DE658450C - Anode neutralization circuit for amplifying short waves - Google Patents

Description

Anode neutralization circuit for amplifying short waves The neutralization the purpose of the grid-anode capacitance is to separate the output circuit of a tube from the input circuit to decouple, so that a reaction of the controlled neutralized stage on the controlling stage is avoided. One flowing in the anode circuit of the controlled stage Alternating current cannot induce an alternating voltage at the controlling stage.

The object of the invention is, in a circuit with neutralization special means for the tube capacities that do not disturb the balance of the bridge to be provided to achieve a feedback.

A feedback is in some cases, e.g. B. with frequency multiplication or also in normal amplifier stages, to increase the amplification desired. The invention is intended in particular for transmitters, but can also be used in receivers be applied.

It is not common knowledge that eliminating the retroactive effect a neutralization is not yet a condition for a feedback is avoided. That feedback can actually occur can be seen if it should be noted that despite a decoupling of the input circuit from the output circuit from the anode alternating voltage, an alternating voltage between grid and cathode can be generated by voltage division. Is such an alternating voltage generated at the grid in phase opposition to the anode alternating voltage, a feedback occurs while there is negative feedback when in phase.

In the case of the in Figs. I to q. illustrated embodiment of the invention a feedback is achieved, the size of which is independent of frequency, and which also is adjustable.

One would have to achieve negative feedback in Fig. I through the capacitor Cl, whereas when this capacitor is replaced by an inductance, feedback is obtained could cause. However, while the negative feedback is frequency-independent (neglecting the inductive resistances of the grid and cathode lines), since the voltage division the anode alternating voltage only takes place via capacitances, would be a feedback frequency-dependent by means of a coil.

According to the invention, there is now a frequency-independent feedback achieved by connecting the capacitor C3 in Fig. i. So that the bridge balance To ensure that there is no interference, the capacitor C4 is also provided.

The invention therefore lies in this embodiment in that to achieve a frequency-independent feedback without disturbing the neutralization the input circuit (E in Fig. i) at the connection point of two capacitors (Cl and C2), of which one with the grid and the other with the a The end of the neutro capacitor (CG, 1) for the grid-anode capacitance is connected, and that the grid via a capacitor (C3) with-, the other end of this neutro-condensate; @ and the anode via a capacitor (C4)% t. the former end of the Neutrokon sators is connected.

In Fig. I the input circle is with E and the output circle with A. designated. The grid-anode capacitance is with the help of the neutro-capacitor CGÄ neutralized by means of anode neutralization circuit. The one shown in dashed lines Capacitor CGK represents the neutro-capacitor for the grid-cathode capacitance. The capacitors C1 and C2 have already been mentioned above. The capacitor C5 in the anode circuit consists essentially of the cathode-anode capacitance of the tube, the second The capacitance of the anode voltage divider is formed by the capacitor C,;.

In Fig. 2 the circuit according to Fig. I is redrawn so that one can see that Better recognizes bridge equilibrium. The parts corresponding to Fig. I are marked with given the same names.

To understand that by means of the capacitor C3 actually a Feedback can be achieved, the corresponding part of the circuit is in Fig. 3 drawn out. If the capacitor C3 equals the grid-anode capacitance, there is cathode potential at the grid, and therefore there is no negative feedback another feedback. However, if the capacitor is larger than the grid-cathode capacitance, so the voltage of the grid is below that of the cathode and is therefore out of phase and- has a feedback, while it has a negative feedback when the capacitor C3 is smaller than the grid-anode capacitance.

In the circuit according to the invention according to Fig. I or 2, the capacitor C3 or C4 is selected so large that the negative feedback caused by the capacitor C1 and the grid-cathode capacitance CGK as well as by the penetration of the tube is more than compensated for. Since the voltage divisions only take place via capacitors, the feedback is frequency-independent. It can be made changeable by making the capacitors C1 or C2 or the capacitors C3 or C4 changeable. The magnitude of the feedback is given by the following equation, in which Er is the alternating grid voltage and Ea is the alternating anode -; *. Voltage: The capacitors C1 and CGK can be thought of as being added with regard to the feedback, since the bridge points a and b do not carry alternating voltages against each other.

In Fig.q. is finally the application of the invention to the Push-pull circuit shown. The two tubes are labeled I and II. It is simply a case of applying the circuit according to Fig. 2.

It should also be mentioned that in Figs. I to q. a throttle for feeding the grid bias must also be simulated in the neutro branch.

Claims (3)

PA TRNTAN SPARDS i. Anode neutralization circuit for amplification short waves, in particular for short wave transmitters, characterized in that for the purpose . Achieving a frequency-independent feedback of the input circuit to the tap a capacitive voltage divider (Cl and C2 in Fig. i) is placed, one of which End with the grid of a tube and the other end with one side of the Neutro capacitor used to neutralize the grid-anode capacitance of the tube and that the grid is connected to the other side via a capacitor (C3) this neutro capacitor and the anode via a capacitor (C4) with the former Side of the neutro capacitor is connected. 2. Circuit arrangement according to claim i characterized in that between the cathode of the tube and the grid connection point opposite side of the voltage divider (Cl, C2) a capacitance (CGK) for neutralization the grid-cathode capacitance. 3. Circuit arrangement according to claim i and 2 characterized by the application to the push-pull circuit (Fig. Q.).