DE9202641U1 - Computer-controlled communication system - Google Patents

Description

y^ &ugr;&igr;&ugr; a &ugr; de

Siemens AG

Computer-controlled communication system

The invention relates to a computer-controlled communication system according to claim 1.

Safety-related programs in communication systems are intended to ensure maximum availability. The safety-related programs ensure that the effects of a fault are limited and, by localizing faults precisely for each component, help to ensure that faults in the system can be eliminated quickly and in a targeted manner. A communication system with such safety-related operating technology is known from a Siemens publication: "ISDN in the office", special edition of telcom report and Siemens magazine COM, ISDN 3-8009-3846-4, Berlin and Munich 1985, 95-106.

The safety-related programs of this communication system analyze errors that occur and determine the type of error, using feedback from recommissioned units to differentiate whether an error is sporadic or permanent or constant. The type of error is determined precisely for the replaceable unit. The measures initiated by the error analysis process depend on the previous diagnostic result. This can be simple fault statistics counts or blocking and recommissioning orders. The recommissioning of an originally blocked hardware unit is acknowledged by the unit itself with a corresponding acknowledgement signal and reported back to the associated control system, which implements the safety-related procedures. If such an acknowledgement signal is not received, for example because the hardware unit in question fails again, it is considered blocked by the control system receiving the acknowledgement signals.

The invention is therefore based on the object of making a communication system of the type mentioned at the outset independent of acknowledgement signals from units that have been put back into operation in terms of its safety-related design.

SZ ü 1 O 9 O DE

This object is achieved according to the invention with the features of the main claim.

It is essential for the invention that after a faulty unit has been deliberately taken out of service, it is put back into service after a predefined period of time and monitored for the occurrence of further errors. If errors occur again, this faulty unit is taken out of service for good; if, on the other hand, no more errors occur, the originally faulty unit is considered to be fault-free by the corresponding control system.

The invention will now be described using a figure as an example. The communication system shown in the figure consists of a switching section SWU and an operational unit ADS (Administration and Data Server). The switching section SWU consists of several line groups LTGl...LTG8 (Line Trunk Group), a central switching network CSN (Central Switching Network), a control CC (Common Control) and a central clock device CCG (Central Clock Generator). This communication system can be structured like the system disclosed in the published European patent applications EP 0306 693 A1 (US-PS 4,903,258), EP 0303 870 A2 (US-PS 5,018,097) and EP 0303 869 A1 (US-PS 5,047,923).

The line groups LTGl...LTG8 each consist of line units LTUl...LTU4, a group switching network GSN (Group Switching Network), a service unit SU (Service Unit) and a group control GCl...GC8 (Group Control).

The connection units LTU1...LTU4 consist of peripheral modules, which form the interface adaptations between the switching system and the digital or analogue environment. 35

The following are used as subscriber-oriented device connections: Digital subscriber connection modules, these are ISDN basic connections for digital mono- and multifunctional terminals, digital subscriber connection modules

92 G 1 O S O DE

groups, which are l-channel connection modules for terminal devices, such as digital voice terminals and switching terminals, analog subscriber line modules for analog voice terminals.
5

The peripheral modules also include line connection modules, which are used to connect to public and private networks or special facilities. These include, for example, digital line harness modules, i.e. ISDN basic connections for ISDN exchange and cross-traffic, digital interface units, i.e. multiplex connections (30 channels of 64 kbit/s each), analog line harness modules, i.e. line connection modules for analog lines and X.21 subscriber or exchange line modules, i.e. connection modules for digital lines in accordance with the ISDN standard X.21.

External reference clock signals are fed to the switching system via the line connection modules, which are referred to below as reference clock supplying modules. 20

Several peripheral modules are functionally and structurally combined to form a connection unit (LTU).

A service unit SUl is assigned to several connection units LTUl...LTU4. The service unit SU consists of a signaling unit, an audio tone generator and, if necessary, a conference facility.

The signaling unit is responsible for supplying the system with audible tones, announcements and receiving DTMF dial tones and trunk dial tones. This function is implemented using signal processors.

Each line group LTG has a group control GC, which sets the coupling stage GSN. A coupling stage GSN connects the four line units LTU1...LTU4 and the service unit SU to each other. It is connected to the coupling stage CSN via eight multiplex channels and, via its connections to other coupling stages GSN, also to other

92 B 1 O 9 O DE

Coupling stages GSN connected.

The CSN coupling stage is made up of units with two MTS (Memory Time Switch) 64 time stages. Each MTS 64 time stage connects any two of the 64 time slots of the 64 incoming and outgoing multiplex channels for voice or data. The group controllers GCl...GC8 and the central controller CC, which can also be duplicated, have the same structure. At least some of these controllers CC, GCl... GC8 are assigned a safety-related program, which is described in terms of its error detection and error handling function. The core of every controller is a uniform data processor with a standard operating system. The basis for this is the SAB8086/80286 processor family from Siemens and a working memory that can be expanded to 32 Mbyte, for example. The memory modules contain highly integrated dynamic RAM components and error correction circuits. The data processor and memory modules are connected by a standardized multibus. The settings for the directly assigned coupling network are made via these interfaces.

To process the HDLC protocol to the connection units LTU and the service unit SU, a processor for signaling control is connected upstream on the multibus. The message exchange with the protocol control in this module takes place via a memory area on the multibus, which can be controlled by both the data processor software and the signaling control software.

The switching system can be designed in such a way that the central clock device CCG generates all the required system clocks (“CLOCK”). In the switching system shown in the figure, these are fed to the units GC and IOCC, which have their own clock repeater devices. These devices forward the system clock “CLOCK” to the switching matrix stages GSN and CSN.

As already mentioned, the central control CC and/or the group controls GC 1...GC 8 are equipped with a safety

92 G 1 O 9 O DE

As with the communication system disclosed in the above-mentioned published European patent applications, the communication system according to the invention also provides that at least some of the subsystems of the communication system are monitored for errors on a subsystem-by-subsystem basis. It can also be provided that error values assigned to the errors are added on a subsystem-by-system basis and that when a predefinable first error threshold is reached, the subsystem in question is taken out of operation.

In the communication system according to the invention, for example, the controllers GCl...GC8 monitor the associated connection units LTU of the respective connection group LTG. The addition of the error values can be carried out using known hardware counting devices. Preferably, however, the addition of the error values is carried out using a corresponding computer program, which then functions as a counting device.

The control program assigned to the controls of the system or subsystems is further designed in such a way that after a predeterminable first time has elapsed after the relevant subsystem has been taken out of service, for which the reaching of the first error threshold value has been detected, it is put back into service. During a predeterminable second time after the relevant subsystem has been put back into service, it is again monitored for errors. The errors that then occur are in turn assigned error values, which are added during the second time. When a predeterminable second error threshold value is reached, the relevant control permanently takes the subsystem that has been put back into service out of service. Such a subsystem, for example a hardware unit LTU, is thus excluded from all switching, safety and operational procedures running in the system. The possible error incentives that this subsystem that has been taken out of service would pass on to the associated control are avoided and therefore do not burden the system. The decommissioned subsystem can then be replaced by a fault-free hardware unit. If, however, the second

U &udigr;&igr;&ugr; y &ugr; ut

If the threshold is not reached, it is assumed that the fault that occurred in the form of errors during the first monitoring period was only of a temporary nature. After the second monitoring period has expired, this system will be included in the switching, safety and operational procedures as before.

The error values assigned to the errors, the first and second error threshold values, the times during which the units are monitored for the occurrence of errors, as well as the first (blocking) time following the first error threshold being reached, can be configured by making appropriate entries in the ADS operational unit.

It can be provided that the first and second monitoring times are of equal length and that the first and second error thresholds have the same value. Furthermore, the safety-related program assigned to the CC and GCl... GC8 controls can be designed in such a way that when the first threshold is reached or exceeded, the relevant hardware counter or the corresponding software program module is reset to zero in the counting position or is reduced by a decrement that can also be configured via the ADS operating device. Alternatively, it is provided that the hardware or software program counter is not reset, so that the second error threshold is arranged above the first error threshold.

Claims (3)

b I U 3 U LJL Protection claims 1. Computer-controlled communication system with subsystems, in particular peripheral units, whereby a control program assigned to the system control (CC, GCl...GC8) is designed in such a way that at least some of the subsystems are monitored for errors on a subsystem-by-subsystem basis, that error values assigned to the errors are added on a subsystem-by-system basis, and that when a predefinable first error threshold is reached, the relevant peripheral unit is taken out of operation, characterized in that the control program assigned to the system control (CC, GCl...GC8) is further designed in such a way that after the expiry of a predeterminable first time after the relevant subsystem has been taken out of operation, the latter is put back into operation and that during a predeterminable second time after the relevant subsystem has been put back into operation, the latter is monitored for errors, that the error values assigned to the errors then occurring are added and that when a predeterminable second error threshold value is reached, the subsystem that has been put back into operation is finally taken out of operation. 2. Computer-controlled communication system according to claim 1, characterized in that a counting device which adds the error values is reset to a value below the first error threshold value when the first error threshold value is reached. 3. Computer-controlled communication system according to claim 2, characterized in that the same value is assigned to the first and second error threshold values.