DE878672C - Circuit arrangement for amplifier with combined current and voltage negative feedback - Google Patents

Description

Circuit arrangement for amplifiers with combined current and voltage negative feedback In amplifiers, through simultaneous current and voltage negative feedback, the internal amplifier resistance becomes independent of the total degree of negative feedback. It is known to design the output circuit of an amplifier as a bridge circuit for this purpose, as shown for example in FIG. You do it here where Ri. means the internal resistance of the output tube, the internal amplifier resistance seen from the consumer (or from the output terminals) is independent of the negative feedback, i.e. of the position of the tap on R. You can then change the gain by changing the negative feedback without influencing the internal resistance of the amplifier.

If you apply the specified circuit to multi-stage amplifiers, which are to be operated with strong negative feedback and their transmission range is large and extends to frequencies above the audio frequency range, trouble easily arises from the fact that the anode winding of the output transformer cannot be connected to earth on one side with alternating currents. It then it often happens that even with relatively weak negative feedback Self-excitation of the amplifier occurs.

If one takes the ratio of the negative feedback voltage U i in the circuit shown in FIG. for the alternating grid voltage U9 of the output tube as a function of the frequency, a curve often results as is indicated in FIG. A little above the upper limit (f2) of the transmission range (f, ... f 2) of the amplifier, the negative feedback voltage disappears at a certain frequency f ,. almost completely.

So if you would operate the amplifier normally and then the negative feedback Increase slowly from a very small negative feedback, then would be relative Self-excitation can already occur with weak negative feedback. The amplifier vibrates doing so at a frequency close to f ,. lies.

The cause of these undesirable phenomena should be based on the in Fig. 3 shown equivalent circuit diagram for the output circuit of the amplifier, which but only represents a rough approximation, will be explained briefly. The end tube of the amplifier is thereby through the voltage source with the EMF E and the inner Resistance Ri shown. As in connection with the disappearance of the negative feedback voltage at f ,, the frequencies are of interest that are above the transmission range, is the output transformer with the consumer through the series connection of the primary Leakage inductance L, with the parallel connection of transmission capacity Co and Load resistance R "replaced. The capacities also drawn in C and C 'represent the capacitances between the windings and the capacitances between Anode winding and core.

If one disregards C , Co and Ra, then the series resonance circle consisting of L and C is immediately noticeable. At the resonance frequency of this circuit, the voltage UA would collapse completely if Ra and Ca were not present. However, because of Co and Rd and the connection of this branch with R3 or R2 (or C ), this effect does not occur exactly. This shifts the resonance frequency and dampens the resonance itself. The two capacitances C and C 'in any case have the consequence that not all of the current entering L 1 also flows through R3. At the frequency f ,. the current component flowing through R3 is now particularly low and therefore also the voltage U ,. just very small.

It has already been noted that the equivalent circuit shown by FIG represents only a rough approximation of the actual situation. The effect of this circuit has therefore only been roughly outlined; However, this should be sufficient for explaining the concept of the invention.

The invention is based on the problem of the explained resonance phenomenon at the output transformer, which is caused by the. primary leakage inductance as well as through the Caused capacitances between the windings or between the anode winding and the core will render harmless. It was already dealt with. been that over the capacitances between the anode winding of the output transformer and the Output winding or the transformer core are present, part of the anode winding the current flowing in from the anode of the end tube flows away and therefore does not flow over the bridge resistor R3 goes. At the frequency f ,. is therefore the one flowing through R3 Electricity particularly small. In order to achieve that almost all of the anode winding AC current flowing in from the end tube also flows through resistor R3, which the prerequisite for avoiding the resonance phenomenon is according to the invention surround the anode winding of the output transformer with a static screen, the end of this winding facing the positive pole of the anode power source connected is.

This ensures that between the two windings of the output transformer and there are no longer any capacities between the anode winding and the core. Instead, there is now a capacitance between the screen and the core and another between the screen and the anode winding. This can be seen without further ado the circuit example shown in Fig. q of a multi-stage, negative feedback Amplifier in which the inventive shielding of the output transformer is used is. All of the current supplied to the anode winding of the output transformer flows here via the parallel connection of the resistor R3 and the capacitances between Shield and core as well as between shield and output winding.

In the frequency range in which the capacitive resistance is parallel the capacitance lying at R3 is large compared to the resistor R3, then practically flows the alternating current supplied to the anode winding is also reduced via R3, regardless of whether now between primary leakage inductance and capacitance between anode winding and Shield a resonance effect occurs or not. So it just depends indicates that even at the highest frequency of interest, the one parallel to R3 capacitive resistance is large against R3.

The output winding is often connected to earth on one side. Frequently But you also have consumers who are symmetrical against_Earth. Depending on how the earthing conditions are on the consumer side, will also be the one R3 partial capacitance lying in parallel, which depends on the capacitance between the screen and the output winding have different values. To get clear relationships here and to be independent of the earthing conditions on the consumer side you also shield the output winding and connect this shield to earth. These Measure is in the embodiment according to FIG. Q. also shown. the Both screens are designated with I and II, the screen II is except for earth also connected to the core.

Parallel to R;, the capacitance of the screen I is now also against the screen II or against the transformer core K, which is caused by the capacitor C ;; is indicated. The resistors R 1, R, R3 are chosen so that the condition is fulfilled, as already stated. The relationship can now be greater, the greater the gain of the amplifier part without negative feedback, over which the negative feedback extends in the operating state. In the case of multi-stage amplifiers, which naturally have a particularly high risk of self-excitation, you generally only need a resistor R3 that is very small compared to Ri. Experience has shown that the capacitance C3, which is obtained in the output transformer, if no special measures are used to make it particularly small, remains small enough so that it does not matter up to frequencies of a few MHz in addition to R3.

With amplifiers for the audio frequency range as well as for the carrier frequency range one can therefore achieve with the help of the screen I that practically all of the alternating current coming from the anode of the end tube and flowing to the anode winding of the output transformer flows through the resistor R3, in the entire frequency range of interest, that is even at frequencies that are far outside the upper limit of the transmission range. The negative feedback voltage U ,. is then also proportional to U. &. The relationship depending on the frequency then no longer shows as originally with f ,. a depression, but runs horizontally in this area as in the transmission area. In the event that a relatively high resistance is selected for R3, so that C3 would have an unfavorable effect with a normal design of the output transformer, this capacitance C can be increased by increasing the thickness of the insulating material between the screens I and II by using insulating material lower dielectric constant considerably. However, increasing the thickness of the insulating material between the screens increases the leakage inductance of the transformer. How far one can go here depends on the particular case at hand. In most cases, the insulation thickness can only be used up to a certain limit, taking into account the leakage inductance.

There are different embodiments of transformers with shielded '\ Vicklung known. These embodiments may partially apply to the present Purpose can be taken directly, but in part they can be easily converted into more appropriate Modify them so that they are useful here. In most cases it isn't necessary that the shields are perfect. It is enough if through the umbrellas what is achieved is that the harmful capacities are so small that they are dangerous Frequency area do not play a role. Therefore, one often comes up with embodiments which correspond to that indicated in FIG. 5 or represent a modification of this.

5 shows a section through half of a jacket core transformer with the core i and the winding body 2. The anode winding wA lies between the split output winding ze, B I and wB IL , and II ", Il ,. It is advisable to use shields made of foil and not shield windings, as the inductances of such windings can easily cause disruptive effects at high frequencies. The foil screens are designed in a known manner in such a way that they overlap and insulate so that no short-circuit turns arise. The intermediate insulating layers between the screens or between the screens and the windings are denoted by a, U, c and a ', 1b', c '.

In the case of transformers whose winding bodies have several chambers, can a similar arrangement can be provided for in the individual chambers. But you can also house the individual windings in separate chambers and then the chambers shield against each other.

As already explained, the shielding of the anode winding and the connection of the shield to the lower end of this winding achieve the ratio Depending on the frequency, it runs horizontally in a frequency range in which, without this measure, the corresponding curve would show a very strong and sharp dip. However, the measure described cannot prevent the voltage Uä from being subject to considerable fluctuations with increasing frequency, even above the upper limit of the transmission range as a function of the alternating grid voltage of the output tube, which result from the fact that the load on the output tube is frequency-dependent. The consumer connected via the output transformer practically only represents an ohmic resistance in the anode circuit of the output tube in the transmission range. Above the transmission range, leakage inductance and self-capacitance play a significant role. The scattered resonance can be pronounced here, but further resonance phenomena are also possible, especially in the case of heavily subdivided and partially shielded winding structures. The fluctuations in the anode alternating voltage UA caused by this as a function of the frequency naturally also occur correspondingly with the negative feedback voltage L% T if U i is in this frequency range. is proportional to Ug.

How strong the occurring fluctuations of L ', ä are depends primarily Line from the special properties of the output transformer. In some cases they do not adversely affect the tendency of the amplifier to oscillate, often but they affect the stability considerably.

It has now been shown that such, impair the stability Fluctuations in U ,. with the frequency can often be almost completely eliminated, that the screen surrounding the anode winding of the output transformer does not match the lower one The end of this winding is connected, but with a tap of the resistor R2. Expediently, this tap is made adjustable, so that the most favorable position can be found experimentally. Such a circuit arrangement is shown in FIG. namely here only the output circuit .the output stage of a multi-stage amplifier shown.

In rare cases it is better to tap the screen I with R1 to connect; Most of the time, however, you can get by with the above-mentioned tap on R2.

The best connection of the screen I is when the relationship between the voltage Ur and the grid alternating voltage of the end tube is almost horizontal in the dangerous frequency range and the previously disturbing fluctuations have almost disappeared.

Claims (5)

PATENT CLAIMS: i. Circuit arrangement to prevent disappearance the negative feedback voltage at one near the upper limit of the transmission range lying frequency f ',. and the resulting self-excitation in amplifiers with combined current and voltage negative feedback in the form of a bridge circuit of the output circuit, characterized in that the anode winding of the output transformer is surrounded by a static screen that is connected to the positive pole of the anode power source facing end of this winding is connected. 2. Circuit arrangement according to claim i, characterized in that the output winding of the output transformer is also is surrounded by a screen that is placed on earth. 3. Circuit arrangement according to Claims 1 and 2, characterized in that a screen is used to reduce the capacitance I / Screen II increases the thickness of the insulating material between the screens is, and that if necessary, an insulating material with a low dielectric constant for this intermediate layer is used. q .. Circuit arrangement according to Claim: [and 2, characterized in that that the screens are made of copper foil and designed so that they are isolated overlap. 5. Circuit arrangement according to claim i, characterized in that that the screen for the anode winding of the output transformer with a tap of the bridge resistor R 2 is connected between the positive pole of the The end of the anode winding (wA) facing the anode power source and the diagonal point the bridge circuit from which the negative feedback path is branched off.