DE1812837A1 - Circuit arrangement for testing a line of a telecommunication system, in particular a telephone system - Google Patents

Description

Circuit arrangement for testing a line of a telecommunications, in particular Telephone system.

The invention relates to a circuit arrangement for testing a Management of a telecommunication system, in particular a telephone system, to its current occupancy status, with a magnetic core assigned to the line with an approximately rectangular hysteresis loop, with an input, query and output coil, with the input coil in the to line to be tested is looped in and the interrogation coil alternates positive and negative interrogation pulses are supplied, which are only in the de-energized state of the test Line switch the core back and forth between the positive and negative remanence point and alternating positive and negative larger read pulses in the output coil induce, in the other state, however, smaller read pulses in the output coil A circuit arrangement of this type is known from DAS 1 060 446. at this circuit arrangement is first a preparatory pulse according to claim 13 given to the interrogation coil which magnetizes the core in the same direction like the current flowing through the querying line. Then it will be a test pulse in the opposite direction is given to the interrogation coil. To the results the read signal of the test pulse is used. The object of the invention is to improve such a switching arrangement with regard to the selectivity in the read signals.

The circuit arrangement according to the invention is characterized in that that the output coil is connected to an evaluation circuit that those Evaluates read pulses, which are caused by the interrogation pulse; the core in the magnetized in the same direction as the line to be tested possibly flowing current.

The progress that can be achieved with the invention is seen in the fact that when evaluating these read signals, a greater degree of distinction between the currentless one and the current-carrying condition of the line to be tested is determined. Besides that one can choose the number of turns of the input coil smaller, since the required Flooding is smaller in amount.

Numerous arrangements are also known in which the test circuit has to scan magnetic cores distributed in the form of a matrix, e.g. B, from DAS 1 041 098, Claim 2.

A further development of the circuit arrangement according to the invention provides to improve such a circuit arrangement that a first query pulse: with opposite direction of magnetization as that of the line to be tested, if applicable current flowing through is given to all interrogation coils of one inch, and that then a second interrogation pulse opposite in time to all columns one after the other Direction to the first interrogation pulse is given.

An advantage of this development is seen in the fact that per matrix level only one read loop and one read signal amplifier is required.

An alternative to this circuit arrangement is characterized in that that a first interrogation pulse with opposite direction of magnetization as the current flowing through the contributions to be checked at the same time is given to all interrogation coils of all columns, and then one after the other second Interrogation pulses opposite to the first interrogation pulse Pi of this circuit arrangement are given to all interrogation coils in a row the column lines are used as read lines, Es @@@ @ wa @ @@@ e @palte necessary, instead, the scanning speed of the entire matrix is higher.

The invention is described below in connection with the drawings explained.

1 shows a known arrangement with a magnetic core for interrogation a line, Fig.2 shows the rectangular hysteresis loop of the magnetic core Fig.l, Fig.3 shows the characteristic curve of the read signal amplitude as a function of the Strength of the signal flow.

The core K shown in Fig.l carries three coils, each of which can consist of a single turn. The input coil is with the one to be tested Signal line S connected. The interrogation coil A are alternately positive and negative Interrogation pulses are supplied and the read pulses are tapped on the read line L.

A toroidal core K with an almost rectangular hysteresis loop Fig. 2, on which the signal flow Es from the signal line S to be tested acts, can either be from a single pulse-shaped interrogation flow #al or of two AbSragedurchflutungen acting one after the other in opposite directions Gal and Ça2 are queried. In the present example, both query flows should Oal and Ga2 work. If the signal line S is de-energized, then the flooding brings about #al the core K from the positive remanence point + Br via the left branch of the hysteresis loop into the negative saturation, if one assumes that the nucleus K was previously in the positive Remanence point + Br, a large negative pulse appears on the read line L. Otherwise, the nucleus K only changes from the negative remanence point Br to the negative one Bred saturation, with a small negative pulse appearing on the read line L. In any case, the core K is at de-energized signal line S after the query by the flow through Oal in the negative remanence point Br. The positive interrogation flow # a2 brings the core K from the negative remanence point Br into positive saturation, a large positive reading pulse appears the reading line L. After the query by the flooding # a2 is the Core K in the positive remanence point + Br.

However, if a current flows through the signal line S, the If a signal flow #s is generated, then the core K is made up of the negative and positive Inquiry flows ial, # a2 only from the positive saturation into the positive Remanence point + Br or driven even further into positive saturation, with only a small negative or positive pulse appears on the reading line L.

If the relative amplitude: Umax of the resulting from the query with #al Reading signal as a function of the signal flow it is recorded so receives the characteristic curve according to Fig. 3. The amplitude of the interrogation flow was determined assumed to be constant. With the two thresholds S1 and S2 of a read signal amplifier, which certainly does not emit an output signal for U: Umax <S1, but for U: Umax> S2 reliably emits an output signal, according to the characteristic curve in Fig. 3 for #s> 0 only two flows # 3, # 4 can be distinguished from each other, with Currents 13 and I4 have the same ratio: I3 / I4 = # 3 / # 4. For #s <0 this is Ratio of the distinguishable currents, I2 / 11 = # 2 / # 1 smaller than with #s> 0.

The same characteristic as with #s <0 and evaluation for Gal results with #s> 0 and evaluation at Ea2.

Since the signal flows # 1 and # 2 are also smaller than the signal fluxes @ 3 and # 4 are also used for given signal currents I1 and 12, which are to be distinguished, the required number of turns of the with the Sig- nal line connected input coil smaller if one that Besesignal evaluates that of the interrogation pulse in the same magnetization direction how the signal flow is generated.

When scanning lines, a high degree of selectivity is required, because the two states "live" and "currentless" only within wide tolerance ranges can be complied with.

3 patent claims, 1 sheet of drawings, 3Fig.

Claims (3)

Claims 1. Circuit arrangement for testing a line of a telecommunications, in particular telephone system on their current occupancy, with a Magnetic core assigned to the line with an approximately rectangular hysteresis loop, with an input, interrogation and output coil, the input coil in the to line to be tested is looped in and the interrogation coil alternates positive and negative interrogation pulses are supplied, which are only in the de-energized state of the test Line switch the core back and forth between the positive and negative remanence point and alternating positive and negative larger read pulses in the output coil induce, in the other state, on the other hand, induce smaller retinal pulses in the output coil, characterized in that the output coil is connected to an evaluation circuit which evaluates those read pulses caused by the interrogation pulse magnetizing the core in the same direction as the one to be tested Line with current flowing through it, if applicable. 2. Circuit arrangement according to claim 1 for matrix-shaped arrangements of magnetic cores, characterized in that a first interrogation pulse with opposite Direction of magnetization as that which may flow through the line to be tested Current is given to all interrogation coils of a line, and that then laterally one after the other on all columns a second interrogation pulse in the opposite direction to the first Interrogation pulse is given, 3. circuit arrangement according to claim 1 for matrix-like arrangements of magnetic cores, characterized in that a first interrogation pulse with opposite direction of magnetization as that to Checking lines, if necessary, current flowing through simultaneously to all interrogation coils of all columns is given, and that then successively second interrogation pulses of opposite directions Magnetization direction to the first interrogation pulse because of all interrogation coils given on one line.