an effective range of the effects of an interruption of operations on a narrowly limited number of subscriber connections and / or connection-specific facilities, such as connection sets, line sets and the like, in the event of a failure-related failure of one Part control unit.

In a circuit arrangement according to the invention, which is one composed of several switching matrices Switching arrangement with reverse grouping represents the establishment of connections via short paths enables; their advantage when establishing connections in coupling arrangements with reverse grouping is known to come into play in a saving of crosspoints. These connections have already been made explained in detail in the relevant specialist literature and are therefore known here as generally known provided. However, in the context of the invention, it should be particularly pointed out that for Short connections within a switching matrix part between two switching matrix connections of two different ones Coupling multiples of the first switching stage all outputs of this switching matrix part, d. H. so all of them multiple circuits and multiple connections connected to these outputs are available, but for normal connections between two switching network connections of two different switching networks in each case only a part of the multiple connections and accordingly a part of the outputs of the relevant two switching matrix parts of the two different switching matrixes. As a connection through-connection It is given priority over connection through-connections over normal routes via short routes particularly expedient that in a coupling arrangement according to the invention for the production of connections A greater variety of routes via short routes

exists than for the connection through normal routes.

With regard to the previously used terms "switching network" and "switching arrangement", it should be noted that that the term "switching network" is used for part of the entire "switching network" only for this reason because in the main paient a number of multiple circuits connected in parallel on the output side Switching matrix parts is referred to as "switching matrix". In order to keep referring to the Main patent to avoid confusion of terms, a plurality of "coupling fields" was according to Main patent in the sense of the present invention referred to as "coupling arrangement". To now accordingly the technical usage of the term "coupling field" for the entire switching arrangement to be able to use, is in the further explanations for the »coupling field« according to the main patent, so the output-side parallel connection of a number of switching matrix parts also always the The term »switching matrix part group« is used.

In the drawings, F i g. 1 to 4, an embodiment of the invention is only essentially related to its Understanding contributing ingredients shown.

In Fig. 1 shows a switching matrix part group I composed of the switching matrix parts A, B ..., N. All switching matrix parts are designed in two stages. The switching matrices are arranged in the switching stages KA and KB . It is just as well possible to design the switching matrix parts in several stages. All switching matrix parts have the same number of switching matrices in the switching stage KB. Each of these switching matrices - shown in a known manner by a short, strong vertical line - has the same number of outputs.

The switching matrix parts differ in two types of switching matrix parts. The switching matrix parts A and ß are on the input side exclusively with subscriber stations, z. B. Ti, T2, T3 and T4 connected. Coupling matrix parts N and similar, not shown, are connected on the input side exclusively with line connection sets VLO and VLF for local connection lines OVL and long-distance connection lines FL, with dial reception sets WS and with internal connection sets / V. As a result of this subdivision into switching matrix parts A and B of a first type on the one hand on the input side exclusively connected to subscriber stations Ti, T2, 73 to Γ4 and on the other hand exclusively on the input side with connection line sets VLO and VLF for local connection lines OVL and long distance connection lines FL, switching matrix parts of a second type connected with dialing reception sets WS and JV It is possible, depending on the different traffic loads on the one hand of the subscriber stations and on the other hand of the mentioned different switching devices required differently for each connection, to dimension the switching matrix parts of the two different types differently.

As already stated, the number of coupling multiples in the second switching stage is the same for all switching matrix parts. The number of switching matrix outputs per switching matrix of the second switching stage is also the same over all switching matrices of the second switching stage. On the other hand, the number of switching matrix inputs of the switching matrices of the / wide switching stages can be greater in the switching field parts A and B of the first type than in the coupling elements N of the second type he first coupling stage per switching network component. Accordingly, the switching matrix parts A and ß of the first type ■> each have a greater number of switching matrices in the first switching stage than the switching matrix parts Λ / of the second type -

Hi fe per switching matrix part, the switching matrices of the first switching stage have the same number of outputs in all switching matrix parts. However, the number of inputs per switching matrix of the first switching stage can be different for the switching matrix parts A and ß of the first type on the one hand and the switching matrix parts N of the second type on the other hand. Have the switching matrices of the first switching stage then in the switching matrix parts of the first type, a greater number of inputs than in the switching matrix parts of the second type. The switching matrix parts of the first type thus differ per of the switching matrix parts of the second type both in the number of switching matrices of the coupling stage A Switching matrix part as well as in the number of inputs per switching matrix in this switching stage. The exact numbers of inputs and outputs per switching matrix and switching matrices per switching matrix part are measured in a manner known per se according to the traffic values of subscriber stations on the one hand and of switching devices required per connection also called connection-specific devices on the other hand.

Apart from that, it is also possible to always have two (or three

J-) etc.) to run intermediate lines in parallel. In this Case, the number of inputs per switching matrix of the second switching stage is twice (or three times, etc.) like this as large as the number of switching matrices in the first switching stage per switching matrix part.

«Ίο As from F i g. 1, the switching matrix part A has its own part control unit TA . The other switching matrix parts also have their own sub-control units. However, these are not shown in the drawing. All sub-control units are connected to a common central control unit. The functioning of the sub-control units can be limited to that of buffer storage and / or encoding devices. The German patent specification 15 37 849 shows and describes details of this.

5 (i The connected to each of the switching matrix parts connection-specific devices can be assigned separate control purposes together. she can be provided individually for each of the different types of connection-specific facilities

ν; be.

The size of each of the switching matrix parts is dimensioned so that in the event of failure of a switching matrix part, e.g. B. A, individually assigned part control unit, z. B. TA, a relatively small part of the relevant mediation

Wi place is temporarily out of order. According to Commonly used operating conditions for telephone exchanges namely allowed from the failure of any telephone equipment only a relatively small part of the participants or

'' Connection-specific facilities are affected, so that the telephone operation remains largely unaffected by this. Partially central institutions or central facilities whose fault-related

Due to a failure, too large parts of a switching system are temporarily out of service would, for this reason, have to be provided in duplicate and work in parallel with it in the event of a failure of one of the two devices working in parallel, the other takes over the switching operation can continue. For this reason, the size of each of the switching matrix parts is such that their Partial control units do not need to be provided twice in each case. The partial control units are therefore per ifl Switching matrix part provided individually.

The switching matrix parts are connected in parallel on the output side via multiple lines Vl-Vx ("multiple circuits" see above). The switching matrix parts connected in parallel on the output side via a bundle of multiple circuits each form a switching matrix splitter group, denoted by "I" in FIG. 1. The number of multiple lines mentioned remains unchanged over several expansion steps. When a switching matrix part group is expanded, the additional switching matrix -TO is part - or the additional switching matrix parts - are in the form shown in FIG. 1 also connected to the multiple lines Vl to Vx . Since in all switching matrix parts, i.e. both the switching matrix parts of the first type and the switching matrix parts of the second type, the number of switching matrices of the second switching stage and the number of outputs of each of these switching matrices are the same, there are no problems with the expansion regarding the interconnection. Simply *> the outputs of the same name with regard to the switching matrix parameters of the additional switching matrix part or the additional switching matrix parts are additionally connected individually to the already existing multiple lines of the relevant switching matrix part group.

There is a possibility of increasing the number of multiple lines Vl to Vx if the number of switching matrix parts becomes so large that the multiple lines existing up to that point can no longer bear the traffic load. For this case it is provided that all switching matrices of the second switching stage are connected in parallel on the input side in all switching matrix parts that are already present. If the outputs of the original and the supplemented switching matrix in the second switching stage are the same, this measure doubles the number of outputs per switching matrix part. If the number of switching network parts exceeds a level that is permissible for the traffic load on the multiple lines Vl to Vx, then the number of multiple lines and thus the traffic load capacity thereof can be doubled in the manner indicated above.

In Fig. 2 are a total of four switching matrix part groups according to FIG. 1 shown one above the other. Accordingly, ^{'i! 5} the designations I to IV for the four switching matrix part groups in Fig. 2, the switching matrix parts as shown in Fig. 1 A, B through N in Figure 2 with A I to Nl is., -4 11 to NU . and so on. Likewise, the multiple lines Ί * designated in FIG or II. Vl, II.V4 and II. V7 etc. Each of the multiple lines shown in Fig. 2, for example I.Vl, Ί> 5 represents three parallel multiple lines, each of which is individually with a coupling output in each of the relevant

35

*O

^{l | 5} switching matrix parts is individually connected.

Each of the switching matrix parts Al. to NIV. In FIG. 2, the switching stage KB contains a plurality of switching matrices which can be shown arranged one above the other based on FIG. 1. However, for the sake of simplification and better clarity of the illustration in FIG. 2, they are not shown in detail. Each of these switching matrices in the switching stage KB has nine outputs. The multiple lines I. V1 to I. V 7 shown in FIG. 2 in the switching matrix part group I, which - as stated above - represent three groups of three multiple lines each, i.e. a total of nine multiple lines, are in each of the switching matrix parts A1. to Nl. connected to the nine outputs of the uppermost switching matrix in each of these switching matrix parts. In the same way, but not shown in detail, the outputs of the second switching matrix of the switching stage KB of each of the switching matrix parts A I. to N 1. are connected to one another. Ultimately, all switching matrix outputs of the same name of the switching matrices of the switching stage KB are connected to one another via multiple lines from switching matrix part to switching matrix part within a switching matrix part group, as is also shown in FIG. 1 is shown.

In addition, FIG. 2 the interconnection of multiple lines of the various switching matrix part groups I. to IV. With the help of multiple connections Wa to Wf. The first three multiple lines of switching matrix parts I. and II .Vl are indicated are interconnected individually via three multiple connections, which are jointly referred to as Wa . In the same way, the three multiple lines that are in the switching matrix part groups I. and III. with I.V4 or III. V4 interconnected individually via three multiple connections, which are jointly denoted by Wb in FIG. - It is unnecessary to explain all further triple multiple connections Wc to Wf , because from FIG. 2 shows the manner in which the multiple lines of the various switching matrix part groups I. to IV. Are connected to one another with the aid of these multiple connections. However, it should be noted that the in F i g. 2 multiple connections Wa to Wf, each representing three individual multiple connections, also only reproduce the individual connections between switching matrix outputs of the top switching matrix in each of the switching matrix parts A I. to N IV. In the switching stage KB . In the same way, however, the switching matrix outputs of the second (third, fourth, etc.) switching matrices of each of the switching matrix parts A1 are also . to NW. individually connected to each other.

Fig. 2 thus shows that the switching matrix part groups I. to IV. are summarized in a total of six groups of switching matrix part groups, each group each comprises two switching matrix part groups. From each of the multiple lines a group of switching matrix part groups is an identical part per switching matrix part group through individual multiple connections united. These multiple connections therefore always only run within the relevant one Group of switching matrix part groups. - In addition, each of the switching matrix part groups belongs to several different groups, the total of four switching matrix part groups I. to IV. form a total of six

Groups of two switching matrix part groups, each group having a different combination of switching matrix part groups includes. In the present case, the size of a group of switching matrix part groups is two each Switching matrix part groups limited in order to make the representation reasonably clear. However, it is also possible to form larger groups of switching matrix part groups and here fewer groups of To form switching matrix part groups than by all conceivable combinations of switching matrix part groups would theoretically be possible.

The number of switching matrix parts connected to the multiple lines of a switching matrix is smaller than the number of switching matrix parts resulting from the maximum traffic load capacity of the multiple circuits of a switching matrix. Within a switching matrix part group according to FIG. 1, fewer switching matrix parts are provided than the maximum traffic load capacity of the multiple lines Vl to Vx would allow. For this purpose, the multiple lines of the various switching matrix splitter groups are connected to one another via the multiple connections Wa to Wf in the manner explained in detail above. In this way, the total number of switching matrix parts can be compared to an arrangement which is based exclusively on FIG. 1 is designed to increase significantly. As a result, the number of switching network connections as a whole can also be increased as a result.

Upon further consideration of the arrangement according to FIG. 2, for the time being, the switching matrices in the switching stage KC and the connections to it are still disregarded. The in F i g. 2 thus already represents a switching matrix with reverse grouping in the switching stages KA and KB . It is known that connections can be established in a switching matrix with reverse grouping both via normal routes and via short routes. For short-path connections between two switching network connections that are located within one and the same switching network part, all outputs of the switching matrix are available in the switching stage Kß of this switching network part. In the case of a short-path connection, it is known that the two switching network connections concerned are switched through via two separate sub-connections to two different inputs of one and the same switching matrix in one of the switching stages - in the present case the switching stage KB - and in this by interconnecting the last-mentioned two switching matrix inputs with one and the same switching matrix output to the short connection concerned. For short connections between two switching matrix connections one and the same switching matrix part and for short connections between two switching matrix connections of two different switching matrix parts in one and the same switching matrix part group, all outputs (switching stage KB) of these switching matrix parts are available. Normally, however, run between two switching matrix connections of two different switching matrix part groups, z. B. the switching matrix part groups 1. and II. Such a normal connection runs over one of the multiple connections Wa. In this context, it is noteworthy that the number of path options for short-path connections is greater than the number of path options for normal-path connections. As explained above, all parallel-connected outputs of the various coupling field parts are available for short-path connections within a switching matrix part group. For a normal route connection between two switching matrix connections, which are located in the two switching matrix part groups I. and II., Only the multiple connections Wa are available. The explained difference in the number of route options on the one hand for short-distance connections and on the other hand for normal-route connections corresponds to the preferred connection establishment via short-distance routes.

As can also be seen from FIG. 2, a third coupling stage can also be provided. In this third switching stage are coupling rows with three switching matrices each. The in F i g. 2 shown Arrangement is again only for the top one

is the switching matrix of the switching stage KB of each of the switching matrix parts A I. to NIV. intended. The same coupling rows of the switching stage KC are for the second (third, fourth, etc.) switching matrix in the switching stage KB of the switching matrix parts Al. to / VIV. provided in a manner not shown in detail. - As has already been explained, for example the designation I.Vl indicates a total of three multiple lines, each of which has the three first outputs of the first switching matrix of the switching stage KB of the switching matrix parts A I. to N I.

associate. These three multiple lines would logically be called LV1, I.V2 and I.V3. Likewise, the designation Wa indicates a total of three parallel multiple connections, each of which is the three multiple lines in the two switching matrix part groups I. and II

I. Vl, 1. V2 and I. V3 on the one hand and II. Vl, II. V2 and II. V3 on the other hand individually connect to one another. The three multiple connections marked with honeycombs correspond to the three switching matrices KCaX, KCa 2 and KCa3 in the coupling row KCa of the coupling stage KC. These three multiple connections are each connected to an input of these three switching matrices. The same applies - as from the systematics in FIG. 2 selected designations already emerge - also for the multiple connections Wb to Wf and for the coupling rows KCb to KCf assigned to them in the coupling stage KC.

In a manner not shown in detail, several coupling arrangements are provided, as shown in FIG. 2 are shown for the coupling stages KA and KB .

These multiple switching arrangements (switching stages ΚΑ / KB) are all connected in the same way in the manner shown in Figure 2 to the inputs of the switching matrices of the switching stage KC . A maximum of as many of the switching arrangements shown in FIG. 2 in the switching stages KA and KB can be connected to the inputs of the switching matrices of the switching stage KC as each of these switching matrices has inputs.

Is now a switching matrix in the one shown in Fig.2 Way constructed from switching matrices in a total of three switching stages, ie those shown in FIG four switching matrix part groups I. to IV. are each provided several times in the manner explained above, exist for the switching through of connections

w again different possibilities, except normal route connections Short-distance connections can also be switched through. A normal route connection consists of two sub-connections, each of which goes from a switching matrix input to an input

^{6: J} switching matrix of the switching stage KC runs. The two partial connections run to two different inputs of one and the same coupling multiple in the coupling stage KC and are here with one another

a normal route connection by interconnecting the two switching matrix inputs with and connected to the same switching matrix output. Short-path connections run in such a switching network between two switching matrix inputs of two different switching matrix parts of two different switching matrix part groups or one and the same switching matrix part group. In addition, there are also short-distance connections possible between two switching matrix inputs within one and the same switching matrix part. In the end Short-path connections can also be switched through between two switching network connections that are connected to one and the same switching matrix lie.

In contrast to the illustration in FIG. 2 it is also possible to form four different groups of three switching matrix part groups each when a total of four switching matrix part groups are present. In this case, not two multiple lines are connected to one another via the multiple connections concerned, but rather three multiple lines. In Fig. 4 is one of the arrangement according to FIG. 2 shows a different combination of a switching network from a number of switching networks. Just as in the arrangement according to FIG. 2 are shown in FIG. 4 a total of four switching matrices are provided. However, the multiple connections connecting the multiple lines of the switching matrices to one another do not run - as in FIG. 2 - in each case from one switching matrix to another switching matrix, but the multiple connections according to FIG. 2 each connect the multiple lines of three switching matrices of three switching matrices with one another. So connect z. B. the multiple connections, which are jointly referred to as Wi , multiple lines of the switching matrices I, II and III. The same applies - as can be seen from FIG. 4 - for the further multiple connections W2, W3 and W 4. The multiple connections IV1 to W 4 according to FIG. Connect 2 with the inputs of switching matrices of a further switching stage. The switching matrices according to FIG. 4 are in the same way as in FIG. 2, each assembled from several switching matrix parts. Only for the sake of simplicity of illustration and description is FIG. 4 in each of the switching matrix parts I to IV only a single switching matrix part, z. B. IA shown. The parallel connection of the outputs of the various switching matrix parts within a switching matrix via multiple lines is only indicated. The variant according to FIG. 4 is based on the same construction principles as the embodiment variant according to FIG. 2. Only the numerical values relating to the number and the type of connection of the multiple connections are included in the arrangement according to FIG. 4 selected differently than in the arrangement according to FIG. 2.

Like F i g. 3 shows, an even larger switching network can be formed in that several switching networks according to FIG. 2 together with the preceding description. In this case, the outputs of the switching matrices of the switching stage KC are shown in FIG. 3 manner shown: further intermediate lines individually connected to one another. In such a switching network, there are options for switching through the connection via a different number of switching stages. A connection can be established via two three coupling stages (normal route). A connection can also be established via two three switching stages, but in the switching stage KC it runs over one and the same switching matrix. In a coupling arrangement according to FIG. 3, such a connection is already a short-path connection. A connection can also be made via

'5 fewer than all coupling stages in the one already described Wise, that is, over short distances of different lengths.

An arrangement of several switching matrices according to FIG. 2, left half of the sheet, in which the switching matrices belonging to the various groups of switching matrices in different combinations with their multiple circuits are interconnected in various ways via multiple connections, is referred to below as a "switching matrix complex". As previously with reference to FIG. 2, several switching network complexes with their multiple connections are connected to the inputs of the switching matrices of the switching group KC. Here, multiple conditions of different switching network complexes are connected to the inputs of one and the same switching multiple of the further switching stage AC. The multiple connections connected to the inputs of one and the same switching multiple of the switching stage KC all belong to different switching network complexes. Multiple connections of each of the various switching network complexes are connected to the inputs of one and the same switching multiple of the switching stage KC . With regard to the grouping sequence, multiple connections of the same name of each of the various switching network complexes are each connected to the inputs of one and the same switching multiple of the switching stage KC . - As already based on FIG. 3, the switching matrices of the switching stage KC connected to the multiple connections of the various switching matrix complexes according to FIG. 2 form a group of switching matrix rows KCa to KCf common to these switching matrix complexes. The outputs of the switching matrices of several such S ° groups of switching matrix rows according to FIG. 2. Right half of the sheet, are systematically connected from group to group via intermediate lines according to FIG. With regard to the grouping sequence, switching matrices of the same name of the several groups of switching matrix rows are connected to one another via intermediate lines.

For this purpose 4 sheets of drawings

Claims (7)

Patent claims: 1. Circuit arrangement for telecommunications switching systems, in particular telephone switching systems, with switching matrices, which are each constructed from switching matrices in several switching stages connected to one another via intermediate lines, and at their inputs in the first switching stage all lines, e.g. B. subscriber lines, local and long-distance connection lines, and all inputs and outputs of switching elements necessary for connection establishment and connection monitoring per connection, e.g. B. dial receivers, connection sets and the like, are switched on, and in which outputs of the switching matrices of the first to penultimate switching stage are connected to the inputs of the switching matrices of the respective downstream switching stage and can be connected in pairs in this, and which are each subdivided into switching matrix parts , to whose inputs the subscriber lines, connecting lines and the switching elements necessary for each connection are connected, and to which their own subcontrol units are individually assigned, and which are individually connected in parallel with their outputs in the switching network, whereby switching network outputs of the same name of the various switching network parts individually with one another in terms of the switching network parameters the number of switching network outputs per switching network part corresponding number of multiple circuits are connected, according to Patent 2443941, characterized in that the number of the multiple circuits of a switching network ang eschlosed switching matrix parts is smaller than the number of switching matrix parts, which results from the maximum traffic load capacity of the multiple circuits of a switching matrix, and that in a switching system a plurality of switching matrices is provided, which are assigned to several groups ^ir > of switching matrices, with one switching matrix belonging to different groups and the switching matrices each belong to one group at the same time different other groups, in that each group comprises a different combination of switching matrices, and that of the multiple circuits in each case a group of switching matrices an equal part per switching matrix are connected by individual multiple connections, each only between the multiple circuits of the switching matrices of the group in question run in that a multiple connection each connects one of the multiple circuits of the various switching matrices of this group to one another. 2. Circuit arrangement according to claim 1, characterized in that the different groups switching matrices belonging to different combinations, their multiple circuits in are interconnected in many ways via multiple connections, each with a 6 " Form switching network complex and that several switching network complexes with their multiple connections additionally individually connected in the manner to inputs of switching matrices of a further switching stage are that multiple connections of different switching network complexes with the inputs each one and the same coupling multiple of the further coupling stage are connected. 3. Circuit arrangement according to claim 2, characterized in that the with the. Inputs respectively multiple connections connected to the same coupling multiple of the further switching stage all belong to different switching network complexes. 4. Circuit arrangement according to claim 2, characterized in that multiple connections each of the various switching network complexes with the inputs each one and the same switching multiple the further coupling stage are connected. 5. Circuit arrangement according to claims 3 and 4, characterized in that with regard to grouped order in each case multiple connections of the same name each of the different Coupling network complexes each with the inputs of one and the same coupling multiple of the others Coupling stage are connected. 6. Circuit arrangement according to claim 2, characterized in that the multiple connections of the various switching network complexes connected switching matrices of the further switching stage a group of these switching matrix complexes form common switching matrix rows and that the outputs of the switching matrix of several such groups of switching matrix rows from group to Group are systematically connected to each other via intermediate lines. 7. Circuit arrangement according to claim 6, characterized in that in terms of grouping Sequence of switching matrices with the same name in each case of the several groups of switching matrix rows are interconnected via intermediate lines.