DE713395C - Circuit arrangement for suppressing certain frequencies by means of a frequency-dependent counter-coupled amplifier - Google Patents

Description

Circuit arrangement for suppressing certain frequencies by means of of a frequency-dependent negative feedback amplifier It is already known to suppress certain frequencies, e.g. ß. of the interference tone of g kHz at the low-frequency amplifier of a receiver, into the transmission line blocking or short-circuiting circuits for these frequencies between two amplifier tubes to be provided. It is known. such blocking circuits in the cathode line of an amplifier tube to use a strong one for the frequencies to be suppressed and a strong one for the others Frequencies, however, a lower negative feedback is caused. With these well-known Arrangements, the cancellation of the frequencies to be suppressed n'.e is complete; rather, the still transmitted and amplified portion of the unwanted frequency the greater, the greater the damping of the trap circuit. With great damping not only the frequency to be canceled is weakened, but also this frequency surrounding, more or less broad area. A sufficiently strong reduction the damping is often not possible or only possible at great cost.

It is also known to be a complete obliteration of all to be transmitted Achieve frequencies by placing the grid and the anode of a tube through an ohmic Resistance to be connected and .the grid of the following tube instead of the anode the previous tube is connected to a sliding contact on this resistor. This sliding contact can be adjusted so that no voltage is transmitted will. This circuit does not yet only allow complete suppression certain frequencies. If one were to create a series resonance circuit in series finite with the resistance switch, one could indeed cause an extinction iler resonance frequency achieve, but the gain of the tube would not be fully utilized, since only one Part of the reinforced; Voltage is tapped from the resistor. When applied of the invention is d: csr; laughing part does not exist.

1; the invention is in a frequency-dependent negative feedback Amplifier for the complete suppression of certain I, relites the output voltage of the negative feedback amplifier part in parallel to its input via an or several parallel paths, which are tuned out to the frequencies to be suppressed Series resonance circles and @% 'ecliselstrotmi-iderstätideti lying in series consist, ge-1; rigekoppel, and it is the impedance of each of these Alternating current resistance would equal the reciprocal product in terms of magnitude and phase the steepness of the tube of the negative feedback amplifier and the amplification including the counter-coupled amplifier part in front of this end tube dimensioned its coupling elements.

The invention is based on the knowledge that in the case of a slanting negative feedback in l'arallet circuit ini contrast to Spanritings negative feedback in series connection the input and output voltage always eliminates the one to be suppressed Frequencies is possible.

In particular, in the case of a single-stage tube amplifier, the resistor switched on between anode and control grid for negative feedback for the Frequencies or frequency ranges to be deleted have Olimian character and are the same the reciprocal steepness of the tube.

A basic embodiment of the invention is shown in Fig. I. Your amplifier 1- 'is supplied with the voltage to be amplified via the input terminals Kl and K. The increased tension is taken off by the small cells K4 and 1i. Terminals K., and K4 are grounded. Terminal Kg, at which a voltage approximately in phase opposition to the voltage at 1i1 should arise, which can always be achieved by appropriate polarity of a tfi @ transformer or, in the case of resistance-coupled amplifiers, by an uneven number of tube stages, is connected to 1i1 via the complex resistor R. so that a negative feedback is effected, which is different for the individual frequencies. That it must be possible to measure the resistance R so to loading for certain frequencies, CLALL IFIR these frequencies is the output voltage of K3 equal 11u11 is clear when nian the input voltage thinks as fixed and assumes that this once over the Amplifier L 'and dci @ other times is transmitted to the output terminal via the resistor R. It niu!: 'I will be possible to adjust the stresses transmitted on both paths by dimensioning i'. that they are exactly the same as anipple, but opposite in phase and thus cancel each other out.

If there are none in the amplifier for the frequencies to be suppressed Phase rotations take place (with the exception of one caused by a tube or a transformer caused exact phase reversal), is the one achieved without counter-coupling: @output voltage exactly in phase opposition to the input voltage. In this case the resistor R must be for the frequencies to be suppressed have an Ohnic character. As for very big ones Resistance A is the output voltage at 1i3 in relation to: g is the input voltage, for an infinitely small resistance R, on the other hand, in phase (since then the output voltage is equal to the input voltage), is readily apparent in his case. the existence Value for R ez: stieren niut>, with which the: @outputspaiinung by the value zero goes, with the phase between output voltage and input voltage of i8o- on o` jumps.

An exact specification for the resistance can be seen very well simply with a single stage amplifier. as shown in Fig. 2. With this amplifier, the anode of the tube is about a growl, just for blocking the DC voltage serving capacitor C and thus lying in Reilu, for The resistor R used for negative feedback is connected to your control grid, to which the Input voltage F_ is. Furthermore, the anode is determined by the load resistance Ra, which, like initially the resistance R, can be any impedance, connected to the positive pole of the anode voltage source.

The replacement scheme valid for the tube. which is obtained on the basis of the known idle equivalent circuit is shown in Fig.3. In this case, the voltage E works via the resistor R on the external resistance R "and parallel to it the inner tube: en-E.4lh - I via the internal resistance of the tube Ri also on the resistance R" from the voltage equations where Il is the alternating current flowing through R. I = the alternating current flowing through the tube, the relationship for the anode alternating voltage U follows by simple calculation: The anode alternating voltage is therefore only zero if the equation applies to the negative feedback resistance: The resistance R must therefore have an ohmic character for the frequencies to be suppressed and be equal to the reciprocal slope S of the amplifier tube.

In the case of the multi-stage amplifier (assuming that the output voltage is exactly in phase opposition to the input voltage), the following is required for complete extinction: where S is the steepness of the end tube and h 'is the voltage amplification factor of the counter-coupled amplifier part located in front of the end tube. The correctness of this formula is clear if the multi-stage amplifier is considered to be equivalent to a single-stage amplifier, in which the slope of the tube is equal to the slope of the output tube of the multi-stage amplifier, multiplied by the amount of preamplification.

The above formula also applies to the most general case that for the to suppressing frequencies, the output voltage is not exactly in phase with the input voltage is, but z. B. still small additional phase shifts .by the between, the Contains coupling links located in tubes. In this case V is and therefore also the resistance necessary for complete extinction is complex.

A practical embodiment is shown in Fig. 4 of your low-frequency amplifier a receiver in which the circuit according to the invention for suppressing the interference tone of 9 kHz is used. The anode of the first amplifier tube V, is across the ohmic resistance R, with the positive pole of the voltage sources, via: the coupling capacitor K with the control grid of the power amplifier tube h2 and via the series connection of the Ohmic resistance R1, the coil L and the capacitor C to the anode of the amplifier tube VZ connected. In the anode line 'of V. is the load dividend R ", the z. B. can be the transmitted speaker resistance.

L and C are dimensioned so that their natural frequency is exactly 9 kHz. R1 can be completely replaced in part by the resonance resistance of the series circuit will. This resonance level must as exactly as possible be equal to the steepness of the Tube V, be. In this case, the frequency of 9 kHz achieved.

With a given resonance resistance, the bandwidth of the series circuit depends and thus the width of the frequency range, which is also caused by the negative feedback branch is significantly weakened, depending on whether Z is large and C is small or vice versa. The larger L, the narrower the extinction area: ch. It's practically straightforward possible to build up the circuit with ordinary coils and capacitors in such a way that the extinction area is very small.

The advantage over the short-circuit circuits previously used as 9 kHz blocks in any case consists in the fact that for complete extinction not one vanishing small damping, but damping of finite size is necessary. At a practically occurring slope of 5 mA per volt, the resonance resistance must be used complete extinction zoo ohms amount, which is without any special lossless Building the circles can be achieved. But even with a larger resonance resistance the weakening of the undesired frequency. still very largely.

In the case of the arrangement shown, it would be further of the to be deleted Frequencies further away from the frequency practically no negative feedback can be achieved. However, if you want a certain .. negative feedback for the purpose of equalization in the entire frequency range can be achieved, as shown in Fig. q. indicated by dotted lines, parallel to the series circle lay an ohmic resistor R2. The condition for an unwanted extinction Frequencies in this case is such that the parallel connection of R1 and R2 is the same the reciprocal steepness must be. This condition is different from the one above are practically not given, since R2 is always much larger than R,.

D'-e invention is not limited to low frequency amplifiers, but can also be used with high frequency amplifiers. Fig.5 shows a Intermediate frequency amplifier stage of a receiver with means for suppressing the two neighboring frequencies which are 9 kHz away from the intermediate frequency. the Anode - the tube is over two series circles K1 and K2 with the control grid AC connected. The two circles are each on one of the ones to be suppressed Matched neighboring frequencies. The resonance resistance must also be equal to the reciprocal The steepness of the tube in order to achieve complete cancellation. Possibly Quartz crystals can be used as circles, these to achieve a sufficiently high resonance resistance with a special ohmic resistance in Must be connected in series.

The negative feedback according to the invention can instead of directly the control grid to which the voltage to be amplified is also applied another grid of the tube in question can be exercised. This is a prerequisite only that the grid, seen from the cathode, is behind the actual control grid and is positively preamble, such as B. the screen grid of a penthode. That The grid must therefore 'be connected to the actual control grid by electron coupling be. Negative coupling arrangements on the screen grid of a cathode are known.

Furthermore, (in particular for phase rotation in the case of the input voltage in-phase output voltage) between the amplifier output and the negative feedback used resistor an additional transformer must be switched on, de: - mostly, since it only serves to transmit a single frequency, it is very simple and cheap can be executed.

Claims (1)

PATENT CLAIMS i. Circuit arrangement for suppressing certain frequencies by means of a frequency-dependent negative feedback amplifier, characterized in that for the complete suppression of these frequencies the output voltage of the negative feedback amplifier part is parallel: to its input via one or more parallel paths, the series resonance circuits matched to the frequencies to be suppressed and from in series AC resistors lying therefor exist, is fed back, and that the impedance of each of these AC resistors is measured in terms of magnitude and phase equal to the reciprocal product of the steepness of the end tube of the counter-coupled amplifier part and the gain of the counter-coupled amplifier part in front of this end tube, including its coupling elements . Circuit arrangement according to claim i, characterized in that when the negative feedback is applied to a single tube stage, the resistor connected between anode and control grid for the frequencies or frequency ranges to be canceled has an ohmic character and is equal to the reciprocal slope of the amplifier tube of this tube stage. 3. Circuit arrangement according to claim a, characterized. that between the anode and the grid of the amplifier tube of the counter-coupled tube stage a series circuit tuned to the frequency to be suppressed is connected, the resonance resistance of which is equal to the reciprocal steepness of this amplifier tube. Circuit arrangement according to Claim i, characterized in that, for the purpose of simultaneous negative feedback for all frequencies, an Ohrn's resistor is placed parallel to the series circuit, which resistor is dimensioned so that, together with the resistors in series with the series resonance circuits, it causes a complete suppression of certain frequencies .