RU2797044C1 - Voltage stabilizer - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention can be used in various power devices for electronic equipment. The voltage stabilizer comprises a control element, a reference voltage source, an output capacitor, an output voltage divider, the first stage of the mismatch amplifier, a separating diode, the second stage of the mismatch amplifier, a protection unit. The regulating element comprises a resistor, an MIS transistor with an induced p- type channel. The reference voltage source comprises two resistors controlled by a programmable stabilitron. The output voltage divider comprises three resistors, one of which is variable. The first stage of the mismatch amplifier comprises a stabilitron, a resistor, a p-n-p-type bipolar transistor. The second stage of the mismatch amplifier comprises a resistor, an npn-type bipolar transistor, a pnp-type bipolar transistor. The protection unit comprises two resistors, a capacitor, a diode, a field-effect transistor with a control pn-junction and an n-type channel.

EFFECT: expanding the functionality.

1 cl, 11 dwg

Description

The field of technology to which the invention belongs

The invention relates to electrical engineering and can be used in various power supply devices for electronic equipment.

State of the art

Known voltage stabilizer (AS 1523991, G05F 1/569), containing: a composite element; reference voltage source; output capacitor; output voltage divider; the first stage of the mismatch amplifier; separating diode; collector resistor; transistor of the second stage of the mismatch amplifier; transistor of the first stage of the mismatch amplifier; zener diode; resistor; power transistor of the composite control element; matching transistor of the composite control element; reference voltage source resistor; reference voltage source zener diode; voltage divider resistor; control voltage diode; control voltage resistor.

The disadvantage of this device is that in the event of a short circuit at the output, the control element operates in a linear mode, that is, it goes into the current stabilization mode. The power dissipation of the control element in this mode usually exceeds the power dissipation in the operating mode, so the short circuit leads to failure of the control element. In addition, at high output power, the current and short circuit power reach significant values, which limits its scope.

The closest analog prototype to the claimed technical solution is a voltage stabilizer (patent RU No. 2472202, IPC G05F 1/10).

The voltage stabilizer contains: a composite control element; reference voltage source; the first stage of the mismatch amplifier; output voltage divider; an n-p-n-type bipolar transistor and a resistor that perform the functions of the second stage of the mismatch amplifier; output capacitor; separating diode; a diode, a resistor, a protective p-n-p-type bipolar transistor, performing the functions of a protection unit, while: the first conclusions of the composite control element and the reference voltage source are connected to the input terminal of the positive polarity of the stabilizer; the second terminal of the composite control element and the first terminals of the first stage of the mismatch amplifier, the output voltage divider, the output capacitor, the cathode of the diode, which is the first terminal of the protection unit, are connected to the output terminal of the positive polarity of the stabilizer; the second terminals of the reference voltage source, the first stage of the mismatch amplifier, the output voltage divider, the output capacitor, the collector of the protective p-n-p-type bipolar transistor, which is the second terminal of the protection unit, the second terminal of the resistor, which is the second terminal of the second stage of the mismatch amplifier, is connected to the negative polarity terminal of the stabilizer ; the emitter of the protective p-n-p-type bipolar transistor, which is the third output of the protection unit, is connected to the third output of the reference voltage source, the fourth output of which is connected to the base of the n-p-n-type bipolar transistor, which serves as the third output of the second stage of the mismatch amplifier; the third terminal of the composite control element is connected to the collector of the n-p-n-type bipolar transistor, which serves as the first terminal of the second stage of the mismatch amplifier, the fourth terminal of which, formed by connecting the first terminal of the resistor and the emitter of the n-p-n-type bipolar transistor, is connected to the cathode of the separating diode; the anode of the separating diode is connected to the third output of the first stage of the mismatch amplifier, the fourth output of which is connected to the third output of the output voltage divider; the base of the protective p-n-p-type bipolar transistor is connected, through a resistor, to the anode of the diode that is part of the protection unit.

The composite control element contains a p-n-p-type power and matching transistors, two resistors and a capacitor, while the emitter of the p-n-p-type power transistor and the first terminals of both resistors serve as the first output of the control element, the second output of which is the collectors of both transistors and the second output of the capacitor, and the third the output, which is the control input, is the first terminal of the capacitor, the second terminal of the second resistor and the base of the p-n-p-type matching transistor, the emitter of which is connected to the base of the p-n-p-type power transistor and the second terminal of the first resistor.

The reference voltage source contains two resistors and a zener diode, while the anode of the zener diode serves as the second terminal of the reference voltage source, and the cathode, together with the second terminal of the first resistor and the first terminal of the second resistor, is the third terminal, the second terminal of the second resistor is the fourth terminal, the first terminal of the first resistor - the first output of the reference voltage source.

The output voltage divider contains three resistors, the second of which is of variable resistance, while the first terminal of the first resistor and the second terminal of the third resistor serve, respectively, as the first and second terminals of the output voltage divider, the third terminal of which is the connection of the second terminal of the first resistor, the first and second terminals the second resistor, the third terminal of which is connected to the first terminal of the third resistor.

The first stage of the error amplifier contains a resistor, a zener diode, a p-n-p-type bipolar transistor, while the cathode of the zener diode serves as the first output of the first stage of the error amplifier, the second output of which is the first output of the resistor, the second output of which is connected to the anode of the zener diode and the emitter of the bipolar p-n-p-type transistor, the collector and base of which serve, respectively, as the third and fourth outputs of the first stage of the mismatch amplifier.

The disadvantage of this device are limited functionality due to:

- low coefficient of voltage stabilization;

- low reliability.

Low reliability due to:

- the implementation of a composite control element based on bipolar transistors, current-controlled devices, whose own energy consumption, and hence the thermal regime, is directly related to the magnitude of the switched current;

- inefficient control of the locking process of the composite control element in the event of an overload of the stabilizer.

Disclosure of invention

The technical result that can be achieved with the proposed invention is to expand the functionality.

The technical result is achieved by the fact that the voltage regulator contains: a reference voltage source, which includes two resistors, while the first output of the first resistor serves as the first output of the reference voltage source, and the second output of the first resistor is connected to the first output of the second resistor, the second output which serves as the fourth output of the reference voltage source; the first stage of the error amplifier is made using a resistor, a zener diode, a p-n-p-type bipolar transistor, while the cathode of the zener diode serves as the first output of the first stage of the error amplifier, the second output of which is the first output of the resistor, the second output of which is connected to the anode of the zener diode and the emitter of the bipolar transistor p-n-p- type, the collector and the base of which serve, respectively, as the third and fourth conclusions of the first stage of the mismatch amplifier; an output voltage divider containing three resistors, the second of which is of variable resistance, while the first terminal of the first resistor and the second terminal of the third resistor serve, respectively, as the first and second terminals of the output voltage divider, the third terminal of which is the connection of the second terminal of the first resistor, the first and second terminals of the second resistor, the third terminal of which is connected to the first terminal of the third resistor; output capacitor; separating diode; the second stage of the error amplifier, which includes an n-p-n-type bipolar transistor, a resistor, the second output of which serves as the second output of the second stage of the error amplifier, and the first output, together with the emitter of the n-p-n-type bipolar transistor, is connected to the fourth output of the second stage of the error amplifier, the third output which serves as the base of a bipolar transistor n-p-n-type; a protection unit, which includes a diode and a resistor, the second terminal of which is connected to the cathode of the diode and serves as the second terminal of the protection unit, while: the first output of the reference voltage source is connected to the input terminal of the positive polarity of the stabilizer; the first conclusions of the first stage of the mismatch amplifier, the output voltage divider, the output capacitor are connected to the output terminal of the positive polarity of the stabilizer; the second conclusions of the first and second stages of the mismatch amplifier, the output voltage divider, the protection unit, the output capacitor are connected to the output of the negative polarity of the stabilizer; the fourth output of the second stage of the mismatch amplifier is connected to the cathode of an isolation diode, the anode of which is connected to the third output of the first stage of the mismatch amplifier; the fourth output of the first stage of the mismatch amplifier is connected to the third output of the output voltage divider; the output of the regulating element, the drain is the second, and the gate connected to the second output of the resistor is the third; to the reference voltage source - a controlled programmable zener diode, the anode of which serves as the second terminal of the reference voltage source, the control electrode is the third, and the cathode is connected to the second terminal of the first resistor and the first terminal of the second resistor; to the second stage of the mismatch amplifier - a p-n-p-type bipolar transistor that allows you to implement the Shiklai circuit, while the emitter of the p-n-p-type bipolar transistor serves as the first output of the second stage of the mismatch amplifier, the collector is connected to the fourth output of the second stage of the mismatch amplifier, and the base is connected to the collector of the bipolar transistor n-p-n-type; to the output voltage divider - the fourth output formed by connecting the third output of the second resistor and the first output of the third resistor; in the protection unit - a capacitor, a field-effect transistor with a control p-n junction and an n-type channel, a second resistor, while the first and second resistors form a high-resistance voltage divider, the middle terminal of which is formed by connecting the second terminal of the second resistor and the first terminal of the first resistor, and connected to the gate of a field-effect transistor with a control p-n junction and an n-type channel, the source and drain of which serve, respectively, as the third and fourth terminals of the protection unit, the first terminal of the second resistor and the anode of the diode are connected to the second terminal of the capacitor, the first terminal of which serves as the first terminal a protection unit, wherein: the fourth output of the output voltage divider is connected to the third output of the reference voltage source, the second output of which is connected to the output of the negative polarity of the stabilizer, and the first output is connected to the first output of the regulating element and the input output of the positive polarity of the stabilizer; the first output of the second stage of the error amplifier is connected to the third output of the regulating element, the second output of which is connected to the first outputs of the first stage of the error amplifier, the output voltage divider, the protection unit, the output capacitor and the output terminal of the positive polarity of the stabilizer; the third output of the protection unit is connected to the third output of the second stage of the mismatch amplifier, and the fourth output is connected to the fourth output of the reference voltage source.

Brief description of the drawings

In FIG. 1 shows a functional diagram of the proposed device.

Figure 2 shows a model for studying the parameters of the circuit of the proposed device in the normal operating mode - in the absence of overload of the regulating element 1 (load resistance 2 ohms).

.Figure 3 presents the results of circuit simulation of the proposed device - the dependence of the output voltage of the stabilizer on the change in supply voltage (U _in = [19.5÷24.5]) with load resistance

.

.Figure 4 shows the results of circuit simulation of the proposed device - the dependence of the output voltage of the stabilizer on the change in supply voltage (U _in = [19.5 ÷ 24.5]) with load resistance

.

.Figure 5 shows the results of circuit modeling of the prototype - the dependence of the output voltage of the stabilizer on the change in supply voltage ( _Uin = [19.5÷24.5]) with load resistance

.

.Figure 6 shows the results of circuit simulation of the prototype - the dependence of the output voltage of the stabilizer on the change in supply voltage ( _Uin = [19.5÷24.5]) with load resistance

.

Figure 7 shows the circuit model of the prototype (load resistance 2 ohms).

Figure 8 presents the results of circuit simulation of the proposed device and the prototype - the dependence of the output voltage of the stabilizer when the load resistance changes from 2 ohms to 0.1 ohms (supply voltage U _in = 20 V).

Figure 9 shows a model for studying the parameters of the circuit of the proposed device in the protection mode of the regulatory element 1 (change in load resistance from 2 ohms to 0.1 ohms).

Figure 10 presents the results of circuit modeling of the proposed device and the prototype - the dependence of the output current of the stabilizer when the load resistance changes from 2 ohms to 0.1 ohms (supply voltage U _in = 20 V).

Figure 11 presents the results of circuit simulation of the proposed device and the prototype - the dependence of the output current of the stabilizer when the load resistance changes from 2 ohms to 0.01 ohms (supply voltage U _in = 20 V).

Implementation of the invention

The voltage stabilizer (figure 1) contains: the control element 1; reference voltage source 2; output capacitor 3; output voltage divider 4; the first stage of the mismatch amplifier 5; separating diode 6; the second stage of the mismatch amplifier 7; protection unit 8, in this case: the first conclusions of the reference voltage source 2 and the regulating element 1 are connected to the input terminal of the positive polarity of the stabilizer; the second output of the regulating element 1 and the first outputs of the first stage of the mismatch amplifier 5, the output voltage divider 4, the protection unit 8, the output capacitor 3 are connected to the positive polarity output of the stabilizer; the second conclusions of the reference voltage source 2, the second stage of the mismatch amplifier 7, the first stage of the mismatch amplifier 5, the output voltage divider 4, the protection unit 8, the output capacitor 3 are connected to the output of the negative polarity of the stabilizer; the fourth and third outputs of the protection unit 8 are connected, respectively, with the fourth output of the reference voltage source 2 and the third output of the second stage of the mismatch amplifier 7, the first output of which is connected to the third output of the regulating element 1; the fourth output of the second stage of the mismatch amplifier 7 is connected to the cathode of the separating diode 6, the anode of which is connected to the third output of the first stage of the mismatch amplifier 5; the fourth output of the first stage of the mismatch amplifier 5 is connected to the third output of the output voltage divider 4, the fourth output of which is connected to the third output of the reference voltage source 2.

The regulating element 1 contains a resistor 10 and an MIS transistor with an induced p-type channel 9, the source of which and the first output of the resistor 10 serve as the first output of the regulating element 1, the drain is the second, and the gate connected to the second output of the resistor 10 is the third.

The reference voltage source 2 contains a resistor 11, the first terminal of which serves as the first terminal of the reference voltage source 2, a resistor 12, the second terminal of which serves as the fourth terminal of the reference voltage source 2, a controlled programmable zener diode 13, the anode of which serves as the second terminal of the reference voltage source 2, the control electrode - third, and the cathode is connected to the second terminal of the resistor 11 and the first terminal of the resistor 12.

The output voltage divider 4 contains resistors 14, 16 and a resistor 15, which is a variable resistance resistor, while the first output of the resistor 14 and the second output of the resistor 16 serve, respectively, as the first and second outputs of the output voltage divider 4, the third output of which is the connection of the second output of the resistor 14, the first and second terminals of the resistor 15, the third terminal of which is connected to the first terminal of the resistor 16 and serves as the fourth terminal of the output voltage divider 4.

The first stage of the error amplifier 5 contains a zener diode 17, the cathode of which serves as the first output of the first stage of the error amplifier 5, a resistor 18, the first output of which serves as the second output of the first stage of the error amplifier 5, a p-n-p-type bipolar transistor 19, the collector and base of which serve, respectively, the third and fourth outputs of the first stage of the mismatch amplifier 5, and the emitter is connected to the second output of the resistor 18 and the anode of the zener diode 17.

The second stage of the error amplifier 7 contains a resistor 22, the second output of which serves as the second output of the second stage of the error amplifier 7, bipolar transistors n-p-n-type 20 and p-n-p-type 21, connected according to the Shiklai scheme, while the emitter of the bipolar transistor p-n-p-type 21 serves as the first output of the second stage of the mismatch amplifier 7, the collector connected to the emitter of the bipolar transistor n-p-n-type 20 and the first terminal of the resistor 22 is the fourth, and the base is connected to the collector of the bipolar transistor n-p-n-type 20, the base of which serves as the third terminal of the second stage of the mismatch amplifier 7.

Protection unit 8 contains: capacitor 23; diode 24; resistors 25, 26; a field-effect transistor with a control p-n-junction and an n-type channel 27, while the first output of the capacitor 23 serves as the first output of the protection unit 8; resistors 25, 26 form a high-resistance voltage divider, the middle output of which is formed by connecting the second output of the resistor 25 and the first output of the resistor 26, and is connected to the gate of a field-effect transistor with a control p-n junction and an n-type channel 27, the source and drain of which serve, respectively, the third and fourth conclusions of the protection unit 8; the first terminal of the resistor 25 and the anode of the diode 24 are connected to the second terminal of the capacitor 23; the second terminal of the resistor 26 is connected to the cathode of the diode 24 and serves as the second terminal of the protection unit 8.

The voltage regulator works as follows.

At the moment the input voltage stabilizer is applied to the input:

- at the gate of a field-effect transistor with a control p-n-junction and an n-type channel 27, protection unit 8, zero potential;

- at the output of the reference voltage source 2, a voltage appears slightly less than stable, but sufficient, due to the low resistance of the channel of the field-effect transistor with a control p-n junction and an n-type channel 27, to transfer the Shiklai composite transistor, the second stage of the mismatch amplifier 7, to ajar state (figure 2).

In this case, current begins to flow through the regulating element 1, charging capacitors 3 and 23.

Due to the shunting action of the diode 24 and the high resistance of the voltage divider on the resistors 25, 26, the gate potential of the field-effect transistor with a control pn-junction and an n-type channel 27 remains zero (908⋅10 ^-9 V, Fig. 2) - the transistor is open, the resistance channel is small.

Since the output voltage is low at the moment of charging the capacitor 3, the voltage at the outputs of the divider 4 is not enough to completely open the controlled programmable zener diode 13 of the reference voltage source 2, as well as the p-n-p-type bipolar transistor 19 of the first stage of the mismatch amplifier 5 and the separating diode 6. Which in turn turn, provides decoupling of the first and second stages of the mismatch amplifier 5, 7, but above all, eliminates the unacceptable abrupt change in current when the capacitor 3 is charged and the possibility of overloading the control element 1.

When capacitor 3 is charged to a level close to the nominal value of the output voltage, the stabilizer switches to the output voltage stabilization mode:

- at the output of the source 2, a stable voltage is established, which ensures, by means of a composite Shiklai transistor, the transfer of the regulating element 1 to the stabilization mode;

- the first stage of the mismatch amplifier 5 and the separating diode 6 come into operation.

Depending on the voltage level at the third output of the output voltage divider 4, by means of the first stage of the mismatch amplifier 5 and the separating diode 6, which has switched to the open state, the voltage across the resistor 22 is changed. As a result, it leads to a change in the voltage at the gate of the MIS transistor with an induced p-type channel 9 of the regulating element 1, compensating for the changed output voltage.

Since the second stage of the mismatch amplifier 7 is made on the basis of a Shiklai composite transistor, this provides a higher sensitivity of the cascade to a change in the base-emitter voltage at a lower value of both the base current and the collector current of the composite transistor than in the case of the prototype.

Moreover, the control element 1, made on the basis of the MIS transistor with an induced p-type channel 9, controlled only by voltage, does not create a second stage of the mismatch amplifier 7, in contrast to the prototype, a shunt effect.

[19,5÷24,5] В) и сопротивления нагрузки (

) предлагаемого стабилизатора напряжения, фиг.3, фиг.4 и прототипа, фиг.5, фиг.6. Анализ параметров прототипа осуществлялся на базе схемотехнической модели, представленной на фиг.7.Figure 3÷6 presents the results of circuit simulation - the dependence of the output voltage of the stabilizer on the change in supply voltage (U _input

[19.5÷24.5] V) and load resistance (

) of the proposed voltage regulator, Fig.3, Fig.4 and prototype, Fig.5, Fig.6. Analysis of the parameters of the prototype was carried out on the basis of the circuit model shown in Fig.7.

The proposed voltage stabilizer is characterized by a voltage stabilization coefficient:

- 9060 with a load resistance of 2 ohms;

- 11038 with a load resistance of 200 ohms.

And the prototype:

- 131 with a load resistance of 2 ohms.

- 139 with a load resistance of 200 ohms;

That is, there is a gain in the voltage stabilization coefficient:

- 69 times with a load resistance of 2 ohms;

- 79 times with a load resistance of 200 ohms.

In the event of a decrease in load resistance, up to a short circuit at the output of the stabilizer:

- the output voltage of the stabilizer drops 1 (Fig.8, curve 1);

- bipolar transistor p-n-p-type 19 and separating diode 6 are closed, which leads to decoupling of the first and second stages of the mismatch amplifier 5, 7 (Fig.9);

- the diode 24 closes, from the second output of the capacitor 23, through a high-resistance voltage divider across resistors 25, 26, a blocking potential (-5.195 V, Fig. 9) is applied to the gate of the field-effect transistor with a control p-n junction and an n-type channel 27, which leads to accelerated locking of both the Shiklai composite transistor, the second stage of the mismatch amplifier 7, and the complete closing of the control element 1 (Fig.8, curve 1, Fig.10, curve 1, Fig.11, curve 1).

While in the prototype there is a transient process (Fig.8, curve 2), during which there is a significant overload of the composite control element (Fig.10, curve 2, Fig.11, curve 2), which undoubtedly reduces the reliability of the prototype .

In the case of the prototype, there is a relatively low reliability. This is due to both inefficient control of the locking process of the composite control element in the event of an overload of the stabilizer, and the implementation of the composite control element based on bipolar transistors. Since bipolar transistors are current-controlled devices, their own power consumption, and hence the thermal regime, is directly related to the magnitude of the switched current. And an attempt to reduce the transistors' own power consumption (increase the efficiency of the device) by using transistors with a lower base current (and therefore a lower allowable dissipation power - will inevitably increase the requirements for increasing heat dissipation), will lead to a decrease in the reliability of the device.

At the same time, MIS transistors with an induced channel are characterized by a number of advantages over bipolar transistors (Oksner E.S. Powerful field-effect transistors and their application. - M .: Radio and communication, 2085, p. 20):

- voltage control (high resistance on the gate side, gate current is almost zero);

- high switching speed;

- almost unlimited output load capacity (if switching speed is not taken into account);

- very low probability of thermal self-heating;

- very low probability of secondary breakdown;

- the admissibility of a sharp change in the drain current.

This means that the proposed device with the same amount of stabilized power as in the case of the prototype will be characterized by higher reliability. Which, in turn, taking into account a higher voltage stabilization coefficient, contributes to the expansion of the functionality of the proposed device.

Claims (1)

A voltage regulator comprising: a reference voltage source, which includes two resistors, wherein the first terminal of the first resistor serves as the first terminal of the reference voltage source, and the second terminal of the first resistor is connected to the first terminal of the second resistor, the second terminal of which serves as the fourth terminal of the reference voltage source ; the first stage of the error amplifier, made using a resistor, a zener diode, a pnp- type bipolar transistor, while the cathode of the zener diode serves as the first terminal of the first stage of the error amplifier, the second terminal of which is the first terminal of the resistor, the second terminal of which is connected to the anode of the zener diode and the emitter of the pnp bipolar transistor - type, the collector and the base of which serve, respectively, as the third and fourth conclusions of the first stage of the mismatch amplifier; an output voltage divider containing three resistors, the second of which is of variable resistance, while the first terminal of the first resistor and the second terminal of the third resistor serve, respectively, as the first and second terminals of the output voltage divider, the third terminal of which is the connection of the second terminal of the first resistor, the first and second terminals of the second resistor, the third terminal of which is connected to the first terminal of the third resistor; output capacitor; separating diode; the second stage of the error amplifier, which includes an npn- type bipolar transistor, a resistor, the second terminal of which serves as the second terminal of the second stage of the error amplifier, and the first terminal, together with the emitter of the npn- type bipolar transistor, is connected to the fourth terminal of the second stage of the error amplifier, the third terminal which serves as the base of an npn- type bipolar transistor; a protection unit, which includes a diode and a resistor, the second terminal of which is connected to the cathode of the diode and serves as the second terminal of the protection unit, while: the first output of the reference voltage source is connected to the input terminal of the positive polarity of the stabilizer; the first conclusions of the first stage of the mismatch amplifier, the output voltage divider, the output capacitor are connected to the output terminal of the positive polarity of the stabilizer; the second conclusions of the first and second stages of the mismatch amplifier, the output voltage divider, the protection unit, the output capacitor are connected to the output of the negative polarity of the stabilizer; the fourth output of the second stage of the mismatch amplifier is connected to the cathode of an isolation diode, the anode of which is connected to the third output of the first stage of the mismatch amplifier; the fourth output of the first stage of the mismatch amplifier is connected to the third output of the output voltage divider, characterized in that the following is introduced into the device: a control element containing a resistor, an MIS transistor with an induced p- type channel, and the source of the MIS transistor with an induced p- type channel, connected to the first output of the resistor serves as the first output of the regulating element, the drain is the second, and the gate connected to the second output of the resistor is the third; to the reference voltage source - a controlled programmable zener diode, the anode of which serves as the second terminal of the reference voltage source, the control electrode is the third, and the cathode is connected to the second terminal of the first resistor and the first terminal of the second resistor; to the second stage of the error amplifier - a pnp- type bipolar transistor, which allows implementing the Shiklai circuit, while the emitter of the pnp- type bipolar transistor serves as the first output of the second stage of the error amplifier, the collector is connected to the fourth output of the second stage of the error amplifier, and the base is connected to the collector of the bipolar transistor npn type; into the output voltage divider - the fourth output, formed by connecting the third output of the second resistor and the first output of the third resistor; in the protection unit - a capacitor, a field-effect transistor with a control pn- junction and an n- type channel, a second resistor, while the first and second resistors form a high-resistance voltage divider, the middle output of which is formed by connecting the second output of the second resistor and the first output of the first resistor and is connected to the gate of a field-effect transistor with a control pn- junction and an n- type channel, the source and drain of which serve, respectively, as the third and fourth terminals of the protection unit, the first terminal of the second resistor and the anode of the diode are connected to the second terminal of the capacitor, the first terminal of which serves as the first terminal of the protection unit , wherein: the fourth output of the output voltage divider is connected to the third output of the reference voltage source, the second output of which is connected to the output of the negative polarity of the stabilizer, and the first output is connected to the first output of the regulating element and the input output of the positive polarity of the stabilizer; the first output of the second stage of the error amplifier is connected to the third output of the regulating element, the second output of which is connected to the first outputs of the first stage of the error amplifier, the output voltage divider, the protection unit, the output capacitor and the output terminal of the positive polarity of the stabilizer; the third output of the protection unit is connected to the third output of the second stage of the mismatch amplifier, and the fourth output is connected to the fourth output of the reference voltage source.

Images