DE1173951B - Circuit arrangement for telecommunications systems, in particular telephone systems, with large collective connections - Google Patents

Description

Circuit arrangement for telecommunications systems, in particular telephone systems, with large collective connections The invention relates to a circuit arrangement for telecommunication systems, especially telephone systems, with large collective connections, whose number of connecting lines is greater than the number of outputs from the last one Elective level of a grouping unit of the last two elective levels.

For example, includes a grouping unit of the last two electoral levels of an office, as shown in FIG. 1 is shown, in the last option level TW a certain number, z. B. ten switching matrix KV with a certain number of accesses, z. B. fifteen, and a certain number of outputs to connecting lines, z. B. ten, it would be conceivable, the number of these switching matrices KV the number of required connecting lines, z. B. two hundred to adapt and to subdivide the output switching matrices AKV of the penultimate elective level TGW into groups, each of which only has access to part of the switching matrix KV of the last elective level TW. A corresponding arrangement in which the output switching matrices AKV of the penultimate selection level TGW are divided into two subgroups is shown in FIG. 2. While namely in the arrangement according to FIG. 1 N coupling groups KG of the penultimate elective level TGW with, for example, nineteen output switching matrices AKV each have access to all ten switching matrices KV of the last elective level TW, are in the arrangement according to FIG. 2 2 coupling groups KG of the penultimate elective level TGW with nineteen output coupling matrices AKV each switched to ten coupling matrices KV of the last elective level.

The general condition for hunt groups is that certain lines, e.g. B. Lines to extensions in single circuit, lines for remote office connection or the like from each coupling group of the penultimate dialing level must be reachable from. In the arrangement according to FIG. 2 would have such lines of both subgroups of the output switching matrices AKV of the penultimate elective level TGW reachable and thus at least two KV switching matrices of the last elective level TW be switched on, so that double the number for such connecting lines of crosspoints in the last elective level TW results.

To avoid this effort, it would be conceivable to use the switching matrix KV of the last option level TW, to which the lines are connected, the individually Must be controllable to modify by changing the number of accesses to these switching matrices belittles. Apart from the fact that under such a solution as with others known arrangements that focus on caller levels with multiple area codes and relate to group election levels, the uniform structure of an office would suffer, Even then, the number of crosspoints to be used would still be relatively large.

The invention takes a different, more expedient way and is characterized in that the output switching matrices of the penultimate selection stage of a grouping unit in a manner known per se in p, z. B. two subgroups are subdivided, each of which is assigned a number n of these switching matrices individually from a number m of switching matrices of the last option level, while the remaining mp - n switching matrices of the last option level are jointly assigned to all subgroups of switching matrices of the penultimate option level and with the Connection lines are wired, which must be individually controllable (e.g. lines to extensions in single night switching, lines for remote exchange connection).

With the invention it is possible without changing the number of accesses or outputs of switching matrices and without unnecessary additional effort of crosspoints Large collective connections, the number of connecting lines is greater than the number of outputs from the last electoral stage of a normal grouping unit to operate so that certain lines can be controlled individually.

In Fig. 3 shows an embodiment of the invention. In this exemplary embodiment, similar to the arrangement according to FIG. 2, the output switching matrices AKV of the penultimate selection level TGW are divided into subgroups, each of which comprises the output switching matrices of several switching groups KG. The output switching matrices A KV are divided into p = 2 subgroups. so that for each subgroup the output switching matrix AKV of Coupling groups belong to the total of N coupling groups, each with nineteen output switching matrices AKV. Each subgroup of output switching matrices AKV now has access to n switching matrices KV of the last option level TW, which can only be reached by this subgroup and to which only connecting lines are connected that do not have to be individually controllable. Since two subgroups are formed and each switching matrix KV of the last option level TW has ten outputs, 20n connecting lines can be controlled via the 2n switching matrices that can be individually reached by the subgroups.

The lines that must be individually controllable are then connected to the remaining m-2 n of the m switching matrices KV of the last option level TW, which are reached by both subgroups of output switching matrices of the penultimate option level.

A total of 10m lines can be reached, of which 20n cannot, while 10m-20n can be controlled individually. If the number 10 m = 160 and the number of lines that must be individually controllable equals 10 m-20 n = 40, then m = 16 switching matrices KV are to be used in the last option level TW, of which n = 6 each only from the output switching matrices AKV of a subgroup of output switching matrices AKV of the penultimate level TGW can be reached, while m-2n = 4 switching matrices KV can be reached by both subgroups.

Claims (1)

Claim: Circuit arrangement for telecommunication systems, in particular telephone systems, with large collective connections, the number of connecting lines is greater than the number of outputs from the last selection level of a grouping unit of the last two selection levels, characterized in that the output switching matrices (AKV) of the penultimate selection level (TGW) in a grouping unit in a manner known per se in p, z. B. two subgroups are subdivided, each of which is assigned a number n of these switching matrices (KV) individually from a number m of switching matrices (KV) of the last elective level, while the remaining mp - n switching matrices (KV) of the last elective level (TW) all subgroups of switching matrices (AKV) of the penultimate dialing level (TGW) are jointly assigned and connected to the connection lines that must be individually controllable (e.g. lines to extensions in single night switching, lines for remote exchange calls). Considered publications: German Auslegeschriften No. 1069 206, 1013326.