DE3806262C1 - Circuit arrangement for monitoring the state of switching points in a digital space-division switching network - Google Patents

Abstract

In an integrated digital switching matrix, the switching points are to be monitored during operation so that it is possible to detect whether individual switching points are defective. It should be possible to store and retrieve information on this. An input multiplexer and an output multiplexer are provided by means of which the individual inputs and the outputs can be cyclically selected in order to compare input signals with output signals. The result of the comparison is evaluated and when faults are detected, the associated address is stored in a memory. Due to the automatic monitoring, in which useful signals are compared with one another, the existence of defective switching points is detected so that the setting commands for switching through connections can be appropriately changed.

Description

The invention relates to a circuit arrangement for Monitoring the state of crosspoints in one digital space matrix according to the generic term of Claim 1.

In an essay entitled: "A switching matrix for 140 Mbit / s in CMOS technology "is in the DE-Zeitschrift ntz, Volume 39 (1986) Issue 5 from page 312 printed. It is a matrix Arrangement of electronic crosspoints for Broadband communication. A block contains one Switching matrix in the size 16 × 16, as well as additional Circuit parts for setting each switching crosspoints. The crosspoints can can be individually addressed so that each input is open only any output can be switched. A monitoring circuit is also provided, which is connected to the outputs according to Figure 1. The The function of this monitoring circuit is shown on page 314 only briefly mentioned in the left column, so that none Details of how to solve such a problem are given are.

DE 36 04 607 A1 describes a broadband signal space switch device known, wherein a crosspoint matrix in FET technology consists of coupling elements, each  from a decoder-controlled, crosspoint-individual Storage cell can be controlled. The state of this crosspoint-specific memory cell can be queried be so that it can be recognized whether a crosspoint should be switched through or not. The state of a crosspoint-specific memory cell is still there no information about whether the crosspoint itself has switched through properly or no signal lets through when it should be locked.

DE 29 51 450 C2 describes a circuit arrangement for Function monitoring of switching network parts and them arranged peripheral controls in centrally controlled Message switching systems, in particular in programs controlled telephone dialing systems known. There are special decentralized testing facilities are provided, which be connected to the access points of a switching matrix part can. These test facilities cause occupancy stimuli, the reactions of the switching system time be monitored. If within a given Evaluation time no so-called message signals determined an alarm signal is generated. These Alarm signals are counted and display means activated. With such a circuit arrangement it is not possible to have a direct impact on that Exercise switching behavior of crosspoints, in the event that they are broken.

A procedure for systematic review of a one-step process Switching network is known from DE 29 39 075 C2. At the In this examination procedure, all possible are successively Connections from a column to an audio transmitter is switched on, via an adjacent column to a certain line switched through, at which a receipt direction for the audible tone is connected. In this way the crosspoints of all columns are checked one after the other. Defective crosspoints can easily be determined alarm messages can be given. At the If there is an alarm message, meter settings, which characterize the crosspoint, together with an identifier characters stored about the target state of the crosspoint will. This procedure will depend on the operating status yielding additional test signals needed to determine to know whether crosspoints are faulty. This means, that the testing of such a single-stage switching network cannot be carried out during the operating state.

The object of the present invention is to introduce a circuit arrangement with which in normal Operating state, i.e. without additional test signals, the state using the digital useful signals of the entire crosspoint matrix determined at any time can be. In the normal operating state testing taking place is supposed to be faulty behavior individual crosspoints can be determined and the associated crosspoint addresses get saved.

A circuit arrangement is used to solve this problem with the features specified in claim 1.

It is advantageously achieved that faulty crosspoints are recognized and marked can, so that with appropriate intelligence the superordinate control devices connecting routes can be switched so that defective crosspoints are not included. It is possible faulty crosspoint blocks, even then keep going if some crosspoints are defective. The specified in the subclaims Developments of the invention provide further features what additional benefits can be achieved.

An embodiment of the invention is as follows described in more detail with reference to drawings. It shows  

Fig. 1, the entire circuit arrangement located in a crosspoint module,

Fig. 2 shows the switching arrangement of a multi-stage switching matrix.

In FIG. 1, a digital switching matrix is illustrated DKM, the crosspoints can connect an input to an output column line in each case. The inputs E and the additional inputs ZE are connected to an input circuit ES , whereby the coupling points are decoupled from the external feeds. The input lines E 1 to E 16 are routed via an input synchronization circuit ESYN so that the incoming bit streams can be regenerated. The additional inputs ZE 1 to ZE 16 are each led directly to only one coupling point, so that they can only be switched through to a predetermined output. These additional inputs ZE are used for the cascade-like interconnection of several switching matrix modules if, for example, a switching matrix with 32 inputs and 16 outputs is to be implemented.

The outputs of the crosspoints are routed via an output synchronization ASYN , so that the individual signals can be passed on precisely to the clock. The outputs of the output synchronization ASYN are connected to the inputs of drivers TR , to which the further output channels A 1 to A 16 are connected.

The setting commands for the crosspoints are received by a processor interface PS and are brought to a hold memory HSP via an internal data bus DB . With a decoding Dec connected , the crosspoints are directly controlled individually. A control device STE is responsible for all control functions within the coupling module for setting and triggering coupling points and for monitoring the coupling points.

An input multiplexer EMUX and an output multiplexer AMUX are provided for monitoring the state of the crosspoints in the digital switching matrix DKM . The inputs of the input multiplexer EMUX are each connected to a column of the digital coupling matrix DKM . The inputs of the output multiplexer AMUX are connected in parallel to the connecting lines running between the output synchronization ASYN and the output drivers TR in parallel. The outputs of the two multiplexers EMUX and AMUX are connected to a comparator VG 1 , the output of which leads directly to the control device STE .

The control device STE now cyclically connects the two multiplexers EMUX and AMUX to the inputs or outputs of the digital coupling matrix DKM via a line bundle . The procedure is such that for a period in which the output multiplexer AMUX is connected to one of the output lines, all input columns are scanned at least once via the input multiplexer EMUX . Of course, the procedure could also be the other way round so that the input multiplexer EMUX remains connected to an input column until all outputs have been connected to the comparator VG 1 at least once via the output multiplexer AMUX .

In this procedure, the comparator VG 1 continuously sends signals to the control device STE which, with their logical state, tell the control device STE whether the input bits match the output bits or not. If the control device STE determines on the basis of the content of the latch HSP that a crosspoint which is currently being queried by the multiplexers EMUX and AMUX should be switched through, then output signals of the comparator VG 1 which signal an inequality are registered. The control device STE then issues a message to the error register FR when a predetermined number of error signals have arrived from the comparator VG 1 .

However, an error signal may also be present if the comparator VG 1 determines that the respective input and the associated output are identical, but the crosspoint should not be switched through due to the content of the hold memory HSP . In each individual test step, which is carried out as described above, the individual coupling points are therefore checked both for their switching behavior and for their blocking behavior. The criteria determined by the control device STE are stored in a status register STR . At the same time, the address of the defective crosspoint is recorded in the error register FR when an error is detected. The error register and the status register can be controlled from a higher-level control device via the processor interface PS , so that the higher-level control device receives knowledge of faulty coupling points. In the case of a multi-stage switching matrix, as shown in FIG. 2, a defective coupling point can then be avoided by switching other paths.

A comparison register VR is also provided, which receives information in parallel with the hold memory HSP . The outputs of this comparison register VR and the outputs of the latch HSP are connected to a further comparator VG 2 . This comparator VG 2 tells the control device STE whether the same information is contained in the comparison register VR as in the hold memory HSP . In each individual scan test step of the multiplexers EMUX and AMUX , the control device STE additionally queries the output of the further comparator VG 2 . If an inequality is found in the setting addresses responsible for the respective crosspoint in the comparison register VR and in the hold memory HSP , the crosspoint in question, which is currently being scanned and is to be switched through, is not marked as faulty.

In FIG. 2 a multi-stage switching network is shown which has a total of 64 input lines and 64 output lines. The switching matrix consists of 3 stages, of which each individual stage consists of 4 switching matrix modules with 16 inputs and 16 outputs, as shown in FIG. 1. The outputs of the first and second stages are each divided into groups of four so that a bundle of 4 lines each leads to different switching matrix modules of the next stage. As can be clearly seen from the drawing, there are circumvention possibilities in each case if a direct connection, for example, of the first input line of the entire three-stage switching matrix cannot take place via the respective first outputs to the first output line of the entire three-level switching matrix. If there is a faulty crosspoint on this route, for example in the first or in the second stage, this is, as has been described above, communicated to a higher-level control device which is responsible for the entire control of a multi-stage switching network. Since each input can be connected to each output within a switching matrix module, a connection of the first input line to the first output line could also be switched such that it runs, for example, over the third switching matrix module of the second stage. In this way, it is possible to keep a multi-level switching network in operation even if individual switching points are defective.

If a defective crosspoint is recorded with its address in the error register FR within a switching matrix module, the control device STE causes the associated output to be permanently switched off from there. For this purpose, the driver TR in question is blocked by a command, so that the relevant output of the digital coupling matrix DKM is disconnected from the forwarding line. These test measures, which take place automatically in normal operation and the bits of useful data are compared with one another, eliminate individual defective coupling points in such a way that they cannot exert any influence on the overall arrangement. If there are defective crosspoints, a signal appearing at the inputs must be switched to another output, so that with a coupling arrangement as shown in FIG. 2, there are inevitably other switching paths, although the same output line as before is reached again can be.

Claims (8)

1.Circuit arrangement for monitoring the state of crosspoints in a digital space switching matrix with a matrix-like structure and complete accessibility within a single-stage matrix, the connections in the switching matrix producing coupling points being individually controllable with address information which are entered into a latch or into a setting register , and wherein an input can be connected to only any output, characterized in that
that an input multiplexer (EMUX) for the query of all inputs and an output multiplexer (AMUX) for the query of all outputs of the digital switching matrix (DKM) are provided, both multiplexers (EMUX, AMUX) being switched on in succession to the respective inputs and outputs and one of the multiplexers (EMUX or AMUX) remains switched on at one of the inputs or outputs until all outputs or inputs have been queried at least once with the other multiplexer (AMUX or EMUX) ,
that the interrogation of the inputs and outputs of the digital switching matrix (DKM) is carried out during normal operation of the switching matrix (arbitrary switching state of the matrix) with the incoming and outgoing data signals (useful signals),
that the outputs of the two multiplexers (EMUX, AMUX) are connected to a comparator (VG 1 ), which emits an error signal if the output information does not match the input information in the case of a coupling point that has been switched through,
and that the address of the faulty crosspoint is then recorded in an error register (FR) . 2. Circuit arrangement according to claim 1, characterized in that the output of the comparator (VG 1 ) is connected to a status register (STR) , where the occurrence of an error is temporarily stored and from there is passed on to a device controlling the switching network. 3. Circuit arrangement according to claim 1, characterized in that when setting the digital cross-point matrix (DKM) the setting information is loaded in a hold memory (HSP) or a setting register also in a comparison register (VR) that a second comparator (VG 2 ) is provided, which compares the content of the latch (HSP) with that of the comparison register (VR) , and that its output signal is linked to the error signal in such a way that a faulty crosspoint is only recognized when the second comparator (VG 2 ) has one Agreement. 4. Circuit arrangement according to claim 1, characterized in that the output of the comparator (VG 2 ) is also connected to the status register (STR) , where the occurrence of an error signal is temporarily stored and passed on to a device controlling the switching network. 5. A circuit arrangement according to claim 1, characterized in that when a defective crosspoint is found, the relevant output driver ( TR) is blocked via a specific coding in the latch (HSP) or setting register and the comparison register (VR) . 6. Circuit arrangement according to claim 1, characterized in that the status register (STR) can be queried via a processor interface (PS) , so that in a multi-stage coupling network ( Fig. 2) other connection paths can be switched through by a higher-level control device if defective Crosspoints are available. 7. Circuit arrangement according to claim 1, characterized in that it is determined at each individual test step whether the crosspoint just detected with the input multiplexer (EMUX) and the output multiplexer (AMUX) must be switched through or not due to the content of the latch (HSP) , and that an error is detected when the comparator (VG 1 ) detects an equality, even though the crosspoint in question should not be switched through. 8. Circuit arrangement according to claims 1 to 7, characterized in that all the circuit parts provided for monitoring and setting the state of the coupling points together with the digital coupling matrix (DKM), their control device (STE) and the other circuit parts are accommodated in a housing.