SU307532A1 - SWITCHING DEVICE - Google Patents

Description

The invention relates to the field of communication and can be used in multi-stage coordinate switching schemes.

Switching devices are known that have a multi-stage multiplexing scheme in which the sources of calls are included in the nodes of the first cascade with complex transposition.

In order to increase the capacity in the proposed switching device, the nodes of the first cascade are transposed into the nodes of the second cascade, while the nodes of the second cascade are combined into groups, each of which is available to call sources through the nodes of the first cascade corresponding to two types of switching on the first cascade; the nodes of the second cascade, accessible to each particular source of calls through the groups of nodes of the first cascade corresponding to different types of switching on the first cascade, are different.

FIG. 1 shows the proposed scheme with complex transposition in the first cascade and transposition in the second cascade; in fig. 2-scheme with a complex (three-dimensional) transposition in the first cascade, with transposition in the second cascade and with nodes of the second cascade, accessible sources of calls through the nodes of the first cascade corresponding to two types of activation in the first cascade; in fig. 3 and 4 schemes with complex transposition in the first cascade, with transposition in the second cascade, with nodes of the second cascade, available sources of calls through the nodes of the first cascade corresponding to two types of switching in the first cascade, and the source of the call through different types of inclusions has access to different nodes of the second cascade.

As shown in FIG. 1, in the first cascade there are three kinds of inclusions, in the second cascade there are two kinds of inclusions. In the scheme, the sources of calls are located in integer points of the three-dimensional parallelepiped with dimensions

 Each node that is at an integer point contains / r call sources. The total number of call sources is equal to / r () - The first cascade (cascade L) is formed together with the sources of calls and switching nodes A. The latter are divided into three groups, designated by L, AS and AZ. The second cascade (cascade B) is formed in conjunction with nodes A and B. Nodes A are nodes of the first stage, and nodes B are

nodes of the second cascade. Kaka can be seen from FIG. 1, cascade A is divided into three groups according to three types of switching on sources of calls to the nodes of this cascade, and cascade B is divided into six groups corresponding to three different

Inclusion in each of the three groups of the cascade B. These groups are designated: B, B, B, B, viB The total number of nodes B is 2X (- -k nizmi +). If nodes B are circuit outputs (or connected to nodes of the next cascade (third), their number may be greater than the number of external (with respect to this circuit) lines included in these outputs, therefore, when the lines are turned on, incomplete inclusion.

Through each nodes L and B can pass one or more connections. (The largest number of connections is called node connectivity).

In the circuit shown in FIG. 1, a two-stage transposed inclusion is formed, which gives an effect that is fundamentally different from the effect produced in the known two-stage scheme with transposition only in the first stage.

The total number of shaded nodes in the scheme is equal to (m2 + ms) mi. Nodes are available to a group of call source, the number of which is equal to / r (h). If there is no transposition in the second stage, then all nodes are located in one of the jSj or GZ rectangles, and there is no other rectangle at all. With transposition in the second cascade, the same nodes are already available in aggregate to a larger number of call sources () If ki 2, then in the second cascade without transposing, in the second stage, access to the nodes in question have hk sources, and in the transposition circuit, hk (2k-1) sources i.e. almost twice as much. A typical numerical example can be the practical use of a thousand subscriber group (,), in which, and M (2fe-1) 190.

Thus, in order to increase the throughput of a multi-stage scheme with complex transposition in the first stage, the nodes of this cascade are also transposed into the nodes of the second stage, resulting in a scheme with two-stage transposed inclusion (two-stage transposition), which allows to improve mixing between call sources and nodes of the second cascade.

If in a two-stage transposition scheme a group of nodes B and B-2 and 5z is joined together (FIG. 2), an even greater intermixing of the sources and outputs of the scheme is created: each group of outputs is available to the corresponding sources of calls through the nodes of the first cascade, corresponding not

one and two types of inclusion. For example, shaded nodes BZ are available to sources through nodes L, and through nodes L. In the diagrams (Fig. 3 and 4), the nodes of the first cascade are included in the nodes of the second cascade so that the nodes of the second cascade accessible to a particular call source through different groups of nodes of the first cascade Are different, resulting in an increase in throughput. In the diagram in FIG. 2, the darkened group of nodes B is available to hkik2 sources, and in the diagrams (Figs. 3 and 4) - to twice as many sources. However, each source (in the scheme of Fig. 2) has access to mim + mims- -mzms nodes S, and in the schemes (Fig.

3 and 4) to 2X {mitn2 + mims + m2m3) nodes B. This increase in accessibility leads to an increase in throughput. In the two-stage switching circuit (Fig. 4), the outputs are incomplete with respect to the sources.

This scheme differs from all known two-stage schemes with incomplete inclusion in that it has the maximum possible number of load groups equal to the number of nodes where the sources of calls are located. For any pair of nodes with call sources, there are outputs that are accessible only to the second node.

Subject invention

A switching device having a multi-stage multiplexing scheme, in which the sources of calls are included in the nodes of the first cascade with complex transposition, characterized in that, in order to increase throughput, the nodes of the first cascade are also included in the nodes of the second cascade transpose; at the same time, the nodes of the second cascade are grouped into groups, each

of which are available to call sources through the nodes of the first cascade, corresponding to two types of switching on the first cascade; second cascade nodes available to each specific call source through groups

the nodes of the first cascade corresponding to different types of switching on the first cascade are selected different.

Priority to be calculated from 21. U1. 1967 (No. 1169984 / L26-9)

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