RU2548594C1 - Meter of dipole parameters - Google Patents

Abstract

FIELD: measurement equipment.

SUBSTANCE: invention relates to inspection technology, automatics, control and industrial electronics. A meter of dipole parameters comprises serially connected a feed pulse generator, a quadripole with a dipole of a measurement object and a dipole with balancing elements, a non-inverting voltage follower, an inverting first amplifier with amplification ratio, equal to two, the first double-input analogue summator, to one of inlets of which a signal is sent from the outlet of the pulse generator, and to the other inlet - from the outlet of the first inverting amplifier, from the outlet of the summator the signal is amplified by the second amplifier and is sent to inlets of two sample and hold circuits, signals from the outlet of each of two sample and hold circuits arrive accordingly to two inlets of the second double-inlet analogue summator, the signal from the second summator is amplified by the third amplifier and via a separating capacitor is sent to a zero indicator. Also there is a control unit, from which signals of synchronisation arrive to the pulse generator and zero indicator, and also control signals to both sample and hold circuits. In the dipole with balancing elements there are two keys and two controlled keys, to control inlets of which via a switch control signals are sent from the control unit. The novelty in the meter of dipole parameters is introduction of three additional resistors, three additional capacitors, two controlled keys, two keys, one switch, two amplifiers, two sample and hold circuits, one double-inlet analogue summator, a control unit and modification in connection of circuit blocks.

EFFECT: increased accuracy of measurement due to reduced measurement error component due to inaccurate balancing of a zero measurement circuit.

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Description

The invention relates to instrumentation, automation, control, industrial electronics and can be used to control and determine the parameters of measurement objects, as well as physical quantities by means of parametric sensors.

Known bridge measuring device (AS USSR No. 1567985, G01R 17/10, 1990, B.I. No. 20), containing in series connecting the generator of supply pulses, an electric bridge, an amplifier, an equilibrium detector, a storage capacitor and an equilibrium indicator. There are also three switches, a control pulse shaper, a delay element, two controlled keys and terminals for connecting two DC voltage sources. They allow you to power from DC sources only those units that operate in a given time interval, and only for the duration of the pulse duration plus the duration of the transient processes.

Its disadvantage is that it is not possible to accurately balance the zero measuring circuit, on the basis of which the device is built. The voltage value of the information signal of the zero measuring circuit, in principle, cannot be reduced to a perfectly zero value. The real situation is aggravated by the fact that there are necessarily noises in electrical and electronic circuits. In the process of balancing the zero measuring circuit for certain parameters, the voltage of the information signal becomes less and less, then becomes comparable with the value of the noise voltage, less than this value and, as it can be said, “drowns” in noise, which prevents further more accurate balancing the zero measuring circuit. Actually, we can only talk about improving the accuracy of balancing the zero measuring circuit. Increasing the accuracy of balancing the zero measuring circuit leads to an increase in the accuracy of the measurement by reducing the component of the measurement error from imperfect precise balancing of the zero measuring circuit. Noise is a source of component error in many versions of instrumentation and automatic devices. The weakening of their harmful effects is an urgent task.

The closest in technical essence and the achieved result to the claimed device is a bipolar parameter meter selected as a prototype (RF patent No. 2152622, G01R 17/10, 2000, B.I. No. 19), containing a series-connected generator of supply pulses, a measuring circuit, non-inverting voltage follower, inverting amplifier with a gain equal to two, two-input analog voltage combiner, isolation capacitor and zero indicator.

Its disadvantage is the insufficiently accurate balancing of the zero measuring circuit, on the basis of which the device is built, due to the presence of noise. Insufficiently accurate balancing leads to a decrease in measurement accuracy due to the component of the measurement error from inaccurate balancing of the zero measuring circuit.

The problem to which the invention is directed, is to increase the accuracy of balancing the zero measuring circuit. Such an increase in the accuracy of balancing leads to an increase in the accuracy of measurement by reducing the component of the measurement error from inaccurate balancing of the zero measuring circuit.

This is achieved by the fact that in a two-terminal parameter meter containing a supply pulse generator that generates a sequence of rectangular pulses u ₁ = K ₀ t ⁰ and linearly varying voltage pulses u ₁ = K ₁ t, where K ₀ and K ₁ are constant coefficients and t - current time, the first output of the pulse generator is grounded, its second output forms the output of the generator relative to the "ground", and the third output forms the input of the generator relative to the "ground" - synchronization input; two terminals connected in series for connecting the two-terminal device of the measurement object and the two-terminal device with balancing elements, the first terminal is connected to the output of the pulse generator (second output), the two-terminal device of the measurement object consists of a resistor and capacitor connected in parallel, one of the resistor terminals and one of the two-terminal capacitor terminals balances are connected to the second terminal for connecting the two-terminal device of the measurement object, the second terminal of the capacitor is grounded; a non-inverting voltage follower, the input of which is connected to the common terminal of the second terminal, resistor and capacitor of a two-terminal device with balancing elements, and the output is to the input of an inverting amplifier with an absolute gain of two, a two-input analog adder, one of whose inputs is connected to the output of the generator pulses, and the other with the output of the inverting amplifier, there is also a zero indicator, to the first (to the signal) input of which one of the outputs of the separation condensate is connected ora, its second input is a synchronization input, the common buses of a non-inverting repeater, an inverting amplifier and a two-input analog adder are grounded, three additional resistors, three additional capacitors, two controlled keys, two keys, two additional amplifiers, two sampling and storage circuits, an additional two-input are introduced analog adder, control unit, switch, and the inclusion of circuit blocks is changed, one of the terminals of each of the three additional resistors is connected to a free terminal the source in the bipolar with balancing elements, the free output of the first additional resistor is grounded, the first controlled key is connected between the free output of the second additional resistor and ground, the first key is connected between the free output of the third additional resistor and ground, one of the terminals of each three additional capacitors connected to the common terminal of the second terminal, a resistor and a capacitor available in a two-terminal device with balancing elements, a free terminal of the first additional the capacitor is grounded, the second controlled key is connected between the free output of the second additional capacitor and the ground, the second key is connected between the free output of the third additional capacitor and the ground, the input of the first additional amplifier is connected to the output of the two-input analog adder, its output is connected to the signal the inputs of two sampling and storage circuits, the outputs of the first and second sampling and storage circuits are connected respectively to the first and second inputs of the additional two an analog analog adder, the output of which is connected to the input of the second additional amplifier, the output of the latter is connected to the free output of the existing isolation capacitor, the control unit has a group of outputs relative to ground, the first output is connected to the synchronization input (third output) of the pulse generator, the second output is connected to to the general output of the switch, the third output is connected to the first control input of the first sampling and storage circuit for putting it into the sampling mode of part of the pulse signal to the signal m of the input intended for subsequent storing of the voltage value in this part of the pulse, the fourth output is connected to the second control input of the first sampling and storage circuit for putting it into the storage mode of the stored voltage value, the fifth output is connected to the third control input of the first sampling and storage circuit for putting it into the reading mode of the voltage value that was previously remembered and stored, the sixth output is connected to the first control input of the second sampling and storage circuit for putting it into the selection mode part of the pulse signal at the signal input, intended for subsequent storing of the voltage value in this part of the pulse, the seventh output is connected to the second control input of the second sampling and storage circuit for putting it into the storage mode of the already stored voltage value, the third control input of the second sampling and storage circuit is connected with the previously mentioned fifth output of the control unit for the simultaneous transfer of both sampling and storage circuits to the reading mode of the voltage values that are stored and stored in them the synchronization input of the existing null indicator is also connected to the fifth output of the control unit, except for the previously mentioned general output of the switch, its first output is connected to the control input of the first managed key, and its second output is connected to the control input of the second managed key, the third switch output is not has connections (open circuit), common busbars of blocks: two additional amplifiers, two sampling and storage circuits, an additional two-input analog totalizer and control unit, are grounded.

The invention is illustrated in the drawing (figure 1), which presents a functional diagram of a meter of two-terminal parameters.

The two-terminal parameter meter contains a supply pulse generator 1, which generates a sequence of rectangular pulses u ₁ = K ₀ t ⁰ and linearly varying voltage pulses u ₁ = K ₁ t, where K ₀ and K ₁ are constant coefficients and t is the current time. The first output of the pulse generator is grounded, the second output forms the output of the generator relative to the ground, the third output forms the input of the generator (synchronization input) relative to the ground.

The output of the generator 1 (second output) is connected to a two-terminal circuit for connecting the two-terminal device of the measurement object, which consists of a resistor 2 (R2) and a capacitor 3 (C3) connected in parallel, and an adjustable resistor 4 (R4) and a resistor 5 connected in series with them (R5). The free terminal of resistor 5 is grounded. In parallel to resistor 5, two circuits are connected. The first of them consists of a series-connected resistor 6 (R6) and a controlled key 7, which, in a particular case, can be a relay. The second circuit includes a series-connected resistor 8 (R8) and a key 9. Each of the two capacitors: an adjustable capacitor 10 (C10) and a capacitor 11 (C11), are connected between the common terminal of the second terminal for connecting the two-terminal device of the measurement object, as well as the resistor 4 and ground. Two circuits are connected in parallel to these capacitors. The first of them consists of a series-connected capacitor 12 (C12) and a controlled key 13, which, in a particular case, can also serve as a relay. The second circuit includes a series-connected capacitor 14 (C14) and a key 15.

The input of the non-inverting voltage follower 16 is connected to the common terminal of the second terminal, resistor 4, capacitors 10, 11, 12, and 14. Its output is connected to the input of the inverting amplifier 17 with an absolute gain of two. One of the inputs of the first two-input analog adder is connected to the output of the inverting amplifier 17, the other input of this adder is connected to the output (second output) of the generator 1. The common buses of the non-inverting repeater 16, the inverting amplifier 17 and the first analog adder 18 are grounded.

The output of the first analog adder 18 is connected to the input of the second amplifier 19, and the output of the latter is connected to each of the inputs of the two sampling and storage circuits 20 and 21. The outputs of both of these circuits are connected respectively to the two inputs of the second two-input analog adder 22. Its output is connected to the input of the third amplifier 23, and the output of the latter is connected to one of the terminals of the isolation capacitor 24. Another terminal is connected to the signal input of the null indicator 25. There is also a control unit 26. Common buses of it, the second amplifier 19, both schemes and storing and 20 and 21, a second analog adder 22, a third amplifier 23 and the zero indicator 25 are grounded.

The control unit 26 has a group of outputs relative to the "ground". Its first output is connected to the synchronization input (third output) of the pulse generator 1. The second output is connected to the common output of the switch 27. The third output is connected to the first control input of the first sampling and storage circuit 20, through which a control signal is received and transfers the sampling and storage circuit to sampling mode of a part of the pulse signal at the signal input for subsequent storing of the voltage value in this part of the pulse. The fourth output is connected to the second control input of the first sampling and storage circuit 20, through which a control signal is received and puts the sampling and storage circuit in the storage mode of the already stored input voltage value. The fifth output is connected to the third control input of the first sampling and storage circuit 20, through which a control signal is received and puts the circuit in the read mode of the voltage value previously stored.

The sixth output of the control unit 26 is connected to the first control input of the second sampling and storage circuit 21, through which a control signal is received and puts the circuit into the sampling mode of a part of the pulse input signal and storing the voltage value on it. The seventh output is connected to the second control input of the second sampling and storage circuit 21, through which a control signal is received and puts the circuit in the storage mode of the already stored input voltage value. The third control input of the second sampling and storage circuit 21 is connected to the previously mentioned fifth output of the control unit 26, i.e. reading the stored voltage values occurs simultaneously from both sampling and storage circuits 20 and 21. Also, the second input (synchronization input) null indicator 25 is connected to the fifth output of the control unit 26.

In addition to the previously mentioned common output of switch 27, its first output is connected to the control input of the first managed key 9, and its second output is connected to the control input of the second managed key 13. The third output of the switch has no connection (open circuit).

Parameters R2 and C3 (resistive resistance and electric capacitance) should be determined, these are the desired parameters. Resistor R4 has a known adjustable resistance value. Resistors R5, R6, and R8 have known constant resistance values. Capacitor C10 has a known adjustable capacitance value, and capacitors C10, C12 and C14 have known constant capacitance values.

In the considered circuit, the equilibrium state of the measuring circuit corresponds to zero voltage at the output of the first adder 18. In this case, two equilibrium conditions are satisfied:

where R is the equivalent value of the resistance between the input of the non-inverting voltage follower 16 and the "ground" in equilibrium, C is the equivalent value of the electric capacitance between these points also in equilibrium. In this state, key 7 is open, and key 9 is closed, i.e. in equilibrium -

The equilibrium conditions (1), (2) can not be fulfilled in two versions. In one of them, these differences have a positive value, in the other - negative. With the polarity of the pulses of the supply voltage from the generator 1 unchanged, this corresponds to voltage pulses of the opposite polarity at the output of the first two-input analog adder 18. A voltage of positive polarity corresponds to one specific value of the balancing parameter, and negative polarity to another value of this parameter. The option is considered near the fulfillment of the equilibrium conditions. With a small degree of non-fulfillment of the equilibrium condition, if the absolute values of the voltage amplitudes of the pulses of opposite polarity are ensured, the arithmetic average of the values of the balancing parameter corresponding to the amplitudes of the voltage pulses of the opposite polarity corresponds to the equilibrium condition.

As a result, in the process of balancing, the voltage of the signal carrying the information does not tend to zero and does not “sink” in noise. It has a finite value, and it is possible to provide it with confidence significantly more than the noise voltage level, which reduces the negative impact of the latter on the measurement error. The value of the balancing parameter is determined analytically as the arithmetic mean, it is possible to set this value and thereby fulfill the equilibrium conditions.

When the supply pulses from the generator 1 of unchanged polarity and with the keys 7 and 9 open after the end of the transition process, the pulse voltage at the output of the first analog adder 18 will be of the same polarity. In this case

The resistance value R6 should be selected less than the value of R8

Then, with the closed key 7 and the open key 9

And after the end of the transition process, the pulse voltage at the output of the first analog adder 18 will be of a different polarity if the first equilibrium condition (1) is not satisfied to a small degree. The values of the resistances R5, R6 and R8 should be such that the bipolar pulses at the output of the first analog adder 18 have equal absolute values of the voltage amplitudes and when the equilibrium condition (1) is satisfied, the equalities

It can be recommended not to choose a small value of resistance R5 (units Ohm). It is better to choose this resistance no less than many tens and hundreds of Ohms. Resistors R6 or R8 are connected in parallel to the resistor R5, and the values of their resistances should, within small limits, change the values of the equivalent resistance. Then it became possible to obtain the values of the resistances R6 and R8 in the region of at least hundreds and thousands of ohms. Such relatively large values of these resistances can significantly reduce the negative effect of the direct resistance of the keys (resistance of the keys in the closed state) on the measurement error, as well as the effect on the error of the instability of this direct resistance of the keys, including due to aging and temperature changes.

The resistance values of the discussed resistors affect the amplitudes of the pulse voltage and at the output of the first analog adder 18, if the controlled key 7 is closed or open, while the key 9 is open at this time. A special case was previously given when these voltage amplitudes are opposite in sign and equal in absolute value. In general, they are not equal. The values of the discussed resistances should be chosen so that the largest of the voltage amplitudes confidently significantly exceeds the level of noise voltage values. It can be recommended that the value of a larger amplitude in absolute value in the worst case is more than twice the value of the noise level voltage.

If relays are used as controlled keys 7 and 13, then the closing and opening of their contacts should occur immediately after the end of the supply pulse from the generator 1, so that the relay contacts bounce between two successive pulses and end by the start of the next pulse. For this, the relation

where t _dr is the length of time during which the bounce of relay contacts is completed (reference parameter), T _P is the repetition period of the supply pulses from the generator 1 and t _AND is their duration. The ratio of 8 also affects the choice of relays and the choice of the pulse repetition period T _P.

The bipolar parameters meter works as follows.

First, a sequence of rectangular pulses is supplied from generator 1. Before starting work, the controlled keys 7, 13, the keys 9, 15 are open, and the switch 27 is in the first position when the signal from the control unit 26 is supplied to the control input of the controlled key 7. When the next pulse is applied after the end of the transient process, the pulse voltage at the non-inverting output repeater 16 has a flat top with superimposed noise and does not depend on the capacitance of the capacitors 3, 10 and 11, but depends on the resistances of the resistors 2, 4, 5. All the supply pulses from the generator 1 are divided into odd (1, 3, 5, ...) andeven (2, 4, 6, ...). When exposed to the first and each odd supply pulse from the generator 1, the pulse voltages at the outputs of the first analog adder 18 and the second amplifier 19 after the end of the transition process have a flat top of positive or negative polarity. From the third output of the control unit 26, a control pulse is supplied to the first control input of the first sampling and storage circuit 20, which puts the sampling and storage circuit in the mode of selecting a time interval close to the end of the pulse for subsequent storing of the signal flat top voltage value from the output of the second amplifier 19. Immediately after the control pulse from the third control output 26 from its fourth output, a control voltage is supplied to the second control input of the first sampling and storage circuit 20, which translates this circuit to the stored voltage storage mode. At the moment of the end of the first and odd pulses from the generator 1, the voltage from the second output of the control unit 26 is supplied to the control input of the controlled key 7 through the switch 27. It transfers the contacts of the controlled key to the closed state. If a relay is used as key 7, then in the pause between pulses the bounce of its contacts ends.

As a result of closing the contacts of the controlled key 7, the resistor 6 is connected in parallel with the resistor 5. Therefore, when the second and even pulses from the generator 1 are exposed, the voltage value of the flat top of the output pulses of the non-inverting repeater 16 and, accordingly, at the outputs of the first analog adder 18 and the second amplifier 19 will change. This changed voltage will be remembered in the second sampling and storage circuit 21. It can be of the opposite polarity with the voltage that is remembered in the first sampling and storage circuit 20 when the condition (1) is small, and if the first equilibrium condition (1) is significantly not fulfilled, these stresses can be of the same polarity. To memorize the voltage of the flat top of the second and even pulses from the second amplifier 19 from the sixth output of the control unit 26, a control pulse is supplied to the first control input of the second sampling and storage circuit 21, which puts the second circuit into the mode of selecting a time interval close to the end of the pulse for subsequent storing of the value flat top stresses. Immediately after the control pulse from the sixth output of the control unit 26, from its seventh output, a control signal is received at the second control input of the second sampling and storage circuit 21, which puts the second circuit into the stored voltage storage mode. At the end of the second and even pulses from the generator 1 to the control input of the controlled key 7, the voltage from the second output of the control unit 26 ceases to be supplied. This puts the contacts of the controlled key into an open state. If a relay is used as key 7, then in the pause between pulses the bounce of its contacts ends.

After the end of the second and even pulses from the generator 1 from the fifth output of the control unit 26 simultaneously to the third control inputs of the first and second sampling and storage circuits 20, 21 a control pulse is received, which puts these circuits into the readout mode of previously stored voltages. These two voltages simultaneously arrive simultaneously at the two inputs of the second analog adder 22. At the output, its voltage of the flat peak of the pulse is proportional to the algebraic sum of the two input voltages. This output pulse voltage of the analog adder is amplified by the third amplifier 23 and through the isolation capacitor 24 is fed to a zero indicator 25.

The synchronization signals to the synchronization input (third output) of the pulse generator 1 are supplied from the first output of the control unit 26. The signals of the fifth output of this unit are also synchronization signals for the zero indicator 25 and provide stable readings of this indicator. The voltage polarity on the zero indicator 25 uniquely determines the direction of regulation of the balancing element (resistor 4). The separation of pulses from the generator 1 into odd and even is not fundamental, conditional and is used to explain the operation of the circuit. It is important here that when a previous supply pulse from generator 1 is exposed, a two-terminal device with balancing elements contains an element (for example, resistor 5) with a known parameter value, and by the beginning of the next supply pulse, this known value will change (for example, the equivalent value of resistances connected in parallel resistors 5 and 6).

By adjusting the resistance value of the resistor 4, we bring the readings of the zero indicator 25 to zero. But in this case, the first equilibrium condition (1) is not fulfilled exactly (strictly speaking, it is not fulfilled). With odd and even supply pulses from the generator 1, the voltage of the flat tops of the pulses from the output of the first analog adder 18 and from the output of the second amplifier 19 significantly exceed the noise voltage level, which corresponds to the resistances R ₅ and R ₅ R ₆ / (R ₅ + R ₆ ). The two inputs of the second analog adder 22 simultaneously receive two stored voltages of the flat tops from the outputs of two sampling and storage circuits 20 and 21. If the values of these voltages are opposite in sign and equal in absolute value, then the pulse voltage at the output of the second analog adder 22 is zero and as a result, the zero indicator 25 shows a zero value. Moreover, in the above signals, the voltage of flat vertices significantly exceeds the noise voltage level, and as a result, these noises have a less negative effect.

Next, turn off the supply of rectangular pulses from the generator 1, put the switch 27 in position two (the contacts of the controlled key 7 are open) and put the key 9 in the closed state. In this case, R8 is connected in parallel with resistor R5 and the first equilibrium condition (1) will be satisfied, where R is determined by expression (3). The count of the desired parameter (R2) is taken from the formula

where on the right side the values of all resistances are known.

After this, we should proceed to the determination of the second parameter C3. To do this, check that the keys 13 and 15 are open, the switch 27 is in the second position, and apply a pulse train of a ramp voltage from the generator 1. Under two equilibrium conditions, the controlled keys 7 and 13 are open, and the keys 9 and 15 are closed. Then equalities (3) hold and

When the supply pulses from the generator 1 are of the same polarity, the first equilibrium condition (1) is fulfilled, and the switches 13 and 15 are open, the pulse voltage at the output of the first analog adder 18 has a flat peak in the time interval from the end of the transition process to the end of the pulse, the voltage of which has one a certain polarity. In this case

Capacitance value C12 should be selected greater than C14

Then, with the closed key 13 and the open key 15

and the voltage of the flat peak of the pulse at the output of the first analog adder 18 will have a different polarity if the second equilibrium condition (2) is not satisfied to a small degree. The values of electric capacitances C11, C12, and C14 should be chosen so that at the output of the first analog adder 18, the pulse voltages with different polarity have equal absolute values of the voltage of the flat peaks, and when the key 13 is opened and the key 15 is closed, the second equilibrium condition is satisfied (2 ) This corresponds to the fulfillment of equality

While maintaining the previous pulse repetition period from the generator 1 and the previous pulse duration, the logic of the meter circuit is completely repeated. Only the value of the electric capacitance of the capacitor 10 should be regulated. The voltage polarity at the zero indicator 25 uniquely determines the regulation voltage of the balancing element (capacitor 10). By adjusting the value of this capacity, the zero indicator readings are brought to zero. But under the influence of odd and even pulses from generator 1, the second equilibrium condition (2) is only close to fulfillment (strictly speaking, it is not satisfied). This allows you to get the voltage of the flat tops of the pulses from the output of the first analog adder 18 and the second amplifier 19 is significantly higher than the noise voltage level, which corresponds to the values of capacitances C ₁₁ and C ₁₁ + C ₁₂ . The two inputs of the second analog adder 22 simultaneously receive two stored voltages of the flat tops of two consecutive pulses from the outputs of two sampling and storage circuits 20 and 21. If the values of these voltages are opposite in sign and equal in absolute value, then the pulse voltage at the output of the second analog adder 22 and, accordingly, at the output of the third amplifier 23 are equal to zero, because the algebraic sum of the reduced stresses of flat vertices is zero. The result is a zero reading of the zero indicator 25.

Next, turn off the supply of pulses from the generator (1), switch 27 to the third position (the contacts of the controlled keys 7 and 13 are open) and put the key 15 in the closed state. Then, in addition to the previously fulfilled equilibrium condition (1), the second equilibrium condition (2) will be satisfied, where C is determined by formula (10). The count of the desired parameter (C3) is taken from the expression

where on the right side the values of all capacities are known.

Thus, from the description of the operation of the meter circuit, it follows that it retained separate balancing. Because the operation of the circuit is based on pulsed signals whose voltage values significantly exceed the noise voltage level even at zero readings of a zero indicator, the harmful effect of noise voltage on the measurement error is thereby weakened.

Claims (1)

A two-terminal parameter meter containing a supply pulse generator that generates a sequence of rectangular pulses u ₁ = K ₀ t ⁰ and linearly varying voltage pulses u ₁ = K ₁ t, where K ₀ and K ₁ are constant coefficients and t is the current time, first output the pulse generator is grounded, its second output forms the output of the generator relative to the "ground" and the third output forms the input of the generator relative to the "ground" - synchronization input; two terminals connected in series for connecting the two-terminal device of the measurement object and the two-terminal device with balancing elements, the first terminal is connected to the output of the pulse generator (second output), the two-terminal device of the measurement object consists of a resistor and capacitor connected in parallel, and one of the resistor terminals and one of the two-terminal capacitor terminals balancing elements are connected to the second terminal for connecting the two-terminal device of the measurement object, the second output of the capacitor is grounded; a non-inverting voltage follower, the input of which is connected to the common terminal of the second terminal, resistor and capacitor of a two-terminal device with balancing elements, and the output is to the input of an inverting amplifier with an absolute gain of two, a two-input analog adder, one of whose inputs is connected to the output of the generator pulses, and the other with the output of the inverting amplifier, there is also a zero indicator, to the first (to the signal) input of which one of the outputs of the separation condensate is connected ora, its second input is a synchronization input, the common buses of a non-inverting repeater, an inverting amplifier and a two-input analog adder are grounded, characterized in that it has three additional resistors, three additional capacitors, two controlled keys, two keys, two additional amplifiers, two circuits selection and storage, an additional two-input analog adder, a control unit, a switch, and the inclusion of circuit blocks is changed, one of the outputs of each of the three additional resistors sub it is free to output the resistor in the two-terminal with balancing elements, the free output of the first additional resistor is earthed, the first controlled key is connected between the free output of the second additional resistor and ground, the first key is connected between the free output of the third additional resistor and ground, one from the terminals of each of the three additional capacitors connected to the common terminal of the second terminal, resistor and capacitor, available in a two-terminal with balancing elements, its the output pin of the first additional capacitor is grounded, the second controlled key is connected between the free output of the second additional capacitor and ground, the second key is connected between the free output of the third additional capacitor and ground, the input of the first additional amplifier is connected to the output of the two-input analog adder, its output connected to the signal inputs of two sampling and storage circuits, the outputs of the first and second sampling and storage circuits are connected respectively to the first and second input ami additional two-input analog adder, the output of which is connected to the input of the second additional amplifier, the output of the latter is connected to the free output of the existing isolation capacitor, the control unit has a group of outputs relative to the "ground", the first output is connected to the synchronization input (third output) of the pulse generator, the second output connected to the general output of the switch, the third output is connected to the first control input of the first sampling and storage circuits for putting it into the sampling mode of a part of the imp If there is a signal at the signal input intended for subsequent storing of the voltage value in this part of the pulse, the fourth output is connected to the second control input of the first sampling and storage circuit to put it into the storage mode of the already stored voltage value, the fifth output is connected to the third control input of the first sampling circuit and storage for putting it into the reading mode of the voltage value that was previously remembered and stored, the sixth output is connected to the first control input of the second sampling and storage circuit for To transfer it to the mode of selecting a part of the pulse signal at the signal input, intended for subsequent storing of the voltage value in this part of the pulse, the seventh output is connected to the second control input of the second sampling and storage circuit to transfer it to the storage mode of the already stored voltage value, the third control input the second sampling and storage circuit is connected to the previously mentioned fifth output of the control unit for simultaneously transferring both sampling and storage circuits to the voltage reading mode, which they were remembered and stored, the synchronization input of the existing zero indicator is also connected to the fifth output of the control unit, in addition to the previously mentioned general output of the switch, its first output is connected to the control input of the first managed key, and its second output is connected to the control input of the second managed key, the third output of the switch does not have a connection (open circuit), common busbars of the units: two additional amplifiers, two sampling and storage circuits, an additional two-input analog adder and control unit, emleny.