DE3045282C2 - - Google Patents

Description

The invention relates to an electrical power vibration generator according to the preamble of claim 1.

The invention can be used in various systems be in which a generation and amplification of electrical Vibrations is required. Is particularly advantageous the use of the invention in high frequency radio and TV channels, intermediate channels and other similar Devices that use electron tubes or transistors are set up.

In the development of electrical vibration generators the main goal is to get a maximum output performance with the greatest possible power amplification factors, which is guaranteed by the individual stages of the generator are going to get. As is known, the gain factor is each step the lower the higher the operating frequency of the generator and the wider the required Durchlaßbe is rich. Accordingly, to increase the output power, especially in the high frequency broadband generators, the number of levels can be increased.

At the same time one is in the development of electric Schwin generation generators naturally endeavors to measure their dimensions and Reduce weights, increase safety and costs belittling. With an increase in the number of generators levels, however, these characteristics will definitely deteriorate.  

As a result, the search continues in the development of electrical Vibration generators there, the stated contradiction between the number of strips of the generator and its para dissolve meters. A particularly effective optimization can by increasing the power amplification factor individual levels can be reached.

In principle, a conventional electrical vibration generator are divided into two main stages: an excitation stage and an output amplifier stage, whose input to the output of the Exciter is switched. Any source can be the pathogen serve the electrical vibrations to be amplified, for. B. un indirectly a self-excited tube oscillator, a self-excited The tube oscillator with one or more at its out Gang switched preamplifier stages, one of which is connected to one Can be switched, a receiving antenna with a modulator or more preamp stages or any other Device whose output emits electrical vibrations. The output amplifier stage contains a controllable active Element (an electron tube or a transistor) with one Input and an output circuit. The output circuit of the active Elements can e.g. B. the transmitter antenna or the subsequent stage for reinforcement, forming etc. if the generator is part of a complex system.

The peculiarity of the electric vibration generator are connected to a significant degree by connecting the and output circuit of the active element of the output amplifiers level or, more specifically, by choosing the common point of the input and output circuit. The following will be two known basic circuits of active components for performance reinforcement discussed and compared.

Electric vibration generators are known (see D. P. Linde, "Radioperedajuschie ustrojstva" (radio transmitters), 1969, ver "Energÿa, Moscow, pp. 122-227, especially Fig. 5-1), the  an exciter and an output amplifier stage for power amplification with a controllable active element, e.g. B. with an electron tube and with an on and an off gear circle is included. The input circle of the active element is in these generators between the emittie rende and control electrode of the active element (between the cathode and the control grid of the tube) switched and with a section connected to the output of the pathogen. The The output circuit is between the emitting and the collector electrode of the active element (between the cathode and anode the tube) switched. The flows in such a generator Alternating current that is supplied to the amplifier stage by the exciter is, over the input circuit of the active element and in the off the active element flows through the circuit Voltage is controlled at its control electrode (cathodes base or emitter circuit).

Power amplification can be achieved with this type of amplifier reach factor of the order of 100. This high ver However, the gain factor is only in a narrow frequency range richly guaranteed. A broadening of the pass band leaves only by shutting the input circuit of the Enable amplification level with an effective resistance that one Part of the pathogen's power takes up, reducing the power gain factor proportional to the broadening of the operation frequency band of the generator is reduced.

The application of such generators in the radio frequency area (begin ending with the shortwave range), as is known, is limited to the use of a triode or transistor by the Presence of parasitic feedback due to Kapa between the collector electrode and the control electrode (e.g. the capacitance anode grid of the triode) which is the most resistant against self-excitation (whistle safety) greatly reduced and the characteristics of the generator deteriorated, and at Use of a tetrode due to construction that is difficult to overcome  and technological complications with the need a guarantee of equipotentiality after the high Frequency of the cathode and the screen grid are connected, making the development of simple, cheap and safe Tetrodes with great performances especially for the meter and Decimeter wavelength range becomes impossible. As a result the cathode base or emitter circuit mainly for Low frequency generators used.

There are also amplifiers in grid base or base circuit be knows (see S. A. Drobov, "Radioperedajuschie ustrojstva" (Funk transmitters), 1951, publisher "Woennoje isdatelstwo", Moscow, Pp. 846-849), in which an input circuit between the emittie rende and the control electrode of the active element and to the Output of the exciter is switched, and in which an output circle with the collector electrode of the active element and with its control electrode and with the output of the exciter so is electrically connected that at least part of the AC current supplied to the amplifier stage from the exciter are flowing.

The generators of this type have a wide use in various facilities found in the high frequency area offers (in the meter, decimeter and centimeter wavelengths range) can be used. This is explained by a number positive peculiarities that are characteristic of these generators.

In contrast to the type of amplifier in the cathode base or Emitter circuits have amplifiers in a lattice base or base circuit a higher self-excitation security (whistle-proof heit), since the parasitic feedback in them by the Kapa between the collector electrode and the emitting Electrode (e.g. between the anode and cathode of the triode) is determined, which is at least one order of magnitude lower is called the capacitance between the collector electrode and the Control electrode. When using a tetrode as controllable  The active element of the amplifier stage is the control and the Shield grid short-circuited via the high frequency. In this The anode-cathode capacity is even lower than in the case Triode, which increases the durability of the generators of this class against self-excitation is additionally increased. The equipo potentiality after the high frequency between the control and the Screen grille easily guaranteed.

Because in the generators, whose amplifier stage is part of the alternating current, d. H. of the excitation current through the output circuit of the active Elements flows into which the payload is switched, the Input circuit of the amplifier stage through a resistor next to it closed, which (in the absence of grid currents) has a value the reciprocal of the slope of the anode grid characteristic line of the active element is the same. As a result, they have Generators a wide pass band.

The specified positive characteristics of the generators with a Ver realized as a grid base or base circuit The generators have a stronger level than cathode base or Emitter circuit implemented amplifier stage practically full constantly from the area of high and maximum frequencies (be especially in broadband facilities).

The power gain factor of an amplifier stage in Git However, the base circuit is very small because of the Exciter delivers a power to the load of the amplifier stage, through that of the active element of the amplifier stage the pathogen is conditioned. To ensure the function of the Amplifier stage in such generators is a powerful one Exciter required that generates vibrations at the output, the Voltage of the voltage on the control electrode of the active ele ment of the amplifier stage is the same and its current is the current of the active element. In other words, when opening construction of medium and high power generators a multi-stage  exciter can be used, which is able to output one Output power that is necessary for the excitation of the output ampl level is sufficient. This complicates the Generator structure and to increase its size and its weight, to increase costs and to reduce the Operational reliability. In addition, additional be created drive difficulties with the coordination of multi-levels system are connected, the energy consumption increases, and the nonlinear distortions and losses are eliminated enlarged.

Over the course of several decades, generators have been using Amplifier stages in grid base or base circuit in their Circuit concept hardly changed. It just became their elements basis - the electro vacuum and semiconductor devices, the elements of the vibration systems and the connecting elements - as well as the Technology perfected. In particular, electrons were tubes with increased steepness and reduced values of Inter-electrode capacities and electronic devices with vibration systems built into the interior of the vacuum envelope developed. However, this has no major improvement in the Power amplification factor result, but at the same time has the Structure of the tubes and their manufacturing technology significant complicated.

The power amplification factors are in the majority of the well-known generators with gain stages in lattice base or basic circuit in the limits of 3 to 20, and at the best modern generators in which the latest achievements electronics are values of the Power amplification factor in the order of 30 er been enough. (see "Spravochnik po radioelektronnym ustroystvam" (Handbook of radio-electronic facilities) by D. P. Linde, Vol. 1, 1978, "Energÿa" Moscow, § 3-3, especially p. 233). This is still the case in all cases a sufficiently powerful pathogen is necessary, and for maintenance  the required output power must be the number of Preamplifier stages with all designated negative Aftermath are magnified.

It is currently believed that the usual ways to Perfection of these generators practically exhausted and that the value of the power amplification factor with the order of 30 probably for them Limit is. The belief that another significant Increasing the power amplification factor in such genera is impossible has become traditional, so that an improvement in the power amplification factor even considered a significant advance by a few percent becomes.

Inhibit the specified peculiarities of such generators the further development of powerful high-frequency Broadband radio devices, especially mobile devices, for which is of particular importance small dimensions and weights, high security and improved operation have characteristics.

The invention has for its object an electrical Power vibration generator with one exciter and one performance realized in grid base or base circuit to improve the amplifier level so that the performance gain factor without additional active elements a special electrical connection of the pathogen with the power amplifier stage increases so that the exciter power to be generated is significantly reduced, wherein the broadest possible frequency range and high stability against self-excitation of the power amplifier stage should be kept.  

The above problem is solved with an electrical one Power vibration generator according to the preamble of Claim 1 according to the invention in the characterizing of Claim 1 included features.

With such an execution of the power vibration genes rators the voltage at the control electrode of the active Elements by the alternating current, the power ver strength level is supplied by the pathogen, and the contra level of the input circuit of the active element d. H. the operating state of the amplifier stage is not changed, but the voltage at the output of the exciter is the sum of the voltage at the input circuit of the active Element and the compensation voltage equal, and this The sum is always less than the voltage at the input circuit. For excitation of the output amplifier stage by the exciter is, just like in the well-known power vibration generators, a current required to generate such a voltage on the control electrode of the active Element sufficient to maintain the pre given operating state of the active element and Maintenance of the required output current (part of of the current at the output of the exciter) under load is necessary while the voltage at the output of the exciter is significantly less than in the known performance vibration generators. Because the performance of the pathogen by the product of its output current and output voltage is determined, there is the advantage that for generating the same power in the payload using an exciter lower performance is required. Thereby, decreases the voltage at the specified section of the input circuit of the active element and the compensation voltage against phase and their amplitudes are equal, the required  Power of the pathogen practically down to zero, that is the voltage at its output by the sum of two voltages equal in amplitude, in phase opposition is determined to be zero.

Thus, the invention allows the power gain factor guaranteed by the power amplifier stage will increase greatly, which in turn enables the Number of amplifier stages in the exciter while maintaining the output power of the power vibration generator to reduce and thereby simplify the construction of the power vibration generator as a whole, a ver decrease in its size and weight, an increase security, cost reduction and simplification to ensure operation.

At the same time arise as a result of the execution of the pathogen as a current source when the compensation voltage is introduced source in the circuit of the power vibration generator no new parasitic feedback, causing the bee Maintaining the wide pass band of the power amplifiers level and its high resistance to self-excitation is made possible in the high frequency range.

An advantageous embodiment is characterized by claim 2 draws.

A further advantageous embodiment characterizes An saying 3.

The compensation voltage on the passive elements ten of the directly into the power amplifier stage led multipole through the flow of the output current  of the exciter over the circles of the multipole. This structure eliminates the need for additional levels with active ones Elements, does not require special synchronization and is therefore characterized by simplicity and security. Such is also a power vibration generator more economical since the compensation voltage in it not brought up by any external sources that require a power supply, but directly in the power amplifier stage by redistribution the energy in the circles of the active element.

Another advantageous embodiment is by claim 4 marked.

This structure of the passive multipole as a parallel resonance In terms of construction, circle is the simplest and most special expedient. It also has a high resistance the output amplifier stage against self-excitation not only in the operating frequency range, but also outside guaranteed the same.

The marked parallel resonance circuit can be according to Claim 5 advantageously be turned on so that it Output circuit of the active element of the amplifier stage will form.

This union of the function of the oscillation circuit as a compensation voltage source and as an output circuit the power amplifier stage ensures an additional simplification of the generator structure. Furthermore in this case, automatic protection of the active Elements (what happens when operating high power generators is particularly important) against overloading its electrodes  guaranteed in the event of a detuning of the output circuit, since the detuning of the circle to a rugged minde compensation voltage leads, consequently the voltage drops at the control electrode of the active element and his electricity is interrupted. This structure is special useful when using active elements with three electrodes (triodes) in the high-frequency range.

Another advantageous embodiment of the invention, where a tetrode serves as an active element Claim 6.

This makes the compensation voltage independent value of the resistance of the payload of the output circuit the tetrode ensures what is under operating conditions of the generator on an alternating load is very important is.

According to the characterizing part of claim 7 is the passive one Multipole, which forms the compensation voltage source, to obtain the required compensation voltage advantageous in shape over the entire operating frequency range a system of coupled resonance circuits leads.

According to claim 8 is advantageously the specified Circuit of the interconnected resonance circuits so turned on that it is the output circuit of the active element the power amplifier stage. This allows to simplify the structure of the power vibration generator and protection of the active element against overloads to ensure in a wide operating frequency range.  

To ensure independence of the compensation voltage from the resistance of the payload in the output circuit of the active element of the power amplifier stage in one wide frequency band can be used according to claim 9 a tetrode as a controllable active element of performance amplifier stage advantageously the circuit of each other coupled resonant circuits can be designed so that the belonging to this circuit resonant circuit between the Control and the screen grid of the tetrode is switched, being the first junction of the branches of this resonance circle with the collector electrode (anode) of the tetrode is electrically connected via its output circuit.

The above features and advantages of the invention as well as the realized specific individual functions based on the following detailed description of the Embodiments with reference to the drawings explained in more detail. It shows

Figure 1 is a simplified electrical functional circuit diagram of the proposed power vibration generator.

Fig. 2 is an electrical equivalent circuit diagram of the power vibration generator shown in Fig. 1;

Fig. 3 is a simplified electrical functional circuit diagram of the power vibration generator with a compensation voltage source, which is in the form of a source that emits an unmodu lated AC voltage;

Fig. 4 is an electrical functional diagram of the power vibration generator with a triode-equipped amplifier stage and a compensation voltage source in the form of a parallel resonant circuit which forms the output circuit of the triode;

Fig. 5 is an electrical schematic diagram of one of the embodiments of the parallel resonance circuit, which forms the compensation voltage source for the power vibration generator of Fig. 4 or 9;

Fig. 6 is an electrical schematic diagram of another embodiment of the parallel resonance circuit, which forms the compensation voltage source for the power vibration generator of Fig. 4 or 9;

Fig. 7 is an electrical schematic diagram of a third embodiment of the parallel resonance circuit, which forms the compensation voltage source for the power vibration generator of Fig. 4 or 9;

Fig. 8 shows the structure of the power vibration generator of Figure 4 with the resonant circuit of Figure 6 with a structure of coaxial conductors.

Figure 9 is an electrical functional block diagram of the power generator with a vibration tetrodenbestückten amplifier stage and a compensation voltage source in the form of a parallel resonant circuit which is connected between the control and the screen grid of the tetrode.

Fig. 10 shows the structure of the power vibration generator of Figure 9 with the oscillation circuit of Figure 6 with a structure of coaxial conductors.

Figure 11 is an electrical schematic diagram of the power oscillation generator with a power amplifier stage triodenbestückten and a compensation voltage source in the form of two mutually coupled resonant circuits that form the output circuit of the triode. and

Fig. 12 is an electrical block diagram of the power vibration generator with a tetrode-equipped amplifier stage and with a compensation voltage source in the form of two mutually coupled resonant circuits, which is connected between the control and the screen grid of the tetrode.

To simplify matters, only those are shown in all drawings AC circuit paths for high frequency current shown vibrations. The food sources, in particular the sources of the heating voltage for the electronic tubes, the anode voltage, the bias voltage, etc., which are common Way to be turned on, as well as others for such a  common elements, e.g. B. decoupling chokes in the supply circuits are not in the circuit diagrams designated.

Fig. 1 is a simplified functional block diagram showing a preferred embodiment. In this functional circuit, the power vibration generator, hereinafter also referred to as generator for short, contains an exciter 1 and a power amplifier stage 2 , which is used for power amplification.

The power amplifier stage 2 is constructed with a controllable active element, for example with an electron tube, the triode 3 , in which the cathode 4 , the grid 5 and the anode 6 function as an emitting or control and collector electrode (grid basic circuit).

The input circuit of the triode 3 contains a resistor 7 , which is usually designed as a reactance and is connected between the cathode 4 and the grid 5 of the triode 3 . A section 7 a of the resistor 7 forms the input circuit of the triode 3 , which is limited by points 8 and 9 and is connected to the output leads 10 a and 10 b of the exciter 1 , the derivative 10 a with the point 8 of section 7 a a compensation voltage source 11 and the derivative 10 b are connected directly to the point 9 of section 7 a , so that the compensation voltage source 11 is connected to the input circuit 7 a of the triode 3 with respect to the output of the exciter 1 in series.

The output circuit of the triode 3 contains a payload 12 , which acts as an active resistor in the operating frequency range of the generator and is connected between the grid 5 and the anode 6 of the triode 3 . The output circuit with the load 12 thus has a direct electrical connection to the grid 5 of the triode 3 and is connected to it at the connection point 8 of the input circuit 7 a , while with the output of the exciter 1 , ie with its output derivative 10 a , this output circuit the compensation voltage source 11 is electrically connected so that part of the current of the vibrations, which are supplied from the exciter 1 of the output amplifier stage 2 , flows through this output circuit of the triode 3 , that is, via the load 12 .

The output circuit of the triode 3 with the load 12 represents the output circuit of the generator. The load 12 may, for. B. represent the antenna of a transmitter or a subsequent amplifier stage in more complex systems.

The exciter 1 is executed with respect to the circuits connected to its output lines 10 a and 10 b of the amplifier stage 2 as a current source, ie its internal resistance was much higher than the input resistance of stage 2 between points 10 a and 10 b which are all level 2 circuits.

The compensation voltage source 11 is designed so that it generates an AC voltage between points 8 and 10 a , the frequency of which is equal to the excitation frequency, and which is so out of phase with respect to the voltage at section 7 a of the input circuit that the sum of these two voltages falls below the voltage at the input circuit 7 a , ie the compensation voltage source 11 generates a compensation voltage which is approximately in phase with the voltage at the input circuit 7 a .

The generator described works as follows:

When the supply voltage of the exciter 1 and the power amplifier stage 2 are switched on, electrical vibrations appear at the output of the exciter 1 , which are characterized by the exciter alternating current I _e and the alternating output voltage U _e . Part of the excitation current I _e flows through the input circuit 7 a of the triode 3 and forms the input AC voltage U _g 'and at the same time generates the control AC voltage U _g , which is applied between the cathode 4 and the grid 5 of the triode 3 . As a result of the appearance of the control voltage U _g on the grid 5 , an electron alternating current (anode current) I _a arises in the triode 3 , which flows from the cathode 4 to the anode 6 and connects to the cathode 4 via the output circuit with the load 12 , the compensation voltage source 11 and closes pathogen 1 . The anode current I _a thus represents part of the excitation current I _e , which is distributed according to the resistance values between the input and output circuits of the triode 3 . When the current I _{a flows} through the load 12 , amplified electrical vibrations are given to it, the power of which is determined by the size of the current I _a and the size of the resistance of the load 12 .

The compensation voltage source 11 generates between the points 8 and 10 a a compensation voltage U _k , the frequency of the frequency of the vibrations which are supplied by the exciter 1 to the amplifier stage 2 , ie the frequency of the excitation current I _{e is the} same. The phase of the compensation voltage U _k is approximately opposite to the phase of the voltage U _g 'at the input circuit 7 a of the triode 3 and the amplitudes of these two voltages U _k and U _g ' are approximately the same. The output voltage U _{e of} the exciter 1 is the sum of the compensation voltage U _k , which acts between the points 8 and 10 a , and the input voltage U _g 'at the input circuit 7 a of the triode 3 , which is between the points 8 and 9 , ie between the Points 8 and 10 b have the same effect. Since the compensation voltage U _k and the input voltage U _g 'are approximately in phase, their sum is always less than each of them, so that the output voltage U _{e of} the exciter 1 always falls below the input voltage U _g '.

The power at the output of the exciter 1 is determined as the product of the excitation current I _e and the output voltage U _e . A due to the introduction of the compensation voltage U _k reduction in the output voltage U _e thus leads to a constancy of the excitation current I _e to a reduction in the power consumed by the exciter 1 , which is necessary to maintain such an operating state of the amplifier stage 2 , which the obtaining required performance at the load 12 guaranteed.

The ratio of the strength of the current I _a flowing through the output circuit of the triode 3 to the value of the current flowing through its input circuit, ie the ratio which characterizes the distribution of the excitation current I _e between the input and the output circuit of the triode 3 , is Product of the slope of the anode grid characteristic of the triode 3 , the value of the resistance 7 of the input circuit and the ratio of the voltage U _g between the cathode 4 and the grid 5 to the voltage U _g 'at the input circuit 7 a of the triode 3 the same. Since the exciter 1 with respect to the power amplifier stage 2 constitutes a power source, the excitation current ie I _e from the input resistance of the connected to the output of the exciter 1 power amplifier stage 2 is not dependent, as well as the specified ratio of the currents depend on the inputs and the output circuit the triode 3 does not depend on the value of the compensation voltage U _k . It follows that the control voltage U _g on the grid 5 of the triode 3 and thus also the anode current I _{a are determined} only by the excitation current I _e and do not depend on the value of the compensation voltage U _k .

The value of the compensation voltage U _k thus exerts no influence on the operating state of the power amplifier stage 2 and only determines the power which is taken from the exciter 1 to generate the required control voltage U _g on the grid of the triode.

In the following the analysis of the dependence of this power on the value of the compensation voltage U _{k is carried out} under the condition of a constant excitation current I _e , ie without changing the operating state of the power amplifier stage 2 . For the sake of clarity, an electrical equivalent circuit diagram of the power oscillation generator described is shown in FIG. 2.

If the compensation voltage U _{k is} equal in amplitude and opposite in sign (in opposite phase) to the input voltage U _g 'at the input circuit 7 a of the triode 3 , the power at the output of the exciter 1 is zero since its output voltage U _e is zero . In this case, the power amplification factor guaranteed by the power amplifier stage 2 (which is determined as the ratio of the output power of the power oscillation generator given off in the load 12 to the power at the output of the exciter 1 ) is infinite. In other words, the exciter 1 does not consume any power to excite the power amplifier stage 2 and only gives the excitation current I _e , which is required for the generation at the grid 5 of the triode 3 of a control voltage U _g , which determines the operating state of the triode 3 and its anode current I _a and thus also determines the output vibration power that is developed in the payload 12 .

If the compensation voltage U _{k is} coupled in phase opposition to the voltage U _g 'and this exceeds the amplitude, the output voltage U _{e of} the exciter 1 becomes in phase opposition to the excitation current I _e . The exciter 1 does not deliver any power, but consumes it from the power amplifier stage 2 . The incoming in exciter 1 through excess power is dispersed in his circles, for. B. at the anode of the active element of the output stage of the exciter 1 or in a special load. In this case too, the exciter 1 only requires the exciter current I _e , and no power is required, while the power amplification factor of the power amplifier stage 2 rises to infinity.

However, if the compensation voltage U _{k is} in phase opposition to the input voltage U _g 'and the amplitude is slightly less than this, the output voltage U _{e of} the exciter 1 will still fall below the voltage U _g ', so that the power emitted by the exciter 1 always is less than in a similar known power vibration generator, in which the output of the exciter is connected directly to the section of the input circuit of the active element of the power amplifier stage and the voltage at the output of the exciter is equal to the voltage at this section of the input circuit. The power amplification factor of the amplifier stage 2 is also higher in this case than in the known generator, ie it is necessary for the described power oscillation generator to obtain the required output power in the load 12 under other identical conditions, an exciter 1 with significantly lower power.

Thus, the power amplification factor of the output amplifier stage 2 in the power oscillation generator described always increases by an amount by which the output power of the exciter 1 decreases.

As follows from the circuit diagram of the power oscillation generator ( FIGS. 1 and 2), with constant excitation current I _e, the changes in the output voltage U _e of exciter 1 (which also serves as a current source) due to the introduction of a compensation voltage U _k no additional return Introduce couplings between the input and the output circuit of the triode 3 compared to the known power vibration generator with a power amplifier stage in a grid-based circuit. The parasitic feedback is also determined in the described power oscillation generator by the anode-cathode inter-electrode capacitance. The power oscillation generator described thus retains all the advantages of the basic grid circuit, above all the high resistance to self-excitation and the broadband capability.

FIG. 3 shows a simplified functional circuit diagram of the power vibration generator, in which the compensation voltage source 11 is designed as an unmodulated voltage source.

In this power vibration generator, the exciter 1 contains a control generator 13 and an amplifier stage 14 , the input of which is connected to the output of the control generator. An amplitude modulator 15 is connected to amplifier stage 14 in the usual way. From the output lines from the amplifier stage 14 form the output lines 10 a and 10 b of the exciter 1

The control generator 13 , the amplifier stage 14 and the modulator 15 can be implemented according to any known circuit. The amplifier stage 14 is designed as a current source, so that its internal resistance the input resistance of the output amplifier stage 2 , which are connected to the output lines 10 a and 10 b of the exciter 1 , many times.

The compensation voltage source 11 in the power amplifier stage 2 is designed as an unmodulated AC voltage source, which is formed by an amplifier stage 16 , the input of which is connected to the output of the control generator 13 , whereby a synchronization of the amplifier stage 16 with the exciter 1 is ensured. The output circuit 17 of the amplifier stage 16 , shown in a generalized form in the drawing, was connected in series with the input circuit 7 a of the triode 3 and connects point 8 of the input circuit 7 a with the output line 10 a of the exciter 1 . As in FIG. 1, point 9 of section 7 a is connected directly to output line 10 b of exciter 1 .

The amplifier stage 16 can be constructed according to any known circuit, e.g. B. similar to the structure of stage 14 , but without input for the modulator. From the output circuit 17 of the amplifier stage 16 can z depending on the operating frequency range of the power oscillation generator. B. be formed by the winding of a transformer or by a resonant circuit.

When operating such a power oscillation generator, the control generator 13 generates electrical carrier frequency oscillations, which reach the amplifier stage 14 of the exciter 1 and the amplifier stage 16 simultaneously. The vibrations with the modulation frequency from the modulator 15 also reach the amplifier stage 14 . At the output of the amplifier stage 14 , vibrations with the carrier frequency appear, which are amplitude-modulated with the vibrations supplied by the modulator 15 .

In the amplifier stage 16 , the vibrations with the carrier frequency experience no modulation and are reproduced at their output (in the output circuit 17 ) with a constant amplitude, which is determined by the amplification factor of the stage 16 , which is chosen so that the amplitude of the voltage at the output the stage 16 of the maximum amplitude of the input voltage U _g 'is approximately the same, which is developed by excitation current I _e at section 7 a of the input circuit of the triode 3 .

The voltage generated in this way at the output of stage 16 is the compensation voltage U _k , which acts in phase with the output voltage U _{e of} the exciter 1 and thus in phase opposition to the input voltage U _g ', the same as in the power oscillation shown in FIG. 1 generator only depends on the current I _e , ie it is amplitude modulated in the present case.

The output voltage U _{e of} the exciter 1 , which represents an alga brazian sum of the voltages U _k and U _g ', in this case has an alternating amplitude which corresponds to the difference between the constant amplitude of U _k and the alternating amplitude of U _g ' and thus always falls below the amplitude of U _g ', which enables a reduction in the power to be extracted from the exciter 1 .

Otherwise, this power vibration generator acts analogously to the power vibration generator shown in FIG. 1.

The described structure of the power vibration generator according to FIG. 3 with an independent (external) source of the compensation voltage can preferably be used in cases when existing generators are modernized on the basis of the present invention, in which for some reason the compensation voltage source is not directly connected to the circuit of the Input or output circuit of the power amplifier stage can be inserted.

In the power oscillation generator, the electrical functional circuit diagram of which is shown in FIG. 4, the output amplifier stage is designed with a triode and with an input and an output circuit in the form of parallel resonance circuits, ie it represents a resonance amplifier.

The input circuit of the triode 3 is executed in this power vibration generator in the form of a parallel resonant circuit, one branch 18 of a reactance 19 and the other branch 20 contains two series resistors 21 and 22 . The reactance of the branch 18 of this circle is opposite to the sign after the common reactance of the branch 20 . e.g. B. carries the resistance of branch 18 a capacitive Cha character, the total resistance of branch 20 has an inductive character. The connection points of the branches 18 and 20 are each connected to the grid 5 and to the cathode 4 of the triode 3 . The resonant circuit, which acts as an input circuit of the triode 3 , is therefore connected between its cathode 4 and the grid 5 . The common point of the resistors 21 and 22 is connected to the output line 10 b of the exciter 1 .

The values of the resistors 19, 21 and 22 of the circuit which forms the input circuit of the triode 3 are chosen so that this circuit is tuned to the center frequency of the operating frequency range of the generator.

The compensation voltage source 11 is designed in the form of a passive three-pole circuit, which is formed by a second parallel resonance circuit which simultaneously forms the output circuit of the triode 3 . In this circuit, one branch 23 contains the reactance 24 . The other branch 25 is in the form of a voltage divider out, which is formed by two reactors 26 and 27 , the same sign of the sign of the reactive resistor 24 of the branch 23 is opposite. The first outer point 28 of the voltage divider, which forms the branch 25 of the circle, is connected directly to the anode 6 of the triode 3 . The center 29 of this divider (connection point of the resistors 26 and 27 ) is connected to the output lead 10 a of the exciter 1 . The second outside point 30 of the specified divider is connected to the grating 5 of the triode 3 . The outer points 28 and 30 of the voltage divider represent the connection points of the branches 23 and 25. The payload 12 is connected in parallel with the branches 23 and 25 . The values of the opposing states 24, 26 and 27 of the oscillation circuit which forms the output circuit of the triode 3 are selected so that this circuit is tuned to the center frequency of the operating frequency range of the generator.

Thus, the resistor 21 forms the portion of the input circuit of the triode 3 , which is connected to the output of the exciter 1 in series with the device 11 for generating the compensation voltage, the connection point of the grid 5 of the triode 3 with the outside point 30 of the Voltage divider formed by resistors 26 and 27 and the junction of branches 18 and 20 of the circuit forming the input circuit of triode 3 represents point 8 which limits the specified section of the input circuit from one side, while the connection point of the resistors 21 and 22 forms the other point 9 , which limits this section of the input circuit from the other side.

During operation of the power oscillation generator according to the Fig. 4 flow a portion of the excitation current I _e on the dummy resistor 21 of the input circuit of the triode 3 and generates the input voltage U _g 'of the power amplifier stage 2, which voltage between the points 8 and 9 acts. This creates a control voltage U _g between the cathode 4 and the grid 5 of the triode 3 , which is in phase with the voltage U _g '. The anode current I _a proportional to the voltage U _{g of} the triode 3 branches into the sub-circuits of the oscillation circuit which forms the device 11 for generating the compensation voltage and the output circuit of the triode 3 , consequently a voltage is generated at the load 12 which increases the voltages U _g ′ and U _{g are} in phases of opposition. Since the reactors 26 and 27 have the same sign, there is the compensation voltage U _k at the resistor 27 , which is in phase with the voltage at the load 12 and thus in phase opposition to the input voltage U _g '. As stated above, in this case the output voltage U _{e of} the exciter 1 is lower than the input voltage U _g 'of the amplifier stage 2 , thereby reducing the power which is taken from the exciter 1 and increasing the power amplification factor, which is guaranteed by amplifier stage 2 . The value of the power amplification factor depends on the relationship of the amplitudes of the voltages U _k and U _g 'in accordance with the dependence of the voltage U _e on the voltage U _k , which was analyzed in detail above.

Outside the limits of the pass band of such a power oscillation generator, the equivalent resistance of the oscillation circuit, which forms the output circuit of the triode 3 , drops steeply, which leads to a sharp reduction in the amplitude of the compensation voltage U _k . Accordingly, the possibility of self-excitation of the amplifier stage 2 is practically excluded at frequencies that lie outside the limits of the pass band, which simplifies the construction of the exciter 1 , since there is no need for it to have a large internal resistance at frequencies outside the operation area.

In the power oscillation generator , which is designed in accordance with FIG. 4, protection of the active element of the power amplifier stage in the event of an abrupt reduction in the resistance of the output circuit, e.g. B. with a detuning of the resonant circuit that forms the output circuit, while in the known power oscillation generators the decrease in the resistance of the output circuit causes an increase in the power that is dissipated at the collector electrode of the active element, which leads to the failure of the latter can. The usual extreme value hedging devices do not respond, since the anode current does not increase in this case. In the power oscillation generator, which is shown in FIG. 4, an abrupt drop in the voltage at the load 12 leads to a strong reduction in the compensation voltage U _k , so that the input resistance of the amplifier stage 2 rises steeply and the exciter 1 stops, one To be a power source. The excitation current I _e drops, which leads to a reduction in the control voltage U _g at the grid 5 of the triode 3 , the anode current I _a and the power which is dissipated at the anode 6 of the triode 3 .

The embodiment of the power oscillation generator according to FIG. 4 allows the construction of the amplifier stage 2 to be simplified, since the functions of the output circuit of the active element and the compensation voltage source 11 are combined in one oscillation circuit.

A similar power oscillation generator with a compensation voltage source 11 in the form of a parallel resonance circuit, which forms the output circuit of the active element of the power amplifier stage, can also be constructed with a tetrode. The structure and all connections of the circuits remain the same, as shown in Fig. 4, while the control and the screen grid of the tetrode are short-circuited in high frequency, for. B. with the help of a capacitance connected between them.

In Figs. 5, 6 and 7 are electrical schematic of the resonant circuit images of the possible construction forms which forms the output circuit of the triode 3, for the case shown in FIG. 4 power oscillation generator provides Darge.

In one of these resonant circuits ( FIG. 5), the voltage divider in branch 25 is formed by two capacitors 31 and 32 and the parallel branch 23 by an inductor 33 .

In another embodiment of the resonant circuit ( FIG. 6), the voltage divider in branch 25 is formed by two inductors 34 and 35 and branch 23 is formed by a capacitance 36 .

A third embodiment of the resonant circuit is shown in FIG. 7. This resonant circuit contains a capacitance 37 in branch 23 . The voltage divider in branch 25 is formed by a transformer 38 , the primary winding 39 of which is connected between the outer points 28 and 30 of the divider, and the secondary winding 40 is connected at one end to the primary winding 39 . The other end of the secondary winding 40 forms the center 29 of the voltage divider. The outer points 28, 30 and the center point 29 of the voltage divider can be easily determined in this case if one uses the well-known equivalent circuit of the transformer, which takes into account not only the inductances of the windings, but also the leakage inductance.

In the construction diagram ( Fig. 8) one of the particularly advantageous embodiments of the power vibration generator, which is shown in Fig. 4, is shown, in which the resonant circuit, which forms the output circuit of the triode 3 and the compensation voltage source 11 , according to which in the Fig. 6 electrical circuit diagram shown is executed.

According to FIG. 8, the resonant circuits in the input and the output circuit of the triode 3, the main action amplifier stage 2 is carried out from portions of coaxial conductor.

The resonant circuit in the input circuit of the triode 3 is due to the capacitance between the cathode 4 and the grid 5 of the triode 2 , which represents a resistor 19 in the branch 18 of the circuit ( FIG. 4), and by the section 41 of the coaxial conductor ( FIG. 8 ) with a center conductor 42 and an outer conductor 43 , which represents an inductive branch 20 of the circuit ( FIG. 4). The section 41 of the conductor ( FIG. 8) is short-circuited at one end by means of an annular web 44 , and the opposite ends of its central conductor 42 and outer conductor 43 are connected to the cathode 4 and the grid 5 of the triode 3 , respectively. The electrical length of the section 41 of the coaxial conductor is less than a quarter of the wavelength of the vibrations which are supplied to the amplifier stage 2 by the exciter 1 .

The resonant circuit in the output circuit of the triode 3 is determined by the capacitance between the grid 5 and the anode 6 of the triode 3 , which represents a resistor 24 in the branch 23 of the circuit ( FIG. 4) and the capacitance 36 in FIG. 6 formed by two series-connected sections 45 and 46 of coaxial conductors ( Fig. 8), which are short-circuited at the ends by means of ring webs 47 and 48 . The sections 45 and 46 form the inductors 34 and 35 ( Fig. 6) of the voltage divider in the branch 25 of the resonant circuit. The center conductor of section 45 ( FIG. 8) is the outer conductor 43 of section 41 , which is connected to the grid 5 of the triode 3 , so that the input and output circuits of the triode 3 have a common connection point 8 with the grid 5 . The outer conductor 49 of the section 45 is connected by means of an annular web 50 to the outer conductor 51 of the section 46 , the central conductor 52 of which is connected to the anode 6 of the triode 3 . The connection point of the outer conductors 49 and 51 of the sections 45 and 46 corresponds to the center 29 of the voltage divider ( Fig. 6). Which exploiting Dende in the coaxial shield 53 of active load 12 (Fig. 8) is connected in parallel to the portion 46 by means of a feed line 54, the center conductor 55, the load 12 to the center conductor 52 of the portion 46 and the outer conductor 45 the screen 53 to the outer conductor 51 of section 46 connects.

The output of the exciter 1 is connected to the amplifier stage 2 with the aid of a feed line 57 . The outer conductor 58 of the feed line 57 is connected to the outer conductor 49 of the section 54 near the junction of the conductor 49 with the outer conductor 51 of the section 46 , so that the outer conductor 58 of the feed line 57 represents the output line 10 a of the exciter 1 , which is connected to the center point 29 of the voltage divider ( FIG. 6). The inner conductor 59 ( FIG. 8) of the feed line 57 runs through the coaxially arranged openings in the conductors 49 and 43 of the sections 45 and 41 , is connected to the inner conductor 42 of the section 41 and represents the output line 10 b of the exciter 1 is connected to the output circuit of triode 3 .

FIG. 9 shows the electrical functional circuit diagram of the power vibration generator, in which a tetrode 60 with a cathode 61 , a control grid 62 , a screen grid 63 and an anode 64 is used as the controllable active element of the output amplifier stage 2 .

In this power vibration generator, the input circuit of the tetrode 60 is in the form of a parallel resonance circuit, which is connected between the cathode 61 and the control grid 62 of the tetrode 60 . The structure and circuit of this resonant circuit is identical to the structure and connection of the circuit which forms the input circuit of the triode 3 in the power oscillation generator, the circuit diagram of which is shown in FIG. 4.

The compensation voltage source 11 is in the form of a parallel resonance circuit, the structure of which is analogous to the structure of the circuit which performs the function of the compensation device in the power oscillation generator shown in FIG. 4. It is only switched on instead of the payload 12 parallel to the branches 23 and 25 of this circuit, a ballast load 65 , the resistance of which has an effective resistance. This resonant circuit is connected between the control grid 62 and the screen grid 63 of the tetrode 60 . The outer point 28 of the voltage divider formed by the reactors 26 and 27 is electrically connected to the anode 64 of the tetrode 60 via its output circuit, which is designed in the form of a parallel resonance circuit, the branches of which contain reactors 66 and 67, respectively. The payload 12 is connected to this output circuit in parallel to the branches of the circuit, ie to the resistors 66 and 67 . The input circuit, which is formed by the resistor 21 and limited by the points 8 and 9 , is connected to the output of the exciter 1 via the compensation voltage source 11 connected in series with the resistor 21 in the same way as in the power oscillation generator, the circuit diagram of which is shown in FIG . 4 is shown.

The compensation voltage U _k is generated in this power vibration generator in the same way as in the power vibration generator, which is shown in Fig. 4, and develops at the resistor 27 of the voltage divider in branch 25 of the resonant circuit. The circuit of this circuit between the control grid 62 and the screen grid 63 of the tetrode 60 , however, ensures independence of the compensation voltage U _k from the resistance of the load connected to the output circuit of the tetrode 60 payload 12th Accordingly, such a power vibration generator can be used effectively when operating on an alternating load 12 .

In addition, in the power oscillation generator shown in FIG. 9, no power is taken from the output circuit of the tetrode 60 for the generation of the compensation voltage U _k , while in the generator, which is shown in FIG. 4, a part of the power Developed in the output circuit of the triode 3 , is used to generate the compensation voltage U _k . So that of the output in FIG. Power oscillation generator illustrated 9 power to the load 12 exceeds the power that is delivered to the load 12 of the Leistungsschwin shown in the Fig. 4 supply generators to a value of _k the product of the compensation voltage U with the Anode current I _a at the same values of the anode current I _a and the resistance of the load 12 is the same in both generators.

In the generator, the circuit diagram of which is shown in FIG. 9, the oscillating circuit connected between the control grid 62 and the screen grid 63 of the tetrode 60 can be , for. B. can be constructed according to one of the basic circuit diagrams shown in FIGS. 5, 6 and 7.

The structural design of the generator shown in FIG. 9, in which the resonant circuit forming the compensation voltage source 11 is constructed according to the circuit diagram shown in FIG. 6, is shown in FIG. 10. The resonant circuits of this power vibration generator are designed with coaxial conductors using the intermediate electrode capacitances analogous to the structure shown in FIG. 8 of the power vibration generator shown in FIG. 4 with a circuit according to FIG. 6.

In contrast to the structure shown in FIG. 8, in the described generator ( FIG. 10) the inner conductor 52 of the section 46 of the coaxial conductor is connected to the screen grid 63 of the tetrode 60 , so that the oscillating circuit performing the function of the compensation voltage source 11 is connected by the Sections 45 and 46 of the coaxial conductor and the capacitance between the control grid 62 and the screen grid 63 of the tetrode 60 is formed and is connected between the grids 62 and 63 . The ballast load 65 is connected in parallel to the section 46 instead of the payload 12 .

The output circuit of the tetrode 60 is in the form of an oscillating circuit, which by the capacitance between the screen grid 63 and the anode 64 , which corresponds to the resistor 66 ( Fig. 9) and by a section 68 ( Fig. 10) of the coaxial conductor is short-circuited at the end by an annular web 69 , is formed. The outer conductor 70 of the section 68 is connected to the screen grid 63 and its inner conductor 71 to the anode 64 of the tetrode 60 . Section 68 represents an inductance that corresponds to resistor 67 ( FIG. 9). The payload 12 is accommodated in the coaxial screen 72 and connected in parallel to section 68 with the aid of a feed line 73 , the outer conductor 74 and inner conductor 75 of which are connected to the outer conductor 70 and the inner conductor 71 of the section 68 , respectively.

Another circuit variant of the power vibration generator is shown in FIG. 11. In this Lei stungsschwingungsgenerator, the power amplifier stage 2 is constructed with the triode 3 , and its input circuit is carried out in the same manner as the input circuit of the described power oscillation generator shown in Fig. 4.

The compensation voltage source 11 represents a passive multipole, which is designed in the form of a system comprising two resonant circuits 76 and 77 which are coupled to one another by means of an autotransformer coupling. This system of coupled resonance circuits 76 and 77 forms the output circuit of the triode 3 .

The resonant circuit 76 represents a parallel resonant circuit, one branch of which contains a capacitance 78 and the other branch of which comprises inductors 79 and 80 connected in series. Both branches are connected to each other in points 81 and 82 . One of these points is connected to the anode 6 of the triode 3 and the other to the point 8 of the input circuit of the triode 3 , which is formed by the resistor 21 . The resonant circuit 77 contains two branches, one of which has the inductor 80 , which thus represents the coupling inductance between the resonant circuits 76 and 77 , and inductors 83 and 84 connected in series with the inductor 80 , while the other contains the capacitance 85 . The load 12 is connected between points 86 and 77 , which represent the connection points between the branches of the resonant circuit 77 . The point 86 of the resonant circuit 77 is connected to the output line 10 a of the exciter 1 .

When this power oscillation generator is operating, a compensation voltage U _k is formed at the inductance 84 , which is close in phase to the voltage at the resonance circuit 76 between points 81 and 82 and is therefore approximately in phase with the input voltage U _g 'at the resistor 21 . Accordingly, as in the examples described above, the power drawn from the exciter 1 is reduced.

The generation of the compensation voltage in one of the coupled resonant circuits, which form the output circuit of the active element of the power amplifier stage 2 , ensures the maintenance of the required relationship between the amplitudes and phases of the voltages U _k and U _g 'in a wider frequency range than with only a resonance circuit is possible, which is due to the wide pass band of the system of the coupled resonance circuits. As a result, the power consumed by the exciter 1 is almost unchanged over a wide frequency band, thereby ensuring a broadening of the frequency band without increasing the power of the exciter 1 . At the same time ensures such a power vibration generator in the same way as the Lei stungsschwingungsgenerator shown in Fig. 4 automatic protection of the triode 3 with a sharp reduction in the resistance of their output circuit.

Another form of application of a plurality of mutually coupled resonant circuits as a compensation voltage source 11 is explained with reference to the circuit diagram shown in FIG. 12. In this embodiment of the power vibration generator, a tetrode 60 is used as the active element of the power amplifier stage 2 , and its input and output circuits are constructed in the same way as in the power vibration generator, the circuit diagram of which is shown in FIG. 9. The system of two coupled resonant circuits 76 and 77 , which performs the function of the compensation voltage source 11 , is constructed according to the circuit used in the power vibration generator shown in FIG. 11. Instead of the payload 12 in the resonance circuit 77, the ballast load 65 is switched, and the payload 12 is switched into the output circuit of the tetrode 60 . This system of coupled resonant circuits 76 and 77 is connected between the control grid 62 and the screen grid 63 of the tetrode 60 , for which point 81 of the parallel resonant circuit 76 is connected to the grid 63 and point 82 to the grid 62 in point 8 .

The principle of generating the compensation voltage U _k at the inductance 84 of the resonant circuit 77 remains the same in such a power vibration generator as in the power vibration generator, the circuit diagram of which is shown in FIG. 11. However, the amplitude of the compensation voltage U _k does not depend on the resistance value of the load 12 in the broad frequency band in the structure described with the tetrode 60 ( FIG. 12).

In the proposed embodiments of the electrical power oscillation generators, the compensation voltage source can be generated not only by resonant circuits which represent a three or four pole, but also by any other passive multipole, e.g. B. a Transforma tor, a capacity or a more complicated combination of passive elements are formed. This passive multipole must be switched on so that one of its poles is electrically connected to the collector electrode of the active element, while two poles of the same with the output lead 10 a of the exciter 1 ( Fig. 1-12) or with the point 8 of the input circuit of the active element. Such a multipole must be designed so that a phase shift of the compensation voltage U _k with respect to the input voltage U _g 'by an angle at which the sum of these two voltages is less than the voltage U _g ', which z. B. can be achieved if these voltages are out of phase.

It was built according to the invention, an experimental vibration generator of electrical vibrations, in which the output amplifier stage was designed with a tetrode according to FIGS. 9 and 10. The generator was designed for operation at a frequency of 350 MHz with a pass band of the anode circuit of 5 MHz. The output power that could be generated in the payload was 16 W with a power of the exciter of 37.5 mW. The implemented power vibration generator thus ensured a power amplification factor of 425.

For comparison, a similar comparison generator was used built in which the same tetrode after a conventional Grid base circuit was turned on. The resonant circles of the input and output circuit of the tetrode were in exactly the same way as in the realized according to the invention Experimental generator executed, and the control and the screen grids were short on the high frequency side closed. In the comparison generator was in operation in same frequency range to get an output power of 16 W an excitation power of 640 mW is required,  d. H. the power gain factor in the output ver Strength level was 25, which is 17 times lower than in the experimental generator. The invention allows it, power vibration generators in the lower, middle and to develop the upper performance range that is used to operate in any frequency range, preferably in the area the meter, decimeter and centimeter waves are. In these power vibration generators you can a power gain in the power amplifier stage get factor that is 10, 100, 1000 times and more is higher than with the known generators, which in Grid base circuit are executed, such. B. can in a number of cases the entire radio frequency channel instead a multi-stage generator only from a power amplifier stage with a high power electronic tube and a transistor-equipped exciter.

A no less important aspect of using the invention is a way of modernizing existing ones Power vibration generators, because for the realization the invention does not require any complicated means are. The main thing is that such a modernization is underway on excluding a number of repeaters steps out, e.g. B. in radio and television stations what to the undisputed advantages of tube transmitters in the Ver right to the transmitter with klystrons and traveling wave tubes can lead.

The proposed invention can be in development used new electronic devices with grid control will. It is known that the main disadvantage of the electronic tubes in a low power amplification factor and consists in the short lifespan. The invention  suggests ways to overcome these two drawbacks. In fact, the improvement of the parameters goes such Tubes basically the way of perfecting them Manufacturing technology, which allows devices with better parameters, but with a sufficiently complicated one To create technology, d. H. with parameters that the Limits are close. The use of the proposed Power vibration generator enables simplification the requirements for some parameters of the tubes, it is omitted e.g. B. The need to get a special one high steepness of the devices, which enables the Ver distance between the control grid and the cathode increase and reduce the heating voltage to a certain extent, which lead to an increase in the life of the devices can.

The solution of special ones is no less interesting Subtasks, e.g. B. the task of electronic protection of powerful tubes in the high frequency range, if the losses are due to a detuning of the circles the anode rises significantly at the nominal anode current. Here falls in the aforementioned power vibration generator the compensation voltage decreases, the input resistance increases was the output amplifier stage, and the exciter does not guarantee the earlier value of the input voltage. Such protection does not require any additional equipment and allow it to work together with the usual quickly electronic protection against the tube on all sides Protect overloads.

In this way, the invention opened, as a result of the described features and advantages, new directions in development high-frequency broadband radio equipment with electronics tubes and transistors and forms a basis for further progress in this area.

Claims (9)

1. Electrical power vibration generator with an exciter ( 1 ) that generates vibrations and a power amplification stage ( 2 ), the power vibration generator having a controllable active element ( 3 ), the collector electrode of which is connected to an output circuit and between its emitter and its control electrode an input circuit is switched on (grid base circuit), which is connected to the output of the exciter ( 1 ) by a series-connected compensation voltage source ( 11 ) connected to the input circuit, which receives a vibration signal from the output circuit of the power amplifier stage ( 2 ) or from a separate compensation unit as a compensation voltage with the same frequency as the excitation frequency and in phase opposition to the phase of the voltage at the input circuit of the active element ( 3 ), characterized in that the exciter ( 1 ) is designed as a current source, the internal resistance of which is much greater than An input resistance of the power amplifier stage ( 2 ), and the amount of the compensation voltage is approximately equal to the amount of voltage (U _g ') on the input circuit ( 7 a) , so that the output voltage (U _e ) of the exciter is very small and thereby the Exciter ( 1 ) drawn power is reduced. 2. Generator according to claim 1, characterized in that if the exciter ( 1 ) generates amplitude-modulated vibrations, the compensation voltage source ( 11 ) generates an unmodulated alternating voltage, the frequency of which is synchronized with the exciter carrier and whose output circuit ( 17 ) is in Row with the input circuit ( 7 a) of the active element ( 3 ) is connected and the input circuit ( 7 a) with the output ( 10 a) of the exciter ( 1 ) connects ( Fig. 3). 3. Generator according to claim 1, characterized in
that the compensation voltage source ( 11 ) forms a passive multipole, a first pole with the collector electrode ( 6 ) of the active element ( 3 ) and a second and third pole with the output ( 10 a) of the exciter ( 1 ) or with Input circuit ( 7 a) are connected so that the circuit of the multipole between the second and third poles in series with the input circuit ( 7 a) , and
that the multipole is designed such that at least a portion of the current of the power amplifier stage ( 2 ) from the exciter ( 1 ) vibrations supplied through this multipole flows and generates a voltage between the second and third poles, which is related to the voltage at the input circuit ( 7 a) is so out of phase that the sum of these two voltages is less than the voltage at the input circuit ( 7 a) ( Fig. 4, 5, 6, 7). 4. Generator according to claim 3, characterized in that the passive multipole is constructed in the form of a parallel resonant circuit, in which one of the branches ( 25 ) is designed in the form of a voltage divider by two reactors ( 26 and 27 ) with the same sign is formed, the first outer point ( 28 ) of this voltage divider is the first pole and is connected to the collector electrode ( 6 ) of the active element ( 3 ) and the center ( 29 ) and the second outer point ( 30 ) the second and third poles form. 5. Generator according to claim 4, characterized in that the parallel resonant circuit forms the output circuit of the active element of the amplifier stage ( 2 ). 6. Generator according to claim 4, characterized in that when using a tetrode ( 60 ) as a controllable active element of the amplifier stage ( 2 ) of the parallel resonant circuit between the control grid ( 62 ) and the screen grid ( 63 ) of the tetrode ( 60 ) is connected, the first outer point ( 28 ) of the voltage divider ( 25, 26, 27 ) mentioned being electrically connected to the collector electrode ( 64 ) of the tetrode ( 60 ) via its output circuit ( FIG. 9). 7. Generator according to claim 3, characterized in that the passive multipole in the form of coupled resonant circuits ( 76, 77 ) is executed, one of which forms the parallel resonant circuit ( 76 ) with two branches, the first connection point ( 81 ) with the collector electrode ( 6 ) of the active element, and whose second connection point ( 82 ) is connected to the input circuit of the active element, the other resonance circuit ( 77 ) being switched on so that its partial circuit ( 84 ), the voltage phase of which approximately corresponds to the voltage phase of the Parallel resonance circuit ( 76 ) is connected between the second connection point ( 82 ) of the branches of the parallel resonance circuit ( 76 ) and the output of the exciter ( 1 ) ( Fig. 11). 8. Generator according to claim 7, characterized in that the coupled resonant circuits ( 76, 77 ) form the output circuit of the active element of the amplifier stage ( 2 ). 9. Electrical power generator according to claim 7, characterized in that when using the tetrode ( 60 ) as a controllable active element of the amplification stage ( 2 ) of the parallel resonant circuit ( 76 ) between the control grid ( 62 ) and the screen grid ( 63 ) of the tetrode ( 60 ) is switched, the first connection point ( 81 ) of the branches of this parallel resonant circuit ( 76 ) being electrically connected to the collector electrode ( 64 ) of the tetrode ( 60 ) via its output circuit.