DE1022271B - Arrangement for damping short-term interference voltage peaks - Google Patents

Description

Arrangement for damping short-term interference voltage peaks The invention relates to a circuit arrangement for damping short-term interference voltage peaks in radio receivers and can e.g. B. in glider radios, radio receivers as well as police and marine radios.

The aim of the invention is to provide a simple danipple circuit specify in which the switching elements used are at least partially also at the same time can be used for demodulation or control voltage generation.

It is known, circuits for damping short-term Störspannun.gsspitzen so, train that in parallel with a high-frequency circuit two from a series circuit of diodes and time constant elements consisting of resistors and capacitors switched and the diodes are polarized in opposite directions.

According to the invention, the diodes are used for demodulation at the same time or control voltage generation for the automatic volume control: for noise suppression the anode of the Demodula.tordiode is negatively biased in a manner known per se.

To determine the volume difference between switched on and not switched on Making noise cancellation inögliclist small is used as a bias for that Noise suppression a regulated bias, preferably via a voltage divider used by the cathode potential of the regulated tube.

A particularly small difference is achieved in that a Resistance is provided that connects the ends of two connected to the rectifier Series resistors are bridged and connected to the tap of the control voltage potentiometer it is connected that with -axis negative control voltage the negative bias voltage is compensated.

An embodiment of the subject matter of the invention is shown in the drawing shown.

The drawing shows a circuit that includes the rectifier or demodulation stage in a radio receiver for amplitude-modulated oscillations between the Intermediate frequency (IF) part and the lower frequency (NF) part of the device Again-To the IF output circuit with the capacitor 1 tnid of the inductance 2 are two rectifiers 3 and 4 connected. The rectifier 3 is used for rectification the intermediate frequency. The resistors 5, 6, 7 and 8 are connected to it one behind the other. while the low frequency at the terminal 9 iil @ he removed the capacitor 11 will.

The diode 4 is used to generate the control voltage via the resistors 12, 13, 14. The control chip reverse voltage decreases. In addition, in tion is effected via the terminal 18 is fed to the control tube or tubes, the resistor 8 is a potentiometer A tap 15 errs. The sides facing away from the diodes 3 and 4 Resistors 5 and 12 are bridged by a resistor 16. Also is a Switch 17 between, the earthed line (connection point of the resistors 14 and 15) and the resistor 7 are provided.

The anode of diode 3 is biased negatively to suppress noise. This bias voltage is regulated via the voltage divider 8 at the cathode of the Tube removed. The negative precompression must be so large that with a signal voltage Zero the diode is blocked. If a signal voltage arrives that is above your Noise level, a current can flow through the diode and the signal can can be removed at point 9, the negative effects required for noise suppression @ Bias can finitely short-circuited the switch 17 after the grounded pole of the circuit with which there is the possibility, in case of need, the noise suppression switch off.

The effect of noise cancellation occurs especially with small ones Signal amplitudes effectively emerge, because in the limit case signal amplitudes vanish the useful-to-noise ratio is increased significantly by suppressing the noise.

With large signal amplitudes, the noise reduction loses: ttng because of the large \ TUtz-Rauscli ratio in importance, and they can be practically Switch off completely (switch 1T). About the volume difference caused by switching off keep zti low, a regulated preload is used, the d, the finite an Your potentiometer 8 is taken off and connected to the cathode of the regulated tube is. This has the consequence that with increasing signals the this Case of large signal amplitudes between the resistors 5 and 6 on the one hand and Resistance connected between 12 and 13 on the other hand. 16 a further compensation the reverse voltage that has already been regulated down by the negative control voltage, the at his between the resistors 12 and. 13 sets the connection lying down.

This automatically adjusts the noise suppression effect for strong. Signals are regulated down, and a complete shutdown by the switch 17 is effected practically no volume difference anymore. In a running device is z. B. a volume difference between activated and deactivated noise cancellation less than 3 db.

The peak limitation is due to the fact that parallel to the ZF circle the two differently polarized diode lines 3 and 4, which with the resistors 5, 12 and 16 as well as the. Capacitors 19 and 10 connected in series are. The time constant of these switching elements is chosen so that disturbance peaks, how they are generated by ignition sparks and the like. With suitable dimensioning can about occurring noise peaks. can be attenuated by 20 db.

The mode of operation of the circuit is as follows: If an interference spike occurs on the circuit, with the amplitude increasing sharply, a strong direct current flows through one of the diodes in every half cycle. This current corresponds to the charging current of the capacitors 10 and 19 and. is only limited by the internal resistance of the diodes. The IF circuit is practically short-circuited until the capacitors have charged. The charging time is determined by the time constants of the RC elements and is adapted to the intermediate frequency and the diodes. The circuit is symmetrical to earth, so that it is avoided that the low frequency passes through the capacitors from one diode to the other. If the capacitors 10 and 19 were chosen to be too large, this would result in distortions. The incomprehensibility of the language would be due to the fact that already. the amplitude changes of the modulation are disturbed.

In an executed circuit have z. B. the resistors and capacitors have the following values: Resistance 5. . . . . . . . . . . . . . 500 kOhm Resistance 12. . . . . . . . . . . . . . 500 kOhm Resistance 16. . . . . . . . . . . . . . 200 kOhm Resistance 6. . . . . . . . . . . . . . 100 kOhm Resistance 13. . . . . . . . . . . . . . 100 kOhm Capacitor 11. . . . . . . . . . . . . . 10 nF Capacitor 19. . . . . . . . . . . . . . 100 pF Capacitor 10. . . . . . . . . . . . . . 50 pF

Claims (3)

PATENT CLAIMS: 1. Circuit for damping short-term interference voltage peaks, in the case of the parallel to a high-frequency oscillating circuit two from a series circuit of diodes and - consisting of resistors and capacitors - time constant elements switched and the diodes are oppositely polarized, characterized in that the diodes at the same time for demodulation (3) or control voltage generation (4) for serve automatic volume control and that the anode for noise suppression the demodulator diode is negatively biased in a manner known per se. 2. Circuit according to claim 1, characterized in that the negative bias is effected thereby that the cathode of the demodulator diode is DC-wise with the cathode end a resistor located in the cathode lead of a gain-controlled tube connected is. 3. Circuit according to claims 1 and 2, characterized. the existence. Resistor (16) is connected on the one hand between resistors (5, 6) in the circuit of the demodulator diode (3) and on the other hand between resistors (12, 13) in the circuit of the control diode (4) and with increasing signal amplitude a compensation of the reverse voltage by the negative control voltage, which occurs at its connection located between the resistors (12 and 13). Publications considered: German Patent Specifications. No. 652 003, 692 843, 728731.