DE3829206A1 - Method for controlling communication switching systems, particularly telephone branch exchanges - Google Patents

Abstract

The aim of this method is that in the case of overloading or a failure of central processors, an immediate replacement is available so that high operational reliability is given even in the case of large communication switching systems. The traffic-handling capacity of a communication switching system should not be reduced significantly even when central sections fail. A number of space-division switching stages of similar construction are provided which are controlled by in each case their own central processor. The space-division switching stages have access to all access unit groups via separate buses. A number of access unit groups are combined in such a manner that the connections coming from these are predominantly switched via a bus and via a space-division switching stage associated with the latter, which is set by a central processor responsible for it. In the event of a failure or overloading of this central processor, the switching-through of connections is taken over by another central processor, in which case a different bus and a different space-division switching stage are then used. In the event of a failure or of the overloading of a central processor, the traffic-handling capacity of a communication switching system is not significantly impaired and the operational reliability is drastically increased.

Description

The invention relates to a method for controlling communication switches systems, in particular telephone private branch exchanges according to the generic term of claim 1.

DE-AS 22 11 400 is a two-stage time division multiplex switching system known. The connecting elements are grouped together and each introduced to a first coupling stage, which works according to the time division principle switches through. The busbars starting from the first coupling stages are connected to a second coupling stage, which is constructed in a matrix and accordingly has switching points switching through in the multiple of space. The control of the entire system is done by a central control computer, which with Channel control via a status and command channel to access the has individual connection organ groups and also the settings in the Makes coupling steps.

It is known that central control devices have a high level of operation security must be given, because otherwise the probability of failure of the Ver system could be too high. Essential aspects that are important to zen central control devices with regard to operational safety are dealt with in the DE specialist book "Computer-controlled switching systems teme "by P. R. Gehrke (see chapter 6.3 pages 102 to 115), Springer Publishing house 1972.

In order to increase the operational security of a switching system, it is known to provide central control devices in duplicate. A procedure for switching the central control device into telecommunications, in particular Telephone switching systems are known from DE-PS 29 06 221. Here  However, the problem arises that the in a malfunction of the first tax establishment, or the first control computer to take over the second Control device, or the second control computer with all current connections supply data is supplied. Such a configuration with a double Control device cannot provide a higher traffic performance than one fold control device, so that especially in large switching systems Overload cases can occur.

The object of the invention is to propose a method by which in the control of communication switching systems, especially remote so that the central control devices are arranged are that against failure-related failures and overloads side help is possible, so that the operation with almost undiminished Performance can be maintained.

To solve this object, features are provided as in claim 1 are specified.

This is advantageously achieved that not only in the event of a failure central control device but also in the event of an overload by others Central control devices take over permanently or temporarily men can be. Since each control device has its own coupling stage adds, there is the additional advantage that the requirements for a An exchange will be given to increase traffic performance if this is required.

Give the developments of the invention specified in the subclaims advantageous embodiments of the method, with which the operating options can be further improved.

An embodiment of the invention is explained below with reference to a drawing. In the overview circuit diagram of a large communication switching system, a large number of connection groups AG 1.1 to AGx.n. shown, which are interconnected via a common data line bundle BUS and have access to central controls IVZ 1 to IVZn . Busbars SS are provided as connection paths , which lead to the higher-level coupling stages KS 1 KSn . Each individual connector group, e.g. B. AG 1.1 is with a transmission bus and a reception bus, z. B. SS 1.1.1 , each of which belongs to an associated superordinate space coupling stage, for. B. KS 1 lead. On each pair of busbars there is a certain number of time slots, so that a corresponding number of connections can be switched through.

Several connecting organ groups, e.g. B. AG 1.1 to AG 1. m are summarized so that the outgoing connections predominantly via a predetermined busbar, for. B. SS 1.1 and one of these busbar SS 1.1 assigned space coupling stage KS 1 are switched. The decentralized group controls in the relevant connection groups AG 1.1 to AG 1. m are programmed in such a way that the occupancy requests of the responsible central control IVZ are offered. This central control IVZ 1 now determines which time slots are free on the relevant busbar SS 1.1.1 . For each connection request, a free time slot is occupied, which is then converted into a different time slot by a time slot conversion device ZU 1 located in the higher-level space switching stage KS 1 if the same time slot was on a busbar, e.g. B. SSx. 1.1 is not available, which belongs to the connecting group, e.g. B. AGx. 1 leads where the destination of a connection is.

A monitoring device ÜE is connected to the already mentioned data line multiple BUS , which can determine whether one of the central controls IVZ 1 to IVZn has failed or is overloaded. If, for example, the central controller IVZ 1 responsible for the connecting group AG 1.1 to AG 1. m is overloaded, the relevant decentralized group controls in all affected connecting group AG 1.1 to AG 1. m are informed that another central unit is now being used for new assignments Control, e.g. B. IVZ 2 is responsible. As a result, other busbars, e.g. B. SS 1.1.2 , which lead to another superordinate space coupling stage KS 2 , used. Since this higher-level space coupling stage KS 2 is connected in the same way via busbars to all the connection groups AG , any type of connection can also be established. In the responsible decentralized group control of a connecting group AG is only recorded in this case that the connection from another central control, for. B. IVZ 2 was built. The relevant connections are thus managed by this central control IVZ 2 , so that triggering processes can be controlled properly. In each decentralized group control of a connecting group AG , a stored information specifies which other central control IVZ will take over the operation temporarily or continuously when the central control IVZ 1 actually responsible is overloaded or has failed.

So that in the event of a central control failure, e.g. B. IVK 1 no extensive data exchange with another central control, z. B. IVZ 2 must take place, it can be provided that in such a case all switched over the relevant space switching stage KS 1 connections are triggered. These connections can then be re-established, with the other central control IVZ 2 then taking over the traffic. Since with a large communication switching system and a corresponding division of the connecting group AG only a small part of the total connections from a failure a central control, eg. B. IVZ 1 and / or the assigned higher-level space switching stage KS 1 is affected, such a measure can be tolerated.

It can also be provided that the assignment of a central control, for. B. IVZ 1 is not fixed to a higher-level space switching stage KS 1 , but that switching devices by switching connections from a central control device, for. B. IVZ 2 also in another superordinate space coupling stage, for. B. KS 1 is made possible.

Since the individual Anschlussorgangruppen AG over several busbars, for. B. SS 1.1.1 to SS 1.1. n have, a decentralized group control located in the Anschlussorgangrupe AG can be set up in such a way that further allocation attempts are made via other busbars, if on the actually for the relevant connection group, e.g. B. AG 1.1 responsible busbar SS 1.1.1 no more time slots are free. In such a case another central control, e.g. B. IVZ 2 controlled so that a connec tion can possibly be switched through a free time slot of another busbar SS 1.1.2 . Such a connection then runs via another higher-level space coupling stage KS 2 , and the management of this connection is the responsibility of the central control IVZ 2 responsible . With such a measure, the access possibilities are increased drastically, so that the traffic performance of the entire communication switching system rises sharply. In this way, bottlenecks occurring in few places during peak hours can be avoided.

Claims (6)

1. A method for controlling communication switching systems, in particular telephone private branch exchanges, which switch digitally according to the time-division multiplex principle, with a time-space-time coupling arrangement being used to connect the connecting elements combined in groups, and in addition to decentralized ones Group controls central control devices are provided, characterized in that
that several similarly designed space coupling stages (KS 1 to KSn) are provided, each of which is controlled by its own central controller (IVZ 1 to IVZn) ,
that the space coupling stages (KS 1 to KSn) have access to all connection organ groups (AG 1.1 to AGm.n) via separate busbars (e.g. SS 1.1.1 to SS 1.1. n) ,
that a plurality of connection member groups (eg. B. AG 1.1 to AG 1 m) are combined so that the extending therefrom compounds agreed predominantly a vorbe busbar and z have one of these busbar (. B. (SS 1.1.1) associated with space switching stage ( KS 1 ) are switched, which is set by a responsible central control (IVZ 1 ), and
that if a central controller (e.g. IVZ 1 ) fails or is overloaded, the switching through of connections is taken over by another central controller (e.g. IVZ 2 ), with another busbar (e.g. SS 1.1. 2 ) and another space coupling stage (e.g. KS 2 ) is used. 2. The method according to claim 1, characterized in that a monitoring device (ÜE) is provided which notifies the decentralized controls located in the port group (AG) when due to overload or failure of the actually responsible central control device (z. B. IVZ 1 ) a busbar (SS 1.1.2 ) leading to another space coupling stage (e.g. KS 2 ) and thus another central control device (IVZ 2 ) must be occupied. 3. The method according to claim 1, characterized in that in the event of failure of a central control (z. B. IVZ 1 ), the existing connections in the associated space coupling stage (KS 1 ) are separated so that no data exchange must take place. 4. The method according to claim 1, characterized in that in normal operation further occupancy attempts over other busbars (SS 1.1.2 to SS 1.1 n) can be undertaken if on the group actually responsible for the relevant connection group (e.g. AG 1.1 ) rail (SS 1.1.1 ) no more time slots are free. 5. The method according to claim 1, characterized in that in the space switching stages (KS) time slot conversion devices (ZU) are seen before so that at a given starting time slot the same time slot in another line group (AG) does not have to be free when a connection must be switched there. 6. The method according to claim 1, characterized in that switching devices are provided in the space switching stages (KS) so that interconnections can also be controlled by others and not only by the responsible central controller (IVZ) .