DE643885C - Receiver with automatic shrinkage control - Google Patents

Description

The invention relates to a receiver with automatic shrinkage control and The aim is to overcome two disadvantages of such recipients, firstly, the occurrence noise and distorted playback during tuning and, secondly, the difficulty of precisely targeting the Tune the carrier wave of the transmitter, because because of the shrinkage control is a sharp Voting only by ear is not possible.

According to the invention, a device is used for noise elimination and sharpening to unlock the receiver above a certain high-frequency input amplitude so selectively coupled to a high frequency leading line of the receiver that it is essentially only responds to the carrier frequencies of the transmitters to be received.

Some exemplary embodiments are shown in the figures.

Fig. Ι initially shows the overall arrangement schematically. The received high frequency is amplified in the high frequency amplifier and fed to the detector. From the output of the high frequency amplifier there is a branch to the control devices, namely fading control and noise elimination. The detector is followed by the low frequency amplifier and the loudspeaker LS A selection circuit called a filter which has the effect that the receiver is only unlocked if it is tuned to the carrier frequencies.

Fig. 2 shows a part as an example of the implementation of this inventive concept a superheterodyne circuit. 1 is the anode of the last intermediate frequency tube, 2 is the demodulator and 3, the first low frequency amplifier tube. The additional control arrangement consists of the two tubes 4 and 5. The regulating rectifier 4 connected as an anode rectifier is connected via a capacitor 6 and an oscillation circuit 7 connected to a point of intermediate frequency potential. The intermediate frequency voltages impressed on the grid of the tube 4 are rectified, and it arises at the resistor 8 lying in the anode circuit, a DC voltage drop. Resistance 8 is short-circuited by capacitor 9 for intermediate frequency voltages. The anode-side The end of the resistor 8 is via a resistance-capacitance element 10, 11 with the Grid of the DC amplifier tube 5 connected so that in the anode circuit of this tube

Claims (4)

The DC voltage fluctuations of the resistor 8 are amplified at the resistor 12 appear. The anode-side end of the. Resistor 12 is via a resistor ', Capacitance member with the grid of the ers ^ ät ^ Xlow frequency amplifier tube 3 connected ^ i The cathode potential of the tube 3 is by tapping on the voltage divider 13 so laid down that the rest bias is the most favorable value for normal work (in the shown example minus 5VoIt). at If the high frequency is absent or too low, the negative grid bias of the tube 3 becomes greatly increased by a large voltage drop across the resistor 12, so that a blocking occurs. Only when a high-frequency amplitude of a sufficient size is supplied is. the block is lifted. Circle 7 should be particularly highly selective, see above that the unlocking of the low frequency tube 3 occurs only when exactly on the station to be received is tuned in. It should be noted that the voltage reaching the Entspemingseinrichtung only one can be those caused by the particularly highly selective circuit of the high-frequency amplifier (in this case by the intermediate frequency amplifier '). When a wide frequency band (noise) is added to the particularly highly selective circle, only a small fraction of these frequencies passed to the unlocking device. The control tube is adjusted so that this small high frequency voltage it is not actuated, rather it is only applied to a voltage of sufficient strength and of the correct frequency Address (carrier frequency '). So if a receiver is equipped with a control according to the invention, he will be silent, except when a station is properly set. He's against Insensitive to noise, as the additional selection circuit does not focus on a frequency band (Noise) responds, but only to the carrier wave of a transmitter. Fig. 3 shows a slightly modified circuit compared to Fig. 2. 1 is again the anode of the last intermediate frequency amplifier tube. The screen grid tube 19 serves here as a demodulator and at the same time high-frequency amplifier for the voltage used for unlocking. The demodulation is carried out between the control grid and the cathode. so that the low-frequency modulation voltages occur at the resistor 20 located in the grid circuit. From there they are fed via a coupling capacitor to a potentiometer 22, the slide of which is connected to the control grid of the first low-frequency tube 2 ^ ₁ . The amplified low frequency is passed on via the transformer 24. A high-frequency transformer 25 is located in the anode circuit of the tube 19. There are amplified jfRvischen frequency spans in the screen grid tube 19, which are fed to the control grid of the regulating rectifier 27 via the circuit 26 with a particularly high degree of selectivity. The DC voltage generated by rectification, after amplification in the DC amplifier 28, is fed to the control grid of the first low-frequency tube 23 as a bias voltage. In addition to this variable bias voltage, there is also a constant bias voltage, in the example in Fig. 3 5 volts. This circuit has the advantage that it supplies higher voltages, nor the Another advantage of an additional automatic control of the size of the control tube 27 applied voltage. This is because, with the increase in the high frequency voltage for the rectifier grid the output voltage for the control tube does not increase proportionally, since the diode effect of the rectifier increases the negative grid bias of the tetrode when it is used as a high-frequency amplifier caused. go The circuits shown are capable of various configurations. For example, the particularly highly selective coupling ^{circuit which supplies the voltage to the low-frequency tube 1 can} be modified in such a way that it gives a greater or lesser selectivity, depending on the construction of the receiver. The type of coupling of the high-frequency amplifier output with the particularly highly selective circuit can also be changed. Alan can also control the output of the low frequency amplifier through a relay instead of controlling the input or gain of the low frequency amplifier by biasing one of the low frequency amplifier tubes into lock. P Λ T E N T Λ N S P RÜ C H E: ι. Receiver with automatic shrinkage control, characterized in that for Noise Elimination and Arming a device to unlock the receiver above a certain High-frequency input amplitude is selectively coupled to a high-frequency line of the receiver in such a way that that it responds essentially only to the carrier frequencies of the transmitters to be received. 2. Receiver according to claim 1, characterized in that the device device for unlocking from a loosely coupled oscillation circuit (7 in Fig. 2), which is connected to a resistor (8) via a rectifier (4) With the incident carrier frequency, a grid bias voltage for unblocking a low-frequency tube (3) is created leaves, which is optionally further amplified in a direct current amplifier (5). 3. Receiver according to claim 1 and 2, characterized in that the rectifier (27 in Fig. 3) for the unblocking voltage the high-frequency voltage via a special branched off High frequency amplifier stage (19) receives, ig 4. Receiver according to claim 1 and 3, characterized in that the branched off The high-frequency amplifier stage consists of a tube (19 in Fig. 3) whose Grid-cathode path as a receiving rectifier in a diode rectifier circuit serves, while only the amplified high-frequency voltage is taken from the anode. 1 sheet of drawings