DE707487C - Amplifier circuit with variable bandwidth - Google Patents

Description

Variable Bandwidth Amplifier Circuit The invention relates to an amplifier circuit in which a change in bandwidth by change the internal resistance of that tube takes place in whose anode circuit the to influencing resonance circuit: is switched on.

Frequently the demand is made to operate frequency-selective Build amplifiers, especially high and intermediate frequency amplifiers, in such a way that that the degree of selectivity, d. H. the bandwidth of the frequency pass range changed simple means within certain, often very broad limits can be. It would be desirable to change the gain in this change in bandwidth remains at least somewhat constant. This requirement is met by the invention Fulfills.

It is known to increase the gain of a stage by changing a Operating voltage of a tube, e.g. B. the control grid or screen grid voltage, to regulate. The internal resistance and thus the bandwidth change at the same time of the resonance circuit in the anode circuit. This change in bandwidth is However, this is only a side issue, since the purpose is gain control is. -It is also known to use the anode-cathode path in an oscillating circuit of a receiver an additional attenuation tube designed as a single grid tube parallel to switch, which is regulated at the control grid. However, this changes at the same time the reinforcement of the stage.

It is also known to reduce the bandwidth by influencing the internal resistance a pentho, de with the help of a change in the retarding grid (safety grid) voltage to regulate. The more negative the braking grid of a penthode is made, the more the inner resistance becomes smaller. With this type of regulation it is quite impossible the gain -during the control process only somewhat constant to keep.

It is also known to change the bandwidth control The gain change occurring in the feedback of a tube by an opposite one To compensate for the gain control on the control grid of another tube stage. One such additional regulation does not apply to the application of the invention.

The invention is based on the known amplifier circuit with variable Bandwidth by influencing the internal resistance a pipe lattice or penthode, in whose anode circuit there is a resonance circuit, by means of regulation of the anode current. According to the invention, the operating point of the tube is so in the Near the maximum of those representing the gain as a function of the anode current Curve placed that over the range to be controlled of the bandwidth of the gain is practically the same.

In resistance amplifiers with penthodes it is known that when the bias voltage on the control grid changes, the gain passes through a maximum. However, this is due to the fact that with a small negative grid bias the anode current is large and therefore due to the large voltage drop at the ohtnschen Anode resistance the anode voltage is only small and that on the other hand at large negative grid bias, the anode voltage is high, but the anode current is small. From this known fact, however, it cannot be inferred that also when switching on a resonance circuit in the anode circuit, which is known the anode voltage does not influence, a gain maximum is present. this is, as will be explained in more detail below, due to the fact that as a result the control increases the anode current, the slope increases and the internal resistance decreases faster. Since the internal resistance is initially high, the influence predominates the steepness until the influence of the decrease in internal resistance on the gain predominates.

To understand the invention, some considerations should be made about the internal resistance of a tube operating with current distribution. As is well known, the following relationship applies to the internal resistance of a penthode or a secondary emission-free screen grid tube: where b is the internal resistance constant given by the construction of the electrode system of the tube, U "is the anode voltage and J" is the anode current. The higher the anode voltage and the smaller the anode current, the greater the internal resistance direct influence on the internal resistance, but only an indirect one, in that it helps to determine the anode current When considering these relationships, the internal resistance of the tube is to be assumed to be connected in parallel to the resonance circuit. The selectivity of the resonance circuit and thus of the entire amplifier stage can be controlled in a known manner by changing the anode current or the anode voltage, or both Therefore set further limits. The change in the anode current can be brought about by changing the negative control grid bias voltage or by changing the screen grid voltage or by changing both variables at the same time.

Due to the choice of the position of the operating point, the bandwidth control according to the invention has the advantage that the gain remains practically the same. As is well known, the following relationship applies to the gain V of a tube: It is not only the internal resistance R !, but also the steepness S depends on the anode current'JQ, and for the normal U "@ '= characteristic curve: S - a # Yes'/;, where a depends on the construction From these relationships it can be read that with an increase in the anode current Ja, the slope S increases, while the internal resistance Rt decreases. But since the slope S increases with JQ'13, the internal resistance R, on the other hand, directly decreases proportionally to ! Q, the gain V of a tube, measured at constant anode voltage U "as a function of anode current 1Q, must first increase with increasing J" and at a certain anode current, the strength of which depends on the external resistance Ra and the product b # U " depends, reach a maxianum, and then decrease again with a further increase of Yes. . The shape of the curve representing the gain as a function of the anode current and the height of the maximum depends very significantly on the course of the Ja U, characteristic (U8 = grid voltage), i.e. on the change in slope as a function of the anode current, and can be changed in in a manner known per se by changing the shape of the characteristic curve, such as, for. B. in an exponential curve, can be largely influenced.

In the drawing, Fig. T shows the gain and bandwidth curves recorded on a penthode as a function of the anode current for various anode voltages. The bandwidth plotted in arbitrary units changes quite considerably along these curves. With very small anode currents, which are below the value belonging to the maximum of the gain curve, the selectivity of the resonance circuit connected to the anode is determined by the internal resistance R; of the tube is not affected at all, since R; > Ra ist- The well-known relationship applies to the gain in this area: V = S # Ra; so it increases roughly proportionally at. In the vicinity of the maximum of V, R = c \ DR, ", so that the bandwidth of the resonance circuit or, more precisely, the complex resistor formed by the resonance circuit and tube, is approximately doubled. The anode current increases to a value which is approximately twice as large as the current value associated with the maximum of the gain curve, the bandwidth is approximately three times the original value; the figures given here are only indicative and can be taken precisely from the curves.

The bandwidth can be changed in a manner known per se Change an operating voltage take place, the size of which affects the internal resistance. The following options are therefore available: i. Anode voltage U "and screen grid voltage US remain constant; Regulation of the anode current I "by the control grid bias U ,.

2. Anode voltage U, and control grid voltage U, remain constant; Regulation of the anode current 1Q by the screen grid voltage U ,.

3. Anode voltage U "constant; control of the anode current IQ by the control grid bias U, and the screen grid voltage U ,.

q .. Simultaneous regulation of the anode current by one of the below i to 3 listed measures and the anode voltage.

For clarification, these control options are illustrated in Figure 2. The tube R contains a cathode I (heated indirectly by the heating element H), a control grid G, the screen grid S and the anode A. It is assumed here that the secondary emission of the anode is excluded by suitable surface treatment or distance measurement. The alternating voltage to be amplified is fed to the input circuit R, while the amplified voltage is taken from the output circuit Ra connected to the anode. A DC voltage supplied to the terminals marked + and - is available, which is supplied by a battery or a power supply unit and which is applied to a voltage divider P. The control grid, the cathode, the screen grid and the anode are connected to these etx by means of the adjustable taps 1, 2, 3 and q In a corresponding manner, only tap 3 has to be shifted for a setting according to FIG n be. A simultaneous change of the screen grid voltage and control grid biasing (case 3) can be done either by moving the taps i and 3 or the tap 2 alone. It is clear that for the fourth case the tap q. must also be changed.

From Fig. I it can be seen that an anode voltage of U "= 200 volts with an anode current of .q. # 5 mA corresponds exactly to the same gain like the anode voltage Ua = 100 volts with an anode rest control of mA, but the bandwidths for these two states are 1: 2.

From this it can be deduced that through a simultaneous increase or change of anode current and anode voltage a bandwidth control at exactly Can achieve a constant degree of reinforcement. The implementation can, for. Am the way that the change in the anode current is caused by one in the screen grid circuit lying series resistor takes place, at the same time the anode voltage through a series resistor located in the anode lead is changed, namely in such a way that with increasing anode current the anode voltage also grows. Instead of a special series resistor you can do the same thing! Of course .also with a voltage divider resistor in the relevant circuits gruechen. As tests have shown, it is possible to use anode and screen grid voltage the same voltage source and a common series resistor or a common voltage divider for regulating the anode and screen grid voltage to use.

An exemplary embodiment is shown in Figure 3. It will be the same Tube as used in Fig. 2, the control grid G of which controls the voltages to be amplified -be fed and from their anode circuit the increased power via the oscillating circuit Ra is removed. The screen grid or anode DC voltage is supplied by a for both electrodes are supplied with a common voltage source UA. In the common circuit The series resistor W1 is located on these two electrodes. Furthermore, can still be fixed or variable resistors W2, W3 are provided to the anode or screen grid rest voltage different to make great. The last two resistors mentioned can also be missing, which in particular with penthodes or other tubes with screen grids and suppressed secondary emissions is easily possible, and then the screen grid and anode rest voltage are mutually exclusive same. The block capacitors Ca, Cä serve as a short circuit in a manner known per se for alternating voltages.

The measures mentioned for changing the selectivity can of course can also be triggered automatically by the wave to be received or amplified. You can z. B. the selectivity to a function of the amplitude of the amplified Vibrations make in the sense that with increasing amplitude a decrease in the Selectivity occurs and the amplifier or receiver in question if it is missing of a signal has the lowest bandwidth and thus the lowest susceptibility to interference owns. The automatic regulation can, however, also work in the opposite sense in that a large input amplitude corresponds to a large selectivity. This case is also known to be of importance for reception technology. In all Cases it is only necessary to set the input amplitude to perform one of the above to use mentioned regulation options by z. B. as grid voltage is used. The polarity of the rectified voltage depends on the desired Type of regulation to be carried out, d. H. depending on whether there is an increase or decrease in selectivity with increasing amplitude. In contrast to similar circuits where The aim is to regulate the gain, the gain remains by bringing the operating point close to the maximum of the gain curve sets, practically constant during the control process. Above all, it seems appropriate to choose the working point so that the maximum of the gain curve after both Pages is fallen short of: in this case is with the lowest possible gain change to be expected, especially since the maximum is fairly flat.

Claims (4)

PATENT CLAIMS: i. Amplifier circuit with variable bandwidth by influencing the internal resistance of a screen grid tube or penthode, in whose anode circuit there is a resonance circuit, by regulating the anode current, characterized in that the working point of the tube is in the vicinity of the maximum the characteristic curve representing the gain as a function of the anode current is placed that over the range of bandwidth to be controlled, the gain is practically the same. 2. Amplifier circuit according to claim i, characterized in that that the anode current by changing the control grid bias or the screen grid voltage is regulated. 3. Amplifier circuit according to claim i, characterized by a such a choice of the operating voltages that the maximum of the gain curve lies in the middle of the control range. 4. Amplifier circuit according to claim i, characterized characterized that with the regulation of the anode current the voltage in the same Meaning how the anode current is regulated in such a way that the regulation range is enlarged shows in which the gain is practically constant.