DE704873C - Device for suppressing disturbing noises - Google Patents

Description

Noise suppression device The invention relates to on a device for the suppression of disturbing noises during reception electrical waves by controlling one of the receiving tubes such that this becomes ineffective if the intensity of the received characters falls below a predetermined one Value falls.

The invention is based on the problem of suppressing background noise, as soon as their intensity is greater than the character intensity or if there are no received characters available. It is already known that the low-frequency amplifier can be used when there is no Block high frequency. This blocking takes place with the known arrangement Help a relay that shorts a low frequency circuit when the intensity the high frequency drops below a predetermined value. It is this one So it is arranged around a so-called noise killer, which works with a contact control. It has also been proposed to use a low frequency amplifier tube by automatic Changing their grid bias to render them ineffective when the high frequency is in a Amplifier with automatic gain control below a certain amount sinks. The control voltage for blocking one or more frequency levels is taken from the anode circuit of a regulated high-frequency tube, and a special tube is used to achieve the appropriate voltage characteristic used. It has also been proposed to provide a means for eliminating noise to use the receiver below a certain high frequency input amplitude blocks, the device being selectively connected to a high-frequency line of the Receiver is coupled so that it is essentially only on the carrier frequencies the station to be received addresses.

The invention forms a device for suppressing noise, the is easily adjustable and has the property, when noises occur, which exceed the desired high-frequency oscillations in a certain ratio, suddenly blocking the low frequency amplifier. This effect has been made according to the present invention achieved in that in an arrangement in which one is located in the receiving channel Low frequency amplifier tube by means of a special, through the signal amplitude from the demodulator controlled reverse tube affects% t-ird that Demodulator designed as a two-pole tube and the reversing tube directly from the Two-pole tube is controlled.

Since a diode is used as a rectifier in this arrangement, the working range of the suppression device can be selected to be practically unlimited «-Earth: because the diode rectifier supplies output currents from zero to any level, which are proportional to the input voltage. The L'nikehr tube in the circuit has such a characteristic that it immediately completes the or Onset of the work of the controlled low-frequency tube can cause. The inventive The circuit is also used in receivers without automatic gain control applicable in the high frequency part.

The circuit according to FIG. I contains a high frequency amplifier i i, which is used to amplify the incoming characters and the input circuit of the two-electrode detector 1 2 prints the amplified characters. The rectified symbol is then amplified by the low frequency amplifier 13 which forms the controlled tube in the arrangement: the amplification of the rectified symbol is influenced according to the invention by means of a device suppressor tube 14, the mode of operation of which is explained in the circuit below.

The input circuit of the radio frequency amplifier tube i i contains one tuned circuit 15 and the output circuit of this amplifier the coil 2o, the ' inductively coupled to the coil of the tuned input circuit 21 of the detector 12 is. The grid discharge resistor 22 and are located in the detector output circuit the high frequency bypass capacitor 23. The grid leakage resistor 22 and the capacitor 23 are dimensioned so that the tube 12. as a two-electrode tube is switched, works as a peak detector.

One end of the resistor 22 is connected to the tuned circuit i via the resistor 2.I; tied together. The output circuit of amplifier ii is completed by the voltage source: a bias battery 3 >> is provided in order, as will be explained later, to bias the grid of the tube with the appropriate bias. The rectified characters are supplied to the amplifier 13 through the coupling capacitor 31 and the resistor 32. The voltage drop along part of this resistor 32 is pressed onto the grid of the amplifier tube 13. The amplifier 13 is provided with a grid bias voltage source 35 and finitely one output circuit which contains the output coil 3 <and the voltage source 37. The module 3 () is connected to the coil 38, the leads 3 <9 of which are in a loudspeaker or with the 1, - input circuit of a further low frequency amplifier: irkers can be connected, inductively coupled. The voltage fluctuations occurring at the resistor 22 are fed directly to the grid of the device table suppression tube 14, the "output circuit of which contains the part of the resistor 32 lying below the tap 34". The voltage source 33 supplies the voltage for the anode of the carrot 14.

The noise canceling tube should have a high gain and have a sharp kink in their grid voltage anode current characteristic, thus a relatively small change in the grid voltage is a decisive one _changes in the anode current. Furthermore, the controlled tube, hi this one If the 1'ir i in amplifier 13, have a sufficiently high gain factor, so that small changes in the negative grid bias bias the tube so that that the: ltioelenstrom is cut off.

In operation, the high-frequency amplifier tube ii is biased by means of the voltage source 30 so that it has its maximum sensitivity when no character is present. The presence of a high mean current across the grid leakage resistor 2 2 causes a negative voltage on the grid of tube ii with respect to the cathode and consequently reduces the gain of the high frequency amplifier.

There are no high frequency signals in the input circuit of the detector 12 fed, the grid of the noise canceling tube i.1 is essentially have the same potential as the cathode, and a maximum anode current will flow through the lower part of the resistor 32. This gives point 34 and the grid of the low frequency amplifier 13 has a bias voltage that is so far below is the normal bias voltage generated by the bias voltage source 33, that the anode current is cut off and no amplification or transmission through the tube takes longer even though the voltage at point 34 is rectified by the Current flowing through the coupling capacitor 31 and the resistor 32 fluctuates.

On the other hand, if the detector is given a sign by the amplifier i i is pressed, the mean current through the resistor 22 and thus the mean voltage at its lower end, and the anode current of the noise suppression tube 14 decreases, causing the tension on the Point 34 rises and it allows the tube 13 as a low frequency amplifier of it through the coupling capacitor supplied character is working.

The noise suppressing effect can be achieved in that one regulates the gain of any tube following that which is the suppression tube feeds, such as B. an intermediate frequency amplifier, the second detector or of the first or second low frequency amplifier.

The cut-off of the anode current of the low-frequency tube is determined by the voltage mean value at the grid discharge resistor 22; therefore, depending on the characteristics of the noise suppressing tube circuits, when a lot of noise occurs, the capacitor 23 and the resistor 22 will develop a voltage sufficient to cause the low frequency amplifier 13 to decrease in bias so that no noise will be transmitted. The point at which the tube 14 is biased so that no anode current flows and thereby the blocking voltage of the tube 13 is canceled can easily be adjusted by hand so that it corresponds to the respective reception conditions and that more or less of the noise is cut off. A particularly suitable arrangement for this purpose consists of a screen grid tube used as a noise suppression tube with an adjustable screen grid potential. With this arrangement, the cutoff of the anode current can be adjusted so that the voltage required across the resistor 22 to start the low frequency amplification is not obtained in the absence of a character.

Such a circuit is shown in Fig. 2; it is largely similar to that shown in FIG. Identical parts are given the same designations in FIG. 2 as in FIG. However, this drawing represents a circuit diagram which has emerged from practice and which differs in principle from the drawing described above in that a common voltage source is provided. In this circuit, a series of resistors is placed between the voltage leads, the negative end of which is represented by 49 and the positive end by 50 . The earth line of the circuit is connected to a middle point 5 i. The bias between: the grid and the cathode of the tube ii is determined by the part of the resistor 22 which lies between the point 22 'and the right-hand end of the resistor, through the resistor 9 and the resistance between the points 49 and 51. If no character is received, the current flowing through the resistor between 49 and 51 will create the initial grid bias. The bias voltage required for automatic volume control is generated by the rectified current flowing through resistor 22. The grid bias of the tube 1q. is obtained by means of the whole resistor 22. A resistor 17 is in the grid lead of the tube 1q. To prevent. That high-frequency signs are pressed onto the grid of the tube 14; a bypass capacitor 18 serves the same purpose. A high frequency bypass capacitor 55 is also connected between the lower end of the tuned circuit 15 and the cathode of the tube zi. The screen grid potential of the tube 1d. can be adjusted as desired by the variable contact 52 on the resistance between points 51 and 53. The contact between the anode and grid leads of the tubes 1d. and 13 is, as indicated by 3q. ' indicated, made changeable, whereby the volume of the receiver can be regulated. The anode circuits of the tubes 14 and 13 contain the resistors 28 and 48, respectively, in order to be able to set the voltages of these parts appropriately. The bypass capacitors 27 and 29 serve to divert high frequencies.

The tap 22 ″ on the resistor 22 can also be connected to previous high-frequency amplifier tubes be connected to an automatic gain control of such tubes if desired to allow. The circuit of Fig. 2 is primarily intended to perform of the invention on the intermediate frequency amplifier and second detector of a superheterodyne receiver to show in which case the circles 15 and 2i are tuned to the intermediate frequency and further high frequency amplifier tubes and a first detector tube are provided are whose grid biases through the connection .mit the tap 22 "of the Resistance 22 can be regulated automatically.

The high gain of the screen noise suppression tube enables a small change in the mean voltage across the grid leakage resistor to cause a large change in the anode current and therefore a large change in the bias of the Ni-ed frequency amplifier. In this way. with a small change in the required voltage across the lattice dissipation resistor, the low-frequency amplifier appears to be switched on and off when the receiver is slowly tuned using a symbol. 3, which shows an overload characteristic of a radio receiver with automatic volume control, serves to explain four modes of operation of the Absclineideniveauregelulig. The ordinates are output voltages from the low-frequency amplifier, and the abscissas represent the characters in 1microvolt that enter the antenna. Curve 60 gives the overall characteristics of a receiver. who works at the highest sensitivity, again. This curve is recorded with the noise output power filtered out. Curve 6o 'is the portion of the output power that belongs to the tube noise that was filtered out in curve 6o. The curve 6o ″ shows the total output voltage based on the reception signals and the tube noises.

Curve 61 shows the output of the low frequency amplifier when the receiver works finitely with lower sensitivity, as is the case e.g. B. with local reception would be the case. The sensitivity of the receiver is then, as indicated, so reduced that there is no noise component in the output emanating from the tubes caused.

Curves 6o-6o "-62 show the output of a receiver with a noise suppressor according to the present invention with the cut-off limit control device, for example for the practically lowest cut-off limit. This limit is in this example has been chosen to give a low frequency output that is half noise and half sign is, assuming the most ideal atmospheric conditions with absolute freedom from atmospheric disturbances. These conditions give a Sensitivity of approximately .4 microvolts. However, if the voltage of the character frequency falls below point 63, which is approximately 3 microvolts. becomes the noise suppressor operate and the controlled tube will not allow character output.

When the noise input strength increases to about 2o. and whenever a received character is stronger than about 30 microvolts, a low frequency output will be obtained according to curve 60 -66. As soon as the characters fall below 30 microvolts, the low-frequency amplifier (learn speakers no longer transmit characters. When a character of 100 microvolts is received, the output voltage of the loudspeaker reaches zoo volts, as indicated by 67. On the other hand, with simple local reception under the same conditions, the output voltage would be for an equally strong sign, be less than 30 volts, as indicated by point 68.

If the noise level is higher, the cut-off control can be operated in this way that a sign of 100 microvolts, indicated by 69, is necessary with it the suppression tube makes the playback equipment work.

The connection from the anode of the noise suppression tube 14 to the resistor 32 may be at any desired spark, e.g. between the tube 13 and the anode circuit of the tube i I increases when the control is set to a higher output volume, whereby the cut-off bias at the grid of the tube 13 increases, because increased suppression is required.

In view of this, it is because of the non-uniform input voltages the volume level would rise and fall when tuning and that the receiver therefore could not be operated sufficiently with a cut-off limit controller, as already noted, it is desirable that the input circuits of a receiver, which contains this noise suppression coating, a uniform performance otherwise the cut-off limit controller would have to be changed while the receiver is voted on his area.

The operation of the circuit in Figure 2 is the same in all other respects the same as in Fig. i.

Claims (7)

PATENT CLAIMS: i. Device for suppressing disturbing noises when receiving electrical waves through such a control of one of the receiving tubes, that this becomes ineffective - if the intensity of the received characters falls below one falls predetermined value, characterized in that in an arrangement in which a low-frequency amplifier tube located in the receiving channel by means of a special, influenced by the signal amplitude controlled by the demodulator the deodulator is designed as a two-pole tube and the inverted tube directly controlled by the bipolar tube. 2. I? Inriclituiig according to claim i, characterized characterized in that the inverted tube serving to the Ger iiiiseliunterdrüclnahm one has high gain so that small changes in grid bias in the Cause large changes in the anode current in the output circuit. 3. Device according to claims r and a, characterized in that when the received signal strength falls the controlled tube receives an increased bias voltage below a predetermined value, so that its working point is below the lower curve bend and .the anode current is practically suppressed. . Device according to claim z and the following, characterized characterized in that a high-frequency amplifier is provided, its gain automatically changes inversely with the strength of the received characters, whereby the Playback of noises when the received signal strength falls below a predetermined one Limit is prevented due to the fact that the gain of the high frequency amplifier has its maximum in the absence of receive characters. 5. Device according to claim x and following, characterized .that in a high frequency amplifier, Detector, noise canceling tube and low frequency amplifier existing receiving circuit the detector on the one hand automatically adjusts the gain of the high-frequency amplifier regulates and, on the other hand, in connection with the noise suppression tube, the mode of operation of the low-frequency amplifier regulates automatically in such a way that despite: the setting the high frequency gain to a maximum in the absence of received characters the low frequency amplifier is shut down. 6. Device according to claim r and following, characterized in that the input circuit of the low frequency amplifier tube a special one, from the voltage drop across the resistor in the output circuit of the suppression tube contains independent bias for its control electrode. 7. Device according to claim r and following, characterized in that a screen grid tube is used as the suppression tube is switched on, the screen grid potential of which corresponds to the desired cut-off limit is set, for example. By a controllable resistance = stood between the Screen grid and the input circuit of the suppression tube.