DE2013862A1 - Switching matrix and method for expanding a switching matrix in telecommunications systems - Google Patents

Description

-Patent attorney.

7 Stuttgart-Feuerbach
Short St. 8

H.Adelaar-M.Den Hertog-C.Cool 58-I09-2

INTERNATIONAL STANDARD ELECTRIC CORPORATION, NEW YORK

Switching matrix and method for expanding a switching matrix in telecommunications systems

The invention relates to a switching network and a method for Extension of a switching network from a number of multistage switching groups, in each of which from any input the large coupling group to any of its inputs at least one path can be established and which are connected to one another with their outputs in such a way that each input each large coupling group has access to the entrances of those Large coupling groups wins, which have a certain number of alternative and over various intermediate lines running Paths with the relevant coupling group can be connected for telecommunications systems.

Such a switching network is essentially known, for example from the article "Automommutateur electronique experimental a reseau de connexion a semiconducteurs (Triode PNPN)", by P. Burstow, published in the journal "Commutation et Electronique", No. 12, March 1966 , Pages Jo to 96.

This known switching network consists of a first sub-switching network (Input switching network) and a second sub-switching network (output switching network). The input switching network has several Input switching groups and the output switching network has several output coupling groups, the outputs of the inputs

March 16, 1970

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large gang coupling groups are in such a way with the outputs of the Output coupling groups connected to that each input coupling group via the specific number of alternative routes and different intermediate lines /? Has access to each output coupling group.

A natural method for expanding the known switching network is that simply the number of input switch groups and output switch groups and each input switch group of the resulting Switching matrix is connected to each output switching group. However, this leads to the disadvantage that the number the intermediate lines between any output of the input switching network and any output of the output switching network of the resulting switching matrix decreases. Therefore, if the resulting switching matrix is a certain Minimum number of alternate paths should have different intermediate lines between any input of the input switching network and any input of the output switching network, thus a certain minimum Traffic quality is assured, the switching network that has not been extended would have to have such a number of intermediate lines that which is considerably larger than the required minimum number. This means that the already existing, not extended Switching matrix the links are used in a very ineffective manner.

The object of the invention is therefore to provide a method for expanding a switching network of the type mentioned at the beginning to create in which the same type of switching network is retained and the disadvantage mentioned is avoided.

According to the invention, this is achieved by a method which is characterized by the fact that the number of large coupling groups is increased, at least one special one

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Large switching group is formed by at least two large subgroups, so that inputs of first switching matrices, which form a switching stage of each large subgroup, are connected via second switching matrices to outputs of such first switching matrices, which form the switching stages in the other large subgroups in the same position, so that each large switching group made up of such subgroups a repentant coupling large group forms, each having at least one path between each input of the sub large groups and each output of the part of large groups, and that the Ausgäife the part large groups are interconnected so that each input of each new coupling large group About WE M nigstens certain number of alternate and has access to each input of the large switching group connected to the respective large switching group.

This method is particularly adapted to the expansion of a switching network, in which the large switching groups form a first sub-switching network (input switching network) and a second sub-switching network (output switching network) and the outputs of the input switching large groups are connected to the outputs of the output switching large groups in such a way that each input switching large group is connected to each output switching large group the Λ certain number of alternative routes running through different intermediate lines has access. An embodiment of the method according to the invention directed at such a switching network is characterized in that the number of output coupling groups and, if applicable, that of input coupling groups is increased, that at least one coupling group is formed with this number of input coupling groups (subgroup) so that the connection mentioned is carried out rd and that the outputs of all new large input coupling groups generated in this way are connected to the outputs of the large output coupling groups in such a way that each input of each new large input coupling group is connected

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at least a certain number of alternative routes and routes running through various intermediate lines, access to each Has input of the output coupling groups.

The invention also relates to a switching network created by using the method according to the invention, which is characterized in that at least one large group of physically different subgroups each of which has a number of inputs and a different number of outputs and is provided with at least one path between each input and each-φ the output that in each subgroup each Switching stage is formed by a part of the switching stage of the associated large switching group and that inputs of first switching matrices of at least one switching stage part of each large subgroup with outputs of first switching matrices from switching stage parts of the same position of the other, to the same large coupling group belonging subgroups are connected via second switching matrices, which are physically different from the distinguish first switching matrices and form parts of the switching stage of the large coupling group.

The invention will now be explained in more detail using several embodiments α. Show it:

Fig.l a switching network in which the method according to the invention can be used,

2 shows a switching network in which the method according to the invention is applied,

FIG. 3 is a traffic diagram of the coupling element according to FIG.

4 shows the switching matrix according to FIG. 2 in a less detailed manner Way,

Flg.5 a coupling matrix in a schematic representation in which the result of the application of the method according to the invention in the switching matrix according to Fig.l is shown,

Fig. 6 to 11 extension examples for different switching matrices.

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In Pig.l a six-stage switching matrix is shown * which a three-stage first sub-switching network Tl (input switching network) and a three-stage second sub-switching network T2 (output switching network) having. The input switching matrix Tl has

1024 inputs II to 11024 and 2048 outputs, which by means of 2048 c intermediate lines el to c2048 to the 2048 outputs the output coupling stage T2 are connected; the output switching matrix T2 has 1024 inputs 01 to 01024. This switching network forms part of a telephone exchange, for example management system, which has four-wire long-distance connection lines, which are connected to inputs II to 11024 and the inputs 01 to 01024 are connected.

The input coupling network Tl is formed by an expansion coupling stage with an expansion ratio of 2 and by 2 mixed coupling stages, while the output coupling network T2 has two mixing coupling stages and a concentration coupling stage with a concentration ratio of 2. The expansion and Concentration switching stages are made up of switching matrices that have eight inputs and sixteen outputs and where each of the eight entrances has access to each of the sixteen exits and vice versa. , The mixed switching stages are made up of switching multiples constructed, each of which has four inputs and four · outputs and in which each of the four inputs has access to each of the four outputs and vice versa. The switching stages of the input switching network Tl are by means of intermediate lines a and b connected, while the switching stages of the output switching network. T2 connected by means of intermediate lines d and e, respectively are.

In Flg.2, the input switching network Tl is made up of eight identical ones Entrance coupling groups All to Al8 formed, each a set of .128 inputs II to 1128, ... ,, '. I897 to 11024, while the output switching network T2 by eight Identical output coupling groups A21 to A28 formed, each with a corresponding set of 128 inputs 01 to 0128, ...., 0897 to 01024. The output double

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groups A21 to A28 have the same structure as the input coupling groups All up to Al8, each with ^ Weils 256 Outputs to the outputs of the eight output coupling groups A21 to A28 by means of corresponding sets of 32 c intermediate lines are connected. Of course, each of the output coupling groups A21 to A2 & also has 256 outputs connected to the outputs of the eight input coupling groups All to AI8 via corresponding sets of 32 c intermediate lines are connected.

Since the large switching groups All to AI8 and A21 to A28 of the ™ six-stage switching network have the same structure, only one large switching group is described in more detail below, e.g. B. the large coupling group All. This large switching group All with 128 inputs and 256 outputs has four identical switching groups Bill to Bl14, which are each formed from four switching matrices ^s x 18 ^s and 16 switching matrices of the 4x4 type. The 64 outputs of the four switching matrices of the type 8 16 are connected by means of 64 intermediate lines a to the 64 inputs of the 16 switching matrices of the type 4x4 in such a way that each switching matrix of the first-mentioned type has access to each switching matrix of the last-mentioned type and that there is a single path between each input of the φ 32 inputs of the coupling group Bill to Bl14 and each output

the 64 outputs of these coupling groups can be produced. The 256 outputs of the four coupling groups Bill are in the same way to Bl14 by means of 256 intermediate lines b to the 256 inputs the 64 Kqgpelvlelfache of the type 4x4 connected in such a way, that each of these switching groups has access to each of the latter switching matrices and that a single path in each case between each of the 256 outputs of the coupling groups Bill bis Bl14 and each of the 256 outputs of the large coupling group All can be produced is.

From this it follows that each large coupling group of the large coupling groups All to A18, e.g. the large coupling group All, for one single path between each of your 128 inputs, e.g. their inputs

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passages II to 1128, and each of its 256 outputs via one Expansion coupling stage and two mixed coupling stages connected in cascade with this. In the same way, cares each of the large coupling groups A21 to A28, e.g. the large coupling group A21, each for a single path between each of its 128 inputs, e.g. inputs 01 to 0128, and each of its 256 outputs via two mixing coupling stages and a concentration coupling stage connected in cascade with these. Since each of the large switching groups All to AIS has 32 c intermediate lines access to each of the large switching groups A21 to A28, each of the 1024 inputs II to 11024 of the switching matrix has 32 alternative and different ones Intermediate lines access to each of the 1024 inputs 01 to 01024.

The traffic diagram with the 32 alternative routes between any input of the inputs II to 11024 and any input of the inputs 01 to 01024 of the switching matrix is shown in FIG. 3, each circle representing a switching matrix. In order to establish a connection between an input I and an input 0 of the switching matrix, five intermediate lines, namely an a-, b- ¹ , c-, d- and e-intermediate line, must be used. It should be pointed out that the number of crosspoints per input, ie the total number of crosspoints divided by the total number of total inputs, is 32 in this switching network. This is also the number of crosspoints per c-link, since the number of c-links is equal to the total number of total inputs.

From the above it follows that a coupling group is one Sub-switching network T1 or T2 of the switching network shown represents a switching arrangement; who has the property access to each of the large switching groups of the other sub-switching network T2 or Tl via a corresponding sentence from these partial couplers connecting c-links, and which for a single path between each of their inputs and cares for each of its outcomes. Let it be in this context

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it was pointed out that the above-mentioned large coupling groups have identical structure and that the number of paths between each input coupling group and each output coupling group has been made constant because it has been assumed that each of the input switching groups All to AI8 handles the same total traffic and that this traffic moves evenly over the large output switching groups A21 to A28 is distributed.

In order to train the switching network described above into a switching network, which 2048 inputs I and 2048 inputs 0 as well as α has the same traffic quality, such that each switching network of the sub-switching networks T1 and T2 of the new switching network is for a single path between each of its inputs and takes care of each of its outputs and has a corresponding sentence . J52 c-links has access to each switching group of the sub-switching matrices T2 and Tl, the method described below can be used.

A further identical switching matrix is added to the existing switching matrix, which consists of the large switching groups AI9 to ΑΙΙβ and A29 to A2l6, which are connected by 1024 c intermediate lines. The large input switching groups are connected to one another in pairs All, AI9, ..., AI8, | r Al16 by means of additional or second switching matrices, each pair having a large switching group of the existing switching network and a large switching group of the added switching network . Since the pairs of the input switching groups All, AI9, ...., AI8, A116 are connected to one another in the same way, only the connections by means of the second switching matrix of the input switching groups All and AI9 are considered in the following. The connections of these input switching groups All and AI9 are made so that the 256 a intermediate lines or the 256 inputs of the 64 switching matrices of the 4x4 type, which form the second switching stage of the input switching group All, with

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the 256 b intermediate lines or the 256 outputs of the 64 switching matrices of the 4x4 type, which form the second coupling stage of the large input coupling group AI9, are connected via an identical switching stage consisting of 64 additional switching matrices of the same type, so that the 256 a - Intermediate lines or the 256 inputs of the 64 switching matrices, which form the second switching stage of the large input switching group AI9, with the 256 b intermediate lines or the 256 outputs of the 64 switching matrices, which form the second switching stage of the large input switching group, via an identical one of 64 additional switching matrices of the type 4 χ 4 formed coupling stage are connected. To be more precise: the M 64 inputs of the 16 switching matrices of the 4x4 type, which are present in the switching groups Bill to Bl14 of the input switching network All, are connected to the 64 outputs of the 16 switching matrices of the type 4x4, which are present in the corresponding coupling groups Bl91 to BI94 of the large input coupling group A1'9. In the same way, the 64 inputs of the 16 switching matrices of the 4x4 type, which are present in the coupling groups Bl91 to Bl94 of the large input coupling group AI9, are connected by means of 16 additional switching matrices of type 4 χ 4 to the 64 outputs of the 16 switching matrices of the type 4x4 in the same position, which are present in the corresponding ^ coupling groups Bill to Bl14 of the large input coupling group All '*.

Thus, in the resulting large input coupling group, there is that of the large input coupling groups connected to one another All and AI9 are formed, each with a single path between each of the 256 inputs II to 1128, 11025 to 11152 and each of the 512 outputs.

Because the input switch group All has access to every output switch group A21 to A24 via a corresponding set of 32 e-Zwisohenleitu ^ ngen of the already existing switching network

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has and because the input coupling group Al9 also Access to each output coupling group A29 to A216 via a corresponding set of c-links of the additional In addition, the resulting input switch group has access to each output switch group A21 to A2l6 via a corresponding set of 52 c intermediate lines of the total number of intermediate lines, which connect the sub-switching fields T1 and T2 of the resulting coupling field with one another. It follows that any resulting Input switching group has the same properties mentioned as each of the input switching groups used.

It should be noted that instead of the connection in pairs of the input switching groups AII to AII6 and the output switching groups A21 to A2l6 would have been connected in pairs can be.

The above-mentioned 128 additional or second switching matrixes, which are used for the connection of each pair of the input switching groups used to obtain a resulting input coupling group are formed by units that are physically different from those units that are created by the coupling stages of each large coupling group forming, first switching matrix are formed. These additional Second switch units can be placed in racks different from those in which the large coupling groups, such as All and AI9, are arranged, but in this case the cable can be connected between these

Divorced bodies become extraordinarily long. If free Places in the racks of the corresponding coupling groups are provided, as shown in Pig.2, then the said additional units from second switching matrices can also be arranged at these points. In this case 1st the length of the cable is less, which is used to connect these additional units from the second switching matrix to the

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Units for the first switching matrices are used, which are the switching stages of the interconnected large switching units form.

It follows that for the purpose of doubling the capacity of a switching network of the type shown in FIG. 1 while maintaining the properties of the existing switching network, a switching network identical to the existing switching network is added and each switching network of the existing switching network is added to one of the connected sub-switching networks of the resulting switching network is connected to a corresponding large coupling group of the additional switching network. To be more precise: one of the coupling stages of any large coupling group from such a pair of large coupling groups is connected to the positional coupling stage of the other large coupling group from the pair of large coupling groups by means of two coupling stages which have the same structure as those coupling stages which are connected to one another and. form a single resulting coupling stage. This resulting switching stage is actually formed from four switching stages and this means, as can be seen from FIG. Here, the inputs, such as inputs - * gear Pl of the first switching matrices and P2 of the second switching matrices, and also the inputs as P3 of the third switching matrices and P4 of the fourth switching matrices connected to each other, while the outputs, such as P5 of the first switching matrices and P6 of the third matrix, and the inputs, like P? of the second matrix and P8 of the fourth matrix

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are connected to each other. However, four such interconnected switching matrices of the type 4 χ 4 are assigned to a switching matrix of the type 8x8, so that the resulting switching matrix shown in FIG _{. 2 can also be represented (} as shown in FIG Substitute

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From each switching matrix of the type 4 χ 4 in a switching stage through a switching matrix of the type 8x8 the number of switching points per input or per c-link of the resulting switching network increases by four , as can easily be calculated. In summary, it can be said that when the capacity of the switching network is doubled, a switching matrix of the type ρ χ ρ is replaced by a switching matrix of the type 2p χ 2p, with the number of coupling points per c-link increasing by ρ.

In order not to change the mode of operation of the telephone system from which the Switching network forms a part, to interfere with the expansion of this switching network, it is advantageous to use the connections mentioned P1P2, Pj5P4, P5P6, FTPS to be provided in advance so that the second switching matrix is only between the connections Pj5P6 and P2P8 in order to realize the desired connections to be stuck.

Instead of the capacity of an existing switching network with e.g. m large input switching groups and m large output switching groups To double this capacity can also be achieved by a paktor k be enlarged. In this case, k-1 switching networks that are identical to the existing switching network can be added to the existing one Switching network can be added / and in one of the connected Sub-switching networks, for example in the input switching network of the switching network thus created, are the m large input switching networks of the existing switching network and the m (k-1) large input switching groups of the k-1 added switching networks in m Groups from k by means of additional second switching matrices connected to one another, each group having a large switching group from each of the k switching matrices. More precisely: one the coupling stages of any large coupling group from such a group of k 1st with the coupling in the same position? stage each of the k-1 other large coupling groups from this group by means of a switching stage connected in the same way as the already connected is formed, taking the total number

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of the identical, position-identical coupling stages, which the resulting Coupling stage of the resulting coupling network follow

den, thus equals k + k (k-1) or k. It means that each switching matrix with ρ inputs and ρ outputs of a switching stage of the existing coupling in the resulting

2
Switching matrix is replaced by k interconnected switching matrices of the same type or by a single switching matrix with kp inputs and kp outputs. As a result, the number of crosspoints per c-connecting line or per input in the resulting switching network will increase by p (kl) in comparison with the existing switching network.

In order to increase the capacity of an existing switching network by a factor k that is greater than 2, it is advantageous to to apply the procedure for doubling the existing capacity p times instead of only using this procedure once, because in the first case the existing number of crosspoints per intermediate line increases by jjp, where ρ is already defined while in the second case this existing number increases by ρ (k-1), where | j— is smaller than p (k-l), if k is greater than 2. In order to achieve a resulting switching network that is constructed as symmetrically as possible, can use the method described to double the capacity of the existing switching network is advantageously used alternately in the input switching network and in the output switching network will.

The method described has the advantage that the intermediate of the existing switching network and the intermediate line «tt of the k ~ l added switching matrices not to be switched However, the process has the disadvantage that the Number of large input coupling groups or large output coupling groups to be connected is relatively large, since the number is equal to m, i.e. equal to the number of entrance blocks large, groups or output coupling groups that are included in "each of the k coupling stops are available.

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Instead of proceeding according to the procedure described above, you can it may be advantageous to do the following whenever possible:

1.1 There are m (k-l) output or input coupling groups added that are identical to those of the existing switching network, 00 that mk output or input switching groups as obtained in the case just described,

1.2 If necessary, a number of large input or output coupling groups is added until q groups of k large input or output coupling groups are formed with the total number of large input or output coupling groups, and the large coupling groups of each such group are connected in such a way that q new large input or output coupling groups are formed, whose coupling multiples of a coupling stage consist of Kqpel ^ multiples of the type ρ χ ρ;

1. ^ there are r new input or output coupling groups added, of which ^ rIe k large input or output switching groups is assigned until q + r = m, and each of which has a switching stage, whose switching matrices through Switching matrices of the type pk χ pk are formed, these Coupling stage in the same position as the interconnected in each of the q groups mentioned 1st;

1.4 each of the new input or output coupling groups will have an equal number of intermediate conductors with each of the output or input coupling groups.

This method has the advantage that the number of new large switching groups, which have at least one switching stage, which is composed of interconnected switching multiples of the type ρ χ ρ, is less than m. The disadvantage of this method, however, is that the intermediate lines must be switched over to the existing switching network.

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For example, if the capacity of the one shown in Fig.l. Coupling matrix in which m = 8 is to be tripled (k = 3), then you can proceed as follows:

2.1 There are m (k-l) or 16 output coupling groups added,

2.2 an input coupling group is added, see above that q = 3 groups formed from k = 5 large input coupling groups will; it is also a coupling stage, for example, the second switching stage of the three switching matrices of each group, connected to one another by means of switching matrices of the 4x4 type, so that a new large input coupling group is created, which has a coupling stage that is derived from each other allied switches of the 4x4 type; therefore three new input switching groups are formed; .

2.5 r = 5 new input coupling groups are added, each of which has the same capacity as each of the three new switching stages, their second switching stage but is formed from switching matrices of the type 8x8;

2.4 each of the eight new input coupling groups is activated by means of 52 links with each of the 24 output coupling groups tied together.

When done in this way, only two groups need from three large coupling groups are connected to each other instead of three groups, as would be necessary according to the procedure described earlier.

The advantage of the method described last becomes clearer, if again the switching matrix is considered, which was described in connection with the Pig. 1 to .3. Instead of eight Add input coupling groups and pair them with. the eight input coupling groups of the existing one Connect the switching matrix in such a way that each pair a large switching group of the already existing switching network and a large switching group of the added switching network,

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It is more advantageous, as shown in Pig. 5, to connect the eight existing large input switching groups in pairs All, A12, ..., A17, A18, so that four new large switching groups with (in the second switching stage) interconnected switching matrices of the type 4x4 are formed, and then four other large input switching groups A19 * AlIo, ...., A115, A116 with switching matrices of the type 8x8 (in the second switching stage) to be added, but these large input switching groups have the same capacity as the other new large switching groups. All of these input switching groups obtained in this way are then each connected to the sixteen output switching groups (not shown). In this case m = 8, q = 4 and r = 4.

If you proceed in this way, only four groups of two large coupling groups have to be connected to one another instead eight groups that would be required if proceeded as described earlier.

In the examples considered above, the capacity of the already existing switching network multiplied by a factor k, which is at least equal to 2. The methods described above and in particular the method described last can also be used, however, if the circuit arrangement of the switching matrix shown in Pig.l is enlarged by 1/4, 2/4 or 3/4 is to be, it is sufficient to connect the eight large input coupling groups in pairs so that create four new input coupling groups with double capacity, and add the following parts:

3.1 a new input coupling group and two output coupling groups in the first pail;

3.2 two new input coupling groups and four output coupling groups in the second pail;

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3.3 three new input coupling groups and six output coupling groups in the third case.

When all outputs of each new large coupling group are connected to all inputs of each large output coupling group and vice versa then the number of intermediate lines per coupling group is theoretically equal to 51 * 2., 42.7 and 36.6 (on related to the above three cases) / with which this number is greater than the one that applies to the existing switching network, which is equal to 32 there.

It follows that regardless of one or the other of the above described., two methods the resulting switching network has at least one resulting large coupling group which has several physically different large coupling groups, each of which has a different number of inputs the total number of inputs of the resulting large coupling group and a different number / of outputs from the Total number of outputs of this resulting large coupling group and of which each for at least a few Way between each of your entrances and each of your exits. The ^ .resulting coupling field in Flg.2 contains so e.g. the resulting coupling group All, AI9, which two physically different coupling groups (All and AI9) has, each of which has a different number of inputs II to 1128 or 11025 to III52 and outputs of the resulting Coupling large group All, AI9 has undYcTerien each for each provides a path between any input.Ill to II28, IIO25 to III52 and each of their outputs.

In addition, is in each of the large coupling groups used a resulting large coupling group each coupling stage by a corresponding part of the ^ same coupling stage of the resulting Large switching group formed, and inputs from the first switching matrix; the at least one coupling stage part each used large coupling group of a resulting large coupling group form, are at outputs of the first, switching matrix

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Positioned coupling step parts in the other used Large switching groups of the same resulting large switching group connected by means of second switching matrices, which are physically differ from the first switching matrix, and the parts of the switching stage mentioned resulting Form large coupling group. Thus, in the large coupling groups All and AI9 used, the resulting one shown in FIG Coupling group All, AI9 each coupling stage through a corresponding part of the same coupling stage of this resulting Large coupling group All, AI9 formed; Entrances of the first Switching matrices of the 4x4 type, which form the second switching stage part each of the used large coupling groups All, AI9 form the resulting large coupling group All, AI9 are on Outputs of the first switching matrix of the type 4x4 of the same position, second coupling stage part of the other large coupling groups used AI9, All of the same resulting large coupling group All, AI9 connected by means of a second 4x4 matrix, which is physically different from the first Switching matrices of the 4x4 type distinguish and which ones too Form parts of the second switching stage of the resulting switching network All, AI9.

In the following, Pig. 6 to 11 are considered, the Koppelfeider represent, which are all of the same type as those described in connection with Figs. 1 and 4, these The latter figures are shown again in FIGS. 7a and 7b are. The expression "the same type" of a switching matrix means that the first switching stage is an expansion switching stage and the last coupling stage is a concentration coupling stage, while the other coupling stages are mixed coupling stages, and that this one Type has two Teilkoppelfeider, which consists of coupling multiples are constructed which have the properties already defined above. In diesel switching networks are the first and last coupling stage from switching matrices of the 4x4 type or of the type 8 χ l6, while the mixed coupling stages from switching matrices of the type 4x4, Ü χ 8 or 16 χ 16.

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Is ... More precisely, in FIGS. 6, 8, Io and 7j 9> .11, both the first and last switching stages are constructed from switching matrices of the 4x8 type and the 8 × 16 type.

Each of Fig. 6 to 11 shows the different switching fields, which by the sequential application of the method described above to double the capacity in the Switching network according to FIGS. 6a to lla are obtained, with each of the last-mentioned switching fields has mixed switching stages, which are made up of switching matrices of the 4x4 type. As far as possible, the method has been applied alternately to the first and second sub-column fields, but before If a new type of switching matrix is used, all switching matrices of the type 4 χ 4 (or 8x8) must be replaced by switching matrices of the type 8 8 '(or 16 l6) in both sub-switching networks Tl and T2 are replaced.

With regard to FIGS. 6 to 11, it should be noted that each of these figures shows switching matrices which have only one or at most two traffic diagrams. The number of inputs that Number of c links and the number of crosspoints each c intermediate line or each connection are entered in these figures. From these figures it can be seen that the just mentioned number increases by 4, if each time a switching matrix of the 4x4 type through a coupling matrix of the 8x8 type is replaced, and that the mentioned number increases by 8 if each time a switching matrix of the type 8x8 is replaced by a switching matrix of type l6 χ 16 is replaced. This has already been explained been.

Around the various switching matrices shown in FIGS In order to be able to compare them better with one another, they will be considered in the following without their first and last coupling stages. The same number of coupling stages for each pair of these

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and switching matrices having the same number of a-links becomes the mascimal number of the crosspoint for each a-link calculated.

To consider the number of crosspoints per a-link in each To get a coupling field, the number 8 or 16 must depend on the entered number of coupling points be deducted whether the original switching network is an expansion switching stage has, which is made up of switching matrices of the 4x8 or 8 χ 16 type.

For the six-stage switching network shown in Pig. Number is equal to 16 for the six-stage switching matrix shown in Fig. Ja , which has the same number of a-links. Therefore, the maximum number of crosspoints per a-link in the six-stage switching networks of FIGS. 6 and 7 with 1024 a-links is equal to 24, this maximum being set for the switching network according to FIG. It can easily be checked that the maximum number of crosspoints per c-link for each pair of the switching matrix which has the same number of a-links considered in FIGS. 6, 7 or 8, 9 or 10, 11, each time for the switching matrices of Fig.6 or 8 or Io is achieved.

If all switching matrices of Fig.6 to 11 in the same way are considered, the following values are therefore obtained for the maximum number of crosspoints per a-link, where the corresponding numbers of the a-intermediate lines are in brackets:

4.1 for the six-stage switching network:

ß ο 1 η ii ΊΟ BATH ORIGINAL

16 (2 ⁸ ), 20 (2 ⁹ ), 24 (2 ¹⁰ ), 28 (2 ^U ), j52 ( ₂ ¹² ), ™ ^mL

4o (2 ¹ ^ Me (2 ^l4 ) j and 56 (2 ¹⁵ ), 64 (2 ¹⁶ ),

V-

009845/1240

H. Adelaar et al 58-109-2

if the switching matrices of the type 8x8 of FIG. 6 are replaced by ■ switching matrices of the type 16 χ Ιβ ; for this maximum number, the number of c-links is 64;

4.2 for the seven-stage switching network:

20 (2 ⁹ ), 24 (2 ¹⁰ ), '28 (2 ¹¹ ), 32 (2 ¹² ), 36 (2 ^15. ), 4θ (2 ¹⁴ );

and 48 (2 ¹⁵ ), 56 (2 ¹⁶ ), 64 (2 ¹⁷ ), 72 (2 ¹⁸ ), ■

if the switching matrices of the type 8x8 of FIG. 8 by switching matrices des, type 1β χ Ιβ be replaced; for these maximum numbers the number of c links is 128;

4.3 for the eight-stage switching network: ■ 24 (2 ¹⁰ ), 28 (2 ¹¹ ), 32 (2 ¹² ), 36 (2 ¹⁵ ), 40 (2 ¹⁴ ), '44 (2 ¹⁵ ), 48 (2 ¹⁶ ) and 56 (2 ¹⁷ ), 64 (2 ^l8 ), 72 (2 ¹⁹ ), 80 (2 ²⁰ ),

if the switching matrices of the type 8x8 of Fig. 10 by switching matrices of type l6 χ l6 are replaced; for these maximum numbers, the number of c-links is 256.

This can also be written like this:

4.1 for the six-stage switching network:

P 1 ρ
for 2 to 2 a-link lines: the maximum number of Koppe1 points per a-link line is 4 χ k; 4 χ 5, 4 χ 6, 4 χ 7, 4 χ 8 (based on the individual groups of numbers); For 2 ^ to 2 a-links: the maximum number of crosspoints per a-link is 8 χ 5, 8 χ β, 8 χ 7 * 8x8;

4.2 for the seven-stage switching network:

Q l4

for 2 ^y to 2 a links: the maximum number of crosspoints per a link. is 4 χ 5, 4 χ 6, 4 χ 7, 4 χ 8 _Λ 4 χ 9, 4 χ 10;

for 2 ¹ ^ to 2 a-intermediate lines: the maximum number of crosspoints per a-intermediate line is, 8 χ 6j 8 χ 7. * 8 χ 8, 8 χ 95 ■ '_.

4.3 for the eight-stage switching network:

for 2 ¹⁰ to 2 a intermediate lines: the maximum number of

001346 / 1240-

- 22 H. Adelaar et al 5 & -lo9-2

pel points per a-connecting line is 4x6, 4x7, 4x8, 4 9, 4 χ 10, 4 χ 11, 4 χ 12;

17 20
for 2 'to 2 a-link lines: the maximum number of crosspoints per a-link line is at most 8x7, 8x8.8x9.8x10.

From the above it follows that if 2 is the number of the a-intermediate lines and η the number of mixed coupling stages is, the maximum number of crosspoints per a-link or per input of the original switching network is the same 4 (N-4) is when N changes from n + 4 to 2 (n + 2), and that this number is equal to 8 (N-4-n) when N changes from 2 (n + 2) + l until 2 (n + 4) changes.

So if N is the smallest power of 2, which is not less than the number of a-links, where N is a positive one Number and is at least equal to n + 4 and where η is the number of., Mixed switching stages of the switching network under consideration, then is the number there? Crosspoints per a link of this switching network or per input of the original switching network not greater than 4 (N-4) if N is not greater than 2 (n + 2) or not greater than 8 (N-4-n) if N is greater than 2 (n + 2) is.

It should be noted that for the switching matrices considered above, which have the above-mentioned maximum number of coupling points per a-intermediate line, the number of c-intermediate lines is equal to 2 ⁿ , i.e. 64 for the six-stage, 128 for the seven-stage and 256 for the eight-stage switching network is. For these switching matrices, the number of c links is a minimum because the number increases as the number

N of the a-links of the switching matrix is less than 2.

The described expansion of a switching network has so far been limited to at least one of the Misoh switching stages to change, whereby the. in this way resulting coupling

009845 / mO

~ ^ 2013562

- 23 - ■; .-. ■ -

H. Adelaar et al 58-109-2

field the same traffic diagram as the original switching matrix having. The original switching network can, however, also be changed by changing the expansion and concentration switching stages, for example by replacing the switching matrix of type 4x8 by switching matrices of type 8 χ 16. In this case, however, the traffic diagram is changed .

The switching networks described above do not have a mirror network ζ characteristic because they are input and output coupling groups > have, the input coupling groups and also the output coupling groups not alternately c-links are interconnected. The one described above! Procedure is. However, it can also be used for switching matrices with mirror network characteristics, i.e. for sdchen switching matrices whose large coupling groups are used alternately by means of c-links are interconnected in such a way that each large switching group has access to every remaining large switching group via a certain number of alternative routes and via various intermediate lines.

24 claims,

Io Bl. Drawings, 11 figures

0 09845/1240

Claims (1)

H. Adelaar et al 58-109-2
Claims Coupling network consisting of a number of multistage coupling groups, in each of which at least one path can be established from any input of the Koppelgraßgruppe to any of its outputs and which are interconnected with their outputs in such a way that each input of each coupling group gains access to the inputs of that coupling group that are connectable via a certain number of alternative routes running over different intermediate lines with the respective large coupling group, for telecommunications systems, characterized in that at least one large coupling group has several physically different subgroups (All, A19; Fig. 2), each of which has a number of inputs and has a different number of outputs and is provided with at least one path between each input (II ... 1128, 11025 ... 11152) and each output (01 ... 0128, 01025 ... 01152) that in each subgroup each coupling stage through part of the coupling stage d he associated large switching group is formed and that inputs of first switching matrices of at least one switching stage part of each sub-large group are connected to outputs of first switching matrices from switching stage parts of the same position of the remaining sub-large groups belonging to the same switching large group via second switching matrices, which are physically different from the first switching matrices and are parts of the switching stage Form large coupling group. 2. Switching matrix according to claim 1, characterized in that all inputs of the first switching matrix, which form the one switching stage part of each subgroup, are connected to all outputs of those first switching matrices which form the switching stage parts in the remaining subgroups in the same position. 009845/1240 H. Adelaar et al 58-109-2 3. Switching matrix according to claim 2, characterized in that the interconnected first switching matrices of the subgroups have the same position. 4. Switching matrix according to one of claims 1 Ms j5, characterized in that the second switching matrix in the
physically different coupling groups are arranged. ■ 5. Switching matrix according to one of Claims 1 to 4, characterized in that the first and second switching matrices have the same structure. 6. Switching matrix according to claim 5, characterized in that each large switching group has k sub-large groups and that the number of second switching matrices is k-1 times as large as the number of first switching matrices, 7. Switching matrix according to one of claims 1 to 6, characterized in that each switching matrix of the first and second switching matrices is designed such that a connection can be made from each input to each output. 8. Switching matrix according to claim 5 and 7, characterized in that each switching matrix of the first and second switching matrices has ρ inputs and ρ outputs, where ρ is a power of the number 2. 9. Switching network according to one of claims 1 to 8, characterized in that each large switching group and sub-large group allows elrm a single path between each input and each output. 00984871140 H. Adeläar et al 58-109-2 10. Switching matrix according to one of claims 1 to 9, characterized in that each large switching group has other, cascaded mixing switching stages, each of which mixes the traffic occurring at its inputs without any concentration or expansion of the traffic from the inputs to the outputs. 11. Switching network according to one of claims 1 to Io, characterized in that the large switching groups form a first sub-switching network (input switching network) and a second sub-switching network (output switching network), the outputs of the input switching large groups being connected to the outputs of the output switching large groups in such a way that each input switching large group has a certain number of alternative paths running over different intermediate lines can be connected to each output coupling group. 12. Switching matrix according to claim 11, characterized in that .. the number of inputs of the input switching network is equal to the number of inputs of the output switching network. 13. Switching network according to claims Io, 11 and 12, characterized in that the numbers of mixed switching stages in each sub-switching network differ from one another by at most one. 14. A switch according to claim 9 to Ij5, characterized in that at least 2 ^nH paths between each input of the input switching matrix and each input does not exceed the output switching matrix ^ 8K§ ^e SI i ⁿ dfi ⁿ äahl of crosspoints per input value 4 (N ² O , if N is not greater than? (n + 2), or does not exceed the value 8 (N-4-n), if N is greater than 2 (nh2), where 2 is the smallest power of 2 and not IcLeLner than the total number of inputs des Koppe LCeLdGa L.Mt and wöbeL U eLne positive whole Number v / «ni; '\' iten: i i'ku · (rt / cio ;; ·! Nh4 and ti the number of Mlsch- _BAD0R , _Q , _NAL H. Adelaar et al 58-109-2 15. Switching matrix according to one of claims 11 to 14, characterized in that in each large switching group, the inputs are connected to Pern connection lines via further switching stages which ensure traffic expansion from the Pern connection lines. 16. A method for expanding a switching network from several large switching groups, each of which has several switching stages and at least one path between each input and each output, the outputs of the large switching groups being interconnected in such a way that each input of each large switching group has a certain ' Number of alternative paths running over different intermediate lines has access to each input of the large coupling groups connected to the large coupling group in question, characterized in that the number of large coupling groups is increased, that at least one particular large coupling group is replaced by at least two subgroups (All, AI9, Fig. 2; All, A12, Fig. 5) is formed that inputs of first switching matrices, which form a switching stage of each subgroup (All), via second switching matrices to outputs of such first switching matrices, which form the switching stages in the other subgroups (A19; AI2) with the same position, in such a way It is concluded that every large coupling group made up of such subgroups forms a new large coupling group (All, A19jAll, A12) which has at least one path between each input of the subgroups and each output of the subgroups, and that the outputs of the subgroups are interconnected in such a way that each input of each new large coupling group (All, AI9, ..., Al8, All6, Fig.2j All, A12, ..., Al ?, Äl8, Pig.5) has at least a certain number of alternatives and different Intermediate lines have access to every entrance of the Koppel-, Großgruppai connected to the respective Koppelgroupgruppe. V-009848 / 124-0 H. Adelaar et al 5Ö-lo9-2 17. The method according to claim 16, characterized in that a coupling stage of each subgroup is connected to each position-identical coupling stage of the other subgroups by means of a coupling stage which is identical to the interconnected coupling stages. 18. The method according to claim 16 or 17, characterized in that all inputs of the fooled switching stage of each sub-large group forming the first switching matrix to all outputs of the same position switching stages of the other ^ Subgroups forming first switching matrix by means of ^ the second switching matrix are connected. 19. The method according to claim 18, characterized in that the interconnected first switching matrices of the subgroups have the same position. 2o. Method according to one of claims 16 to I9 for expanding a switching matrix, wherein the coupling large groups form a first sub-switching matrix (input switch fabric) and a second sub-switching matrix (output combiner) and the outputs of the input coupling large groups are connected to the outputs of the output coupler large groups such that ψ each input coupling large group to each output coupling group has access via the certain number of alternative routes running over different intermediate lines , characterized in that the number of output coupling groups and possibly that of input coupling groups is increased, that at least one coupling group is formed with this number of input coupling groups (subgroup) that said connection is carried out and that the outputs of all the new large input coupling groups created in this way are connected to the outputs of the large output coupling groups in such a way that each input is each new n input coupling large 009845/1240 H. Adelaar et al 58-109-2 group (A11, A19, ..., AI8, Αΐΐβ, Pig.Sj All, A12, ..., AI7, ■ ' AIS, Fig. 5) about at least the certain number of alternative and access to each input of the output switching groups via various intermediate lines Has. 21. The method according to claim 2o, characterized in that the number of large output coupling groups and optionally that of large input coupling groups is increased, that at least one new large input coupling group is formed from this number of large input coupling groups (subgroups), that said connections are laid, that at least one such new one Input coupling group is added and that the named link connections are laid. 22. The method according to claim 2o, characterized in that the number of large input and output switching groups is increased, that “at least one new large switching group is formed with this number of large input switching groups and that said connections and the. Intermediate line connections are laid. 23. The method according to any one of claims 2o to 22, characterized in that it is used several times and ^ alternately in the input switching network and output switching network until at least all mixed switching stages of a sub-switching network consist of first and second switching matrices, and that the method is then used several times in the other sub-switching network until at least all mixed switching stages of this other sub-switching network consist of first and second Köppelvielfaohen. 24. The method according to any one of claims 16 to 23, characterized . indicates that the second switching matrices are arranged at empty positions in the physically different large switching groups. 009045/1240 ^V " E - No. Reg. No. H. Adei2faar et al Cose: 5Ö-109-2 Title: Switching matrix and method for expanding a switching matrix in telecommunications systems List of terms used Reference
sign Original language 009845 / 12th translation η first 3-stage part first sub-switching network
(Input switching network) T2 second "" second sub-switching network
(Output switching network) 11 ...)
Ilo24) input first terminal entry 91 ...)
o2o48) c-link c intermediate line 01 ...)
01024) output first terminal entry All..As first switching array Large entrance paddock group A21 ... A28 second switching array Output coupling group B111 ... B114 switching block Coupling group a, b, d, e link Intermediate line AI9 ... AII6,
A29..A216 ν switching array- Large coupling group BI9I ..
Bl 94 switching block Coupling group Pl..P4)
P7.P8) inlet entry P5, P6 outlet exit ► 0 Blank page