DE1217464B - Circuit arrangement for the compensation of an interference voltage in the output voltage of a demodulator for frequency-modulated, electrical high-frequency oscillations caused by amplitude modulation - Google Patents

Description

Circuit arrangement for compensating one of an amplitude modulation resulting interference voltage in the output voltage of a demodulator for frequency-modulated, : electrical high-frequency oscillations To compensate for interference voltages at the output of FM demodulators, which are affected by a disruptive amplitude modulation of the high .. or Intermediate-frequency carrier originates, circuit arrangements are known in which the input voltage of the FM demodulator rectified by means of an AM rectifier, For example, a Riegger circle, the braking grids of two working in push-pull Pentodes is fed, at whose control grid the high-frequency push-pull voltages of the Rieggerkreis. In another one working in single cycle operation A variant is the demodulated, low-frequency output voltage of a Riegger circuit fed to the first control grid of a pentode, and that by AM rectification The low-frequency voltage obtained from the input voltage is applied to the braking grid.

The push-pull circuit arrangement adhere to the large expenditure of tubes to interconnect the voltages to be compensated the disadvantages that, because of the non-linear tube characteristics, compensation can only be achieved within a very narrow voltage range and that because of multiplicative Mixture of the low-frequency ones on the first control grid and brake grid Interference voltages the second harmonic of the same occurs with considerable amplitudes, which are disturbing in the case of tube asymmetries.

The circuit arrangement working in single-ended mode with only one pentode has the major disadvantage that, for example, when the trader frequency occurs Without frequency modulation, a compensation effect is excluded because while the LF output of the Riegger circuit is dead, the disruptive one, the amplitude modulation corresponding interference voltage controls the braking grid fully and therefore the interference voltage increasingly appears at the anode of the pentode. With simultaneous frequency and amplitude-modulated carrier arises just as with the push-pull arrangement by multiplicative mixing the second harmonic of the interference frequency that too obtained with complete compensation of the fundamental oscillation of the interfering LF voltage remain.

The invention is based on the stated disadvantages to avoid and at the same time to bypass the considerable expense of tubes. the Compensation for an interference voltage in the resulting from an amplitude modulation Output voltage of a demodulator for frequency-modulated, electrical high-frequency oscillations by means of an amplitude demodulator from the input voltage of the frequency demodulator obtained tension is achieved according to the invention in that this tension and the voltage supplied by the frequency demodulator over one dimensioned accordingly Resistor are applied to the output terminal of the circuit.

The mode of operation of the circuit arrangement is illustrated in FIG. 1 illustrated block diagram. If a simultaneously amplitude- and frequency-modulated input signal reaches the FM or AM demodulator via the HF and IF sections, the AM rectifier only demodulates the amplitude modulation, while the FM rectifier demodulates both the amplitude modulation and the the voltage resulting from the frequency modulation. Because the LF voltages corresponding to the amplitude modulation are in phase opposition, they compensate each other at the connection point of the two resistors R1 and R2 connected to the LF output terminals if they are dimensioned in such a way that they correspond to the interference voltages -I- US and - US specified bridge conditions are sufficient. The voltage U ", which corresponds to the frequency modulation and originates from the FM demodulator, appears at the LF output terminal A with an amount that is given by the division ratio of the two resistors R1 and R2.

In Fig. 2 is a practical embodiment of an FM demodulator shown with the compensation arrangement according to the invention, with a known Network for converting the frequency-modulated oscillation into an amplitude-modulated one vibration is used. The transistor T ,. provides a simultaneous frequency and amplitude-modulated oscillation in point E of the demodulation and compensation circuit. The amplitude-modulated oscillation is rectified by means of the diode D2 and supplies a DC voltage with a polarity that is negative in relation to ground, that of the Amplitude modulation corresponding LF interference signal - US is superimposed. On common The connection point of the two series-connected capacitors C2 and C3 can be on known type a high- or intermediate-frequency carriers are tapped, the amplitude-modulated Input signal fluctuates at the same time in the rhythm of this amplitude modulation. The FM and AM rectification serving diode Dl provides a ground positive DC voltage which superimposes the useful signal U "and the interference signal -I- US is. These two rectified voltages are dimensioned accordingly via the Resistors R1 and R2 are applied to the output terminal A, thereby compensating for the Interference voltage -I- US is caused.

Between the point E and the mass it is possible to limit it in a known way another limiter arrangement, consisting of a diode and an RC element Time constant to be switched on.

Claims (1)

Claim: Circuit arrangement for compensating one of one Interference voltage resulting from amplitude modulation in the output voltage of a demodulator for frequency-modulated electrical high-frequency oscillations by means of a with a Amplitude demodulator obtained from the input voltage of the frequency demodulator Voltage, as a result of the fact that this voltage and that of the frequency demodulator voltage supplied to the output terminal via a correspondingly dimensioned resistor the circuit are placed. Publications considered: German Patent Specifications No. 874 615, 938 970, 967 013; German Auslegeschrift No. 1112 556; German interpretation document P 10511 VIIIa / 21 a4 (published on March 3, 1956); British Patent Specification No. 487 880, 866 975; U.S. Patent No. 2,251,382; "Radio-Magazin", 1951, no.12, P. 405.