DE607165C - Feedback circuitry - Google Patents

Description

The. The invention forms a feedback circuit which is opposite known arrangements characterized in that from an oscillation circuit in the secondary circuit of a pipe in the input oscillation circuit this pipe or in that of another pre-pipe energy via ohmic or predominantly ohmic Resistance is returned.

«O There are already feedback circuits became known about ohmic resistances. One of the same has with resistance amplifiers found in the way 'application that the feedback takes place across two tubes, in the series with a variable feedback resistance to the grid leakage resistor of the second tube which is part of the amplified voltage on the input of the first tube returns. Another arrangement is the so-called kallirotron, in which the same tube with the aid of a reversing tube for generating the phase shift necessary for the feedback is fed back between anode voltage and grid voltage.

However, when implemented, the invention follows the idea of extracting the energy to be returned from a circuit part capable of resonance. As far as feedback circuits of this type have become known, imaginary resistances are mainly used for the return of the energy. However, this method requires the peculiarity that the natural frequency of the two circuits must be higher than that of the vibrations to be generated, to occur when a Rückkopplungswir ^u effect on the imaginary resistance. In the same way, of course, the attenuation of the feedback system does not take place in its natural frequency. In a multi-circuit receiver, these facts have the practical effect of the disadvantage that the resonance curve of the feedback system is shifted with respect to the resonance curves of the other oscillation circuits. To illustrate this result, three curves are drawn in Fig. 1, α is the resonance curve of the first tuning circuit of a receiver, which in a three-circuit receiver without feedback would be the same as those of the two following circuits. If the circles 2 and 3 are fed back to one another, then only the resonance curve b results for this fed back system. The resonance curve of the entire receiver with the feedback of the circles 2 and 3 results from the multiplication of the curves α and b and is illustrated by c. This curve is asymmetrical. Compared to a symmetrical curve, this means a deterioration in selectivity.

However, this phenomenon does not occur when the feedback according to the invention is applied, according to which the return

Coupling energy supplying oscillation circuit with the circuit to be de-attenuated via a ohmic or predominantly ohmic vision lying in both oscillation circles at the same time Resistance 'is current-coupled. In this type of feedback, the opposite occurs to that of imaginary resistances the optimal feedback effect with purely ohmic resistance exactly in the ίο tuning frequency and otherwise practically in the tuning frequency of the resonance circuits.

FIG. 2 shows an example of a circuit using the new type of feedback. A and B designate the tubes of two successive stages. L ₁ and C ₁ or L ₂ and C ₂ are the members of the two oscillation circles. The resistors Y ₁ and R » ^ra it the bridging capacitances are used to generate the bias voltage on the grid of the tubes. If one follows the drawn-out circuit diagram, one recognizes that the two oscillating circuits S ₁ and So are each closed via the resistor R ₁ and that both circuits are current-coupled.

A further resistor R ₂ can be inserted into the circuit to regulate the feedback, as indicated by the dashed part of the diagram, so that the two circuits are also voltage-coupled. In order to be able to readjust the feedback in a known manner, either one of the resistors is adjustable or both resistors are selected to be variable.

In addition to the purely ohmic feedback, inductive or capacitive members can be provided in the event that it is necessary to achieve a certain desired frequency dependence of the feedback proves useful.

Claims (3)

Patent claims: ι. Feedback circuit in which the one necessary to de-attenuate a circuit upstream of an amplifier stage Feedback voltage at one connected in the output circuit of this stage Ohmic resistance is generated, characterized in that an oscillating circuit which supplies the feedback energy with the circuit to be de-attenuated via an ohmic signal lying in both oscillation circles at the same time or predominantly ohmic resistance is current-coupled. 2. Feedback circuit according to claim i, characterized in that the Oscillating circuits are voltage-coupled via a resistor. 3. feedback circuit according to claim ι and 2, characterized in that that one or more of the resistors used to regulate the feedback are variable. 1 sheet of drawings