DE3438494A1 - Circuit arrangement for telecommunications systems, in particular telephone switching systems, with input/output processors interacting via bus lines with central data processing systems - Google Patents

Abstract

If the operating voltage of a processor fails, the latter completes a currently running bus cycle of a data exchange process with an input/output device using the power stored in a blocking capacitor. De-activation of the processor on the basis of coincidence of failure signal and bus cycle end signal. <IMAGE>

Description

Circuit arrangement for telecommunications systems, in particular

Telephone exchanges, with over bus lines with central Data processing systems cooperating input-output processors The invention relates to a circuit arrangement for telecommunications systems, in particular telephone switching systems, in which central data processing systems have bus lines with input-output processors are in the forced operation process, e.g. receipt-controlled, in data exchange, and in which a data processing system on the one hand and cooperating with it Input-output processors on the other hand with operating voltage from independent Voltage sources are fed that are buffered by means of individual blocking capacitors which bridges the short-term drying up of the respective voltage source and the supply of operating voltage is continued, or as a result of increasing Capacitor discharge the data exchange is ended.

A circuit arrangement of this type is already mentioned in the magazine telcom report "1981, supplement, described telephone switching system is known. In particular, reference is made to the article on page 33 ff. As in picture 1 on Page 34 is shown, a central processing unit (data processing system) works together with several input-output processors via a central bus line. If this cooperation takes place in the aforementioned compulsory process, this means that the individual data transmission processes, for example, through opposite transferred Acknowledgment sign as received or confirmed by synchronous signals (ready signals) are designated as complete and to be accepted by the respective recipient. This forced operation method has the known advantage that the relevant transfer processes and other processes can be completed in less time than if would be worked in a known manner with appropriate time monitoring.

Since when a processing unit is heavily loaded, this is done in individual cases actually an above-average amount of time to carry out a transfer process or an internal processing procedure, time monitoring would have to be carried out on the other side, i.e. in one that works together with the processing unit Input-output processor take this into account for the timing process would result in a disadvantageously high time requirement and thus a slowdown in the Totality of the transfer processes and other processes.

As can be seen from the above-mentioned Figure 1, there is a substitute switching case also a cooperation of one of the two processing units with the input-output processors the respective other processing unit provided.

Each of the two processing units may now have its own Be equipped with a voltage supply device. If one of the two fails, in the equivalent switching situation, it can happen that this occurs during a The transfer process currently in progress happens, that is, one of the two processing units is directly affected by this power failure, but not a straight one their input-output processor working together in this transfer process. A similar case can occur when a processing unit on the one hand and its assigned input-output Processors, on the other hand, two have different power supply devices.

From the contexts explained, the problem arises that a the transfer process that has just been completed in the forced operation process can be interrupted can, and that someone who is not affected by the voltage failure in question Input-output processor is paralyzed because he is on the logical continuation of the current transfer process is waiting. This can lead to blockages central facilities, as well as serious disruptions to transmission processes, by, for example, in a not yet completed, but in the one described If the transfer process has been interrupted, another transfer process plays into it, which can have unmistakable consequences in terms of data corruption. For the invention the task is in a circuit arrangement of the type specified below the conditions mentioned to ensure that there are no supply voltage failures affected transmission processes cannot lead to data corruption.

The invention solves the problem in that the blocking capacitors can also be used if the voltage source runs dry during one ongoing data exchange process the relevant data processing system up to To supply the end of the same with operating voltage, and that a coincidence circuit is provided by a voltage supply device of the data processing system concerned a first signal of an operating voltage failure and from the data processing system receives a second signal indicating the progress of a data exchange process, and that the coincidence circuit in the presence of the first signal and in the absence of it of the second signal Lock signal to the data processing system transmits that this causes no new data exchange process to be started.

In the drawing, an embodiment of the invention is only in The components that are essential to their understanding are shown where they are however, is by no means limited.

The description continues in the magazine ~ telcom report as known. Also the short names of the individual elements in the drawing are based on the representation in Image 1 on page 34 in the magazine mentioned.

The drawing is represented by a dash-dotted line horizontally Line divided into two parts. Above the dash-dotted line is among other things a processing unit PUO is shown, which is part of a central processor is. A bus arbiter BAD and a memory unit also belong to the central processor MUO.

These parts within this central processor are one below the other connected in a manner known per se via a central system bus CSBO. This System bus runs (further to the right) to input-output units not shown in detail, assigned to the central processor indicated above the dash-dotted line are.

Also below the dash-dotted line shown horizontally a processing unit PU1 is indicated. This belongs to a second central one Processor.

Input / output devices IOP-PT1, IOP-MDD1 are assigned to this. The processing unit PU1 also protrudes one not shown central system bus with the aforementioned input-output units in connection.

In the event of a malfunction in one of the two central processors it is ensured that the other central processor is known per se The tasks of the central processor affected at the time of the malfunction with takes over. Two bus expansion units BEUO-O and BEUl-l are provided for this purpose, with their help, a second central system bus CSBE1 with the central system bus CSBO of the other central processor can be connected. On this one Paths can be the data exchange between the processing unit of the malfunction unaffected central processor with the one affected by the malfunction central processor associated input-output units are handled.

It is now provided that all switching devices above the dash-dotted line shown horizontally from a common voltage supply device are fed, and that also all below the dash-dotted line switching devices shown from a second power supply device be fed. The voltage supply device shown in the drawing So W is the common voltage source for the processing unit PUO as well for the other components of the central processor concerned, as well as for the not assigned to this central processor above the dash-dotted line input-output devices shown in detail, to which the central System bus CSBO leads there. The processing unit PUO is therefore a data processing system with which the input-output processors below the dash-dotted line in the Substitute switching case together work. You will be using operating voltage fed from independent voltage sources. The one above the dash-dotted line Processing unit PU0 shown in the line is operated by the voltage supply device W fed while the input-output devices shown below the dash-dotted line be fed by another voltage supply device.

As can be seen from the drawing, the power supply device W buffered by means of a blocking capacitor K in a manner known per se. Through this are very sporadic short-term voltage drops on the part of the voltage supply device bridged in a known manner. The power supply from a voltage converter may via the two conductors x. The transmission of the operating voltage to the processing unit PU0 and to the bus arbiter BAD, the memory unit MU0 and others not shown Establishments should take place via the two conductors y. Now the one from the above dries up Voltage converter existing voltage source, so the supply with operating voltage briefly continued with the help of the aforementioned blocking capacitor K until as a result increasing capacitor discharge the data exchange of the processing unit concerned PU0 inevitably stops.

The data exchange between the processing unit PU0 and the input-output processors processed, takes place in the compulsory process. This has already been explained in the introduction.

If the voltage supply fails in the manner described one, it may be that this is taking place during a data exchange process. Is it a data exchange process between the processing unit? PU0 and the input-output device IOP-PT1 and falls from the operating voltage supplied from the voltage supply device W, then the the aforementioned input-output device is not affected by this. She can do this Power failure cannot be recorded immediately as a change in the operating situation.

Now to the current data exchange process, which -as mentioned - it is processed in the forced operation procedure, to be completed, is in the bus allocator BAD, among other things, a coincidence circuit z is provided. This coincidence circuit receives a signal from the voltage supply device W via the current path a, which signals the failure of the operating voltage supply. The coincidence circuit z also receives the run of a from the bus distributor BAD via the current path b in Second signal indicating the data exchange process. The coincidence circuit gives when the first signal is present via the current path a and when the is not present second signal via the current path b from a blocking signal via the current path c, the causes that no new data exchange process can be started. this will by the bus allocator BAD in that it does not initially allocate a new bus performs more. The bus allocation given in this operating situation remains. When the relevant data exchange process has been completed, the system bus becomes CSBO free again. A renewed allocation of the same is prevented for the time being. The operations the request and the implementation of a bus allocation are known per se and are therefore not described in detail.

With the help of the coincidence circuit is thus accomplished that a at the moment a malfunction occurs in the voltage supply device W ongoing data exchange process is continued, with the further voltage supply is accomplished with the help of the blocking capacitor K, which serves as an auxiliary voltage source for a short time. It is now necessary that the Operation of the processing device PUO is stopped at the right moment. Therefor is the voltage supply device W via the current path a said first Signal that is of a preparatory nature. If the processing unit PUO is currently The current data exchange process is ended, the output signal of the coincidence circuit z, thereby causing the processing unit PUO no longer starts a new data exchange process in that the bus allocator has the Data bus no longer allocated.

It is ensured that a failure of the operating voltage supply the data exchange process concerned is still being completed. The one from the failure the operating voltage supply is not itself affected by the input-output processor however, remains unaffected by any consequences of this failure.

3 claims 1 figure

Claims (3)

Claims 1. Circuit arrangement for telecommunications systems, in particular Telephone switching systems in which central data processing systems have Bus lines with input-output processors in forced operation, for example receipt-controlled, are in data exchange, and in which a data processing system on the one hand and input-output processors that work together with it on the other are supplied with operating voltage from independent voltage sources, which are buffered by means of individual blocking capacitors, which means that the Drying up of the respective voltage source bridged and the supply of operating voltage is continued, the data exchange is terminated due to increasing capacitor discharge it will be shown that the blocking capacitors are added can also be used if the voltage source runs dry during an already running one Data exchange process the data processing system in question to the end of the same to be supplied with operating voltage, and that a coincidence circuit is provided, from a voltage supply device of the data processing system concerned a first signal of an operating voltage failure and from the data processing system receives a second signal indicating the progress of a data exchange process, and that the coincidence circuit in the presence of the first signal and in the absence of it of the second signal transmits a blocking signal to the data processing system, that this causes no new data exchange process to be started. 2. Circuit arrangement for telecommunication systems, in particular telephone switching systems, in which a bus distributor is assigned to a bus line, d a d u r c h g ek e It is not indicated that the coincidence circuit is assigned to the bus arbiter. 3. Circuit arrangement according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the coincidence circuit as an AND circuit with a negating Input is formed through which it is fed the second signal, and that the first signal is fed to it via the other input.