DE860500C - Receiver with automatic low-frequency bandwidth control - Google Patents

Description

Receiver with automatic low-frequency bandwidth control Es is known, the low-frequency bandwidth of a receiver as a function of to regulate the received field strength automatically. This known regulation aims to in the case of remote reception of weak stations, those in the range of high audio frequencies Suppress or reduce background noise.

It is also known to advance one of the fading control voltage Regulated low-frequency tube with one that only works for the high audio frequencies Equip negative feedback, which inevitably increases as a result of remote reception The gain of the low frequency control tube makes the high audio frequencies stronger suppressed as, at -local reception.

It is also known to be parallel to the output of the end tube or one Another low-frequency amplifier tube - a series resonant circuit tuned to 9 kHz to switch to the 9 kHz tone caused by the interference of two adjacent frequencies Sender arises to suppress. With simultaneous use of the above The 9 kHz lock would cause negative feedback from the high audio frequencies prevent the 9 kHz tone. However, it is desirable to also use this tone frequency counter-couple stronger suppression.

The invention relates to a receiver whose low-frequency fret width by regulating a control tube with negative feedback for the high audio frequencies by means of: the fading control voltage is influenced, and the output one by one 9 kHz short circuit, loaded protective grille tube. According to the invention is the negative feedback voltage in such a receiver the high audio frequencies are tapped from the protective grille of the end tube, and this is it Protective grid over an ohmic or inductive resistor or preferably over one 9 kHz tuned resonance circuit connected to its bias source.

In the example. Figure shows a double diode h1, which Low-frequency control tube V2, which with the control voltage obtained in the right diode is regulated, the tuning indicator tube V, and the protective grille end tube h4. The display tube Via the resistors R2, R3 and R4, Vg becomes one formed by R1 and by C3 Smoothed fading control voltage supplied as a display value. R7 is a resistor in the protective grid circuit of the output tube T14, on which an alternating voltage develops. This alternating voltage is fed to the control grid of the display tube via the capacitor C1 h, supplied, This alternating voltage, which also occurs at resistor R4, is generated by Gain in the display tube a voltage across resistor R5, which is about a small Capacitor C2 is transferred into the grid circuit of the low frequency tube h2. C1 and C2 are dimensioned so that the negative feedback predominantly for the highest frequencies, is particularly effective in the range of 9 kHz. With the rest. drawn switching elements no special dimensioning or new meaning is to be given. These elements are therefore also unspecified.

The negative feedback voltage is, not from the anode circuit, but taken from the protective grid circle of the tube h4. Namely, lies in the anode circle the 9 kHz blocker Sp, which effect when the negative feedback voltage from the anode decreases that the negative feedback voltage also has a minimum for these frequencies. In addition, when it is removed from the anode circuit, due to its inductive load under certain circumstances, undesirable phase shifts can easily occur.

Instead of the drawn ohmic resistance R7, a frequency-dependent one can also be used Resistance, especially a choke or one tuned to the high frequencies Find resonance circuit application. Dias is advantageous because it results in a further restriction of the negative feedback to the high frequencies results, d. H. the The edge of the frequency curve becomes steeper. On the other hand, a notable frequency-dependent effect Resistance in the protective grid line is in itself a frequency-dependent influence the gain, the tube, as a protective grid alternating voltage is known to have negative feedback. It is used here for negative feedback Frequencies from the output tube. .in. taken from the way. that at the same time the gain the output tube is reduced for these frequencies. A frequency-dependent switching element instead of the resistor R7, it has a multiplicative effect on the Frequency response. Exploiting this effect is only then of practical use It makes sense if you put a parallel resonance circuit tuned to 9 kHz in the protective grid lead because the 9 kHz lock is effective for both long-distance and local reception allowed, whereas a general suppression of the high frequencies by the immediate Protective grid negative feedback is not desired; because this is not subject to the Shrinkage control is therefore always effective.

Should the resonance circuit switched on instead of resistor R7 cause a tendency to feedback through phase shift, then this would have to go through an opposite phase shift in the following negative feedback wagon compensated will.

Claims (1)

PATENT CLAIM: Receiver whose low-frequency bandwidth through Control of a control tube with negative feedback for the high audio frequencies by means of the Fading control voltage is influenced, and the output one by a 9 kHz short-circuit circuit loaded protective grid tube, characterized in that that the negative feedback voltage of the high gate frequencies from the protective grille of the output tube is removed and that this protective grille has an ohmic or an inductive one Resistance or via a resonance circuit preferably tuned to 9 kHz its bias source is connected. Printed publications: German U.S. Patent No. 669,904; French patent specification No. & 24 rad2 '; British Patent No. 425 5925 507 884; U.S. Patent No. 1,936,597.