SU561278A1 - Pulsed two-stage tube amplifier - Google Patents

Description

The invention relates to radio engineering. A power amplifier containing several stages of amplification is known, each of which includes an electrovacuum triode fed by an overvoltage :, and large capacitors are used as interstage communication elements. The disadvantages of this amplifier are large dimensions of elements and large parasitic capacitances. Closest to the proposed infrared two-stage tube lamp containing two similar amplification stages on vacuum triodes, the anodic circuit of each of which includes two consecutive twoHCTopei, the connection point of which is connected via a capacitor and a resistor to the source of a pulsed signal and a capacitor and a resistor and a common bus included a zener diode, with the anode of the vacuum triode of the first cascade connected via a transition capacitor to the grid of the vacuum triode of the second cascade. The disadvantage of this amplifier is the presence of large parasitic capacitances. The purpose of the invention is to reduce the parasitic capacitance of the transition capacitor in that in a pulsed two-stage amplifier containing two similar amplification stages on vacuum triodes, two resistors are connected in series to the anode circuit of each of them. Pa, the connection point of which is connected via a capacitor and a resistor to a pulse signal source, and between the coefficients of the capacitor and resistor and the common bus is connected a stub 1 liter, and the anode of the vacuum triode of the first cascade is connected via a transition capacitor to the grid of the vacuum triode of the second cascade a transitional capacitor includes a correction circuit, consisting of two inductively coupled branches, each of which consists of two series-connected inductive coils, and between and the coil connections of each inductive 1vtv include additional capacitors, and parap

The coils of the second inductive branch included resistors.

The principal electrical circuit of the amplifier is shown in the drawing.

The amplifier contains vacuum triodes 1, 2, resistors, capacitors 13–19, zener diodes 2O, 21, shading coils 22, 23, and 24, 25 inductively coupled to each other. Capacitors 26, 27 may be included to provide a predetermined amplitude-frequency characteristic. The inputs 28, 29 are supplied with power supply pulses, the input is a 30 input signal, and the output sirnal is removed from output 31. The power sources are not shown in the diagram.

The amplifier works as follows.

The negative bias applied to the control grid of triode 1 is chosen such that it works on the linear part of the anode-grid characteristic. Through resistors 3 and 4, a positive anode voltage is applied to its anode. Through a resistor 5, a capacitor 15, a resistor 3, a capacitor 17 to the control grid, tp1 | ode 2, pulses of positive polarity stabilized by a stabilizer, 2O with a duration slightly longer than the amplified pulse and C} are delivered. The amplitude of this pulse is selected depending on the polarity of the pulses applied to the grid of the triode 1 grid. Triode 2 is covered by a negative voltage supplied through the resistor 12 from the bias source. A positive anode voltage and a pulse voltage from a source of pulse signals are applied to its anode, as well as to the anode of triode 1. To expand the dynamic range of amplitudes of amplification of video signals by a triode. 2 when applying to the control grid of triode 1 negative impulses, the amplitude of the pedestrian pulses should be such that the operating point of the control grid of triode 2 is set to the initial part of its anode-grid characteristic. When amplifying positive pulses, the operating point of the control grid of triode 2 must be set to the final part of the linear part of the anode-grid characteristic.

For example, when applying to the control i grid of the triode 1 video pulses of the negative

body polarity with a steep front and pedestrian pulses that force the work of triode 1 across the anode and triode 2 across the grid, on the resistor 3, amplified video signals are formed with

by pedestal positive polarity C of resistor 3 through capacitor 17, they enter the control grid of the triode. 2, The capacitance of the capacitor 17 is chosen such that its charge time is constant due to the grid pulses. The coil was an order of magnitude longer than the transmitted onts, but the parasitic capacitance was so smaller than the total output capacitance of triode 1 and the input capacitance of triode 2, so that its parasitic capacitance did not have a significant effect on the establishment time of the amplified video impulse. The capacitance of the capacitor 18 is chosen for an order of magnitude larger than the capacitance of the capacitor 17. The parasitic capacitance of the capacitor 18 has little effect on increasing the front of amplified pulses | since it is connected to the capacitor 17 through inductive wires 22 and 23, the inductance of which is large.

To reduce the inductive impedance of the coils along the signal circuit, it is necessary to ensure maximum connection between them. For this, the coils should be wound with two wires on one wire. frame and apply ferrite cores. To eliminate the oscillatory charge of the parasitic capacitance of capacitor 18, the inductor 2 3 was shunted by a resistor 10, whose resistance is an order of magnitude greater than the resistance of resistor 3. After the voltage on the capacitor 18 is set relative to the chassis, the capacitor 17 becomes a bridged capacitor 18 through the inductors. To extend the range to lower frequencies, capacitor 18 is connected to capacitor 18 through inductors 24 and 25, the capacitor 19 is connected, the capacitance of which is much higher than capacitor 18. Coils 24 and 25 are in relation to coils 22 and 23 and are biased by resistor 11 .

I

Connecting the correction circuit parallel to the transition capacitor allows you to select a transition capacitor with a minimum parasitic capacitance, and thus, increase the speed of the amplifier, reduce the distortion of the top of the pulses at high pulse grid currents.

On the resistor 6, triode amplified video pulses and a portion of the pedestal pulse of negative polarity are formed. By choosing the amplitude of the pedestal impedance of 1 ca fed to the input 29, it is possible to compensate a part of the transducer impedance fed to the input 2Н, and then

on coidelator 16, only a useful amplified video pulse is generated.

Claims (1)

Claims. A pulsed two-stage tube amplifier containing two similar amplification stages on vacuum triodes, and two resistors are connected in series to the anode circuit each, the connection point through which the capacitor and the resistor are connected to the signal source, and between the connection point of the mentioned capacitor and resistor and common bus included stabil-. The throne, the anode of the vacuum triode of the hiatus cascade, is connected via a transition capacitor to the grid of the vacuum cable of the second cascade, characterized in that, in order to reduce the parasitic capacitance of the transition capacitor, the corrective transition circuit is connected to the parallel transition capacitor consisting of two inductively connected branches, each of which consists of two series-connected inductors, and additional capacitors are connected between the points of connection of the inductors of each inductive branch, and parallel to the coils of the second inductive branch included resistors. L23 8} -0 +