DE2343550C3 - Method and device for measuring parameters of the components of a complex circuit - Google Patents

Description

15th

The present invention relates to a method according to the preamble of the patent claim 1 and to a device for performing the method according to the preamble of the claim 3.

The inventive method for measuring parameters of the components of a complex circuit and the device intended for its implementation are mainly used to measure the characteristics of complex RC and AL circuits of various communications and electronic devices, but can also be used to measure the characteristics of film-like ÄC Components and to measure signals from RCL encoders and micro encoders.

A method for measuring the characteristics of a complex circuit is known, in which to Measuring circuit, which includes the complex circuit, an electrical signal arrives and an implementation of the Characteristic values of the electrical signals received at the output of the measuring circuit takes place in time intervals whose size the characteristic values of the complex circuit are determined (compare e.g. SU inventor's certificate No. 219 013).

According to this method for measuring the characteristics of a complex circuit a DC voltage is applied to the input of the measuring circuit is applied, wherein the measurement circuit is a voltage divider formed by the series circuit of a normal reflection Stan of and a parallel AEC circuit with measurement of the characteristic values of the latter, by the series connection of a series-connected ÄL-circuit and a normal resistor when measuring the characteristic values of the series-connected ÄL-circuit, through the series connection of a series-connected ÄC-circuit and a normal capacitor when measuring the characteristic values of the series-connected ÄC-circuit. A transition process takes place in the measuring circuit, which causes the voltage change at the output of the measuring circuit, i.e. the voltage divider mentioned is measured. Then a zero potential is applied to the input of the measuring circuit and the time interval from this point in time up to a point in time at which the voltage of the repeatedly excited transition process and a certain part of the previously stored direct voltage are equal to each other.

In the method described above for measuring the characteristics of a complex circuit, there are no linear dependencies between the sizes of the resulting time intervals and the sizes of the components and the time constant of the complex circuit; on the other hand, separate information about the sizes of the components and the time constant of the complex circuit requires a mathematical processing of the numerical or digital equivalents that result when measuring the mentioned time intervals. In addition, the described method does not allow measurement of the characteristic values of a complex circuit, measurement of the size of the components and the time constant of the parallel AL circuit, since in this case the measuring circuit must consist of a series connection of a normal inductance coil and a parallel AL circuit and in the steady state State, the voltage taken at the output of the measuring circuit is not determined by the size of the inductance L of the inductance coil of the parallel ÄL circuit, but by the ratio between the resistance values (losses) of the inductance coil of the parallel ÄL circuit and the normal inductance coil.

All of this limits to some extent the field of application of the above-described method for measuring the characteristics of a complex circuit due to the low precision of the method (due to the non-linearity of the conversion function) for measuring the sizes of the components and the time constant of the parallel ÄC circuit and that in series connected RL and ÄC circuits as well as due to the impossibility of measuring the sizes of the components and the time constant of the parallel connected ÄL circuit.

A device for performing the method for measuring de is known; Characteristics of a complex circuit in which a changeover switch, whose first input is connected to the output of a DC voltage source and whose second input is grounded , switches on its first input to a signal from a control block that coincides with an external signal at its output, whereby dei The output of the switch is connected either via a complex circuit to the terminal of the standard component, which is electrically connected to a voltage measuring block and a comparison block, or via the standard component to the terminal of the complex circuit which is electrically connected to the voltage measuring block and the comparison block, and the output of the Comparison block is connected to the control block input, which in turn is connected to a block for measuring time intervals (compare e.g. SU Inventor's Certificate No. 243 732).

The control block gives an external signal eir control signal to the changeover switch, which is accordingly the The output of the DC voltage source is connected to the input of the measuring circuit, which connects a series circuit creation of a normal resistance and a parallel ÄC-circle when measuring the characteristic values; the latter, a series connection of a shawl in series A L circle and a normal resistance Measurement of the characteristic values of the series-connected ÄL circuit, a series connection of one in series « switched ÄC circuit and a normal capacitor when measuring the characteristic values of the in series « switched ÄC-circle represents where the anden

The input of the measuring circuit is connected to the earthed input of the changeover switch. After the expiry of the The control block gives a signal to the practical end of the transition process in the measuring circuit Voltage measuring block and to a memory device, the input of which is connected to the output of the measuring circuit, d. H. with the common interconnection point of the normal component and the complex circuit is connected, while the output is connected to a voltage divider having the partial factor e ~ ' Input of the comparison block is switched on. In response to this signal, the memory device stores the Output voltage of the measuring circuit, while the voltage measuring block, its input with the output of the measuring circuit is connected, whose output voltage measures. The control block then gives a signal, to which the changeover switch connects the input of the measuring circuit to its grounded input, during the Block for measuring the time intervals begins to measure the time interval over the end of which a signal is sent to the Block for measuring the time intervals from the comparison block at the point in time at which the Voltage of the repeatedly excited transition process taken from the output of the measuring circuit is taken from the output of the voltage divider Tension equals.

When measuring the characteristic values of a complex circuit according to the above-mentioned method, a high measurement accuracy cannot be achieved, since the numerical equivalents of the voltage and the time interval resulting from the measurement are not linearly related to the characteristic values of the complex circuit. What is more, the numerical equivalent of the time interval, the end of which is detected by the comparison block, depends at the same time on the sizes of the two components of the complex circuit, while the numerical equivalent of such an important characteristic of the complex circuit, such as the time constant, is absent at all The measurement accuracy is additionally reduced by bridging the complex circuit or the standard component through the input resistance of the comparison block. Another major disadvantage is the impossibility of measuring the characteristic values of the parallel A / L circuit due to the fact that after the end of the initially excited transition process, the current (and consequently also the voltage at the output) in the measuring circuit, which in this case comes from the series connection of the normal inductance coil and the parallel λL circuit is not determined by the size of the inductance L of the inductance coil of the parallel λL circuit, but by the ratio between the resistances (losses) of the normal inductance coil and the inductance coil of the parallel RL circuit.

The invention is based on the object, while eliminating the disadvantages mentioned, a method for Measurement of the characteristic values of the components of a complex circuit and a device for it Implementation to develop in soft a change in the nature of the electrical effects on the Measuring circuit enables an increase in the measuring accuracy and an acceleration of the measuring process

It is now the subject of an earlier application (file number: P 23 29 4613-35 of June 8, 1973, which goes back to the same inventor) a method and a device according to the preambles of claims 1 and 2 or 3 and 4. Thereby the complex circuit and the normal component are each available in parallel at two different outputs of the switch.

In contrast, the invention differs according to the characteristics of claims 1 to 4.

The method according to the invention for measuring the characteristic values of the components of a complex circuit and the equipment intended for this purpose increases the accuracy of the measurements and reduces the duration of the measurement and expand the number and range of parameters to be measured. Also, this stands out Facility characterized by the simplicity of its construction and its small external dimensions.

The invention is made clear by the description of exemplary embodiments explained with reference to the drawing. It shows

F i g. 1 shows the functional circuit diagram of a first exemplary embodiment the device according to the invention for performing the method according to the invention for Measurement of the characteristic values of the components of a complex circuit,

F i g. 2 shows the functional circuit diagram of a second exemplary embodiment the device according to the invention,

F i g. 3 shows the functional circuit diagram of a third exemplary embodiment the device according to the invention,

F i g. 4 shows the functional circuit diagram of a fourth exemplary embodiment the device according to the invention,

F i g. 5a, 5b show the timing diagram of the voltages Vi and V ₂ at the output of a changeover switch or at the output of a direct current amplifier.

The device according to the invention for carrying out the method for measuring the characteristic values of the components of a complex circuit is equipped with a changeover switch 1 (FIG. 1), which consists of electronic switches 2, 3 and 4, each of which is equipped with a transistor. The first input 5 of the changeover switch 1 is the input of the electronic switch 3, the second input 6 of the changeover switch 1 is the input of the electronic switch 4 and the third input 7 is the input of the electronic switch 2. The output of the changeover switch 1 is those connected to one another Outputs of the electronic switches 2, 3 and 4. The first input 5 of the switch 1 is connected to the output of a DC voltage source 8, which is carried out according to a circuit known per se with semiconducting components while the second input 6 is grounded

The device is also equipped with a control block 9 consisting of triggers 10, 11, 12 and 12 and a transmitter 14 of a calibrated time interval, with a transmitter 14 in this exemplary embodiment is used according to a circuit known per se designed monostable multivibrator. To the Input of the trigger 11, the zero input of the trigger 12 and the input of the encoder 14 of the calibrated time interval, an external signal is supplied from an appropriate source (not shown). The output of the encoder 14 of the calibrated time interval is with the input of the trigger 10 and the Zero input of trigger 11 connected. The outputs of triggers 10, 11 and 12 correspond to the Control inputs of the electronic switches 2, 3 and 4 are connected.

The output of the changeover switch 1 is via a complex circuit, which in the present exemplary embodiment of the device consists of the parallel connection a resistor IS and an inductance coil 16

703 607HIS

is formed, both with a connection of a normal component, which is formed in the embodiment of the device described here by a normal resistor 17, and with the input a DC amplifier 18 is connected. The output of the amplifier 18 is connected to the free terminal of the Normal resistor 17, with the input of a voltage measuring block 19, which is used as a digital voltmeter a circuit known per se, equipped with semiconductor components, and with the Input of a comparison block 20 connected. The comparison block 20 comprises comparison circuits 21, 22, 23 and voltage dividers 24 and 25, each of which is equipped with two resistors

The DC amplifier 18 and each of the comparison circuits 21, 22 and 23 have one integrated circuit.

One of the inputs of the comparison circuit 21 is grounded, one of the inputs of the comparison circuits

22 and 23 is correspondingly connected to the output of the voltage divider 24 and 25, while the other inputs of the comparison circuits 21,22 and

23 are combined with the output of the DC amplifier 18 and connected. The outcome of the Comparison circuit 21 is connected to the zero input of trigger 10, to the input input of trigger 12 and connected to the input of the voltage measuring block 19. The output of the comparison circuit 22 is with the input of the trigger 13 and the output of the comparison circuit 23 with the zero input of the Triggers 13 connected.

The device is also equipped with a block 26 for measuring time intervals consisting of a There is pulse crystal generator 27, which is designed according to a known circuit equipped with semiconductor components, from electronic Switches 28 and 29, which correspond to the electronic switches 2, 3 and 4 are similar, decade number counters 30 and 31, which are based on a known per se, from semiconductor triggers constructed circuit are executed. The output of the pulse crystal generator 27 is connected to the inputs of the electronic switches 28 and 29 connected, the control inputs corresponding to the outputs of the Trigger 10 and 13 and their outputs are connected to the inputs of the digit counters 30 and 31

The third input 7 of the switch 1 is connected to the inputs of the voltage dividers 24 and 25 and to the output of a DC voltage source 32 which is similar to the source 8 but has a different polarity _S o

Another option is also possible, as described above Similar embodiment of the device for carrying out the method for measuring the characteristic values the components of a complex circuit.

The difference here is that as a complex circuit, a parallel connection of a Resistor 33 (Fig.2) with a capacitor 34 is used, which is similar to that in Fi g. 1 shown circuit of the resistor IS and the inductance coil 16 is A normal capacitor 35 (FIG. 2) is used here as the normal component, which is similar to the Normal resistor 17 (FIG. 1) is connected

A third one, the one described above, is also possible Similar embodiment of the device for carrying out the method for measuring the characteristic values ier components of a complex circuit.

The difference here is that as complex circuit the series connection of a

Resistor 36 (Fig. 3) and an inductance coil 37 is used, which is similar to the normal resistor 17 (Fig. I) is switched. A normal inductance coil 38 is used as the normal component, which is similar to the parallel connection of the resistor 15 (Fig. 1) and the inductance coil 16 is connected

A fourth embodiment of the device for carrying out the method for measuring the Components of the characteristic values of a complex circuit.

The difference here is that a complex circuit is a series connection of a Resistor 39 (Fig. 4) and a capacitor 40 is used similar to the normal resistor 17 (Fig. 1) A normal resistor 41 (FIG. 4) is used as the normal component, which is similar how the parallel connection of the resistor 15 (Fig. 1) and the inductance coil 16 is connected

The device according to the invention for performing the method for measuring the characteristic values of components of a complex circuit works as follows:

The external signal emanating from the source (not shown) triggers the transmitter 14 (FIG. 1) of the calibrated time interval of the control block 9 and converts the triggers 11 and 12 to the one or zero state. The transmitter 14 of the calibrated time interval starts counting the calibrated time interval T ₀ , the potential to be taken from the output of the trigger 11 which is in the one state opens the electronic switch 3 of the changeover switch 1 and the potential to be taken from the output of the trigger 12 closes the electronic switch 4 As a result, a direct voltage - Eo from the output of the direct voltage source 8 is fed directly through the open electronic switch 3 to the input of the complex circuit formed by the parallel connection of the resistor 15 with the resistance value R and the inductance coil 16 with the inductance value L. .

For a better understanding of the method for measuring the characteristic values of the components of a complex circuit, timing diagrams are shown in Fig. 5a and 5b, with the time on the abscissa axis and the voltages V and V ₂ on the ordinate axis at the output of the switch and at the output of the DC amplifier The voltage -E ₀ and the time interval T ₀ smd are plotted in the diagram of FIG. 5a shown

Through the complex circuit, current begins to flow, which reaches the input of the direct current amplifier 18, in whose circuit of the parallel negative feedback the normal resistor 17 with the resistance value R _{0 is} connected. The voltage V _{2 is} taken from the output of the white current amplifier 18 (Fig. 5b). , which is proportional to the current flowing through the complex circuit Therefore, the comparison of this current with two reference currents is replaced by the comparison of the voltage V ₂ with two reference voltages, which comparison is made by means of the comparison circuits 22 and 23 of the comparison block 20 to the other inputs of the circuits 22 and 23 become the reference voltages Vj and Vi

created accordingly by the outputs of the

Voltage dividers 24 and 25 are removed, to whose inputs the DC voltage + E ₀ from the output of a DC voltage source 32 with a polarity opposite to the source 8 is applied. At the point in time at which the reference voltage V _{3 is} equal to the S voltage at the output of the direct current amplifier 18, the comparison circuit 22 responds and the signal emitted by its output converts the trigger 13 to the one state. The electronic switch 29 of the measuring block 26 for measuring the time intervals is opened, and the pulses from the output of the quartz generator 27 begin to reach the input of the decade counter 31, which begins to measure the time interval fi (FIG. 5b) between the points in time at which the voltage at the output of the DC amplifier 18 successively becomes equal to the two reference voltages. If the reference voltage V * and the voltage at the output of the DC amplifier 18 are the same, the comparison circuit 23 responds, whereby the signal from its output returns the trigger 13 to the zero state.The electronic switch 29 is closed and the decade counter 31 ends the measurement of the time interval fi.

After the end of the counting of the calibrated time interval T ₀ (T ₀ > L / R) tnlt a signal at the output of the transmitter 14 of the calibrated time interval, which brings the trigger 10 back into the one state and the trigger 11 into the zero state closed while the electronic switches 2 and 28 are opened. The pulses from the quartz pulse generator 27 begin to arrive at the input of the decade counter 30, which begins to measure the time interval h (FIG. 5, diagram b), while the output of the switch 1 via the open electronic switch 2 to its third input 7 is switched on. As a result, the voltage + E _{0 is} applied to the complex circuit from the output of the DC voltage source Λ2 (FIG. 5a), which has an opposite polarity with respect to the previously applied voltage (FIG. 5b) V ₂ (FIG. 5b) at the output of the DC amplifier 18 begins to decrease. As soon as this voltage approaches zero and, accordingly, the current flowing through the complex circuit is also zero, the comparison circuit 21, which has a grounded input, responds, whereby the signal from its output returns the trigger 10 to the zero state and the trigger 11 to the one state

The electronic switches 2 and 28 are closed and the electronic switch 4 is opened. The decadent _{pulse counter 30 ends the measurement of the time interval f 2} (FIG. 5b), the DC voltage applied to the complex circuit is switched off and the output of the switch 1 is grounded to its second _{Input 6 switched on In addition, the voltage measuring block 19 performs the measurement of the voltage V 2} or V taken from the output of the direct current amplifier 18 on a signal arriving from the input of the comparison circuit 21, which voltage is proportional to the current flowing through the complex circuit after it is switched on the grounded second input 6 of the switch 1 flows

Based on the obtained, measured time intervals ti and h and the voltage V , the size of the inductance 11 of the inductance coil 16 of the complex circuit, the size of its time constant and the size of the conductance Y- = MR de; Resistance 15 of this circuit can be determined as follows:

^L r

= E _n -

The operation of the second embodiment of the device for performing the method for Measurement of the characteristic values of the components of a complex circuit is the same as that described above similar.

The only difference is that by connecting the capacitor 35 in the circuit of the parallel negative feedback of the direct current amplifier 18 (FIG. 2) the output voltage of this amplifier is proportional to the integral of the current flowing through the complex circuit

On the basis of the measured time intervals t \ and f2 obtained and the voltage V , the resistance value R of the resistor 33 belonging to the complex circuit, the time constant of the circuit and the capacitance C of the capacitor 34 belonging to this circuit can be determined as follows:

Ί ~

'2 = T ₀ -C- R;

The operation of the third embodiment of the device for performing the method for Measurement of the characteristic values of the components of a complex circuit is the same as that described above similar.

The only difference is that by using the inductance coil (Fig. 3) as a normal component and by the connection of the inductance coil 37 connected in series with the resistor 36 of the complex circuit in the circuit of the parallel negative feedback of the DC amplifier 18 the complex circuit is fed with a linearly variable current and the output voltage of the DC amplifier 18 becomes equal to the voltage produced by the complex circuit is removed.

On the basis of the obtained, measured time intervals fi and ti and the voltage V , the size of the conductance value can be clearly determined

Y =

of the resistor 36 of the complex circuit that Size of its time constant and the size of the

Inductance L of the inductance coil 37 this, current f-2 "^«? * ^ "^" * Circle can be determined as follows: can be determined as follows.

E ₀ R

I ₂ - J ₀ - - = r,

R ₀ -C;

= T ₀ -RC;

The operation of the fourth embodiment of the device for performing the method for Measurement of the characteristic values of the components of a complex circuit is the same as that described above similar.

The only difference is that by using the resistor 41 (FIG. 4) as a normal component and by the connection of the capacitor 40 connected in series with the resistor 39 of the complex circuit in the circuit of the parallel negative feedback of the DC amplifier 18 the complex circuit is fed with direct current and the output voltage of the direct current amplifier 18 becomes equal to the voltage taken from the complex circuit.

Based on the obtained, measured time intervals t \ and h and the voltage V , the size of the capacitance C of the capacitor 40 of the complex circuit, the size of its time constant and the size of the resistance value R of the method according to the invention for measuring the characteristic values of the components a complex circuit and the device intended for it have a high operating speed, a wide field of application and a high measurement accuracy.

When measuring the characteristic values of separate components, the method according to the invention and the device intended for it enable the measurement accuracy to be increased by eliminating the errors caused by a conversion, which are caused by losses in the capacitors and inductance coils

will. .

The method and the device intended for this enable a reduction in the power loss in the Measuring circuit, whereby the characteristic values of the film-like KC components are measured and digit equivalents of the ÄCL micro-encoder signals result be able.

The device for carrying out the method for measuring the characteristic values of a complex circuit is characterized by a simple structure and small external dimensions.

In addition 5 sheets of drawings

Claims (4)

Patent claims: 1. Method for measuring parameters of the components of a complex circuit, namely a parallel connection of an ohmic resistor on the one hand and an inductance coil or a capacitor on the other, i.e. the resistance value R of the resistance on the one hand and the inductance L of the inductance coil or the capacitance on the other Cdes capacitor, where an electrical measuring circuit including the complex circuit and a normal component, namely a normal resistance with a normal resistance value R ₀ or a normal capacitor with a normal capacitance Ci, is supplied with direct voltage during certain times directly at the input of the complex circuit, with the one at the output of the electrical measuring circuit tapped current or the integral of this current is converted into two time intervals t \, fe by using a calibrated time interval T ₀ the time between the reaching of predetermined values by the current from the measuring k rice or the current integral is determined, and the switching off of the applied direct voltage takes place depending on the value of the current from the measuring circuit or the current integral, characterized in that the current (~ V ₂ ) from the measuring circuit including the complex circuit ( 15, 16 or 33, 3 *) and the latter downstream normal component (17 or 35) or the integral of this current is compared with two reference currents ~ V ₂ , ~ V ₄ , the smaller of which is greater than the direct current component of the current (~ V ₂ ) of the measuring circuit or the integral of this current is that the first time interval fi is measured between the times at which the current (~ ^ J) is equal to the two reference currents ~ V ₃ , ~ V ₄ that when the calibrated time interval T ₀ , which exceeds the size of the time constant of the complex circuit and from the time the DC voltage is applied - E _{0 is} counted to the complex circuit, the polarity of the applied DC voltage - So is changed, <let the second time interval f ₂ be measured from the time of the polarity change to a time at which the current (~ V ₂ ) from the measuring circuit or the current integral becomes zero, that at this time the applied polarity changed DC voltage + £ b switched off and that the current - V then flowing from the measuring circuit is measured; whereupon the searched parameters are determined from: R = _ E ₀ R ₀ L = f, 55 60 C = , ν E ₀ RC = T ₀ -I ₂ ,
(Fig. 1 and 2; 5a, b). 2. Method for measuring parameters of the components of a complex circuit, namely on the one hand an ohmic resistor and on the other hand an inductance coil or a capacitor, i.e. on the one hand the resistance value R of the resistor and on the other hand the inductance L of the inductance coil or the capacitance C of the capacitor, The electrical measuring circuit including the complex circuit and a standard component, namely a normal resistor with a normal resistance value Ro or a normal capacitor with a normal capacitance Co, is supplied with an electrical signal during certain times, the voltage tapped at the output of the electrical measuring circuit in two time intervals t \, h is converted by using a calibrated time interval 7Ό the time between the reaching of predetermined values by the voltage from the measuring circuit is determined, and the signal applied to the measuring circuit as a function of the value of the Voltage is controlled by the measuring circuit, characterized in that the complex circuit is a series circuit of on the one hand an ohmic resistor (36 or 39) and on the other hand an inductance coil (37) or a capacitor (40), that the applied signal is a linearly variable current or a direct current ~ £ b is that the voltage from the measuring circuit including the complex circuit and the latter upstream normal component (38 or 41) is compared with two reference voltages V ₂ , V ₄ , the smaller of which is greater than the direct voltage component of the voltage (V ₂ ) of the measuring circuit is that the first time interval fi is measured between the points in time at which the voltage (V ₂ ) from the measuring circuit is equal to the two reference voltages V ₂ , V ₄ , that at the end of the calibrated time interval T ₀ , the size exceeds the time constant of the complex circuit and is counted from the point in time at which the linearly variable current or direct current is fed in ird, the direction of the change in the linearly variable current supplied or the direction of the direct current ~ Eo is changed so that the second time interval h is measured from the time of the change in direction to a time at which the voltage (V ₂ ) from the measuring circuit equals zero it is that at this point in time the change in the linearly variable current fed in is interrupted or the direct current ~ fi is switched off and the voltage V then taken from the measuring circuit is measured; why the searched parameters are determined from: - '0 LJlL E ₀ R ~ R = RC = T ₀ -I ₂ ,
(Fig. 3 or 4; 5) 3. Device for performing the method according to claim 1, with a changeover switch, of which a first input is connected to the output of a first DC voltage source, a second £ ^: igang to ground and a third input to a second DC voltage source of a different polarity and which is connected to a The signal arriving from the control block, which coincides with an external measurement trigger signal, connects to its output its first input, the output of the switch via a measuring circuit including a complex circuit from the parallel connection of a resistor on the one hand and an inductance coil or a capacitor on the other hand a downstream DC amplifier with negative feedback, one terminal of which is connected to a standard component, namely a standard resistor or a standard capacitor, is electrically coupled to a voltage measuring block and to a comparison block, the output of which is connected to the input ang of the control block is connected, which in turn is connected to a block for measuring time intervals, and at the times at which the output voltage of the DC amplifier successively equal to certain values including zero, the comparison block three different signals to the voltage measuring block and to measure the Time intervals ft, t ₂ to the control block which, using a calibrated time interval, controls the block for measuring the time intervals and also the state of the changeover switch which controls the connection of the first and second direct voltage source to the measuring circuit during the measurement, characterized in that, that the negative feedback of the direct current amplifier (18) is formed by the normal component, namely the normal resistor (17) or the normal capacitor (35), that the comparison block (20) generates the three signals when the output voltage (Vj) of the direct current amplifier (18) equals two different from zero Reference voltages (V ₃ , Vi) and zero is that via these three signals the control block (9) controls the block (26) for measuring the time intervals in such a way that the beginning of the first time interval to be measured (t \) coincides with the first of the Comparison block (20) and the end coincides with the second signal from the comparison block, that of the second time interval to be measured (t ₂ ) the beginning chronologically with the end of the calibrated time interval f7o), which is counted from the time of arrival of the external measurement trigger signal, and the end coincides with the third signal arriving from the comparison block (20), and that the control block (9) controls the state of the switch (1) in such a way that after the calibrated time interval (T ₀ ) the output of the switch (1) also the third input (7) of which is connected to the DC voltage source (32) of a different polarity (+ Eo) , the output at the point in time at which the third signal from the comparison block (20) arrives of the changeover switch (1) is connected to its grounded second input (6) and the voltage measuring block (19) begins to measure the voltage (V ₂ ) at the output of the direct current amplifier (8) (Fig. 1 or 2; 5). 4. Device for performing the method according to claim 2, with a changeover switch, of which a first input is connected to the output of a first DC voltage source, a second input to ground and a third input to a second DC voltage source of different polarity and which is connected to one of one Control block incoming signal that coincides in time with an external measurement trigger signal, connects to its output its first input, the output of the switch via a measuring circuit including a standard component, namely a normal inductance coil or a normal resistor, and including a downstream DC amplifier with negative feedback from the a terminal is connected to a complex circuit consisting of a resistor on the one hand and an inductance coil or a capacitor on the other hand, is electrically coupled to a voltage measuring block and to a comparison block, the output of which is connected to the input of the control block s is connected, which in turn is connected to a block for measuring time intervals, and at the times at which the output voltage of the DC amplifier successively becomes equal to certain values including zero, the comparison block sends three different signals to the voltage measuring block and for measuring the time intervals ti , t ₂ outputs to the control block which, using a calibrated time interval, controls the block for measuring the time intervals and also the state of the switch which controls the connection of the first and second DC voltage sources to the measuring circuit during the measurement, characterized in that the negative feedback of the direct current amplifier (18) is formed by the complex circuit itself, namely a series circuit comprising, on the one hand, a resistor (36; 39) and on the other hand an inductance coil (37) or a capacitor (40) that the comparison block (20) generates the three signals when the output voltage (V ₂ ) of the direct current amplifier (18) is equal to two non-zero reference voltages (Vy, V «) and it becomes zero that, via these three signals, the control block (9) controls the block (26) for measuring the time intervals in such a way that the first time interval to be measured (u) begins at the same time as the first from the comparison block (20) Signal and the end coincides with the second signal from the comparison block that of the second time interval to be measured (t ₇ ) the beginning chronologically with the end of the calibrated time interval (T ₀ ), which is counted from the time of arrival of the external measurement trigger signal, and the end with that of the comparison block (20) incoming third signal coincides, and that the control block {9) controls the state of the switch (1) in such a way that after the calibrated time interval (T ») the output of the switch (1) with its third input (7) to the DC voltage source ( 32) of a different polarity is connected, the output of the changeover switch (1) being connected to its grounded second input (6) and the voltage measuring block (19) measuring the voltage (V ₂ ) begins to measure at the output of the DC amplifier (8) (Figs. 3 or 4; 5).