RU2761890C1 - Device for measuring peak values - Google Patents

Abstract

FIELD: measuring technology.

SUBSTANCE: invention relates to measuring technology and physics and can be used to isolate and control short single pulses of certain amplitudes and durations against the background of random or periodic interference of longer duration, for example, in dosimetry, vibration measurement of shock processes, flaw detection. The device for measuring peak values contains a passive sensor, the first pin of which is connected to the input of the converter amplifier, the output of which is connected via a capacitor to the first pin of the first resistor, the output of the first operational amplifier is connected to the first pin of the first diode, the second pin of which is connected via a parallel serial RC circuit and the second resistor is connected to a common bus, to which the second pin of the passive sensor, the third and fourth resistors, the second diode, the second operational amplifier and a positive or negative voltage bus, according to the invention, an additional shock excitation circuit is introduced, the first pin of which is connected to a common bus, and the second pin is connected to the inverting input of the first operational amplifier, the output of which is connected to the third pin of the shock excitation circuit, and the non-inverting input is connected to the second pin of the first resistor and the first pin of the third resistor, the second pin of which is connected either to the non-inverting input of the second operational amplifier, or to the output and inverting input of the second operational amplifier, the non-inverting input of the second operational amplifier is connected through the fourth resistor to the positive or negative voltage bus and through the second diode to the common bus.

EFFECT: claimed invention is aimed at simplifying the design, increasing noise immunity and increasing speed.

2 cl, 5 dwg

Description

The invention relates to measuring technology and physics and can be used to isolate and control short single impulses of certain amplitudes and durations against the background of random or periodic interference of a longer duration, for example, in dosimetry, vibration vibrometry, and defectoscopy.

A device for measuring peak values is known (see. "Instruments and experimental techniques" No. 4, 1978, p. 112, V.G. Goldort and others), containing a passive sensor (radiation receiver), made on a photomultiplier tube (PMT), the output of which is connected to a non-inverting charge-sensitive amplifier (PCA), made on an integrating capacitor and a source follower, the output of which through the first analog switch is connected to the non-inverting input of the first operational amplifier, the inverting input of which is connected to the combining point of the anode of the diode, the non-inverting input of the second operational amplifier, the first plate of the first capacitor, the input of the second analog switch, the output of which is connected to a common bus connected to the second plate of the first capacitor, the cathode of the diode is connected to the output of the first operational amplifier, the inverting input of the second operational amplifier is connected to the point of combining the output of the peak voltmeter, the input third analog key and p the first plate of the second capacitor, the second plate of which is connected to the common bus, the output of the third analog switch is connected to the output of the second operational amplifier, the control inputs of the first, third and second switches are connected respectively to the first, second, third outputs of the command pulse generator, the input of which is connected to the bus launch.

The disadvantages of the device are:

1. Bulky due to the large dimensions of the electrovacuum photomultiplier and the elements of its protection from mechanical loads.

2. The fragility of the electrovacuum photomultiplier, which does not allow working under high shock loads.

3. Low gain of the stages following the PMT, which makes it impossible to use passive sensors with low sensitivity, for example, photodiodes, piezo accelerometers, etc., which are indestructible under shock loading.

4. Limiting the dynamic range from above and below and reduced noise immunity due to the lack of compression of the output information and the absence of resonant filtering of low-frequency interference from mechanical influences on the PMT, which prevent the selection of short pulses of a passive radiation sensor (photomultiplier tube).

The closest in technical essence to the claimed invention is a device for measuring peak values (see patent RU No. 2343429, priority dated 04.16.2007, authors Gutnikov A.I., Gusev V.E., IPC: G01J 1/44, publ. 10.01.2009, bull. No. 1), containing a passive sensor, an amplifier-converter, a one-shot with a control input, the first operational amplifier, the first diode, the second diode, the first analog switch, the second operational amplifier, the first resistor, a serial RC-circuit, the second resistor, third resistor, active or passive L-shaped RC high-pass filter, second analog switch, non-inverting operational amplifier, reference voltage bus, third operational amplifier, eighth, seventh, sixth, fifth, fourth resistors, capacitor, third diode. The passive sensor is connected to the amplifier-converter. The output of the first operational amplifier is connected to the cathode of the first diode and the anode of the second diode, the cathode of which is connected to the input of the first analog switch, the non-inverting input of the second operational amplifier, the first terminal of the first resistor and through a serial RC circuit to the common bus to which the output of the first analog switch is connected ... The output of the second operational amplifier through the second resistor is connected to the anode of the first diode and the inverting input of the first operational amplifier, the non-inverting input of which is connected to the first terminal of the third resistor. The control inputs of the first and second analog switches are respectively combined and connected to the output of the one-shot, the output of the amplifier-converter is connected through an active or passive L-shaped RC high-pass filter to the second terminal of the third resistor, the non-inverting input of the first operational amplifier is connected through the second analog switch to the common bus. The reference voltage bus is connected to the non-inverting input of the third operational amplifier, the output of which is connected to the cathode of the third diode, the anode of which is connected to the inverting input of the third operational amplifier and through the fourth resistor to the first terminal of the capacitor, to the non-inverting input of the non-inverting operational amplifier and to the first terminal of the fifth resistor. The second terminal of the fifth resistor is connected to the first terminals of the sixth resistor and the seventh resistor and to the output of the second operational amplifier, the inverting input of which is connected to the second terminal of the sixth resistor 21, the second terminal of the seventh resistor is connected to the second terminal of the first resistor and through the eighth resistor with a common bus, to which is connected to the second terminal of the capacitor.

The disadvantages of the device are:

- complexity due to the presence of an additional amplifier and a piecewise linear approximator;

- low noise immunity due to the low (no more than 1) gain of the non-resonant L-shaped high-pass filter, which does not ensure the selection of a useful signal of a certain duration against the background of large periodic (random) interference of lower frequencies;

- low performance due to the peak detector diode completely locked in the initial states, which does not provide the required performance of the peak detector due to the presence of a high-resistance "heel" of the diode (several megohms) at the initial moment of charging through this diode of the serial RC-circuit capacitor that stores the signal amplitude. Low speed due to the lack of expansion of the input pulse by the resonant circuit of shock excitation.

A technical problem is the creation of a simplified device for measuring peak values, which has increased noise immunity and increased speed.

The technical results to be achieved by the claimed invention are to simplify, increase noise immunity and improve performance.

These technical results are achieved by the fact that in a device for measuring peak values containing a passive sensor, the first terminal of which is connected to the input of the amplifier-converter, the output of which is connected through a capacitor to the first terminal of the first resistor, the output of the first operational amplifier is connected to the first terminal of the first diode, the second terminal of which is connected to a common bus through parallel-connected serial RC-circuit and the second resistor, to which the second terminal of the passive sensor, the third and fourth resistors, the second diode, the second operational amplifier and the bus of positive or negative voltage are connected, new is that in addition a shock excitation circuit is introduced, the first output of which is connected to the common bus, and the second output is connected to the inverting input of the first operational amplifier, the output of which is connected to the third output of the shock excitation circuit, and the non-inverting input is connected to the second output of the first resistor and the first output One of the third resistor, the second terminal of which is connected either to the non-inverting input of the second operational amplifier, or to the output and inverting input of the second operational amplifier, the non-inverting input of the second operational amplifier through the fourth resistor is connected to the positive or negative voltage bus and through the second diode to the common bus.

The use of a shock excitation circuit in the negative feedback circuit of the first operational amplifier forms a resonant shock excitation amplifier and provides an additional amplification function, which makes it possible to exclude the use of an additional amplifier and a piecewise linear approximator, as in the closest analogue, which simplifies the device circuit. The formed resonant amplifier of shock excitation ensures the selection of pulses of certain durations and amplitudes and increases the response speed, since more sensitive to short impulses that excite the shock excitation circuit. Also, the formed resonant amplifier of shock excitation ensures the selection of a useful signal of certain durations and amplitudes against the background of large periodic (random) interference of a lower frequency than in the duration of the input pulses, which increases noise immunity.

In addition, an increase in the speed of response is also achieved due to the fact that the second diode opens the first diode, which ensures the maximum speed of the peak detector on the first diode and the series RC circuit by eliminating the high-resistance "heel" of the first diode (several MΩ) at the initial moment of charging through the first diode for storing the signal amplitude of the capacitor of the series RC-circuit.

The amplifier-converter (photocurrent or charge of a passive sensor into a voltage) provides a standard conversion of the charge of a passive sensor into a voltage and is made on an operational amplifier, an integrating RC circuit and a blocking capacitor, the first terminal of which is the input of the amplifier-converter, and the second terminal is connected to the input of the integrating RC-circuit and the inverting input of the operational amplifier, the non-inverting input of which is connected to the common bus, and the output is connected to the output of the integrating RC-circuit and is the output of the amplifier-converter. The blocking capacitor at the input of the amplifier-converter eliminates the influence of the constant component of the passive sensor signal, which increases the noise immunity of the device as a whole.

The shock excitation circuit is made on a series-connected capacitor, an inductance and a resistor, the second terminal of which is the third terminal of the shock excitation circuit, the second terminal of which is the point of combining the resistor and inductance, the second terminal of the capacitor is the first terminal of the shock excitation circuit. This implementation of the shock excitation circuit included in the negative feedback circuit of the first operational amplifier ensures the maximum achievement of the technical results, the implementation of which is aimed at the proposed device. This requires a large inductor.

The shock excitation circuit is made on the first, second, third and fourth resistors, the first, second, third and fourth capacitors, the first terminal of the first capacitor is the first terminal of the shock excitation circuit, the combining point of the first and second resistors is the second terminal of the shock excitation circuit and is connected to the first the terminal of the second capacitor, the combining point of the third capacitor and the resistor is the third terminal of the shock excitation circuit, the combining point of the second terminals of the second and third resistors is connected to a common bus, to which the combining point of the second terminals of the second and third capacitors is connected through the fourth resistor, the second terminal of the first capacitor is connected with the second terminal of the first resistor. This implementation of the shock excitation circuit included in the negative feedback circuit of the first operational amplifier ensures the achievement of technical results, the implementation of which is aimed at the proposed device. This eliminates a large inductor.

FIG. 1 a) shows a variant of the circuit of the claimed device for measuring peak values, made with a passive sensor on a photodiode and its capacitor and resistor, and made on the RLC-circuit of shock excitation. FIG. 1 b) shows a passive sensor on a piezoaccelerometer (as you know, a piezoaccelerometer contains sources of signal and noise currents, equivalent capacitance and resistance). FIG. 1c) shows the RC circuit of shock excitation, made on a double T-shaped bridge.

FIG. 2 shows the signal Uout at the load 9 of the device with the signal of the passive sensor 1 with an amplitude of 1 μA, duration of 0.25 μs and superimposed sinusoidal interference. In this case, the position of the useful signal of the passive sensor 1 relative to the interference is arbitrary (Fig. 2 a), 2 b), 2 c)). FIG. 2d) shows the dependence of the output signal of the device on the signal of the passive sensor 1 with an amplitude of 1 μA and a duration of 0.25 μs without interference. An analysis of the diagrams (Fig. 2 a), 2 b), 2 c)) showed that after processing the signal and interference with the RLC or RC circuit of shock excitation, the value of the output signal Uout does not depend on the level and location of the interference, but depends on the amplitude of the input current Iin and signal duration t.

FIG. 3 shows the dependence of the signal Uout at the load 9 of the device on the signal of the passive sensor 1 with an amplitude of 2 μA and durations t (0.1; 0.25; 0.5; 1.0; 1.5) μs.

Analysis of the diagrams (Fig. 3) showed that the value of the signal Uout at the load 9 proportionally depends on the duration of the signal t.

FIG. 4 shows the dependence of the signal Uout at the load 9 of the device on the signal of the passive sensor 1 with a duration of 1 μs and an amplitude A (1 ... 31) μA.

Analysis of the diagrams (Fig. 4) showed that the value of the signal Uout at the load 9 proportionally depends on the amplitude of the signal Iin.

FIG. 5 a) a linearly proportional dependence of the signal Uout at the load 9 of the device on the signal of the passive sensor 1 with its duration of 1 μs is proved.

FIG. 5 b) a linearly proportional dependence of the signal Uout at the load 9 of the device on the duration of the current pulse of the passive sensor 1 with its amplitude of 2 μA is proved.

The device for measuring peak values (Fig. 1 a)) contains a passive sensor 1, an amplifier-converter 2, the first 3 and second 4 operational amplifiers, the first 5 and second 6 diodes, a capacitor 7, the first 8, the second 9, the third 10 and the fourth 11 resistors, serial RC-circuit 12, shock excitation circuit 13, bus 14 of positive or negative voltage.

The first terminal of the passive sensor 1 is connected to the input of the amplifier-converter 2, the output of which is connected through the capacitor 7 to the first terminal of the first resistor 8. The output of the first operational amplifier 3 is connected to the anode (first terminal) of the first diode 5 and the third terminal of the shock excitation circuit 13. The cathode (second terminal) of the first diode 5 through parallel-connected serial RC-circuit 12 and the second resistor 9 is connected to the common bus, to which the second terminal of the passive sensor 1 is connected. The first terminal of the shock excitation circuit 13 is connected to the common bus, and the second terminal is connected to inverting input of the first operational amplifier 3. The non-inverting input of the first operational amplifier 3 is connected to the second terminal of the first resistor 8 and the first terminal of the third resistor 10. The second terminal of the third resistor 10 is connected by means of a conventional key 15 either to the non-inverting input of the second operational amplifier 4, or to the output and the inverting input of the second operational amplifier 4. The non-inverting input of the second operational amplifier 4 through the fourth resistor 11 is connected to the bus 14 of positive or negative voltage and through the second diode 6 to the common bus.

The amplifier-converter 2 includes an operational amplifier 16 integrating an RC-circuit (resistor 17 and capacitor 18 connected in parallel) and a capacitor 19. The first terminal of the capacitor 19 is the input of the amplifier-converter 2, and the second terminal is connected to the input of the integrating RC-circuit 17, 18 and the inverting input of the operational amplifier 16. The non-inverting input of the operational amplifier 16 is connected to the common bus, and the output is connected to the output of the integrating RC circuit 17, 18 and is the output of the amplifier-converter 2. The inverting amplifier-converter 2 provides matching with the passive sensor 1 having a significant capacitive component in the output impedance. It converts the photocurrent pulse of the passive sensor 1 into a voltage pulse with a gain of not more than unity.

The passive sensor 1 is made on the parallel connected photodiode 20 in the reverse bias mode, its equivalent capacitance 21 and the load resistor 22, the first leads of which are the first lead of the passive sensor 1, the second leads are the second lead of the passive sensor 1.

For a positive signal at the output of the device, the polarity of switching on the first 5 and second 6 diodes is shown in FIG. 1 a), for a negative signal the polarity of the first 5 and second 6 diodes should be reversed ((not shown in Fig. 1 a)).

The passive sensor of FIG. 1 b) is made on a piezoaccelerometer 23, the first output of which is the first output of the passive sensor 1, the second output of the piezoaccelerometer 23 is the second output of the passive sensor 1.

Passive sensor 1 generates a charge in the form of short single pulses of photocurrent with amplitude from 1 to 31 μA and duration from 0.125 to 1.5 μs with superimposed low-frequency (up to 100 kHz) periodic or random interference.

Impact drive circuit 13 of FIG. 1 a) is made on a series-connected capacitor 24, an inductance 25 and a resistor 26, the second terminal of which is the third terminal of the shock excitation circuit 13, the second terminal of which is the point of combining the resistor 26 and the inductance 25, the second terminal of the capacitor 24 is the first terminal of the shock excitation circuit 13 ...

Without the inductive circuit 13 of the shock excitation of FIG. 1 c) contains the first 27, the second 28, the third 29 and the fourth 30 resistors, the first 31, the second 32, the third 33 and the fourth 34 capacitors. The first terminal of the first capacitor 31 is the first terminal of the shock driving circuit 13, the point of combining the first 27 and the second 28 resistors is the second terminal of the shock driving circuit 13 and is connected to the first terminal of the second capacitor 32. The combining point of the third capacitor 33 and the resistor 29 is the third terminal of the circuit 13 shock excitation. The point of combining the second terminals of the second 28 and third 29 resistors through the fourth capacitor 34 is connected to the common bus, to which the point of combining the second terminals of the second 32 and third 33 capacitors is connected through the fourth resistor 30, the second terminal of the first capacitor 31 is connected to the second terminal of the first resistor 27.

The series-connected capacitor 7, the first 8 and the third 10 resistors form a differentiating circuit, and at the same time, the first 8 and third 10 resistors are an integral element in terms of the selectivity function of a resonant amplifier with high gain, made on a non-inverting first operational amplifier 3 with a shock excitation circuit 13. The resonant amplifier, having a resonant characteristic due to the shock excitation circuit 13, and in combination with a differentiating circuit, provides a large amplification (selection) of a useful signal of a certain duration and amplitude (given by a short photocurrent pulse) of the order of 40 dB and a significant attenuation of periodic or random low-frequency interference (up to 100 kHz).

The fourth resistor 11, the second diode 6 and the bus of positive or negative voltage 14 form a zero bias circuit at the output of the first operational amplifier (OA) 3 directly or through the second OA 4, which sets the first diode 5 to a half-open state using the forward-biased second diode 6, which is achieved thermal compensation of the characteristics of the first 5 and second 6 diodes at close currents through the fourth 11 and second 9 resistors and the increased speed of the claimed device as a whole due to the elimination of the high-resistance diode "heel", which prevents the fast charging of the capacitor 35 of the series RC-circuit 12. Due to this, an increased speed, i.e. the ability to isolate shorter pulses of passive sensor 1 against the background of interference. In the absence of a voltage follower 4, the current through the fourth resistor 11 should be chosen much higher than the current through the second resistor 9, so as not to affect the differentiating circuit made on the series-connected capacitor 7, resistors 8, 10. Due to this, the temperature coefficient (TKN) of the second diode 6 is greater than the TKN of the first diode 5, and in a static state (without an input signal) at the output of the device there is a temperature-dependent initial zero bias voltage, which can be used, if necessary, as an additional function of temperature control until the passive sensor 1 (photodiode) is triggered.

Due to the high gain of the useful signal at resonance, the inclusion of an additional amplifier and piecewise linear approximator, used in the closest analogue, is not required, thereby simplification is achieved.

A circuit with an RLC or RC circuit 13 of shock excitation, having high selectivity (noise immunity) and amplification, makes it possible to process small currents and pulse durations of passive sensors 1. For example, for a passive sensor 1, currents from one μA to tens of μA are processed on a photodiode with discrimination pulse durations from 0.125 to 1.5 μs (linear dependence up to 1 μs). In this case, the gain is adjusted by choosing the ratio of the first 8 and third 10 resistors. If necessary, instead of the first 8 and third 10 resistors, a controlled digital potentiometer can be used, the arms of which are the first 8 and third 10 resistors.

The current flowing through the open second diode 6 is selected using the fourth resistor 11. When the currents of the first 5 and second 6 diodes are equal and the voltage follower 4 is turned on, thermal compensation and a low zero mixing voltage are provided. With a large current of the second diode 6 at the output of the device, there is a higher zero mixing voltage (about 0.6 V), depending on the temperature with the TKN of the second diode 6, about 2 mV / ° C.

The device for measuring peak values works as follows.

In the initial static state, the signal at the output of the passive sensor (photodiode) 1 is absent, and at the output of the amplifier-converter 2 there is also a zero signal. At the anode of the forward-biased voltage from the bus of positive or negative voltage 14 of diode 6, there is a voltage (both with and without voltage follower 4), equal to 650 mV. This voltage is repeated at the output of the first op-amp 3. At the cathode of the first diode 5, the voltage is about 250 mV, depending on the current through the second diode 6 when the fourth resistor 11 and the second resistor 9 are selected.

With a short current pulse from a passive sensor 1 of a certain duration and amplitude, an equivalent voltage pulse appears at the output of the amplifier-converter 2, coming through the differentiating circuit on the capacitor 7 to the first 8 and third 10 resistors to the input of the resonant non-inverting amplifier on the first op-amp 3 with an RLC circuit 13 shock excitation in its negative feedback circuit.

The initial phase of the voltage at the moment the pulse arrives from the amplifier-converter 2, which appears on the RLC circuit 13 of the shock excitation, coincides with the phase of the input pulse on the differentiating circuit, since the resonant amplifier on the first op-amp 3 is non-inverting. At the time of the end of the input pulse from the passive sensor 1, the signal at the output of the amplifier-converter 2 is also absent, and on the LC circuit of the RLC circuit 13 of shock excitation and the output of the first op-amp 3 due to the stored energy of the inductance 25, damped oscillations continue, the intensity (amplitude and duration ) which depends on the initial conditions, the latter are determined by the current in the LC circuit of the RLC circuit 13 of the shock excitation at the end of the input pulse.

The amplitude of the first (after exposure to the input pulse) half voltage period at the output of the first op-amp 3 has a maximum value if the duration of the input pulse from the amplifier-converter 2 satisfies the condition: t = 0.5T ₀ , where T ₀ is the period of free (damped) oscillations in RLC-circuit 13 of shock excitation on the capacitor 24, inductance 25, resistor 26, and the first op-amp 3. When the duration of t decreases to 0.051T ₀ (10 times), the maximum value of the amplitude of the oscillatory voltage at the output of the first op-amp 3. If the duration t is constant, and the amplitude of the exciting pulse of the passive sensor 1 and the amplifier-converter 2 increases, then the maximum oscillation amplitude at the output of the non-inverting resonant amplifier on the op-amp 3 with the RLC circuit 13 of shock excitation in its negative feedback circuit also increases proportionally. Those. the device as a whole is both a selector of pulses from the range of known durations at constant amplitude, and a selector of pulses from the range of known amplitudes at their constant duration t (see Fig. 2 - Fig. 5).

As a result, the area of the pulse is determined, which generally estimates the power density of the photocurrent pulse coming from the passive sensor 1, or estimates the area of the pulse (energy) coming from the piezoaccelerometer.

In the initial static state, there is no signal at the output of the device; at the output of the amplifier-converter 2, there is also a zero level. At the output of the resonant amplifier (anode of the first diode 5) there is a voltage equal to the voltage drop across the second diode 6 due to the flow of current from the bus of positive or negative voltage 14 through the second diode 6, since the stage is a DC voltage follower. At the cathode of the first diode 5, due to the flow through the large second resistor 9 of a smaller current than through the second diode 6, set by the fourth resistor 11, there is a small voltage (about 0.2 V), the value of which is stabilized with temperature changes due to the close coincidence of the TKN of both diodes 5, 6. With a larger difference in currents of diodes 5, 6, there is no temperature compensation, but there is a function of additional temperature control by the magnitude of a large zero bias voltage (about 0.6 V).

When a signal from passive sensor 1 appears, which is a mixture of single short photocurrent pulses (from 0.25 to 2 μs) with an amplitude of 1 to 31 μA and periodic (random) noise with a bandwidth of less than 100 kHz and an amplitude of 1 to 31 μA, the conversion begins ...

The resonant amplifier has an asymmetric (due to the built-in differentiating circuit) amplitude-frequency characteristic (AFC) with a steeper low-frequency roll-off to increase noise immunity in the low-frequency region. The maximum AFC of 40 dB is in the passband of single short photocurrent pulses of the passive sensor 1, and the low-frequency interference signal is suppressed, i.e. the gain is much less than unity in the bandwidth over 75 kHz. In this case, to increase the effect of suppressing low-frequency interference up to 120 kHz, a built-in differentiating circuit is used on the capacitor 7, the first resistor 8 and the third resistor 10 of the resonant amplifier. Because in parallel with the selection of the useful signal from the imposed noise, it is amplified in amplitude and buildup in duration, then an additional amplifier and a piecewise linear amphroximator of the closest analogue are excluded (redundant), which simplifies the device and makes it faster.

на втором резисторе 9 и конденсаторе 35 последовательной RC-цепи 12. При этом имеется температурная компенсация в диапазоне от минус 40 до 50°С окружающей среды за счет близкого равенства ТКН диодов при близких токах.The second diode 6 opens the first diode 5, providing a small zero bias voltage

on the second resistor 9 and capacitor 35 of the serial RC-circuit 12. In this case, there is temperature compensation in the range from minus 40 to 50 ° C of the environment due to the close equality of the TKN diodes at close currents.

A small resistor 36 of the serial RC circuit 12 removes overshoot and provides stability at the output of the first op-amp 3 with a steep edge of the signal at its input.

With a large signal of the passive sensor 1, the voltage across the load 9 of the device can be adjusted both by changing the ratio of the resistances of the first 8 and third 10 resistors, and by changing the resistor 17 of the integrating RC-circuit of the amplifier-converter 2 additionally.

The input capacitor 19 of the amplifier-converter 2 is a dividing one, which prevents the output of the amplifier-converter 2 from shifting from a possible direct current of the passive sensor 1.

In the passive sensor 1, the photodiode 20 is reverse biased, in FIG. 1 a) is not shown, because follows from the definition of the photodiode), the capacitor 21 is about 400 pF, the resistor 22 is small (about 10 kΩ) - it prevents the accumulation of a low-frequency interference signal on the total capacitance of the reversely mixed diode 20 of the passive sensor 1 (capacitor 21).

In fact, passive sensor 1 is the total source of short pulses of signal and low-frequency interference sources of photocurrent or piezoaccelerometer charge.

The inverting amplifier-converter 2 converts the total photocurrent or charge of the passive sensor 1 into a voltage for subsequent processing by a resonant amplifier with a shock excitation RLC circuit 13 in a negative feedback circuit. In this case, the series-connected capacitor 7, the first 8 and third 10 resistors form a differentiating circuit and, at the same time, the first 8 and third 10 resistors are an integral functional element of the resonant amplifier. If the current signal of the passive sensor 1 is excessively large, then the resistance of the first resistor 8 is set higher than the resistance of the third resistor 10. If the current signal of the passive sensor 1 is small, then the resistance of the first resistor 8 is set lower than the resistance of the third resistor 10. The ratio of the resistances of these resistors changes. ...

An increase in noise immunity is achieved due to the introduction into the negative feedback circuit of the operational amplifier of a shock excitation circuit with a period T of free oscillations, which ensures effective selection of a useful signal of a certain amplitude and duration I against the background of large periodic (random) interference, while the duration t = (0.05 ... 0.5) T.

The increase in performance is achieved due to the fact that the second diode 6 provides a slightly opening of the first diode 5, which ensures the maximum performance of the peak detector by eliminating the high-resistance "heel" of the first diode 5 (several megohms) at the initial moment of charging the passive sensor 1 of the capacitor 35 of series RC that stores the signal amplitude -chain 12. An increase in the response speed is also achieved by exciting the resonant RLC or RC-circuit of shock excitation 13 with a single pulse of shorter duration than the half-period of free oscillations of the resonant circuit 13.

FIG. 2 shows the dependence of the output signal of the device on the signal of the passive sensor 1, where:

U _in - signal of passive sensor 1 in the form of a short single pulse of photocurrent (charge) with superimposed low-frequency (up to 100 kHz) periodic or random interference;

U _out is the voltage across the load 9 of the device, corresponding to the useful pulse of the photocurrent (charge) of the passive sensor 1.

Analysis of the diagram (Fig. 2) shows that the extraction of a useful photocurrent signal with a duration of 0.25 μs and an amplitude of 1 μA occurs against a background of periodic (random) interference with an amplitude close to the amplitude of the useful signal and a frequency of up to 100 kHz. In this case, the position of the useful signal of the passive sensor 1 relative to the interference is arbitrary (Fig. 2 a, 2 b, 2 c). FIG. 2 d) shows the dependence of the voltage across the load 9 of the device on the signal of the passive sensor 1 with an amplitude of 1 μA and a duration of 0.25 μs without interference. Analysis of the diagrams (Fig. 2 a, 2 b, 2 c) showed that the voltage Uout at the load 9 of the device does not depend on the location and level of interference, but depends on the amplitude of the input photocurrent Iin and its duration t.

FIG. 3 shows the dependence of the voltage across the load 9 of the device on the photocurrent signal of the passive sensor 1 with an amplitude of 2 μA and durations (0.1; 0.25; 0.5; 1.0; 1.5) μs.

Analysis of the diagrams (Fig. 3) showed that the value of the voltage Uout at the load 9 of the device proportionally depends on the duration of the signal t (linearly up to 1 μs).

FIG. 4 shows the dependence of the voltage at the load 9 of the device on the signal of the passive sensor 1 with a duration of 1 μs and an amplitude (1 ... 31) μA.

Analysis of the diagrams (Fig. 4) showed that the value of the voltage Uout at the load 9 of the device proportionally depends on the amplitude of the signal Iin.

FIG. 5 a) a linearly proportional dependence of the signal Uout at the load 9 of the device on the signal of the passive sensor 1 with its duration of 1 μs is proved.

FIG. 5 b) a linearly proportional dependence of the signal Uout at the load 9 of the device on the duration of the current pulse of the passive sensor 1 with its amplitude of 2 μA is proved.

A mock-up of the claimed device was assembled, the study of the characteristics of which under the influence of mechanical and thermal loading confirmed the possibility of its implementation and the achievement of the above-described characteristics. The element base of the claimed device contains typical domestic electrical radioelements: dual operational amplifiers of type 544UD 15 or 544UD2, diodes 2D419 V or 2D522A, frameless resistors R1-12 or R1-8P, precision small size frameless capacitors K10-43 V elements, passive sensor for is made with a value of 8 μH.

As a result of prototyping, it was revealed that the speed was increased eight times (up to 0.125 μs instead of 1 μs), a simplified circuit for three operational amplifiers with a higher gain, increased noise immunity in an interference band of more than 100 kHz instead of 40 kHz for the closest analogue.

Claims (2)

1. A device for measuring peak values, containing a passive sensor, the first terminal of which is connected to the input of the amplifier-converter, the output of which is connected through a capacitor to the first terminal of the first resistor, the output of the first operational amplifier is connected to the first terminal of the first diode, the second terminal of which is connected through parallel-connected serial RC-circuit and the second resistor is connected to the common bus, to which the second terminal of the passive sensor, the third and fourth resistors, the second diode, the second operational amplifier and the bus of positive or negative voltage are connected, characterized in that the shock excitation circuit is additionally introduced, the first terminal which is connected to the common bus, and the second terminal is connected to the inverting input of the first operational amplifier, the output of which is connected to the third terminal of the shock excitation circuit, and the non-inverting input is connected to the second terminal of the first resistor and the first terminal of the third resistor, the second terminal of which is connected either with the non-inverting input of the second operational amplifier, or with the output and the inverting input of the second operational amplifier, the non-inverting input of the second operational amplifier through the fourth resistor is connected to the positive or negative voltage bus and through the second diode to the common bus. 2. A device for measuring peak values according to claim 1, characterized in that the amplifier-converter includes an operational amplifier that integrates an RC-circuit and a capacitor, the first terminal of which is the input of the amplifier-converter, and the second terminal is connected to the input of the integrating RC-circuit and the inverting input of the operational amplifier, the non-inverting input of which is connected to the common bus, and the output is connected to the output of the integrating RC-circuit and is the output of the amplifier-converter.

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