EA026493B1 - Output stage of audio-frequency power amplifier - Google Patents

Abstract

The invention is related to electronics and radio engineering, namely, to electronic amplifiers, in particular, to Hi-Fi, Hi-End audio-frequency amplifiers of class A. A significant reduction of inertia in maintaining a constant through current value is attained, which improves stability of the output stage operation. The output stage comprises a first and a second voltage followers connected between power terminals. The point of connection of said followers is the output of the stage, and control inputs of the first and second voltage followers are connected to each other by a bias resistor. The output stage includes also a third voltage follower the input of which is connected to the input of the output stage, and the output is connected to the control input of the first voltage follower; a first current generator the output of which is connected to the control input of the second voltage follower; a second current generator the output of which is connected to the input of the first current generator and a set-up resistor; a power transformer with two windings, each having a central tap; the ends of the first winding are connected, through the first rectifier unit, to the first power terminal, and the ends of the second winding are connected, through the second rectifier unit, to the second power terminal, and the central taps of said windings are connected to the common power terminal; a current sensor capable of current measurement through the central taps of the transformer, the sensor output being connected to the control input of the second current generator.

Description

The claimed invention relates to electronics and radio engineering, namely to electronic amplifiers, in particular to sound frequency amplifiers Ηί-Ρί, Ηί Εηά class A.

State of the art

In class AB amplifiers, the main way to reduce current instability at the operating point is thermal feedback (Douglas Self Design of audio frequency power amplifiers, M., DMK Press, 2009). The bias voltage is generated in the temperature sensor, which is installed on the heat sink. Such a system has the following disadvantages: inertia and approximation of the sensor temperature to the quiescent current. Such a system only simulates a change in current in the output stage. These circuits do not allow for direct adjustment of the quiescent current at the operating point.

Disclosure of invention

The technical problem to which the claimed technical solution is directed is to increase the accuracy and reduce the inertia of measuring the quiescent current of the output stage.

The technical result achieved by the claimed technical solution is a significant reduction in the inertia of maintaining a constant value of the through current, which leads to an increase in the stability of the output stage.

The essence of the output stage is that it contains a serial circuit of the first and second voltage followers connected between the first and second DC power inputs, and the connection point of the first and second voltage followers is the output of the cascade. It differs in that the control inputs of the voltage followers are interconnected by a bias resistor. The output stage also contains a third voltage follower, the input of which is connected to the input of the output stage, and the output to the control input of the first voltage follower;

a first current generator, the output of which is connected to the control input of the second voltage follower;

a second current generator, the output of which is connected to the input of the first current generator and a driving resistor;

power transformer with two windings, each of which is made with an average output. The ends of the first winding through the first rectifier unit are connected to the first power input, and the ends of the second winding through the second rectifier unit are connected to the second power input. In this case, the middle terminals of said windings are connected to a common power terminal;

a current sensor configured to measure current through the middle terminals of the transformer, the output of the current sensor being connected to a control input of a second current generator.

The current sensor can be installed in the gap of the connection of the middle terminal of the first transformer winding with the common power output, or in the gap of the connection of the middle terminal of the second transformer winding with the common power terminal, or in the gap of the connection of the first rectifier unit with the first power input, or in the gap of the connection of the second rectifier unit with a second power input.

The second current generator is preferably made in the form of a bipolar transistor, the base of which is connected to the output of the operational amplifier, the non-inverting input of which is connected to the current sensor through the smoothing CS filter, and the inverting input is connected to the reference voltage source.

The output stage can be performed as follows:

the first voltage follower is made in the form of a bipolar transistor of the p-p-η type, and the second voltage follower is made in the form of a bipolar transistor of the p-p-p type, with the connected emitters of these voltage repeaters being the output of the output stage;

an accelerating capacitor and a series-connected shunt resistor and thermal relay are connected in parallel with the bias resistor;

the third voltage follower is made in the form of an η-type field effect transistor, the source of which is connected to the base of the transistor of the first voltage follower, and the gate is connected to the input of the output stage;

the first current generator is made in the form of a bipolar transistor of the pnp type, the base of which is connected to the output of the second current generator, the collector with the base of the transistor of the second voltage follower;

the current sensor is made in the form of a resistor connected between the midpoint of the second transformer winding and the common power output, the output of the current sensor being the connection point of said resistor with the midpoint of the second transformer winding;

the first rectifier unit is two rectifier diodes, the connected cathodes of which are connected to the first power input, and the anodes of these diodes are connected to the ends of the first winding of the transformer;

the second rectifier unit consists of two rectifier diodes, the connected anodes of which are connected to the second power input, and the cathodes of these diodes are connected to the ends of the second transformer coil.

The output stage can also be performed as follows: the stage is equipped with an additional DC power input;

the first voltage follower is made in the form of a pp-type bipolar transistor, and the second voltage follower is made in the form of a pp-bipolar transistor, wherein the connected emitters of these voltage followers are the output of the cascade;

an accelerating capacitor and a series-connected shunt resistor and thermal relay are connected in parallel with the bias resistor;

the third voltage follower is made in the form of a p-type field effect transistor, the source of which is connected to the base of the transistor of the first voltage follower;

the first current generator is made on an electronic lamp, the cathode of which is connected to the base of the transistor of the second voltage follower;

the output stage contains a first filter, in which the first input is connected to the input of the cascade, the second input is connected to the cathode of the electronic lamp, the first output is connected to the control grid of the electronic lamp, and the second output is connected to the gate of the transistor of the third voltage follower;

the first current generator also contains an adjustable voltage regulator made in the form of a p-type field effect transistor, the drain of which is connected to an additional power input, the source is connected to the anode of the electron lamp, and the gate is connected to the output of the second current generator, and the gate and source of the said transistor are connected through zener diode;

the first current generator also comprises a booster capacitor connected between the cathode of the electron lamp and the gate of the transistor of an adjustable voltage regulator;

the current sensor is made in the form of a resistor connected between the midpoint of the first transformer winding and the common power output, and the output of the current sensor is the connection point of said resistor with the midpoint of the first transformer winding;

the first rectifier unit is two rectifier diodes, the connected anodes of which are connected to the first power input, and the cathodes of these diodes are connected to the ends of the first transformer winding;

the second rectifier unit is two rectifier diodes, the connected cathodes of which are connected to the second power input, and the anodes of these diodes are connected to the ends of the second winding of the transformer;

the output stage also contains the first and second protective zener diodes, the first protective zener diode connected between the control input and the output of the third voltage follower, and the second protective zener diode connected between the cathode and the control grid of the electronic lamp.

Brief Description of the Drawings

In FIG. 1 shows a diagram of the claimed output stage; in FIG. 2 is a cascade diagram of example 1; in FIG. 3 is a diagram of a zero setting; in FIG. 4 is a cascade diagram of example 2; in FIG. 5 is a diagram of a first filter.

Options for the implementation of the output stage.

The output stage of the audio frequency power amplifier (Fig. 1) contains an analog input (1); analog output (2);

the first (14) and second (15) DC power inputs, respectively, with voltages VI, ν ₂ , preferably VI = -ν ₂ ;

first (3) and second (4) voltage followers connected in series between the first (14) and second (15) power inputs. In this case, the first voltage follower (3) is connected to the first power input (14), and the second voltage follower (4) is connected to the second power input (15). The connection point of two voltage followers (3, 4) is the analog output (2) of the declared output stage. The control inputs of the voltage followers (3, 4) are interconnected by a bias resistor (5);

the third voltage follower (6), the output of which is connected to the control input of the first voltage follower (3). A repeater (6) is also connected to the first power input (14). The input of the third voltage follower (6) is connected to the analog input (1) of the declared output stage;

the first current generator (7), the output of which is connected to the control input of the second voltage follower (4). Also, the first current generator (7) is connected to the second power input (15);

a second current generator (8), which is a controlled current generator. The output of the second current generator (8) is connected to the input of the first current generator, and through the driving resistor (9) is connected to the second power input (15). The second current generator is configured to smoothly increase the output current when the power is turned on;

power transformer (10) with two windings, each of which is made with an average output. The ends of the first winding through the first rectifier unit (11) are connected to the first power input (026493) (14), and the middle terminal of this winding is connected to a common terminal (zero power). The ends of the second winding through the second rectifier unit (12) are connected to the second power input (15), and the middle terminal of this winding is connected to the common terminal (zero power) through the current sensor (13). The current sensor (13) is configured to measure current through the middle terminals of the transformer (10) and therefore can also be placed in the open connection of the middle output of the first winding with the common output (power zero), as well as in the open connection of one of the rectifier blocks (11 or 12) with appropriate power input. The output of the current sensor (13) is connected to the control input of the second current generator (8).

A power transformer (10), rectifier units (11, 12), a current sensor (13) and a second current generator (8) are a quiescent current controller.

Case Studies

Example 1

U ₁ = +24 V, U ₂ = -24 V. The first voltage follower (3) is made in the form of a bipolar transistor p-p-p type 28C5200. and the second voltage follower (4) is made in the form of a bipolar transistor rp-r type 28L1943 (Fig. 2). Moreover, the connected emitters of these voltage followers (3, 4) are the output (2).

In parallel to the bias resistor (5), an accelerating capacitor (20) and a series-connected shunt resistor (21) and a thermal relay (22) are connected. The mentioned series circuit is designed to transfer the output stage to the class AB operation mode when transistors are overheated.

The third voltage follower (6) is made in the form of a n-type field transistor ΙΚΡ630, the source of which is connected to the base of the transistor of the first voltage follower (3), and the gate through the zero-setting circuit (23) is connected to the input (1) of the inventive output stage.

The zero setting circuit (23) is a capacitor (40) connected between its signal input (41) and output (42) (Fig. 3). The signal input (41) is connected to the input stage (1) of the output stage, and the signal output (42) is connected to the gate of the transistor of the third voltage follower (6).

The zero setting circuit (23) also contains an operational amplifier (44), the output of which through a resistor is connected to the output (42) of the circuit. The non-inverting input of the operational amplifier (44) is connected through a resistance to a common output (power zero). The inverting input of the operational amplifier (44) is connected through a series circuit of two resistors (45, 46) to the control input (43) of the circuit (23), which in turn is connected to the output (2) of the claimed output stage. The inverting input and output of the operational amplifier (44) are connected by a capacitor. The connection point of the resistors (45, 46) is connected to a common terminal (zero power) through a circuit of parallel-connected capacitor and two diodes, one of these diodes being connected to zero by the anode and the other by the cathode.

The first current generator (7) is made in the form of a bipolar transistor of type 28C5200, the base of which is connected to the output of the second current generator (8), the collector with the base of the transistor of the second voltage follower (4), and the emitter through the resistance with the second power input (15). The base of the transistor of the first current generator (7) is connected by a capacitor to the second power input (15).

The second current generator (8) (controllable) is made in the form of a bipolar transistor (24) of a rpn type, the base of which is connected to the output of the operational amplifier (25), the collector with a driving resistor (9), and the emitter through a resistor - with the first power input (14).

The signal from the current sensor (13) is fed to the non-inverting input of the operational amplifier (25) through the smoothing CS filter (26), and the potential of the reference voltage source (27) is supplied to the inverting input.

The reference voltage source (27) is made in the form of a stable current generator to the reference diode (28). The source (27) contains a KT9115 type bipolar transistor, the emitter of which is connected to the first power input (14), and the base is connected through a resistor to a common output (power zero). The collector of the aforementioned transistor is connected through a circuit of parallel-connected capacitors (29), a reference diode (28), and a tuning trim (30) to a common terminal (power zero). The output of the reference voltage source (27) is the tuning resistance engine (30).

The capacitor (29) is designed for smooth installation of the reference voltage when you turn on the circuit and change the position of the trimmer resistance engine (30). When you turn on the power at the output of the reference voltage source (27), the reference voltage begins to gradually increase, which is supplied to one of the inputs of the operational amplifier (25). At the same time, a smooth increase in current occurs at the measuring resistance of the current sensor (13).

The current sensor (9) is made in the form of a resistor connected between the midpoint of the second winding of the transformer (10) and the common output (zero power). The output of the current sensor is the connection point of the said resistor of this sensor with the midpoint of the second winding of the transformer (10).

The first rectifier unit (11) is two rectifier diodes, the connected cathodes of which are connected to the first power input (14). The anodes of these diodes are connected to the ends of the first winding of the transformer (10).

The second rectifier unit (12) is two rectifier diodes, the connected anodes of which are connected to the second power input (15). The cathodes of these diodes are connected to the ends

- 3 026493 second winding of the transformer (10).

Rectifier diodes are made in the form of 8K30100 diodes.

Example 2

Similar to example 1. In this case, to power the second current generator (8), including its operational amplifier (25) and the reference voltage source (27), the output stage is equipped with third and fourth DC power inputs with voltages, respectively, +15 V and -15 V.

Example 3

VI = -45 V, ν ₂ = +45 V. The output stage is equipped with an additional DC power input with a voltage of +110 V (Fig. 3). The first voltage follower (3) is made in the form of a bipolar transistor rpr type 28L1943, and the second voltage follower (4) is made in the form of a bipolar transistor rpp type 28C5200. Moreover, the connected emitters of these voltage followers (3, 4) are the output (2).

In parallel to the bias resistor (5), an accelerating capacitor (20) and a series-connected shunt resistor (21) and a thermal relay (22) are connected. The mentioned series circuit is designed to transfer the output stage to the class AB operation mode when transistors are overheated.

The third voltage follower (6) is made in the form of a p-type field transistor ΙΚΡ9630, the source of which is connected to the base of the transistor of the first voltage follower (3), and the drain is connected to the first power input (14).

The first current generator (7) is made on an electron lamp (31) 6C19P, the cathode of which is connected to the base of the transistor of the second voltage follower (4). The lamp (31) is also a cathode follower.

The electron lamp (31) together with the third voltage follower (6) are the cathode-source follower. The output stage also contains a first filter (32), in which the first input is connected to the input (1) of the cascade through the zero-setting circuit (23), the second input is connected to the cathode of the electron lamp (31), and the first output is connected to the control grid of the electron lamp (31), and the second output is connected to the gate of the transistor of the third voltage follower (6). The first filter (32) in combination with the input capacitance of the control grid — the cathode of the electron tube (31) and the input capacitance input – output of the third voltage follower (6) —is designed to suppress sampling noise at the output (2) of the inventive cascade.

The first filter (32) is made in the form of a series circuit of two resistors (50, 51), which connects the first input of this filter (32) through the resistor (52) to the first output of this filter, and connects the first input of this filter through the resistor (53) ( 32) with the second output of this filter (Fig. 5). The connection point of the resistors (52) and (53) through a capacitor (54) is connected to a common terminal (power zero). The second input of the first filter (32) is connected through a capacitor (55) to the connection point of the resistors (50) and (51).

The first current generator (7) also contains an adjustable voltage stabilizer (33), the signal input of which is connected to an additional power input (16), and the output is connected to the anode of the electron lamp (31). The voltage stabilizer (33) is equipped with a control input, which is connected through the second (34) and third (35) filters to the output of the second current generator (8). The second filter (34) is designed to reduce sampling noise, and the third filter (35) is designed to filter the anode voltage.

The adjustable voltage stabilizer (33) is made in the form of a p-type field effect transistor, the gate of which is a control input, and the drain is a signal input. In this case, the gate and source of said transistor are connected through a zener diode.

The second filter (34) is made in the form of a series circuit of two resistors, the connection point of which through a capacitor is connected to a common output (power zero).

The third filter (35) is made in the form of a series circuit of three resistors, the connection point of which through the capacitors is connected to a common output (power zero). Through the capacitor with the common output is connected and the output of the filter connected to the second current generator (8).

The first current generator (7) also comprises a boost booster capacitor (36) connected between the cathode of the electron tube (31) and the voltage regulator control input (33);

The zero setting circuit (23) is a capacitor (40) connected between its signal input (41) and output (42) (Fig. 3). The signal input (41) is connected to the input stage (1) of the output stage, and the signal output (42) is connected to the gate of the transistor of the third voltage follower (6).

The zero setting circuit (23) also contains an operational amplifier (44), the output of which through a resistor is connected to the output (42) of the circuit. The non-inverting input of the operational amplifier (44) is connected through a resistance to a common output (power zero). The inverting input of the operational amplifier (44) is connected through a series circuit of two resistors (45, 46) to the control input (43) of the circuit (23), which in turn is connected to the output (2) of the claimed output stage. The inverting input and output of the operational amplifier (44) are connected by a capacitor. The connection point of the resistors (45, 46) is connected to a common terminal (zero power) through a circuit of parallel-connected capacitor and two diodes, one of these diodes being connected to zero by the anode and the other by the cathode.

- 4 026493

The second current generator (8) (controlled) is made in the form of a bipolar transistor (24) of the pnp type, the base of which is connected to the output of the operational amplifier (25), the collector - through a driving resistor (9) - with an additional power input (16 ), and the emitter through a resistor with the first power input (14).

The signal from the current sensor (13) is fed to the non-inverting input of the operational amplifier (25) through the smoothing CS filter (26), and the potential of the reference voltage source (27) is supplied to the inverting input.

The reference voltage source (27) is made analogously to example 1, except that the emitter of the source transistor (27) is connected to the second power input (15).

The current sensor (13) is made in the form of a resistor connected between the midpoint of the first winding of the transformer (10) and the common output (zero power). The output of the current sensor (13) is the connection point of the mentioned resistor of this sensor with the midpoint of the first winding of the transformer (10).

The first rectifier unit (11) is two rectifier diodes, the connected anodes of which are connected to the first power input (14). The cathodes of these diodes are connected to the ends of the first winding of the transformer (10).

The second rectifier unit (12) is two rectifier diodes, the connected cathodes of which are connected to the second power input (15). The anodes of these diodes are connected to the ends of the second winding of the transformer (10).

Rectifier diodes are made in the form of 8K30100 diodes.

The output stage also contains the first (37) and second (38) protective zener diodes. The first protective zener diode (37) is connected between the control input and the output of the third voltage follower (6). The second protective zener diode (38) is connected between the cathode and the control grid of the electron lamp (31). Protective zener diodes (37, 38) are designed to protect against short circuit.

The implementation of the structural elements of the claimed invention is not limited to the above examples.

Description of the output stage.

When using the claimed output stage, its input is connected to the analog output of the sound source, mainly to the output of the digital-to-analog converter, and the output to the sound reproducing device. The power inputs are connected to the corresponding terminals of the power source. When the power is turned on, a smooth increase in current occurs on the current sensor (13).

If the supply voltage VI> ν ₂ , then the current from the first winding of the power transformer (10) through the first rectifier block (11) is sent to the power bus with voltage VI. Further, the current through the first (3) and second (4) voltage followers flows into the power rail with a voltage of ν ₂ , from where through the second rectifier unit (12) is sent to the second winding of the power transformer (10). Further, from the midpoint of the second winding of the transformer (10), the current is directed to the current sensor (13). The voltage corresponding to the measured current value is supplied from the current sensor (13) to the control input of the second current generator (8), which regulates the current through a driving resistor (9).

At the same time, in the output stage performed according to example 1, the voltage from the resistor of the current sensor (13) is supplied through a KS filter (26) to the non-inverting input of the operational amplifier (25). In the cascade of example 1, the mismatch signal of the reference and measured voltage is supplied to the base of the transistor (24), which regulates the current through the master resistor (9) depending on the mentioned mismatch signal.

If at a certain point in time the controlled current increases, then the second current generator (8) will increase its output current. The voltage at the driving resistor (9) will increase. This will lead to a decrease in the current of the first current generator (7) and the current through the resistor (5), which is responsible for the bias of the first (3) and second (4) voltage followers. The voltage at the control inputs of these repeaters (3, 4) will decrease, which will lead to a decrease in current through the repeaters (3, 4), that is, to a decrease in current and through the current sensor (13).

When executing the output stage according to example 2, if at a certain point in time the controlled current increases, then the second current generator (8) will increase its output current. The voltage drop across the master resistor (9) will increase. Therefore, the voltage on the voltage regulator (33) will decrease. This will lead to a decrease in the anode voltage on the electron lamp (31), which will lead to a decrease in the cathode current of this lamp (31) and the current through the resistor (5).

In the absence of a signal at the input (1), the analog output (2) has a midpoint potential between VI and ν ₂ . Since, according to the preferred embodiment, VI = -ν ₂ , in the absence of a signal at the input (1), the analog output (2) has a ground potential. When a signal is applied to input (1), it is repeated by the voltage at the output (2).

The protection against short circuit described in example 2 works as follows. If a positive polarity signal with a high level is supplied to the input (1), which passes through the first filter (32) and enters the lamp control grid (31), then the emitters of the voltage follower transistors (3, 4) have a zero potential (short circuit mode) . The base of the transistor of the second voltage repeater (4) and the lamp cathode (31) will have a potential slightly greater than zero. In this case, the second protective zener diode (38) will begin to limit the input signal so as to reduce the power dissipated in the second voltage follower (4). If a negative polarity signal with a high level is supplied to the input (1), the input signal will be limited by the first protective zener diode (37).

Thus, from the foregoing, it follows that in the claimed output stage the claimed technical result: a significant reduction in the inertia of maintaining a constant value of the through current, which leads to increased stability of the cascade is achieved due to the fact that the output stage contains a serial circuit of the first and second voltage followers connected between the first and second DC power inputs, and the connection point of the first and second voltage followers is the output of the cascade. In this case, the control inputs of the voltage followers are interconnected by a bias resistor. The output stage also contains a third voltage follower, the input of which is connected to the input of the output stage, and the output to the control input of the first voltage follower;

a first current generator, the output of which is connected to the control input of the second voltage follower;

a second current generator, the output of which is connected to the input of the first current generator and a driving resistor;

power transformer with two windings, each of which is made with an average output. The ends of the first winding through the first rectifier unit are connected to the first power input, and the ends of the second winding through the second rectifier unit are connected to the second power input. In this case, the middle terminals of said windings are connected to a common power terminal;

a current sensor configured to measure current through the middle terminals of the transformer, the output of the current sensor being connected to a control input of a second current generator.

Due to the direct regulation (measurement and change) of the quiescent current, there is no regulation inertia, and the push-pull end stage operates with a constant through current, and its accuracy does not depend on the temperature and voltages of the first (3) and second (4) voltage followers. The driver stage (in example 2, this is an electronic lamp (31) and the third voltage follower (6)) occurs in class A.

Industrial applicability

The author made prototypes of the claimed device, tests of which confirmed the achievement of the technical result.

The claimed invention is implemented using industrially produced devices and materials, can be assembled at any radio engineering enterprise and will be widely used in radio engineering.

Claims (5)

CLAIM 1. The output stage of the audio frequency power amplifier, containing a serial circuit of the first (3) and second (4) voltage repeaters, connected between the first (14) and second (15) DC power inputs, and the connection point of the first (3) and second ( 4) the voltage follower is the output (2) of the cascade, characterized in that the control inputs of the voltage followers (3, 4) are interconnected by a bias resistor (5), while the output stage also contains a third voltage follower (6), the input of which is connected to input (1) output of the cascade and an output - with a control input of the first voltage follower (3); the first current generator (7), the output of which is connected to the control input of the second voltage follower (4); a second current generator (8), the output of which is connected to the input of the first current generator and a driving resistor (9); a power transformer (10) with two windings, each of which is made with a middle terminal, while the ends of the first winding through the first rectifier block (11) are connected to the first power input (14), and the ends of the second winding through the second rectifier block (12) are connected with a second power input (15), while the middle terminals of said windings are connected to a common power terminal; a current sensor (13), configured to measure current through the middle terminals of the transformer (10), and the output of the current sensor (13) is connected to the control input of the second current generator (8). 2. The output stage according to claim 1, characterized in that the current sensor is installed in the open connection of the middle output of the first winding of the transformer (10) with a common power output, or in the open connection of the middle output of the second winding of the transformer (10) with a common power output, or into the gap in the connection of the first rectifier block (11) with the first power input, or in the gap of the connection of the second rectifier block (11) with the second power input. 3. The output stage according to claim 1, characterized in that the second current generator (8) is made in the form of a bipolar transistor (24), the base of which is connected to the output of the operational amplifier (25), the non-inverting input of which through a smoothing CS filter (26) connected to a current sensor (13), and the inverting input to a voltage reference source (27). 4. The output stage according to claim 3, characterized in that the first voltage follower (3) is made in the form of a bipolar transistor of the p-p-p type, and the second voltage follower (4) is made in the form of a bipolar transistor of the p-p-p type, the connected emitters of these voltage followers (3, 4) are the output (2) of the output stage; an accelerating capacitor (20) and a series-connected shunt resistor (21) and a thermal relay (22) are connected in parallel with the bias resistor (5); the third voltage follower (6) is made in the form of a p-type field effect transistor, the source of which is connected to the base of the transistor of the first voltage follower (3), and the gate is connected to the input stage (1) of the output stage; the first current generator (7) is made in the form of a bipolar transistor of the pnp type, the base of which is connected to the output of the second current generator (8), the collector with the base of the transistor of the second voltage follower (4); the current sensor (9) is made in the form of a resistor connected between the midpoint of the second winding of the transformer (10) and a common power output, and the output of the current sensor is the connection point of the aforementioned resistor with the midpoint of the second winding of the transformer (10); the first rectifier unit (11) is two rectifier diodes, the connected cathodes of which are connected to the first power input (14), and the anodes of these diodes are connected to the ends of the first transformer winding (10); the second rectifier unit (12) is two rectifier diodes, the connected anodes of which are connected to the second power input (15), and the cathodes of these diodes are connected to the ends of the second winding of the transformer (10). 5. The output stage according to claim 3, characterized in that the stage is equipped with an additional DC power input; the first voltage follower (3) is made in the form of a bipolar transistor of the r-p-p type, and the second voltage follower (4) is made in the form of a bipolar transistor of the r-p-p type, while the connected emitters of these voltage repeaters (3, 4) are output (2) of the cascade; an accelerating capacitor (20) and a series-connected shunt resistor (21) and a thermal relay (22) are connected in parallel with the bias resistor (5); the third voltage follower (6) is made in the form of a p-type field effect transistor, the source of which is connected to the base of the transistor of the first voltage follower (3); the first current generator (7) is made on an electronic lamp (31), the cathode of which is connected to the base of the transistor of the second voltage follower (4); the output stage contains a first filter (32), in which the first input is connected to the input (1) of the cascade, the second input is connected to the cathode of the electron lamp (31), the first output is connected to the control grid of the electron lamp (31), and the second output is connected to the gate transistor of the third voltage follower (6); the first current generator (7) also contains an adjustable voltage stabilizer (33), made in the form of a p-type field effect transistor, the drain of which is connected to an additional power input (16), the source is connected to the anode of the electron lamp (31), and the gate is connected to the output a second current generator (8), wherein the gate and source of said transistor are connected through a zener diode; the first current generator (7) also contains a boost booster capacitor (36) connected between the cathode of the electron lamp (31) and the gate of the transistor of an adjustable voltage regulator (33); the current sensor (9) is made in the form of a resistor connected between the midpoint of the first winding of the transformer (10) and the common power output, and the output of the current sensor is the connection point of the aforementioned resistor with the midpoint of the first winding of the transformer (10); the first rectifier unit (11) is two rectifier diodes, the connected anodes of which are connected to the first power input (14), and the cathodes of these diodes are connected to the ends of the first transformer winding (10); the second rectifier unit (12) is two rectifier diodes, the connected cathodes of which are connected to the second power input (15), and the anodes of these diodes are connected to the ends of the second transformer winding (10); the output stage also contains the first (37) and second (38) protective zener diodes, the first protective zener diode (37) connected between the control input and the output of the third voltage follower (6), and the second protective zener diode (38) connected between the cathode and the electronic control grid lamps (31).