RU174639U1 - DEVICE FOR FORMING RADIO PULSES - Google Patents

Abstract

The utility model relates to radio engineering, communication systems and can be used in radio transmitting devices, radar, secure communication systems, pulse technology, etc. The technical result of the utility model is to approximate the shape of the radio pulse to the shape of the sinusoidal wave with the exception of the asymmetry of the positive and negative half-periods of the sinusoid relative to the voltage, a constant level, which has the required value within the power supply voltage of the device. This is achieved by the fact that a comparator, a short pulse shaper, the first and second logic elements 2I-NOT, RS-flip-flop, the seventh resistor, the first and second n-channel field-effect transistors with an insulated gate, the first and second p-channel insulated gate field effect transistors and voltage regulator.

Description

The proposed utility model relates to radio engineering, communication systems and can be used in radio transmitting devices, radar, secure communication systems, pulse technology, etc.

A device for the formation of radio pulses (Author's certificate No. 1030948 SU, IPC Н03В 11/00, Medvedev Yu.A., Toporin V.I., Rybynok V.A., published on July 23, 1984, Bull. No. 27). This device contains three resistors, three capacitors, two varicaps, an electronic switch, an amplifier, an additional amplifier, a parallel oscillatory circuit, including the first capacitor and an inductor with a tap, an additional inductor. The device operates as follows. When the key is closed, a direct current flows through an additional inductor. There is no radio pulse at the output of the device. When you open the key through an additional inductor, the direct current stops flowing. In this case, due to the inductive coupling between the inductors, a pulse is induced in the inductive coil with a tap. This leads to the appearance of sinusoidal oscillations in the oscillatory circuit. Sinusoidal oscillations passing through the amplifier appear at the output of the device. When the key is closed through an additional inductor, DC will again flow. In addition, a sinusoidal signal from the amplifier output will begin to flow through this coil. This leads to the fact that at the frequency of sinusoidal oscillations in the additional inductor there is a short circuit mode, which ensures the termination of the oscillatory process in the oscillatory circuit. Accordingly, at the output of the device, the formation of the radio pulse will also stop.

Signs of an analogue that coincide with the features of the proposed technical solution is the presence of three resistors and a capacitor. The disadvantages of the analogue include the following.

1. The oscillatory process that occurs in the oscillatory circuit is of a damped nature. The lower the quality factor of the oscillating circuit, the faster the oscillation damps. In this regard, at the output of the device, the shape of the radio pulse will be far from sinusoidal.

2. In an additional inductor, a short circuit mode cannot occur if there is a signal on it that varies according to a sinusoidal law. However, if there are signals in antiphase that change at the same frequency in an additional inductor (for example, the phase is 180 °) and an inductance coil with a tap (for example, the phase is 0 °), the oscillation process can be stopped in the oscillatory circuit when summing these two signals. But at the same time, even with a small mismatch of the phases and amplitudes of these signals, which is possible due to the use in the device of varicaps that have a non-linear dependence of the capacitance on the applied voltage and the amplifier in the oscillatory circuit, the oscillation process will continue in pauses, distorting the shape of the radio pulse, for example, increasing its duration.

A device of the shaper of radio pulses is known (Copyright certificate No. 1108613 SU, IPC Н03К 3/80, Pisarchuk V.M., Golubeva V.G., published on August 15, 1984 Bul. No. 30). This device has a D-trigger, to the D input of which a manipulating signal is supplied. In this case, the C input of the D-trigger is connected to the direct output of the generator, which forms a sequence of rectangular pulses. The direct output of the D-flip-flop and the inverse output of the square-wave pulse generator are respectively connected to the inputs of the two-input logic element I. The output of the logical element And is connected to one of the inputs of the switch. The inverse output of the D-flip-flop is connected to the input of the DC voltage generator in pauses, the output of which is connected to the second input of the switch. The output of the switch is connected to the input of a low-pass filter, at the output of which an output signal appears in the form of a radio pulse.

Signs of an analogue that coincide with the features of the proposed technical solution is the presence of a two-input logic element I.

The disadvantage of the analogue is the following. In the device, in order to form radio pulses, a sequence of rectangular pulses is converted into a signal similar to a sinusoidal one using a low-pass filter. However, for f _in >> f _{cp the} signal at the filter output changes linearly, for f _in = f _{cp the} signal at the filter output is closest to sinusoidal, however, it is still a sequence of pulses whose edges change exponentially, when f _in << _{fc, the} signal at the filter output is a sequence of rectangular pulses with littered edges, where f _in is the repetition frequency of rectangular pulses, af _cf is the cut-off frequency of the low-pass filter. Thus, the analogue allows you to generate a radio pulse, however, its shape will be far from sinusoidal, which leads to an increase in the components in the spectrum of the signal at the output of the device.

Of the known technical solutions, the closest in technical essence to the claimed one is the shaper of radio pulses (Copyright certificate 1259478 A1 SU, IPC Н03К 3/80, Glukho V.I., Glukhova OM, publ. 23.09.86, BI No. 35). The radio pulse generator includes limiting and matching resistors, a zener diode, a capacitor, a sinusoidal signal source, a voltage follower, two electronic switches, where each of them includes two resistors (the first and second resistors) and an n-p-n-type bipolar transistor, an inverter. The first terminal of the limiting resistor is connected to a source of positive supply voltage. The second terminal of the limiting resistor is connected to the first terminal of the terminating resistor, the first terminal of the capacitor, the zener diode cathode, and the collector of an n-p-n-type bipolar transistor of the second electronic key. The zener diode anode and the second capacitor terminal are connected to a common bus. The output of the source of sinusoidal signals is connected to the second output of the matching resistor and the input of the voltage follower. The output of the voltage follower is connected to the collector of an n-p-n-type bipolar transistor of the first electronic switch. The control signal, which is a rectangular pulse with a duration equal to the duration of the generated radio pulses, is fed to the input of the first electronic switch (the first output of the first resistor) and to the input of the inverter. The inverter output is connected to the input of the second electronic key. The outputs of the first and second electronic keys, which are the connection nodes of the second output of the second resistor and emitter of an n-p-n-type bipolar transistor, are interconnected and are the output of the radio pulse shaper. In electronic switches, the second terminal of the first resistor, the first terminal of the second resistor and the base of an n-p-n-type bipolar transistor are interconnected.

The signs of the prototype, which coincide with the features of the proposed technical solution, are the first and second npn-type bipolar transistors, the first and second resistors, where the second output of the first resistor is connected to the first output of the second resistor and the base of the first npn-type transistor, the third and fourth resistors, where the second terminal of the third resistor is connected to the first terminal of the fourth resistor and the base of the second npn-type bipolar transistor, the fifth and sixth resistors, a sinusoidal signal source, a capacitor and an inverter, to the input to The control signal, which is a stream of rectangular pulses, is fed in otorogo.

The prototype is characterized by the following disadvantages.

1. The description of the prototype says that "the control signal is received at the control input of the first controlled electronic key - rectangular pulses with a duration equal to the duration of the radio pulse". In accordance with this and, in addition, considering the structural electric circuit of the prototype, we can conclude that the time moments of the appearance of the control pulses and the sinusoidal signal on the first electronic key are not synchronized. In this case, at the radio pulse for the leading and trailing edges, the phases of the sinusoid will be undefined. They can vary from 0 to 360 °. This will lead to an unjustified increase in the spectral composition of the radio pulse and, accordingly, to a distortion of the shape of the radio pulse.

2. In contrast to the goal, which is stipulated in the prototype, a strong asymmetry of the radio pulses with respect to the voltage of a constant level is possible in the device. Consider this as an example. Let the Zener diode KS191A with a stabilization voltage U _st = 9.1 V be selected. The minimum and maximum stabilization currents, respectively, are equal to: I _st.min = 3 mA; I _st.max = 15 mA. (Tereshchuk PM, Tereshchuk K.M., Sedov S.A. Semiconductor receiving-amplifying devices: Radio amateur manual. Kiev: NAUKOVA DUMKA, 1981. P. 172). We choose the average stabilization current I _st.sr = 10 mA. Let the supply voltage of the device be U _pit = 12 V. Then the resistance value of the limiting resistor will be equal to

The resistance value of the terminating resistor should be significantly less than the input resistance of the voltage follower. Choose a value of the matching resistor is the same as the resistance of limiting resistor R = 290 ohms _acc. In this case, when the amplitude of the sinusoidal signal at the output of the source of this signal is equal to U _m = 3 V, the current flowing through the zener diode will tend to zero. The current from the power supply will flow through the circuit R _ogr -R _sogl - the output of the sinusoidal signal source. In this case, the stabilization of a constant voltage level at the input of the voltage follower will be violated. This voltage will decrease, which will lead to asymmetry of the sinusoidal signal relative to a constant voltage level. With a further increase in the amplitude of the sinusoidal signal, the asymmetry problem will only increase. This will distort the shape of the radio pulse.

3. The bipolar transistor (10) operating in the key mode, in the open state, can be in the saturation mode, which will lead to a significant reduction in the upper frequency of the device and distortion of the shape of the radio pulse.

The objective of the proposed device is to reduce the distortion of the radio pulse, namely, the approximation of the shape of the radio pulse to the shape of the sinusoidal oscillation with the exception of the asymmetry of the positive and negative half-periods of the sinusoid relative to the voltage of a constant level, which has the required value within the specified supply voltage of the device.

The technical result is achieved by the fact that in the driver of radio pulses containing the first and second bipolar transistors of npn type, the first and second resistors, where the second terminal of the first resistor is connected to the first terminal of the second resistor and with the base of the first transistor npn-type, the third and fourth resistors, where the second terminal of the third resistor is connected to the first terminal of the fourth resistor and the base of the second npn type bipolar transistor, the fifth and sixth resistors, a sinusoidal signal source, a capacitor and an inverter, to the input of which о a control signal is supplied, which is a stream of rectangular pulses, a comparator, a short-pulse shaper, the first and second logical elements 2I-NOT, RS-flip-flop, the seventh resistor, the first and second n-channel insulated gate transistors, the first and second p -channel field-effect transistors with an insulated gate and a voltage stabilizer, while the non-inverting input of the comparator is connected to the output of the sinusoidal signal source and to the first output of the capacitor, the second output of the capacitor is connected to the connection node of the second output of the first resistor, the first output of the second resistor and the base of the first npn type bipolar transistor, the inverting input of the comparator is connected to a common bus, the output of the comparator is connected to the input of the short-pulse former, the output of which is connected to the first inputs of the first and second logic elements 2 NAND, the second input of the first logic element 2 NAND is connected to the input of the inverter, the output of the inverter is connected to the second input of the second logic element 2 NAND, the output of the first logical element and 2I-NOT connected to the S input of the RS-flip-flop, the output of the second logic element 2I-NOT connected to the R input of the RS-flip-flop, the first leads of the first and third resistors and the collectors of the first and second npn-type bipolar transistors are connected to the output of the voltage regulator, the second the terminals of the second, fourth, fifth and sixth resistors are connected to a common bus, the first terminal of the fifth resistor is connected to the emitter of the first npn-type bipolar transistor and the sources of the first n-channel and p-channel field-effect transistors, the first the output of the sixth resistor is connected to the emitter of the second npn type bipolar transistor and the sources of the second n-channel and p-channel field-effect transistors with an isolated gate, the drains of the first and second n-channel, first and second p-channel field-effect transistors are connected to the first the output of the seventh resistor, the connection node of these elements is the output of the device, the second output of the seventh resistor is connected to a common bus, the gates of the first n-channel and second p-channel field-effect transistors are isolated the gate are connected to the direct output of the RS-flip-flop, the gates of the first p-channel and second n-channel field-effect transistors with an isolated gate are connected to the inverse output of the RS-flip-flop, the input of the voltage regulator is connected to the bus of the source of positive supply voltage.

The analysis of the essential features of analogues, prototype and the claimed technical solution revealed that in the claimed technical solution with a low level of the control signal (logical "0") at the direct output of the RS-flip-flop, a low level of potential will be established, and at the inverse output of the RS-flip-flop, a high level will be established potential. This will lead to the fact that the first n-channel and p-channel field-effect transistors with an insulated gate will be locked, the channel resistance of these transistors can reach several GΩ, respectively, the sinusoidal signal from the source of the sinusoidal signal will not pass to the output of the device. The second n-channel and p-channel field-effect transistors with an insulated gate will be open, respectively, the channel resistances of these transistors will be several tens of Ohms. In this case, a constant level voltage will be established at the output of the device:

where U _article - voltage at the output of the stabilizer; R ₃ and R ₄ are the resistances of the third and fourth resistors, respectively; V ₀ is the voltage incident on the forward biased pn junction of the base-emitter of the bipolar transistor (for silicon transistors, this voltage is 0.5 ... 0.7 V). Thus, with a low level of the control signal at the output of the device, a constant level voltage U _{0 is established} , the value of which depends on the voltage U _st at the output of the stabilizer and the division ratio of the resistive voltage divider R ₃ -R ₄ . At a high level of the control signal (logical “1”), a high voltage level will be established at the direct output of the RS-flip-flop, and a low voltage level will be established at the inverse output of the RS-flip-flop. This will lead to the fact that the second n-channel and p-channel field effect transistors with an insulated gate will be locked, the channel resistances of these transistors can reach several GΩ, respectively, the voltage from the stabilizer to the output of the device will not pass. The first n-channel and p-channel field-effect transistors with an insulated gate will be open, respectively, the channel resistance of these transistors will be several tens of ohms. In this case, a sinusoidal signal from the source of the sinusoidal signal will begin to pass to the output of the device. The formation of the radio pulse relative to the voltage U ₀ constant level begins. When a low level of the control signal appears (logic “0”), the first n-channel and p-channel field-effect transistors with an insulated gate will be locked, and the second n-channel and p-channel field effect transistors with an insulated gate will be open. This will ensure the cessation of the passage of a sinusoidal signal to the output of the device and the establishment of a constant voltage level at the output of the device. Thus, a radio pulse will be formed at the output of the device, in which the leading and trailing edges will repeat the change in the sine wave, and the positive and negative half-periods of the sine wave, which is the high-frequency harmonic filling of the radio pulse, will be symmetrical with respect to the voltage of a constant level.

Evidence of a causal relationship between the claimed combination of features and the achieved technical result is given below.

The essence of the proposed device is illustrated by drawings.

In FIG. 1 is a schematic diagram of an electrical circuit diagram for generating radio pulses.

In FIG. 2 is a diagram illustrating the operation of the device for generating radio pulses.

A device for generating radio pulses (Fig. 1) contains a sinusoidal signal source (1), a comparator (2), a device for generating short pulses (3), an inverter (4), the first logic element 2I-NOT (5), the second logic element 2I -NOT (6), RS-flip-flop (7), first resistor (9), second resistor (10), third resistor (15), fourth resistor (16), fifth resistor (12), sixth resistor (18), seventh resistor (21), capacitor (8), first npn type bipolar transistor (11), second npn type bipolar transistor (17), first (13) and second (19) n-channel field effect transistors with an insulated gate, the first (14) and second (20) p-channel field effect transistors with an insulated gate, voltage stabilizer (22). The output of the sinusoidal signal source (1) is connected to the non-inverting input of the comparator (2) and the first output of the capacitor (8). The inverting input of the comparator (2) is connected to a common bus. The output of the comparator (2) is connected to the input of the short pulse shaper (3), the output of which is connected to the first inputs of the first logic element 2I-NOT (5) and the second logic element 2I-NOT (6). The control signal u _control (t), which is a stream of rectangular pulses, is fed to the input of the inverter (4) and to the second input of the first logic element 2I-NOT (5). The output of the inverter (4) is connected to the second input of the second logic element 2I-NOT (6). The output of the first logic element 2I-NOT (5) is connected to the S input of the RS-trigger (7). The output of the second logic element 2I-NOT (6) is connected to the R input of the RS-flip-flop (7). The second terminal of the capacitor (8) is connected to the second terminal of the first resistor (9), the first terminal of the second resistor (10) and the base of the first npn type bipolar transistor (11). The emitter of the first npn type bipolar transistor (11) is connected to the first terminal of the fifth resistor and the sources of the first n-channel (13) and p-channel (14) field-effect transistors with an insulated gate. The second terminal of the third resistor (15) is connected to the first terminal of the fourth resistor (16) and the base of the second npn type bipolar transistor (17). The emitter of the second npn type bipolar transistor (17) is connected to the first terminal of the sixth resistor (18) and the sources of the second n-channel (19) and p-channel (20) insulated gate field effect transistors. The output of the voltage stabilizer (22) is connected to the first terminals of the first (9) and third (15) resistors and to the collectors of the first (11) and second (17) npn type bipolar transistors. The second terminals of the second (10), fifth (12), fourth (16) and sixth (18) resistors are connected to a common bus. The drains of the first (13) and second (19) n-channel and the first (14) and second (20) p-channel field-effect transistors with isolated gates are connected to the first terminal of the seventh resistor (21). This node connecting the elements is the output of the device on which the output signal u _o (t) is formed. The second terminal of the seventh resistor (21) is connected to a common bus. The input of the voltage stabilizer (22) is connected to the bus positive voltage + E _p . The direct output of the RS flip-flop (7) is connected to the gates of the first n-channel (13) and second p-channel (20) field-effect transistors with an insulated gate. The inverse output of the RS flip-flop (7) is connected to the gates of the first p-channel (14) and second n-channel (19) field-effect transistors with isolated gates.

A device for the formation of radio pulses as follows.

From the output of the sinusoidal signal source (1), the signal (Fig. 2, a) is fed to the non-inverting input of the comparator (2) and through the capacitor (8) to the connection node of the second output of the first resistor (9), the first output of the second resistor (10) and the base first npn type bipolar transistor (11). The first (13) and second (17) npn-type bipolar transistors are included in the device according to the scheme with a common collector (OK) and play the role of voltage followers. The device must ensure equal resistance of the first (9) and third (15) resistors, and the second (10) and fourth (16) resistors. In addition, the first (11) and second (17) npn-type bipolar transistors must have the same parameters. In this case, the voltage U _{0 of a} constant level at the emitters of the first (11) and second (17) npn type bipolar transistors will have the form

where U _article is the voltage at the output of the voltage stabilizer; R '= R ₁ = R ₃ - resistance of the first (9) and third (15) resistors; R '' = R ₂ = R ₄ - resistance of the second (10) and fourth (16) resistors; V ₀ is the voltage incident on the forward biased pn junction of the base-emitter of the bipolar transistor (for silicon transistors, this voltage is 0.5 ... 0.7 V).

Relative to the voltage U ₀ constant level will change the signal component, which is a sinusoidal signal coming from the output of the source of the sinusoidal signal (1). For undistorted transmission of this signal, it is necessary that the direct current flowing through the resistors R 'and R''meet the condition

where I _b is the base current of the first (11) and second (17) npn-type bipolar transistors.

Thus, the current of the resistive divider R'-R '' should be significantly greater than the current base of the transistors. In this case, on the one hand, the shape of the radio pulse will not depend on the amplitude of the sinusoidal signal, and on the other hand, in the radio pulse, the positive and negative half-periods of the sinusoid will be symmetrical with respect to the voltage U _{0 of a} constant level.

When a positive half-cycle of a sinusoidal signal appears at the non-inverting input of the comparator (2), a voltage jump from the zero level (logical “0”) to a high level (logical “1”) appears at the output of the comparator (2) (Fig. 2, b). This voltage step provides the formation of a short pulse at the output of the shaper of short pulses (3) (Fig. 2, g). At the end of the positive half-cycle of the sinusoidal signal at the output of the comparator (2), the voltage again returns to the zero level. Thus, at the output of the comparator (2), a stream of rectangular pulses will follow, the period of which is equal to the period of change of the sinusoidal signal (Fig. 2, b). Short pulses following from the output of the short pulse shaper (3) are supplied to the first inputs of the first (5) and second (6) logic elements 2I-NOT.

Provided that u _control (t) = 0 (logical “0) (Fig. 2, c), the output of the first logic element (5) will maintain a high voltage level regardless of whether pulses from the shaper pulses (3), or not (Fig. 2, d). At the second input of the second logic element 2I-NOT (6) there will be a high level of potential (u _control (t) is inverted in inverter (4)). In this case, the pulses from the short-pulse shaper (3) will pass through the second logic element 2I-NOT (6) to the R input of the RS-flip-flop (7) (Fig. 2, f), dropping it. In this case, a low voltage level will be established at the direct output of the RS-flip-flop (7) (Fig. 2, g), and a high voltage level will be established at the inverse output of the RS-flip-flop (7) (Fig. 2, h). This will lead to the fact that the first n-channel (13) and p-channel (14) field-effect transistors with an isolated gate will be in the closed state (the channel resistance of these transistors can reach several GΩ). Accordingly, a sinusoidal signal from the emitter of the first npn type bipolar transistor (11) will not pass to the output of the device. The second n-channel (19) and p-channel (20) field-effect transistors with an isolated gate will be in the open state (the resistance of the channels of these transistors will be several tens of ohms) (Analog electronic key on the field-effect transistor. Electronic resource http: // www .newreferat.com / ref-751-2.html). In this case, a constant level voltage U ₀ from the emitter of the second npn type bipolar transistor (17) will be transmitted to the output of the device.

In the case when the control signal u _control (t) will have a high voltage level (logical "1") (Fig. 2, c), pulses from the short pulse shaper (3) will pass to the output of the first logical element 2I-NOT (5) ) Logical “1” will be written to the RS-trigger (7). In this case, a high voltage level will be established at the direct output of the RS-flip-flop (7) (Fig. 2, g), and a low voltage level will be established at the inverse output of the RS-flip-flop (7) (Fig. 2, h). This will lead to the fact that the second n-channel (19) and p-channel (20) field-effect transistors with an insulated gate will go into the closed state (the channel resistance of these transistors will reach several GΩ). In this case, the voltage U ₀ constant level from the emitter of the second npn type bipolar transistor (17) will not be transmitted to the output of the device. The first n-channel (13) and p-channel (14) field-effect transistors with an insulated gate will go into the open state (the channel resistance of these transistors will be several tens of ohms). Accordingly, the sinusoidal signal from the emitter of the first npn type bipolar transistor (11) symmetrically with respect to the constant level voltage U ₀ will begin to pass to the output of the device. Thus, the output of the device will begin the formation of a radio pulse (Fig. 2, and).

When a low level of the control signal u _control (t) (logical "0") appears at the output of the first logical element 2I-NOT (5), a high voltage level will be established, short pulses will appear at the output of the second logical element 2I-NOT (6). This will lead to the fact that at the direct output of the RS-flip-flop (7) a low voltage level will be established (Fig. 2, g), and a high voltage level will be established at the inverse output of the RS-flip-flop (7) (Fig. 2, h). This will lead to the fact that the first n-channel (13) and p-channel (14) field-effect transistors with an insulated gate will go into a closed state. Accordingly, the sinusoidal signal from the emitter of the first npn type bipolar transistor (11) will cease to pass to the output of the device. The second n-channel (19) and p-channel (20) field-effect transistors with an insulated gate will go into the open state. In this case, the voltage U _{0 of a} constant level is established at the output of the device. The formation of the radio pulse will cease.

In accordance with the description of the operation of the device for the formation of radio pulses, the following should be noted.

1. During the formation of the radio pulse, the sinusoidal signal is tied to a constant voltage, in addition to the output of the device it passes through bipolar transistors connected according to the OK circuit and operating in voltage follower mode, and channels of an n-channel and p-channel field effect transistors with an insulated gate whose channel resistance in the open state is equal to several tens of Ohms and has a dependence close to linear in a wide range of changes in the amplitude of the sinusoidal signal, which eliminates distortion forms of a radio pulse and asymmetry of positive and negative half-periods of a sinusoid in a radio pulse.

2. The time moments of the beginning and end of the radio pulse are monitored by the potential difference between the inverting and non-inverting input terminals of the comparator (from 1 to 3 mV). This suggests that when the amplitude of the sinusoidal signal is several volts, the radio pulse appears almost immediately when a positive half-period of the sinusoidal signal appears and almost immediately ends when the negative half-period of the sinusoidal signal ends. Thus, the leading and trailing edges of the radio pulse repeat the change in the sinusoid, which allows us to keep the shape of the leading and trailing edges of the radio pulse close to sinusoidal.

Thus, the practical feasibility of the claimed device for the formation of radio pulses is proved.

Claims (1)

A device for generating radio pulses containing the first and second npn-type bipolar transistors, the first and second resistors, where the second terminal of the first resistor is connected to the first terminal of the second resistor and the base of the first npn-type transistor, the third and fourth resistors, where the second terminal of the third resistor connected to the first output of the fourth resistor and the base of the second npn type bipolar transistor, the fifth and sixth resistors, a sinusoidal signal source, a capacitor and an inverter, to the input of which a control signal is supplied, representing a stream of rectangular pulses, characterized in that a comparator, a shaper of short pulses, the first and second logic elements 2I-NOT, RS-flip-flop, the seventh resistor, the first and second n-channel field-effect transistors with an insulated gate, the first and second are introduced into it p-channel field-effect transistors with an insulated gate and a voltage stabilizer, while the non-inverting input of the comparator is connected to the output of the sinusoidal signal source and to the first output of the capacitor, the second output of the capacitor it is connected to the connection node of the second output of the first resistor, the first output of the second resistor and the base of the first npn type bipolar transistor, the inverting input of the comparator is connected to a common bus, the output of the comparator is connected to the input of the shaper, the output of which is connected to the first inputs of the first and second logic elements 2 NAND, the second input of the first logic element 2 NAND is connected to the input of the inverter, the output of the inverter is connected to the second input of the second logic element 2 NAND, the output of the first logic element 2 AND NOT connected to the S input of the RS-flip-flop, the output of the second logic element 2 AND NOT connected to the R input of the RS-flip-flop, the first leads of the first and third resistors and the collectors of the first and second npn-type bipolar transistors are connected to the output of the voltage regulator, the second leads the second, fourth, fifth and sixth resistors are connected to a common bus, the first output of the fifth resistor is connected to the emitter of the first npn-type bipolar transistor and the sources of the first n-channel and p-channel field-effect transistors, the first you the water of the sixth resistor is connected to the emitter of the second npn type bipolar transistor and the sources of the second n-channel and p-channel field-effect transistors with an isolated gate, the drains of the first and second n-channel, first and second p-channel field-effect transistors are connected to the first the output of the seventh resistor, the connection node of these elements is the output of the device, the second output of the seventh resistor is connected to a common bus, the gates of the first n-channel and second p-channel field effect transistors The shutter connected to the direct output RS-flip-flop, the gates of the first p-channel and second n-channel field effect transistors with an insulated gate connected to the inverted output of RS-trigger, the voltage regulator input is connected to the positive supply rail voltage.

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