DE812931C - Amplifier circuit, especially phase reversal circuit for push-pull amplifiers - Google Patents

Description

Amplifier circuit, in particular phase reversal circuit for push-pull amplifiers It is known that a cathode resistance causes negative current feedback, which in general is undesirable because it reduces the gain and the effective internal resistance the associated tube enlarged. The cathode resistance is only used for generation a negative grid bias, it is known to be due to a sufficiently large one Capacitor bridged.

It is also known, the antiphase AC voltages for a To gain a push-pull amplifier instead of a transformer using a tube, their anode resistance evenly divided between the anode and cathode side is, so that the antiphase alternating voltages are removed from the anode and the cathode can be. The disadvantage of this circuit is that the relatively large cathode-side resistance causes a strong negative current feedback. In this In this case, bridging with a capacitor is of course not possible.

Circuits have already become known which are used in the two mentioned Eliminate the current negative feedback in other ways. With these circuits namely, the capacitor of the anode screen member of the preceding tube does not become to the cathode of this tube, but to the cathode of the following tube, to the the cathode resistance is connected. This ensures that the anode alternating voltage the first tube directly feeds the grid cathode section of the second tube, so that the negative feedback effect of the cathode resistance of the second tube is eliminated.

The invention brings in the event that the tube with cathode resistance a screen grid tube (protective grid tube) is a savings. In the invention an amplifier circuit with a tube is therefore required, at its cathode resistance an alternating voltage occurs. Here, in particular, the above-mentioned known Phase reversal thought. According to the invention, the anode resistance is the preceding, via a capacitor or a galvanically coupled tube instead to the anode voltage source to the screen grid of the tube with cathode resistor (Phase reversal tube) connected, which is DC-wise over. a resistance to a positive direct voltage and alternating current via a capacitor the cathode of the tube with cathode resistance (plias reversal tube).

The invention thus shows that the screen member for the screen grid voltage the tube with cathode resistance and the filter element for the anode voltage of the previous one Tube can be combined in a common sieve member. It stays that way Obtained advantage that the current negative feedback of the cathode resistance is eliminated is.

The figures show exemplary embodiments of the invention.

In Fig. I is a bypass capacitor for the cathode resistance Rk superfluous because the circuit shown causes negative current feedback of the cathode resistance prevented. According to the invention, the anode resistance Ra of the tube I is The screen grid of the tube 1I connected, which is DC-wise across the resistor R is fed by a positive voltage, while it is ac-wise with the Cathode is connected across the capacitor C. That is why the feeds at the anode resistor Ra occurring alternating voltage only the grid cathode path of the tube 1I and is not due to the cathode resistance Rk. This resistance is not part of the Anode resistance of the tube I effective because a certain at him through the tube II AC voltage is generated which is in series with the anode AC voltage of the tube i is switched.

The invention is also to be regarded as applied when the Cathode resistance Rk is bridged by a small capacitor. Indeed is this both with regard to the negative feedback and with regard to the screening effect of the Switching elements R and C unnecessary.

In Fig. 2 is the known phage reversal circuit mentioned in the second paragraph above based on which the grid alternating voltages for the push-pull tubes a and b can be removed from the anode and cathade of tube 1I. The effective anode resistance the tube 1I is divided into the two resistors R, and Rk for this purpose. Otherwise the circuit is the same as in Fig. I. Receives in this circuit the tube I has a larger anode voltage than in Fig. i, because of the cathode resistance Rk is greater to achieve a sufficiently large AC voltage (20 to 5o kOhm) and therefore the screen grid also has a higher voltage to earth.

The tubes I and 1I in Fig. 2 can be galvanically or via the resistance capacitance coupling shown in dashed lines must be coupled. Are. she galvanically coupled, the circuit according to the invention effects an additional one DC negative feedback in the sense of stabilizing the circuit. At a Namely, anode current increase in the phase inversion tube 1I decreases the screen grid voltage from and through the resistor Ra the grid bias in the negative direction to, so that the anode current increase is weakened.

Some changes to the circuits are still possible. The screen grid resistance As is known, RS can be used in amplifiers with galvanic coupling instead of the Anode voltage source can be connected to the cathode of the tube 1I. The resistance In both figures, R can be connected to the anode of the Tube II must be laid. Then it is no longer parallel to the cathode resistance in terms of alternating current, but parallel to tube 1I.

Claims (2)

PATENT CLAIMS: i. Amplifier circuit with a tube, on whose Cathode resistance an alternating voltage occurs, characterized in that the Anode resistance (R ") of the previous one, via a capacitor or galvanically coupled tube (I) instead of the anode voltage source to the screen grid of the Tube (II) with cathode resistor (Rk) is connected, which is direct current Via a resistor (R) to a positive direct voltage and alternating current Via a capacitor (C) at the cathode of the tube (1I) with cathode resistance (Rk) lies. 2. Amplifier circuit according to claim i, characterized by the application to a phase reversal circuit for push-pull amplifiers, in which the anode resistance of the phase inversion tube is evenly divided between the anode and cathode side and the antiphase alternating voltages are removed from the anode and cathode (Fig. 2).