DE720125C - Cascade amplifier with changeable negative feedback - Google Patents

Description

Cascade amplifier with changeable negative feedback negative feedback are known in amplifier technology for the purpose of linearizing the frequency band or the amplitude dependence is used. In many cases it is necessary the negative feedback corresponding to the gain that the negative feedback amplifier should own to make it changeable.

The gain factor is due to the usual frequency-dependent, phase-rotating switching elements of the amplifier, such as the coupling elements and tubes, complex. In the case of the negative feedback amplifier, positive feedback now occurs the two frequencies at which the phase angle of this frequency-dependent gain factor including the phase angle of the negative feedback factor (the phase rotating Elements in the negative coupling path also contribute to the phase shift) I8o` achieved. The size of the gain drop, i.e. H. the (frequent) Damping, in these points results in the possible size of the negative feedback without self-excitation. The negative feedback must always be smaller than the decrease in the gain factor, including the negative feedback factor for the phase shift of I8o- (cf. also H. S. B l a c k, The Bell System Technical Journal, January 193-) # If used multiple cascades, the phase angle of the gain factor grows much faster than the cushioning. The possible stable negative feedback becomes with an increased number of Amplifier cascades are therefore lower. Reference is made to Fig: I for an explanation.

This figure shows an example of the dependency of the damping and the phase angle of a simple coupling element as a function of the Frequency .. The curves for the attenuation and for the phase angle as a function of the frequency are related to the same abscissa. This diagram illustrates the conditions in a coupling member which has the high Frequencies attenuates as it z. B. one of a resistor along and a capacitor across Transmission path or an inductance along and a resistor across the transmission path introduces existing coupling link. The corresponding diagram: lmni is frequency reciprocal for coupling elements that put the low frequencies at a disadvantage. The frequency f, The so-called cut-off frequency means that the apparent resistance is at this frequency the coupling element longitudinally and the coupling element transversely to the transmission path to each other are the same. At this point, the phase angle 45 'and the attenuation are therefore the same i- .. From this diagram it can be seen that when using a single link the attenuation is infinite at a phase angle of 9o ', d. H. any size Negative feedback can be used without fear of positive feedback is. The phase angle of i So 'is not reached at all in this case. Even in the case of two coupling elements, at the above-mentioned phase angle of a `; 9o ° = 18o ° the damping is infinite. But if you use three coupling elements with the same Cut-off frequency, then i 8o 'total plias rotation are already reached if each Coupling element has a phase angle of only 6o '. Now occurs with a simple one Coupling element with a 6o 'phase shift only approximately twice attenuates. Since the resulting damping is given by the three coupling elements, the achieved maximum possible damping 23 times, i.e. H. 8 times the amount. Already at three terms with the same cut-off frequencies can only be used with a smaller one can be used as the 8-fold negative feedback. These connections are already known. If the number of coupling elements increases, the possible negative feedback falls still very strong. It should be noted that especially at the high frequencies the The number of phase-shifting links (coupling elements) is always greater than the number of Amplifier stages is because of the distributed capacities (e.g. the tube capacities and the line capacitances # and the distributed inductances are further undesirable Phase rotations arise.

It has therefore already been suggested the possible negative feedback due to a very extensive shift in the individual cut-off frequencies of the coupling elements to enlarge the cascades. The frequency-dependent .11) case of the gain factor including the negative feedback factor then essentially arises at only one Coupling member, and the cutoff frequencies of all other coupling members are so far from that the voice of the phase rotations of all other coupling elements essentially (o 'does not exceed.

With negative feedback amplifiers with a wide frequency band, one is such a wide separation of the limit frequencies of the coupling elements in general only possible if the frequency band of the amplifier not fed back through the coupling element, which is supposed to provide the great damping, so severely trimmed becomes that the required frequency bandwidth is only available in the negative feedback state is.

Fig. Z illustrates the frequency-dependent amplification with and without negative feedback for two amplifiers with different frequency bandwidths. The curve i shows the gain curve of the non-negative feedback amplifier whose transmission range z. B. 3 is 0 to 10000 Hz. If this amplifier is fed back, the curve z. This amplification curve has become more straightforward than curve i and, secondly, the transmission range has been expanded considerably. These relationships are known. At the frequencies at which the phase angle of the amplification factor including the negative feedback factor i is 8o ', this amplification curve is known to have maxima, since positive feedback occurs for these frequencies according to what has been said above. The height of these 'maxima is given by the damping of the coupling elements including the elements in the negative feedback path. In order to obtain the curve i according to Fig. 2, it is necessary, as has already been suggested, e.g. B. for the high frequencies, the cutoff frequencies of the coupling elements and also that element that is supposed to enable the negative feedback by increasing the attenuation to be placed well above the upper frequency limit of the transmission range.

However, this is not possible without a significant loss in gain of curve i possible, since the amplification factor of the amplifier is determined by laying out the cut-off frequency sinks.

These disadvantages can be avoided in that the gain curve i according to Fig. a the cutoff frequencies of the coupling elements, which are only used for phase rotation of the amplification factor should only be put out as far as without significant gain loss is possible, but the cutoff frequency. of the Counter-coupling by the coupling element that enables the attenuation increase the cut-off frequencies of the aforementioned elements is lowered far. Since the Negative feedback linearizes the frequency band, despite the fact that curve 3 in Fig. 2 of the non-negative feedback Amplifier no longer the target frequency band bridged, the gain curve: 1 of the negative feedback amplifier in the required Frequency range be straight forward. _ This known procedure is "no longer possible, if, as in the present invention, the negative feedback can be set to different sizes should be made. Either is then the frequency band of the non-negative feedback Amplifier is sufficient, but then as a result of the impossibility of the cutoff frequencies the remaining coupling elements move out far enough, not sufficient negative feedback to be possible; or by inserting the cut-off frequency of the negative feedback the coupling element that makes it possible in the first place achieves a large negative feedback, but then the frequency band of the amplifier that is not fed back is no longer used be sufficiently straight, as curve 3 in Fig. a shows. The change in size The negative feedback is particularly necessary when one and the same amplifier to serve several different purposes, e.g. B. in studio systems as a line amplifier or as a control amplifier or as a modulation amplifier.

This frequency band limitation in the non-negative feedback state can according to the invention in a cascade amplifier with variable negative feedback and coupling = breakdown of different cut-off frequencies are avoided, that with an arbitrary change in the size of the negative feedback voltages inevitably also the cut-off frequencies of the ones in the transmission path of the amplifier Coupling elements or additional switching elements lying in the negative feedback path can be changed in such a way that the limit frequencies are increased when the negative feedback is increased those elements that determine the frequency band to be transmitted by the amplifier, without the influence of an increased Considered negative feedback, further into the transmission frequency range of the amplifier be pushed in (Fig. a).

This can e.g. B. for the high frequencies according to Fig. 3 by simultaneous Change of the capacitor C1 lying parallel to the grid of the tube R, 3 with the change in the negative feedback resistance R1 ,, - take place. It corresponds here large negative feedback, so large resistances R ", large values of the capacitor Cl. It is useful here to use the two switching elements that can be changed at the same time with a control button to operate, thus a positive feedback by wrong Adjustment of the switching elements is inevitably avoided. It can e.g. B. for the high frequencies this frequency band clipping also by changing the value of a Coupling element at another point of the amplification path or in the negative feedback path take place. Furthermore, this can be changed at the same time as the negative feedback resistance Coupling element designed as a chain conductor or as a resonant circuit or as a transformer be. The circuit arrangement and the dimensioning of the mutually variable switching elements must be chosen in such a way that for each adjustable degree of negative feedback, if necessary the frequency band to be transmitted is distortion-free even in the non-negative feedback state is transmitted.

As already mentioned, the switching elements are dimensioned in such a way that that with negative feedback zero or with very small negative feedback the frequency band of the amplifier practically meets the requirements. In the case after Fig.3 there is an additional limitation of the high frequencies by the capacitor Cl not. In this case, this only becomes simultaneous when larger negative feedback is used with Rk variable switching element, z. B. the capacitor Cl, changed in such a way that the frequency band of the negative feedback amplifier meets the conditions although fulfilled without further ado, however, the frequency curve in the non-negative feedback state falls off much earlier.

The above statements related to the high frequencies occurring conditions. With a corresponding change in the individual relationships the same derivatives also apply to each other for the low frequencies. For example the frequency limitation of the amplification at the low frequencies in Fig the resistance RT take place. Here, too, chain ladders or oscillation circles can be used can be used both in the amplification path and in the negative feedback path.

As stated above, the limit frequencies of those coupling elements which may only have a slight phase shift in order to achieve greater negative feedback, be placed far away from the transmission area, d. H. for the upper limit frequencies be shifted to very high frequencies far beyond the upper transmission limit. In this case, the cut-off frequencies can only be reduced by reducing the size of the Anode resistances of the tubes can be achieved. The gain decreases at the same time in the transmission range. Since only with large negative feedback the cut-off frequencies far must be outsourced and large negative feedback is synonymous with a large decrease in gain, this loss of gain plays a role no significant role due to the reduction of the anode resistances.

If, however, the amplifier is switched off by reducing or switching off the Negative feedback should be used at the same time with higher degrees of gain, so is the gain loss due to the wide exposure of the cutoff frequencies of the the aforementioned coupling elements undesirable. According to a further invention are therefore also expediently the switching elements influencing the upper limit frequencies, e.g. B. anode resistances, changed together with the negative feedback, in such a way, that with large negative feedback, the anode resistances are reduced and vice versa.

Claims (1)

PATENT CLAIMS: i. Cascade amplifier with variable negative feedback and coupling members of different cut-off frequencies, characterized in that inevitably in the case of an arbitrary change in the size of the negative feedback voltages also the cut-off frequencies of the coupling elements in the amplifier's transmission path or additional switching elements lying in the negative feedback path are changed in this way be that when the negative feedback increases, the cutoff frequencies of those Elements that determine the frequency band to be transmitted by the amplifier, without the The influence of an increased negative feedback that widens the useful frequency band of the amplifier considered. moved further into the transmission frequency range of the amplifier (Fig. 2). a. Amplifier according to Claim a, characterized in that the the switching element changing the negative feedback and that or the electrical properties of the transmission or Gegenkopplungsw-eges changing coupling element by a common control handle are operated, in particular that all to be changed Switching elements can be controlled from a common axis. ;. Amplifier after Claim i, characterized in that one for cutting off the high frequencies variable capacitor in parallel with the transmission path and / or a variable one Resistance along the transmission path is used, which together with the the degree of Negative coupling regulating switching element can be adjusted. 4 .. amplifier according to claim i, characterized in that a variable to influence the low frequencies Resistance across the transmission path and / or a variable capacitor along of the transmission path is switched, which together with the degree of negative feedback regulating switching element can be adjusted. 5. Amplifier according to claim i, characterized characterized that chain conductors, oscillating circuits, transformers for frequency limitation or the like, whose electrical properties can be changed. 6. Amplifier according to claim i, characterized in that the cutoff frequencies of those coupling elements which only contribute little to the phase shift. can also be changed with the negative feedback are in the way z. B. that the anode resistances at the same time with the negative feedback resistance to be changed.