DE908745C - Circuit arrangement for the compensation of residual voltages in push-pull or double push-pull modulators - Google Patents

Description

To compensate for the residual stresses of one of the frequencies to be modulated, e.g. B. the carrier frequency, it is known for push-pull and double push-pull modulators to cause this residual voltage to compensate a counter voltage selected according to size and phase. Particularly beneficial can be accessed in a known manner within the modulator arrangement from that input terminal the frequency to be compensated with regard to its residual current, that of the transformer used for compensation is not adjacent, switch an impedance to the end point of the winding of the transformer, and although preferably a variable impedance to the two end points of the winding of the transformer. Real parts and imaginary parts of the two branches are each inevitable and opposite mutually changeable. The real part is determined, for example, by a potentiometer lying parallel to the equalizing transformer and the imaginary part formed by a differential capacitor. Such a training is feasible Values of the elements used for compensation a compensation z. B. the carrier frequency residue enables. The disadvantage of the known arrangements is that these circuit arrangements only difficult to different frequency areas, z. B. the carrier frequency can be adjusted so that it becomes necessary to develop different compensation means for the different frequency ranges. The invention provides a remedy here.

A circuit arrangement according to the invention for compensating residual voltages of one of the with each other Frequencies to be modulated in the output and / or input of push-pull or double push-pull modulators is characterized by the use of two bridge circuits of the same type, in which two adjacent branches consist of variable resistances of the same type and the two others consist of equal resistances and with ίο those of one diagonal currents of one modulation frequency, z. B. the carrier frequency, are supplied by using different Series resistances in the corresponding diagonals of the two bridge circuits by one phase shifted by a substantial amount, and the voltages on the other diagonal to compensate to be used. In particular, an ohmic one is used as the series resistance Resistor and once a capacitor. For the two bridge circuits are in particular the branches containing the same resistors in common. For example, you can use a differential throttle or an ohmic resistance or through the differential winding of one of the modulator transformers be educated. A particular advantage of the arrangement according to the invention is therein see that similar control elements are used to balance the two components of the residual voltage will.

Real voltage dividers, as shown, for example, in the exemplary embodiments in FIGS. 1 and 2, are advantageously used. It is assumed that a message band is fed to terminals 1, 2 of the modulator M , while the carrier frequency originating from the carrier frequency generator TG is fed to terminals 5, 6. The resulting sidebands can then be removed from the output terminals 3, 4. The bridge circuits used according to the invention have two common branches which consist of the differential choke Dr (FIG. 1) and the differential winding of the output transformer U _{2 of} the modulator (FIG. 2). The other two branches of one bridge are formed by the variable potentiometer W ₁ and in the other bridge circuit by the variable potentiometer W ₂ . The supply of the carrier frequency takes place in the diagonal of the two bridge circuits, namely in the one bridge circuit via the series resistor R and in the other bridge circuit via the series capacitor C. To keep the power loss small, W ₁ and W _{s are} advantageously made large compared to the Load resistance R _a . The capacitor C is to be dimensioned in such a way that the _{carrier current supplied to the potentiometer PF 2} receives a substantial phase shift (e.g.> 45 °) compared to the current supplied ^{to T 1} F _1. So it should be

W _t

(oC

The resistance R, on the other hand, can also be dimensioned to be _{smaller than W 1.} It is only intended to limit the current in W ₁ to a value that is dependent on the greatest counter-voltage to be generated. If W _{1 is} large enough for this, R can also be omitted. A particular advantage of the circuit arrangement is that it can easily be adapted to the most varied frequency ranges of the carrier frequency. It need only be of the pre-condenser C varies, the same value of the capacitance C but can be maintained for a range of about one octave.

In the embodiments shown in FIGS. 1 and 2 using real voltage dividers, it is also easily possible to have the voltage dividers W ₁ and W ₂ coincide, so that both bridge circuits have common bridge branches. The carrier current is then fed to the common voltage divider via separate taps, ie once via a series resistor R and once via the series capacitance C

Instead of real voltage dividers, capacitive voltage dividers, e.g. B. differential capacitors, can be used as it is, for. B. Fig. 3 shows in which the potentiometers W ₁ and W _{2 are} replaced by differential capacitors DK ₁ and DK ₂ . As in the exemplary embodiment according to FIGS. 1 and 2, the resistor R can optionally be omitted, so in this exemplary embodiment the capacitor C can optionally be omitted. The resistor R , on the other hand, must bring about a substantial phase shift in the current, that is to say approximately equal to or greater than half the resistance of the differential capacitor DK _Z.

Terminals 3, 4 and 5, 6 are all shown Arrangements can of course be interchanged with one another.

Finally, the terminals 3, 4 as Input can be used if it is required that the residual carrier at the input should be suppressed. In In this case, terminals 3, 4 can also be interchanged with 5, 6.

Claims (12)

PATENT REQUIREMENTS: i. Circuit arrangement for compensating the residual voltage of one of the modules to be modulated with one another Frequencies, in particular the carrier frequency, marked in the output and / or input of push-pull or double push-pull modulators through the use of two bridge circuits of the same type, in which two adjacent branches of variable resistors of the same type and the other two consist of equal resistances and with iao those of one diagonal currents of one of the frequencies to be modulated with one another are supplied, which are generated by using different series resistances in the corresponding diagonals of the two bridge circuits by a substantial amount are out of phase with each other and the voltages on the other diagonal to compensate to be used. 2. Circuit arrangement according to claim i, characterized by using an ohmic resistor and a capacitor as series resistors in the diagonals of the two Bridge circuits. 3. Circuit arrangement according to claim 1 and 2, characterized in that for both bridge circuits which branches containing the same resistors are common. 4. Circuit arrangement according to claim 3, characterized by the use of a differential throttle or a differential winding of a transformer for the two bridge circuits common branches. 5. Circuit arrangement according to one of the preceding claims, characterized in that the branches of the two bridge circuits containing the variable resistors real voltage dividers are formed. 6. Circuit arrangement according to claim 5, characterized in that the resistance of the Voltage divider is chosen large against the load resistance. 7. Circuit arrangement according to one of the preceding claims, characterized in that that the resistance of the series capacitor is equal to or greater than half the resistance of the Voltage divider is. 8. Circuit arrangement according to one of the preceding claims, characterized in that the resistance of a voltage divider is chosen so large that the series resistance in the Diagonal can come in omission. 9. Circuit arrangement according to one of claims 5 to 8, characterized in that the real voltage divider is common to both bridge circuits and separate movable taps are provided for the various power supply lines in one diagonal. 10. Circuit arrangement according to one of claims ι to 4, characterized in that the the branches of the two bridge circuits containing the variable resistors capacitive voltage dividers, in particular differential capacitors, are formed. 11. Circuit arrangement according to claim 10, characterized in that the series resistance in the power supply is equal to or greater than that half the resistance of the capacitive voltage divider. 12. Circuit arrangement according to claim 10 and 11, characterized in that the capacitive voltage divider is dimensioned so that the Series capacitor can come in omission. 1 sheet of drawings 1 5904 3.54