DE2521297C3 - Monitoring circuit for matrix-shaped scanning circuits - Google Patents

Description

The application relates to a monitoring circuit for scanning circuits constructed in the form of a matrix, at to which the rows are individually controlled and the query results assigned to the columns Evaluation members are included, in particular for telecommunications systems.

A switching center contains a certain number permanently or temporarily with lines and circles connected units for the transmission and reception of signals that the construction, the holding and Control triggering of connections. These units include the dialing signal transmitters and receivers, which are connected to the lines and circuits as required, as well as the connection sets which are constantly are connected to a wide variety of input and output circuits.

In a centrally controlled exchange, the central unit must have the status of each individual unit be informed in order to recognize all important processes and according to the intended operations to control the resulting operations or to obtain information about the switching situation bring up to date.

It is known to use a scanner for this purpose, which controls the units from the central unit queries in groups and communicates the data determined in this way to the central unit. Any group of units an noise amplifier is assigned. A system of sense amplifiers containing as many amplifiers as Units per group are available is connected to the various groups via read wires. An interrogation amplifier supplies the various units in a group with an interrogation signal. Depending on its status, each unit forwards the signal to a read amplifier via a read conductor Further. All signals emitted by the sense amplifiers together identify the state of the Units of a group.

Since the sense amplifiers are connected to all groups, it is important that when interrogating a group only the amplifier belonging to this works. However, it happens that when addressing this Amplifier another amplifier is controlled due to an error. Thus, at the same time two groups are queried and the results are superimposed in the sense amplifier. However, this result can do not correspond to the image of an individually queried group. Likewise, the units can be based on cause short circuits due to their design. A short circuit in a unit of a first specific group can enable the transmission of a read signal that originates from a unit of the second group. This read signal thus reaches all units of the first group. You are in the same situation as before.

The invention is based on the object of providing a monitoring circuit of the type mentioned at the beginning specify that tests the operation of an interrogation amplifier and detects the short circuits in a unit. According to the invention, this is achieved in that a constant current source is assigned to each line, which at Control of a current of a predetermined strength via wires to a first common to all groups Stromerkenner provides that the simultaneous working of more than one constant current source and thus the simultaneous query of more than one group recognizes and suitable by means of an alarm pulse

4 »Initiates processes.

Further features of the invention can be found in the subclaims. The benefits are in the called the following description.

The invention will now be explained in more detail with reference to the exemplary embodiment shown in the drawings described. It shows

Fig. 1 is a block diagram of an Aotasteinrichtung and

F i g. 2 shows a detailed circuit of this device.

In Fig. 1, units such as C0 / 0 are arranged in the form of a matrix. These units are divided into 64 groups of 16 units each, with each group forming a line. A line wire such as FIO is arranged along each line and connected to the inputs of the unit CO / 0 to CO / 15 of the line. A column wire such as FL 0 along each column is connected to the outputs of the units G 0/0 to C 63/0 of the column.

each row such as FIO is with a

M> interrogation amplifier ΛΙ0 connected. A decoding device DC marks one of the output cores DCO to DC63 leading to an interrogation amplifier according to information received at the input INF. [every line vein such as B. FIO, the associated

■ Amplifier AIO is controlled, is also connected to a current source SCO , each individual source supplies a current of strength /. The outputs of these current sources 5CO to SC63 are all with one

Stromerkenner DT connected, which works when it receives a current of at least 2 / receivable

Each of the column cores FLO to FL 15 is connected to one of the sense amplifiers AL 0 to AL 15.

It is now assumed that the decoder DC receives an information word at its input / Λ / F. The decoder then sends an interrogation signal to one of the output wires DCO to DC63, e.g. B. on wire DCO. The amplifier AlO works and supplies an interrogation signal via AJer FIO to all units G0 / 0 to G0 / 15 of the line. Depending on the state in which the units are, they transmit a signal to one of the column wires FLO to FL 15, via which they are connected to the amplifiers ALO to AL 15. The latter amplifies the received signals to a predetermined level and transmits them further to the wires to SO 515. In this manner, the polling of the units G 0/0 to G0 / 15 by means of amplifier AIO according to the state of the units G-G 0/0 0/15 signals on wires 50 to 515 result. It should be noted that the current source 5C0 is controlled by the interrogation signal. You yeast the current detector DT via wire 5D0 a current of strength /. The current detector does not work because, as already mentioned, it only responds at a current strength of 2 /.

If the decoder DC mistakenly two output wires z. B. DCO and DC63 marked at the same time, then work two interrogation amplifiers AIO and Λ / 63, which via the line wires F / 0 and F / 63 an interrogation signal to the units G0 / 0 to G 0/15 so = / ie G 63/0 Send to G 63/15 of the corresponding lines. Under these conditions, the query results of the units of both rows are superimposed on the column wires FLO to FL 15. The result shown on wires 50 to S15 is therefore insignificant for the status of a unit group. It is therefore necessary to recognize that the two amplifiers AIO and / 4/63 are working at the same time. Since both current sources 5CO and 5C63 are working, and each supplies a current of the strength / via the wires 5D0 and 5D63 to the current detector DT , the latter receives a current of 2 / and emits a signal at its output SDT. This signal triggers an alarm due to the incorrect operation.

The system according to the invention also detects a short circuit in a unit. For this purpose, it is assumed that the unit G 63/0 causes a short circuit between the row wire F / 63 and the column wire FLO. In response to the query of the units G0 / 0 to G 0/15 described above, a signal is transmitted on wire FLO according to the status of the unit G 0/0. This signal is transmitted from the unit G 63/0 via the row wire F / 63 and represents the interrogation signal for the units G 63/0 to G 63/15. These units each forward a signal according to their status via the column wire. As above, these signals are superimposed on those of the units G 0/0 to G 0/15 as a query result. It is necessary to recognize this incorrect way of working. Since the current source 5C63 works at the same 7> it as the current source 5C0, the current detector DT is excited and emits an alarm-triggering signal at its output SDT. It can thus be seen that the system according to the invention makes it possible to identify both the simultaneous operation of two interrogation amplifiers and the short circuit b ^r > of a unit that has not been interrogated.

The circuit of an exemplary embodiment according to the invention will now be described in detail with reference to FIG described.

In this figure, only the constant current sources and the current detector DT are shown in detail. The current sources SCO to SC63 are constructed identically, in particular the resistors R 0 to R 63 are the same. These resistances determine the amperage / output from each current source.

The current detector DF essentially contains two differential amplifiers / C15 and / C17, which work when the potential on the SDE wire reaches a reference value determined by the resistors Re 5. Re 6, Re 7 and ReS. In this way, the amplifier / C15 works when the current flowing through the SDE wire has the strength / and the amplifier / C17 works when this current has at least the strength 2 /. There are opposite Fig. 1 two test circuits £> £ 0 and DFl are also provided, the function of which will be described later. The units such as B. G0 / 0 are not shown in detail. Any designs can be used for this; for example scanning gates with capacitors as described in DE-OS 21 62 964. According to their state, these scanning gates are sensitive to positive interrogation pulses.

If the decoder DC has a wire. z. B. DCO marked, the interrogation amplifier AIO emits a positive interrogation pulse on the line F / 0. According to their status, the units G 0/0 to GO / 15 transmit this pulse via the wires FLO to FL 15 to the sense amplifiers ALO to AL 15 and the output wires SO to S15.

At the same time, the positive interrogation pulse makes the transistor TO conductive and this transistor and the resistors R 0 and Re 4 are traversed by a current of strength /. This current activates the differential amplifier / C15, which emits a signal at its SDTO output in order to acknowledge the query at any point in the system.

The following describes the case in which two line cores, for example F / 0 and F / 63, each receive an interrogation signal. Because of the wrong operation of the decoder DC the two amplifiers AlO and / 4/63 are activated or it works only one amplifier AlO and the unit G 63/0 is shorted. As already described, the two current sources SCO and SC63 and thus the transistors TO and Γ63 then work. A current of strength / flows through the wires SDO and SD 63, so that the wire SDE is traversed by a current of strength 2 /. As a result, the amplifier / C17 works and sends an alarm-triggering signal to the SDT1 wire, which signals the abnormal operation to any point in the system.

The operation of the test circuits D £ 0 and DFl is described below.

The test circuit DFO is structured like the current sources SCO and SC63. In particular, the resistance Re 3 is equal to that of RO and / 63, so that the output current is equal to /. The test circuit DF1 is structured in the same way as the test circuit DFO; However, it contains two resistors ReI and Re 2, both of which are as large as Re 3 , so that the current intensity delivered by this test circuit is 2 /.

Z ^u until it is believed that controlled by an unillustrated unit passes a signal to the input of the test circuit FDFO DFO. The transistor TS 2 conducts and feeds the SDF wire with a current of the strength /. This current controls the differential amplifier / C15 so that the latter outputs a signal on the SDTO wire.

It can be seen that the test circuit DFO tests the operation of the differential amplifier IC 15.

It is now assumed that the above-mentioned units (not shown ) send a signal to the input EDE 'of the test DEX. Transistor TS \ conducts and feeds wire SDE with a current of strength 21. This current controls the differential amplifier / C17, which then sends a signal to wire SDTX. Thus, the test circuit DEl the operation of the

Monitor differential amplifier / C17.

According to the intended mode of operation, the DEO and DfI test circuits are activated one after the other at regular intervals. These test circuits allow the operation of the current detector to be checked: DT, in order to ensure maximum security against errors zi when irregularities are detected when querying the status of the units C 0/0 b C3 6/15.

Here 1 sheet of drawings

Claims (4)

Patent claims: 1. Monitoring circuit for matrix-shaped scanning circuits, in which the rows are controlled individually and the query results are recorded by the evaluation elements assigned to the columns, in particular for telecommunications systems, characterized in that each row is assigned a constant current source (SC) which, when controlled, is a predetermined current Strength via wires (SD) to a first current detector common to all groups (/ C17 in DT) , which detects the simultaneous operation of more than one constant current source and thus the simultaneous query of more than one group and initiates suitable processes by means of an alarm pulse. 2. Monitoring circuit according to claim 1, characterized in that a second current detector (/ C15 in DT) is provided which detects the operation of a current source and thus of at least one interrogation amplifier (AI). 3. Monitoring circuit according to claim 1, characterized in that a controlled by a test device first test current source (DfI) is provided, which via the wire (SD) the current detector (DT ) delivers a current twice as strong as a constant current source (SC). 4. Monitoring circuit according to claim 2 and claim 3, characterized in that a controlled by the testing device second test current source (DE 0) is provided, which supplies the current detector (DT) via the wire (SD) with an equally strong current as a constant current source (SC) .