DE886768C - Circuit arrangement for regulating or modulating an alternating voltage - Google Patents

Description

Circuit arrangement for regulating or modulating an alternating voltage In electron tube amplifiers are; often one or more so-called tax brackets built in for specific purposes, by. which the amplification manually or automatically is controlled. These control stages can either be constructed so that at your control one yourself over the whole. Amplitude range of the transmitted signal extending uniform change is achieved, or be built so that a larger one for a particular part of the amplitude range of the transmitted signal or minor change in gain compared to that of the rest Parts of the amplitude range is effected. In the latter case there is a compression or a stretching of the emitted signal compared to the recorded signal achieved, so that one speaks of compressing and stretching.

An amplifier control, as was previously the case by supplying a voltage to a control grid or a power distribution grid is with very large disadvantages associated with the control of the signal amplitude to be achieved with a corresponding change in the anode direct current of the controlled tube, connected is. This always results in a certain instability a, and if the controls are subject to rapid changes, which is particularly the case with the use of compressors and stretchers for acoustic impulses is the case, the anode circuit of the control tube creates voltage pulses that are passed on and in the following, amplifier stages are increased and finally to a considerable extent Noise generation during signal reproduction.

To eliminate these noises, inter alia. Control stages in push-pull connection been used. With this type of circuit, the resulting during control should be Changes in the anode current theoretically neutralize each other; in the In practice, however, it turned out that only an incomplete compensation is achieved, since the two tubes in the circuit usually do not have quite the same characteristics to have. To achieve a good balance it must. paid attention to during manufacture so that tubes with characteristics that are as similar as possible for the control stages to be selected. Furthermore, with push-pull control it is necessary that @ the control stage, coupled to the other amplifier stage by transformers is, which is considerably more expensive than using resistive couplings: could.

The invention comprises a circuit arrangement for control stages in Amplifiers, through which a more complete compensation for changes in the control system accompanying uniform anode current by simpler and cheaper means than the previously used is achieved.

A circuit arrangement according to the invention for control and modulation stages is characterized in that the stage has at least two tubes: (tube systems) contains: a main tube, which consists of a multigrid tube, with an outer: Control grid or equivalent grid that acts as a power distribution grid, to which a signal voltage or carrier voltage is applied, and an auxiliary tube, preferably a pentode, which with the main tube a fully or partially has common cathode impedance 'and supplies power to the anode circuit of the main tube, in addition, in a tube a control grid controlling the emission current of this tube is arranged, which is set up for the supply of a control voltage or a modulator voltage is, and in the other tube the corresponding grid connected in such a way is that the emission current of the latter tube decreases when the emission current of the former tube increases, and vice versa.

In one embodiment of the invention, the main duct and the Auxiliary tube connected in parallel with respect to its anodes and cathodes, and the emission control grid, to which no control or modulation voltage is supplied is with one place connected to the common cathode impedance. It is also useful that the Emission current control grid to which a control or modulation voltage is supplied will, as. Variable gain grating is formed while the tube, on whose emission current control grid the voltages mentioned are not applied are, a large, and essentially constant, steepness with respect to the aforesaid Has grid.

In the drawing a control stage according to the invention is shown, which is described in more detail below.

The control stage has a control or main tube i and an auxiliary tube 2. - In the figure, the main tube consists of a heptode that provides such operating voltages are supplied that their outer control grid 3 as. Power distribution grid, and its inner control grid 4 also as a grid with a variable gain factor is designed so that the tube has a greatly variable steepness with respect to has her inner control grid. Instead of a heptode, any other can of course be used Tube can be used as the main tube in a control stage according to the invention, provided that they first have an external control grid or other equivalent Has arranged grid that can act as a power distribution grid, and secondly a grid located within a power distribution zone suitable as a Serve control grid. The hepto, de i can, therefore z. B. by a pentode or Hexode to be replaced.

A tube with a large and is preferably used as the auxiliary tube essentially. uniform slope, e.g. B. an ordinary pentoid. the Anodes and cathodes of the auxiliary tube 2 are directly connected to the corresponding electrodes the main tube i connected so that the auxiliary tube 2 and the main tube i are related their anodes and cathodes are connected in parallel. The control grid 5 of the auxiliary tube 2 is directly earthed or with a point on the cathode resistor of the main tube i connected so that the voltage drop across the whole resistor or part the same represents the voltage supply for the auxiliary tube 2. Instead of the direct The cathode of the auxiliary tube 2 can of course be connected between the cathodes shown also be connected to a tap of the cathode resistor 6.

The operating voltages are supplied to the two tubes i and a via the with Plus denoted line from a direct current source not shown in the drawing fed. From this line the anodes of the two tubes i and 2 receive the Voltage across a common output resistor 7, while the screen grid 8 the main tube i its voltage via a resistor 9 and the screen grid io the auxiliary tube 2 its voltage over a. Resistor i i and a potentiometer 12 receives. The two: screen grids are also grounded, namely that of the main tube. i through a resistor 13, and. that of the auxiliary tube 2 via a potentiometer 12 and a resistor 14, the signal voltage to be amplified by the control stage is between the outer control grid 3 and the cathode of the main tube i via the Terminal 15 supplied. As a result of the power distributing effect of the outer control grid 3 is then receive an anode current in a known manner, which is accordingly .the signal voltage changes. Furthermore, between the inner control grid q. and the cathode of the Main tube i fed a control voltage via terminal 16, which the strength of the emission current flowing into the electricity distribution zone is determined and in its absence a signal at the outer control grid 3 also the strength of the, the anode, reaching Part of the emission current. A gain in the control voltage therefore causes a Amplification of the anode direct current and consequently. also an increase in the steepness the tube for the. Signal voltage. The potential at the cathode of the tube that is by which changes in the emission current adapts is decisive for the anode equilibrium current, because of the current distribution control there is no significant current with signal frequency flows through the cathode resistor 6. With the circuit shown, the auxiliary tube delivers 2, as can easily be seen, the additional anode circuit shared with the main tube i Current that increases when the anode current of the main tube, i decreases, and vice versa, so that the anodem current change is compensated for by the control effect is achieved. The signal amplified in the stage is then connected to the output terminals 17 forwarded.

So that the said increase and decrease in the anode current of the relevant Tube neutralized each other as largely as possible, of course, is a certain Coordination of the operating conditions of the tubes required. According to the invention this is done by setting a suitable screen grid potential for the tubes. For this purpose, a potentiometer 12 should preferably be in the Screen grid lead of the auxiliary tube 2 corresponding potentiometer in the screen grid lead the main tube i can be arranged. At the cheapest. Attitude is achieved a practically complete compensation within a not too large control range. The fact of achieving such a complete compensation that no, uncompensated Control margin remains, is explained by the fact that the anode direct current, its Changes to be compensated for, only part of that supplied by the auxiliary tube Em: is.sion.sstroms. The screen grid potential is therefore only needed in this way to adjust that exactly as much emission current from: the tube in question through the screen grid conductor flows away, so that the total current in the anode circuit is constant. However, if the tax areas are larger, there will generally be none full compensation achieved within the entire control range. According to a However, further development of the invention, full compensation: can be achieved through appropriate use of so-called sliding screen grid voltages. In the The embodiment shown in the drawing is the sliding screen grid voltages through in the screen grid supply lines, connected series, ltwideratoren 9 and i i generated.

As can be seen from the above, has a tax step after the Invention various advantages over the previously known systems of this type. The ones associated with the use of: Couplings in push-pull circuits are omitted Requirements for the. Equality in terms of the individual components, etc. of this used tubes and the transformer couplings to the other parts of the amplifier. The new circuit arrangement also shows in addition to the cheaper production far better compensation properties. Minor changes in the characteristics of the Tubes such as B. the characteristics, not, as with the previously known Circuits, corresponding compensation defects, but such defects are automatic compensated by the sliding screen grid voltage. Changes in the anode resistance of the auxiliary tube help improve the compensation. Another factor which can be of practical importance due to the associated simplification the coupling, consists in that the cathodes or anodes of the main tube and the Auxiliary tubes are directly connected to each other, as a result, there is the possibility of to replace both tubes with a special combination tube, which the required characteristics and a smaller number of external connections.

Although the circuit arrangement according to the invention so far only for a. Area of use was described, namely as a control stage in an amplifier, so, there are still many other important uses. she can z. B. can easily be used as a moidulator. In this case the, Moldulation stress, such as B. a low frequency signal voltage, the control grid q. fed instead the control voltage, and to the outer grid 3, the carrier voltage instead of the signal voltage. The circuit then works as a compensation modulator, in which as a result of the effect of the auxiliary tube only the monodulation products of the sum and difference frequencies appear at constant anode direct current strength The invention is of course not on the shown. Design types are limited and substantial modifications are possible still as in the frame. to be regarded as lying within the inventive idea. For example the connections of the tube grids controlling the current emission can be interchanged so that the control grid of the auxiliary tube is supplied with control voltage and the inner control grille of the main tube, e.g. with a point on the cathode impedance connected. A circuit modified in this way is that described above completely equivalent. Furthermore, it is not necessary that the output electrodes of the two tubes are directly connected to each other, because the same effect can essentially be achieved when. the anode current the auxiliary tube only flows through part of the anole impedance of the main tube.

Claims (5)

PATENT CLAIMS: e.g. Circuit arrangement for regulating or modulating a first. AC voltage by a second AC voltage or by a pulsating DC voltage using two electron tubes, with common cathode and anode impedance, of which at least one is a multi-grid tube with two control grids and a screen grid arranged between them, the said first alternating voltage acting as a power distribution grid outer control grid of the multigrid tube and said second voltage is supplied both to the inner control grid of the multigrid tube and to an electrode of the other electron tube in such a way that the emission current. im, the one. Tube increases when. it decreases in the other, and vice versa, characterized in that the second-mentioned electron tube is controlled essentially only by the said second voltage, the common cathode impedance of the two tubes; is essentially ohmic with regard to both of the voltages mentioned and the tubes and the operating voltages supplied to them, in particular the screen grid voltages, are selected so that the resulting anode voltage at the common anode impedance does not have any component of the sequence or the character of the aforementioned second voltage contains. 2. Circuit arrangement according to claim r, characterized in that that, the anodes and the cathodes of the two tubes are interconnected and one the emission current of the second: tube controlling electrode of this tube to one; Point of the cathode impedance common to both tubes is connected. 3. Circuit arrangement according to claim r or 2, characterized in that the inner control grid of the first tube has a variable slope. 4. Circuit arrangement according to claim 2, .da-characterized by da.ß die, the emission current of the second. Steering tube Electrode .dieser tube has a large and essentially constant slope. 5. Circuit arrangement according to claim r, characterized in that, ß also the second Tube has a screen grid and the screen grid has its operating voltages Obtain resistances of such a size that they result in sliding screen grid voltages, which cause that to participate in the common. Anode impedance of the two tubes resulting resulting anode voltage within, a second control range none Component of the frequency or character of said second. Contains tension.