DE886157C - Device for testing a characteristic impedance - Google Patents

Description

Apparatus for checking a characteristic impedance The invention relates to to a device in an automatic telecommunication system, e.g. B. an automatic Telephone system for the selective testing of a characteristic impedance.

Characteristic impedances are used to electrically establish certain Properties or the nature of an apparatus, such as e.g. B. the outputs of Voters, connecting lines or the like. To display. Different properties or Textures are characterized by characteristic impedances with different, characteristic values indicated.

There are z. B. with a known system voter with the help of Characteristic impedances set, which are connected to the marking contacts of the outputs and whose impedance value is characteristic of the number of the associated output. The control device of a switch tests a test arm while it is moving of the switch the impedances of the successive outputs, e.g. B-. by comparison these values in a bridge circuit with one in a register accordingly the desired number ordered comparison impedance. As soon as an exit is reached whose characteristic impedance is in a certain ratio to the comparison impedance, z. B. corresponds to her, the Sehalter is on.

Characteristic impedances can also be used to make a distinction of a different kind between different starting groups. It can e.g. B, the outputs of call seekers or Final voters through characteristic impedances be marked that. a; Reference to the nature of the to the: output connected lines, e.g. B. the specification that a line has a multiple connection belongs to that to: the line is connected to a telephone booth or a payphone is that in a defined traffic direction there is the possibility of a desired one To convey the connection in a detour that a subscriber is not authorized, Making remote connections, etc. Such selective markings are generally used checked after the voter has been stopped. Here too: a bridge circuit are used, in .der the tested characteristic impedance with different Comparison impedances is compared. As a criterion z. B. apply that, the tested impedance corresponds to a certain comparison impedance or that the sum the characteristic impedance and the comparison impedance assume a certain value.

In a circuit arrangement of the type in question here the characteristic impedance is connected to a multiple point associated with the apparatus to which the characteristic impedance belongs and that of a number of different test devices is accessible.

There are z. B. those associated with a characteristic impedance. Marker contacts of a selector connected several times to the corresponding output contacts of other voters. The test of the characteristic impedance is carried out with the aid of a test current, e.g. B. one Direct or alternating current, which via the characteristic impedance, the multiple point and the test device flows through and. directly or indirectly from the testing device is checked.

The mode of operation of the known test devices is not entirely reliable, due to the fact that the same multiple point is in principle simultaneously can be connected to several test devices in different ways. It can then: the case occur that at the same moment a characteristic impedance over different selectors are tested by two or more test fixtures. Particularly at. Places where there is a lot of traffic, such as B. in the first group elective levels, such a simultaneous test is by no means unthinkable.

The current flowing through the characteristic impedance is then distributed over the test devices so that none of the test devices receives the rated current, which corresponds to the resistance tested. The devices thus receive a wrong one Indication of what has the consequence that you can react incorrectly and z. B. a voter set to an undesired output.

A circuit for testing characteristic resistors has already been proposed, in which these difficulties cannot arise, since special measures have been taken: are, which are prevented; that two or more test devices can simultaneously generate a test current across the resistance to be tested. This circuit contains an electronic flip-flop with a discharge tube, which means that a discharge path is connected to the test circuit. The flip-flop can be in two electrically stable states. are: Usually the flip-flop is in a first state in which the discharge tube is blocked and the test device has a particularly high input resistance. The flip-flop remains in d'i'esem state when the test device is connected to a characteristic resistor that is already being tested by another test device, in that the other test device sends such a test direct current across the resistor that you multipoint a potential has, in which the flip-flop circuit in, the first-mentioned test device is not in the other electrical state. can pass. This test device thus maintains a high internal resistance: and cannot interfere with the measurement carried out by the other device. However, if the test device is connected to an untested characteristic resistor, the multiple point has a potential that the trigger circuit changes to - the other state - in which the discharge tube is conductive and such a test current flows through the characteristic resistor that the potential of the multiple point assumes a value at. which a test device; which is then connected to the multiple point, can no longer respond.

With this circuit arrangement proposed earlier, there is Potential of the multiple point an indication of the fact whether the characteristic resistance at that moment is being tested or not, and that potential is through the Test current itself conditional.

In the device according to the invention, a marking voltage is also used used, which is an indication of the test or non-test of the characteristic impedance gives. The difference to the aforementioned device, however, is this Marking voltage through. requires a different current than the test current.

In the device according to the invention for checking a Kenudmped'änz, their value for one of the characteristic impedance assigned. Apparatus is characteristic, the characteristic impedance is connected to a multiple point assigned to the apparatus, connected to the test device during the test and several at the same time Test devices accessible. The test of the characteristic impedance takes place ' with the help of the characteristic impedance, the multiple point and the test device test current flowing through, which is basically both an alternating current and a Can be direct current or a mixture thereof.

The device has the feature that .the apparatus continues through a marking voltage is identified, the value of which gives an indication of whether the characteristic impedance is checked or not, and that the test device means for Check the marking voltage, which respond to the presence of a marking voltage, diie meets the state in which the characteristic impedance is not checked, whereby when these means respond and controlled by them, the test current via the characteristic impedance switched on and the marking voltage is changed to a value that corresponds to the state in which the characteristic impedance is checked by using a current other than the test current is sent through an impedance assigned to the apparatus.

With this device, the marking voltage does not need to be applied to the same Multiple point to be created, to which the characteristic impedance is connected. This offers the advantage that, unlike the circuit proposed earlier: the marking voltage must be checked without power and! a relay can also be used for this purpose can. It is also possible to carry out the test using an alternating current and the testing or non-testing of the characteristic impedance by means of a DC voltage the multiple point connected to the characteristic impedance. The DC voltage can be made usable for other purposes, e.g. B. to display a further numerical criterion in the form of a direct voltage with a characteristic value or also to display the occupied or free status of an exit.

The invention is illustrated in more detail below with reference to several and simplified form of the embodiments shown in the drawing explained.

Fi, g. i provides training on setting: a group selector according to a resistance marking process, where. the test: by direct current carries out; Figure 2 illustrates a circuit for checking the impedance mark of a Switch represents the test: the marking voltage with the help of electronic Means carries out -and the test of the kena impedance with the aid of an alternating current is carried out.

In Fig. I, two test devices 011 and 0J2 are shown: which, if necessary via previous selection levels, control the number setting of the group selectors GK and GK2. The figure shows only those elements which are necessary to understand the invention. The number marking contacts c11, c12, etc. of the selector GK, which are painted in front of the test arm cl, are connected to a negative terminal of the battery Ba via characteristic resistors R, 1 and R ,, 2. tied together; whose positive terminal is grounded, and are further connected in a known manner to corresponding marking contacts c21, c22 of the selector GK2 swept by the test arm, c2 and other not @shown selector of the electoral level. The value of the characteristic resistors R., 1, R ". Etc. is indicative of the number of the associated output. Characteristic resistances,: the outputs corresponding to different numbers, are therefore different from one another. In general, output marking contacts are each with a single resistor be connected, the value of which is then the same in groups. The marking contacts d11, d12 or d21, d22 marked by the test arms dl, d2 of the selector GK or GK2 are intended to indicate the fact "@ that an output is checked according to the number or not, and are also used for the usual free or occupied marking of the exits. These marker contacts are connected to the battery Ba via resistors Rbl and Rb2, respectively.

The test devices OJI and 0J2 each contain a differential relay T1 or T2 for testing the number marking and a test relay B1 or B2 for testing the busy marking. The relays TI and T2 are represented in the figure by their two windings T11 and T12 or T21 and T22. The relays B1 and Bz are indicated by the windings B11 and B12 and B21 and B22, respectively, which are placed in friction.

During the test, the brush cl eats via the make contact b11 of the relay Bi and the winding T12 similar to the brush c2 via the make contact b21: of the relay B2 and the winding T2.2 connected to earth. The brushes: n dl and d2 are also earthed via windings B11 and B12 or B21 and B22. The normally open contact t11 of the relay T1 or t21 of the relay T2 is located between the D.rehm.agneten Dl of the selector GK or D2 of the selector GK2 and the battery Ba. The marker switches MS, of the test device OJ1 and MS., Of the test device 0J2, after receiving a number disc signal, assume a position that corresponds to the digits, whereby the arm of this switch is connected to one of the comparison resistors R ", 11, R" 12, etc. or R.21, R.22 etc. is connected. The arms of these marker switches are: further via contacts a1 and a2, relays not shown, and via the windings T1. or T21 connected to earth.

The mode of operation of the circuit is identical. After the relevant digit has been received by the marker switches and, if necessary, voters in; previous selection steps have been set, the contact a1 closes. As a result, the relay T1 is energized in a circuit from battery Ba, via a comparison resistor R "111, the marker contact and the brush of the switch MSI, the contact a1, .the winding Tll to earth. The strength of this current in this circuit is from the value of the switched-on resistor R11111 and is therefore characteristic of the selected digit. The normally open contact t11 of the relay T1 closes an excitation circuit for the rotary magnet Dl. As a result, the selector GK is set in motion, whereupon via: the brush dl the marking contacts d11, d12 etc. The marking contacts which speak to the outputs which are already occupied or whose resistance identifying the numbers is being checked at this moment show: a potential such that the relay BI cannot pick up. However, if an unoccupied output is reached, the number marking resistance of which is not checked, the relay B is in a circle from; earth via the windings 8111 and B12, brush d1 and marking contact of the selector GK, and further via the resistor Rb ,, or Rb2 wsw connected to this M.arkierk ontakt. mach: the battery Ba energized. The relay B1 short-circuits its high-resistance winding B11 via its normally open contact b12, which means that the connected in: grater; Resistance flowing through the current and as a result the potential of the relevant marker contact changes in such a way that the relay B of another test device cannot pick up if it were then connected to the same marker contact. As a result of the closing of the normally open contact b11 of the relay B1, a circuit is closed from earth via winding T12, normally open contact b11, the brush c1, the multiple point M and the resistor R ″ after the battery Ba. The current flowing through this circuit depends on the value of the resistance R. from, which is checked, and is therefore characteristic of the number that is assigned to the output: If the output does not belong to the desired group, then the ratio between the currents flowing through the windings Til and T12 is such that -that the relay T1 remains energized; and the selector continues to move. During the transition of the brush dl to the next marker contact, the circuit for the relay is interrupted, causing this relay to drop out. so the magnetizations of the windings T11 and T12 compensate each other, and the relay T. The normally open contact t11 opens the excitation circuit of the rotary magnet Dl, and the selection r holds.

Would during the test of a characteristic resistor by 011 the voter GK, reach a position similar to GKl, so .can: Relay B2, as already said, do not tighten, so that the normally open contact b21 does not close either can and the examination of the number marking wilderness of the exit concerned 0T1, not affected before 012. Relay B1 remains during a call excited so that the exit reached is marked as occupied.

At the in Fing. 2, the test is carried out to determine whether a characteristic impedance is checked or not, and the activation of the test current below Using electronic means. This offered the advantage that the test device responds more narrowly than during the test, through a relay, so that more time for the actual test of the characteristic impedance remains available.

The characteristic impedances associated with the output marker contacts that are brushed by the test brush d: of the selector KS, are from the Parallel connection of a resistor R "and a capacitor Cx formed. The On the other hand, nominal impedances are via an alternating voltage source V, 1 with a Glei.ch voltage source V, connected; whose voltage z. B. contributes -6o V to earth. The test path of the characteristic impedances is carried out by alternating current, while the marking voltage, which indicates that the characteristic impedance is being checked or that the output is occupied by the DC voltage of the same marking contact. is formed with which the relevant Characteristic impedance is connected.

The testing device 0T checks the marking voltage and switches it on Test current through a flip-flop which contains the discharge tubes B1 and B2. The 'control grid of the tube Bi is over, a winding of the. Transformer T, whose Effect is explained below; to a tap point of a voltage divider R1, R2 to closed, the one between the anode of the tube B2 and, a negative DC voltage source T13 is switched on. The tapping point is chosen so @ that when the tube B2 is conductive, the control grid B, a voltage of -3o V has to earth, while, when tube B2 is blocked, the voltage of the control grid nearly; equals earth potential. The control grid of the tube B2 is on appropriate Way over then. Voltage divider R3, R4 coupled to the anode of tube B1. the Anodes, the tubes Bi and B2 are further connected via resistors R5 and Re with a positive Voltage source T12 connected.

The tube B1 contains a screen grid connected to one arm of the marker switch MS. The output contacts of this selector MS are connected to comparison impedances, which are formed by the parallel connection of a resistor R "and a capacitor C," and which each correspond to the different characteristic impedances: which are connected to the marking contacts of the selector switch KS. The comparison impedances R, ", C," are, on the other hand, connected to the DC voltage source T12 via an AC voltage source V12. A voltage divider R7, R8 is connected between the screen grid and the cathode of the tube B1. The tapping point P of this voltage divider is connected via the alternating voltage: gsqwelle VW 3 and the point Q to an alternating voltage measuring device WO . This device can e.g. B. consist of an AC voltage amplifier, the output voltage of which is fed to a rectifier, while or output direct current or the output direct voltage of the rectifier controls a relay or another Entladuiugsröhre.

The alternating voltage sources V, 1, I1 ", 2 and T1" 3 can be advantageous are formed by secondary windings of transformers, their, primary windings connected to a common alternating voltage generator. The resistance of the voltage divider R7, R8 is so high that the current flowing through it is negligible is small compared to the smallest possible test current.

In the rest position of the circuit: the tube B1 is blocked, so that the The anode of this tube and, consequently, the grid of the tube B2 too have high potential and the tube B2 is conductive. The anode that has tube B2 a relatively low potential, reducing the potential of the control grid , of tube B1 approximately equal to -3o V 'st. The DC voltage of the The marking contacts of free outputs is equal to -6o V, while the marking contacts of Outputs whose characteristic impedance is checked or which are occupied, approximately ground potential exhibit. Now, the cathode of the tube Bi via the test arm d with the marking contact connected to a checked or an occupied output, this is potential the cathode of the tube Bi so much higher than that of the control grid that: the tube remains locked. The test device sends it, apart from the special low current that flows through the resistors R7, RS, no current .by: the Characteristic impedance R ", C", so that a possible test of the same by another test device is not disturbed.

The alternating voltage test device WO i.st is designed in such a way that it can only respond when the amplitude of the alternating voltage at point Q is at least almost zero. The alternating voltage of the point P is then equal to 11 ", 3. As already noted, the value of the resistors R7 and R $ is high compared to the comparison impedances R., Cm occupied or tested output is very low, under these conditions the alternating voltage at point P is almost equal to 1/2 1 ", 2. The alternating voltages h ″ 1, V12 and 11w3 are selected in such a way that half the sum of the alternating voltages at points U and W is equal to V ″, 3. If the voltages V, 1 and 1112 are equal to one another and are in phase opposition, the voltage 1113 thus has the zero value, so that the source 1113 can be omitted. The measuring device WO can therefore only respond when the voltage of the point P is equal to half the sum of the voltages 1111 and V12. The device WO cannot respond when the brush d hits a contact of an output which is occupied or a tested output, because in this case the voltage at point P is equal to 1 / s T112. The switch then continues to move. It can be seen that in principle it is not necessary that the mutually interdependent characteristic impedances and comparison impedances are identical to one another, but that there can also be a fixed relationship between the values other than one. The tapping point does not have to be in the middle of the voltage divider R7, R $, but in such a way that the tapping point divides the resistance in a fixed ratio, with the voltage T113 also having to be measured accordingly.

As soon as a free, untested output is reached, the DC voltage of the cathode of tube B1 drops to -6oV. The potential of the control grid of the tube B1 is then 3o V positive with respect to that of the cathode, and the tube Bi becomes conductive. As a result, the anode voltage of this tube and thus the voltage of the control grid stink. of tube B2, whereby this tube is blocked. This has the consequence that the voltage of the control grid of the tube B1 rises to approximately ground potential. That way it opens up. . the tube B1 suddenly completely, and the test alternating current is. switched on. This current flows through the circuit from the DC voltage source V2 via the AC voltage source T112, the comparison impedance R, n, Cm, the marker switch MS, the screen grid and the cathode of the tube Bi, the test arm d and the marker contact of the selector KS, the Characteristic impedance Rx, C !, the alternating voltage source V ", to point V1. The values of the resistors R5, R3 and R4 are so high that only a negligible fraction of the emission current of the tube B1 is diverted through these resistors and practically the whole Emission current flows through the screen. Resistances R7 and Ra are equal to one another. If the tested characteristic impedance Rz, C "is also equal to the comparison impedance R., Cm, then the alternating voltage at point P is equal to half the sum of the alternating voltages in the points U and W, and so the device WO will respond as discussed above. The device WO then blocks by not shown in the figure, otherwise. known means the movement of the voter. KS by demagnetizing the rotary magnet D.

It should be noted that that of the discharge path between the cathode and the screen grid of the tube B1 formed resistance parallel to the Voltage divider R7, R8 is placed, so that the value of this resistor has no influence the determination of the mutual equality of the characteristic impedance and the comparison impedance exerts as long as the value of this resistance is small compared to the sum of the resistances R7 and! R8 is.

Further, as a result of the conduction of the tube B1 flows in; Direct current increases the resistance R, x, and the potential of the marker contact rises to approximately ground potential, because the voltage of the cathode of the tube Bi corresponds to the voltage of the control grid. follows. The relevant exit is then. marked as occupied or checked, so that another test device which controls a voter whose test brush now reaches a corresponding marking contact, as indicated above, cannot respond. 'At the response of the device WO means not shown, is known by itself to the the brush directly grounded d, so that the output is open permanently marked.

If the characteristic impedance is not equal to the comparison impedance, then the alternating voltage at point P is also not equal to half the sum of the voltages in points U and W, and the device WO therefore does not respond either. The voter then continues his movement. Naturally, however, as a result of the conduction of the tube Bi during the test; , ie as long as the brush d is in contact with the relevant marking contact, the output is marked as checked. As soon as the brush d leaves the marking contact, the cathode line of the tube B1 is interrupted, whereby the tube Bi is blocked and the tube B2 opens again, whereupon the test device has returned to the starting position. The interaction described is repeated as soon as the brush d reaches the marking contact of a subsequent free output, Since the marking contacts of a switch are connected several times to contacts of other switches, the internal capacitance of the wiring associated with the test brush can assume considerable values, namely by so higher if a characteristic impedance is checked over a number of selectors in cascade. The internal capacitance of the wiring can significantly interfere with the accuracy of the measurement, because part of the test current is diverted to earth via it.

To avoid this influence, is at. a special precaution has been taken for the circuit according to FIG. For this purpose an additional tube B3 is used, the cathode of which is connected to a suitably selected voltage source and: whose control grid is connected to the cathode of the tube Bi. The anode circuit of the tube B3 is coupled via the transformer T to the grid circuit of the tube Bi in such a way that the alternating voltage of the cathode is transmitted to the control grid of the tube B1 to a greater extent and in opposite phase. If the voltage: the cathode of the tube Bi is equal to V>" the voltage of the control grid of the tube B1 is equal to. Hg and the steepness of the tube Bi is equal to S, then, as is well known, applies to the negative: emission current T, ie to that of the Brush d in the direction of the cathode flowing current, = s (vx-vg).

If the cathode voltage is transmitted to the control grid: of the tube Bi by a factor -f, amplified by B3, then vg = -f ' viz, so that the apparent internal resistance of the tube, seen from the brush d; same Without the tube B3, the internal resistance would be equal to roo SZ for a slope S = ro mA / V: the test device. With a hundredfold amplification through: the tube B3, the internal resistance of the test device for alternating currents is only about r f2. The alternating voltage amplitude of the cathode of the tube Bi and thus also the alternating voltage, which is related to: the disruptive intrinsic capacitance: of the wiring, are consequently practically zero, so. @ that the internal capacitance of the wiring has almost no influence on the test of the characteristic impedance.

The attitude described can advantageously be used to set a final selector. In this case, two digits are assigned to the output contacts, namely the tens digit and the ones digit of the number of the called subscriber. These two digits can, independently of one another, be identified by the size of the alternating current impedance, the characteristic impedance and this direct current resistance, the characteristic impedance. These two impedances can be checked simultaneously by the test device. The test device must be assigned a device for measuring the direct voltage of point P, which may be of a known type. The test of the alternating current impedance is carried out in a very similar manner to that described above. The characteristic impedance: durdhfließ: end @ e direct current in the conductive state of the tube B1 now fulfills a double function, i.e. as a result of the direct voltage drop across the resistor R, -, the output is marked as tested, similar to the previous case, as follows: that another test device cannot respond. Secondly, the direct current acts as a "test current for the resistor R". If the resistance Ra is equal to the resistance R "set by the marker switch MS, the voltage at point P is equal to half the sum of the direct voltages at points U and W . the device that measures the DC potential of the point P, thus must be designed such that it responds when the voltage of the point P is equal to 1 / z (U1 -i- V2).

The test device must be set up in such a way that it only responds and interrupts the excitation circuit of the rotary magnet when both the AC voltage test device WO and the DC voltage measuring device respond.

Claims (1)

PATENT CLAIMS: r. Test device in an automatic telecommunication system for the selective testing of a characteristic impedance, the value of which is characteristic of an apparatus assigned to the characteristic impedance and which is connected to a multiple point assigned to the apparatus, which is connected to the test apparatus during the test and is simultaneously accessible to several test apparatuses The test of the nominal impedance is carried out with the aid of the characteristic impedance, the multiple point and the test current flowing through the test device, characterized in that the apparatus is further characterized by a marking voltage, the value of which gives an indication whether the characteristic impedance (R, i) is checked or not, and: that the test device contains means for testing the marking voltage which respond in the presence of a marking voltage which corresponds to the state in which the characteristic impedance (_R, 1) is not checked is, whereby when addressing n these means and @controlled by them n dec test current over -the characteristic impedance switched on and. the marking voltage is changed to a value = corresponding to the state in which the characteristic impedance is checked by passing an impedance other than the test current through an impedance (Rv 1) assigned to the apparatus and connected to the point to which .die Marking voltage is supplied. a. Test device according to claim i, for testing a characteristic impedance which is connected to a marking contact of an output of a voter which is swept by a first brush of a voter. connected to a test current. is, characterized "that means (B11, B12) for checking a marking voltage on another, swept by a second brush (d1) of the selector" connected via a second impedance (Rbi) to a voltage source marking contact of the output available which are set up in such a way that they respond when the voltage of the voltage source (-Ba) is found at the second marker contact and then send such a current through the second impedance that the means do not respond to another test device, if. this is connected to the output via another selector, and that the means further hold a test current via the characteristic resistor (R "1) cinSc! (b11), further means (T12) for testing this test current being available: 3. Device according to Claim z for testing: a characteristic impedance d'urc'h an alternating test current, which characteristic impedance is connected to a marking contact, an output of a selector,. Characterized in that the characteristic impedance has a finite direct current resistance different from zero value and on the other hand to a direct current source (h1) is connected, and that means (Bi) for testing the marking DC voltage of the marking contact are provided, which are set up in such a way that they respond when the voltage of the direct current source is present at the marking contact, and not only the test alternating current, but also insert such a direct current across the characteristic impedance that the direct voltage of the marking contact changes to a value ert, in which the means in another test device, which is connected to the output via another selector, do not respond, and that the test device contains further means (WO) for testing the test alternating current and the test circuit contains at least one alternating current source ( V, 1) contains. q .. Device according to claim 3, @daduirch characterized in that the means for checking the DC marking voltage: g contain an electronic flip-flop circuit (Bi, B2) which can be in two different, electrically stable states; and which is provided with at least one discharge tube, which is blocked in: the first electrical state and, in: the second electrical Zuistantd, conductive and with a discharge path during the test in the test circuit between the test brush (d) of the selector, and a second direct current source (l'2) is switched on, the flip-flop is switched to the first electrical state before the test and remains in this state if. A voltage is found at the Miarkicrkontakt whose difference from the voltage of the second direct current source is smaller: than a certain threshold value, but the discharge tube becomes conductive if a potential is found at the multiple point "whose difference from the voltage of the second direct voltage source is greater than the given threshold value, whereby the flip-flop switches to the second electrical state and such a direct current flows through the characteristic impedance to be tested (R ") that the difference between the voltage of the marking contact and the second direct voltage source is brought to a value that is smaller than the given Threshold is. 5. Apparatus according to claim 4, characterized in that a discharge path of a first in the test circuit. Vacuum discharge tube (Bi) is inserted, the cathode of which is connected to the test brush of the switch during the test and in which a control electrode for direct current is coupled to one point of an output circuit of a second vacuum discharge tube (B2) Output circuit of the first discharge tube is coupled, such that when the first tube is blocked, the second tube is conductive, and vice versa. 6. Apparatus according to claim 5, characterized in that the control electrode of the first discharge tube (Bi) is coupled to a point of the test circuit in such a phase that the input impedance of the test device is lowered. 7. Apparatus according to claim 6, characterized in that the cathode of the first discharge tube is coupled to a control electrode of a third discharge tube (B3), in which an output electrode is coupled to the control electrode of the first discharge tube (Bi) in such a way that the cathode alternating voltage is amplified and transferred in the opposite phase to the control electrode of the first tube. 8, device according to claims q: to 7, characterized in that the end of the discharge path of the first discharge tube facing away from the test brush is connected to a voltage source (II.) Via a comparison impedance (R., Cm) and the discharge path is connected to a voltage divider ( R7, R8) is bridged, their. Resistance value against the: highest occurring value of the characteristic impedance (Rx, C ,,) and the comparison impedance, and further means for checking the AC voltage of a tapping point (P) of the voltage divider are present, and this tapping point is the voltage divider in the same ratio as the ratio between the impedances of the associated characteristic impedance and comparison impedances divided. 9. Apparatus according to claim 8, characterized in that an alternating current source (h, 1 or Tl, 2) is connected both in series with the comparison impedances and with the characteristic impedances. ok according to claim 8 or 9, characterized in that there are further means for checking the direct voltage of a tapping point of the voltage divider.