DE716676C - Circuit for receiving modulated carrier waves - Google Patents

Description

Circuit for receiving modulated carrier waves The invention forms an improvement and further development of the subject matter of the main patent 687374, in which a circuit for receiving modulated carrier waves was specified, in which the transmitted modulation bandwidth is simultaneously automatically dependent on the reception strength of the desired signal and the strength of the existing signal Disturbances is regulated.

It is known that the most favorable reception results are taken into account of existing interference can only be achieved if the one let through by the receiver Bandwidth covers the entire receiving band if possible, but the existing ones Excludes disturbing vibrations as effectively as possible. As the reception conditions switch is therefore only possible with receivers that have a setting of the let through Allow bandwidth, adjustment possible. The main patent now gives a circuit on, in the case of which this adaptation is automatic due to an automatically acting arrangement is made, at the same time the intensities of the desired received oscillation and the existing disturbances are taken into account and to a certain extent offset against each other will. The arrangement was such that with increasing reception strength the transmitted modulation bandwidth of the desired signal has been increased and also for the additional setting of the bandwidth depending on the Reception disorders an organ in the recipient that is particularly responsive to the disorders was provided, with the help of which the bandwidth would be automatically reduced, when the reception strength of the interference increased.

One possibility of realizing this principle of the main patent is that, according to the known symmetrical expansion and narrowing of the transmitted modulation bandwidth, depending on the intensity of the people received @: input switching also the bandwidth changes under your influence of the occurring the st «run <jeii s@-inmetri-.cli to the middle of the band made. The optimal adjustment of the belt wider range of recipients to the enip- f2ingslieclingtuigen is only given if only those modulation freduences or groups of such fre- sequences within the overall modulation band through the selection effect deleted that are actually disturbed. This principle requires a selective approach to the individual frequencies appropriate control organ. A close approximation of this ideal is now formation of the invention achieved in that at the same time finite the reduction in the bandwidth left as a result of one on one Side: the disorder occurring the hancles Middle of the let through dumbbell: in the Density scale shifted v% ird, namely in one direction away from said Disturbance. Your university booth will be billed carry that yes a disturbance oscillation -frequently only on one side, that heals within the a sideband of the desired I-nip fangsscliEVnung.-is present. Demented speaking this needs from the receiver to uenonImetie frequency band in general only on the side of the carrier oscillation to be drawn into the crowd. on which the Fault lies. The other side can tied completely on lines, so das ;, no noticeable neglect of the higher modulation frequencies occurs. There: Ausnial3 of shifting the mb away of the disturbance this shift caused is according to the invention determined by the interference value of this Perturbation, which is one of the amplitude of the Interference and its frequency spacing-from that Desired carrier frequency certain size represents. The extent of the shift So u will have to be bigger the bigger the amplitude of the disturbance is and the smaller the frequency difference from the desired "The carrier frequency is. With the preferred guide form Invention contains a seen selector two resonance circles that both based on the reception carrier frequency "are estiinti1t. To regulate the through- left bandwidth is the vote of the circles in the opposite sense changes. As a means of position of voting discharge tubes that are arranged in such a way that that they are the weaknesses of the circles change and thereby the resonance frequency The necessary changes in reactances are achieved by changing the grid biases applied to the tubes.

For the cessation of the vote, auxiliary circles are provided by «-Which the bias voltages are generated for the regulating tubes mentioned. This one The input frequency mixture is fed to auxiliary circuits. In the preferred embodiment the invention, at least one auxiliary circuit is provided, which at the same time the Abstirninung Unfortunately, selector circles influenced to the bandwidth in direct dependence on symmetrically to adjust the amplitude of the desired receiving oscillation. Further Auxiliary circuits are tuned so that they are on the next to the desired carrier frequency respond more strongly than to the desired wearer. These help circles generate, each independently of the other, the bias of a control tube, so that only the resonance frequency of the associated circle shifted in such a direction is that the interference frequency is no longer allowed through. will. The extent of the shift, which, according to the above, depend on the interference value of the disturbance should, is determined by the dimensioning of the 1-lenietite that swirls together.

If there is interference on only one side of the desired carrier frequency is available. the dimensioning is expediently made so that the mean band frequency away from this carrier and by half the amount of the simultaneous Belt alignment is moved. If disturbances occur simultaneously on both Side of the desired carrier frequency, then is the direction of the shift away from the St (-) - l # finite larger interference value. The comfort of this shift is then half the difference between the amounts of the I '#. which are caused by these faults.

In Fig. I is the circuit of a superheteroclave catcher with a preferred embodiment of the invention shown. The recipient contains a tunable high-frequency amplifier and transposition part io, whose input circuit to an antenna i i and earth 12 and its output circuit to a Ztvisclienfreduenz amplifier 13 is coupled. The output circuit of amplifier i3 is connected to further intermediate frequency amplifiers 14th and 13th connected.

The device for setting the passed bandwidth according to the inventor, is contained in the second intermediate frequency amplifier 1. #: it will described in more detail later. Such filter devices can of course also be present in the amplifiers 13 and 15. The output of the third intermediate frequency amplifier 15th acts on a detector and low frequency amplifier 16.

The tunable high frequency amplifier and transposition part io, the intermediate frequency amplifiers 13 and 1_5 and the detector and low frequency amplifier 16 can be of a known type and mode of operation: a description of these Parts is therefore unnecessary.

The vibrations picked up by the antenna are known Way amplified and transformed into intermediate frequency oscillations, which in the intermediate frequency amplifiers 13 ,. 14 and 15 are reinforced selel @ tiv. The amplified intermediate frequency oscillations are then fed to your, detector and low-frequency amplifier 16; the reinforced Low frequency characters are then fed to a loudspeaker for playback.

There can be different types of selectivity control circuits can be used, but the invention is particularly useful run a band pass selector consisting of several tuned circles and to change the circular reactances contains discharge tubes, with the help of which the vote of the circles can be influenced, so as to the selectivity of the selector to regulate. Such an arrangement is shown in Fig. I, the adjustable Band filter in the second intermediate frequency amplifier i-1 is located.

The amplifier 14 contains a tube i; the input circuit of which is coupled to the output circuit of the amplifier 13 in a customary manner. The output circuit of the tube 17 is coupled through a band filter with the input circuit of the intermediate frequency amplifier 15, which contains an intermediate frequency transformer whose primary winding i9 through the capacitor 2o and its secondary winding 2i through the capacitor 22 are tuned to the civil frequency. The coils 19 and 21 are loosely coupled to one another, as indicated by ig in the drawing, so that the filter only lets through a relatively narrow frequency band when both resonance circuits are tuned to the subcarrier frequency. In order to be able to regulate the selectivity in accordance with the respective reception conditions, resistors 23 and 24 are provided in the capacitance branch and inductance branch of the filter circuits i9, 20 and 21, 22. The impedances of these resistors are small compared to those of the reactance elements of the associated filter circuits at the intermediate frequency. The input circuits of the tubes 25 and 26 are parallel to the resistors 23 and 24, via the coupling capacitors 27 and the resistors 28. In the cathode circuits of the tubes 25 and 26, the bias batteries 29 are present, which give the tubes such a large amount in the idle state Provide bias that practically no anode current flows.

Each anode circle of the tubes 25 and 26 is parallel to the associated one Filter circuit; the anode voltage is supplied to the tubes via the inductances of the associated Circuits fed from the DC voltage source + B. The anode impedances of the Tubes 25 and 26 are compared to the impedances of the matched circuits Resonance preferably high, so that the phase shift of the anode currents through the impedances of the circuits is not significantly affected. The tubes 25 and 26 are shown as triodes, however, because of their higher anode impedance Pentodes can also be used.

In the arrangement shown, the input circuit of the tube 25 is parallel connected to a resistor in the capacitance branch of the associated filter circuit; therefore the intermediate frequency voltages across the grid of this tube are opposite to the voltages at the filter circuit 19, 20 by approximately 9o ° im. Leader. Because, on the other hand, the input circle of the tube 26 in parallel with a resistor in the inductance branch of the filter circuit 21, 22 is switched, the intermediate frequency voltages remain on the grid of the tube 26 compared to the voltages on the associated resonance circuit by approximately 90 °. Therefore, the anode currents of the tubes 25 and: 26 versus the voltages across the The associated filter circuits are essentially phase-shifted by 90 ', and in fact leading at the tube. 25 and lagging at the tube 26. The tubes therefore behave just like a capacitance and an inductance, the value of which depends on the magnitude of the anode current depends. So they can be used to tune the filter circuits to regulate by changing the grid bias applied to the tubes, whereupon will come back later.

Within the circuit described is a special intermediate frequency amplifier-3o provided, which contains a rectifier for automatic gain control. The auxiliary intermediate frequency amplifier 3o is arranged to have a very wide Frequency band passes, d. H. it not only reinforces the desired character, but also all interference caused by the high frequency quadruple and Transposition part are allowed to pass and their amplitudes are so large that the transposition part is overridden or disturbances are caused.

In Fig. 3, the relative gain in decibels is versus the frequency difference plotted from the subcarrier frequency in IzHz for this amplifier. These Curve - tends to favor the neighboring disturbances over the desired character will. The bias voltage developed by your control voltage rectifier becomes the Control grids of one or more tubes of the high frequency amplifier and transposition part io supplied as negative control voltage. Part of the control voltage can also be used Control grids of one or more tubes of the intermediate frequency amplifier are supplied will. in order to reduce the input amplitude at the demodulator for strong fluctuations to keep the reception strength essentially constant.

In the circuit, a control device 31 is provided, which with is coupled to the output of one of the intermediate frequency amplifiers and is used to generate the V4'action of the control tubes 25, 26 to control. This control device contains a Amplifier tube 32, whose input circuit via the capacitors 33 and the resistor 34 is coupled to the output circuit of the amplifier i S. The starting circle of the Tube 32 contains three inductive units 35 connected in series, via which the anode voltage -i- h is supplied for the tube and «-which the primary coils are three separate ones Transformers with the secondary coils 36, 37 and 38 form. The coil 36 is through a capacitor 39 at a frequency 10 kHz below the subcarrier frequency, the coil 37 through a capacitor 4o to the subcarrier frequency and the coil 38 through the capacitor q.i to a frequency io lcHz above the subcarrier frequency Voted. The three coordinated circles 36, 39, 37, .4o and 38, 41 are the Diode rectifiers 42, 43 and 44 connected, the load circuits of which the capacitors : I5, 46 and 47 and resistors .48, q.9 and So included.

The bias voltage developed across the resistor 49 becomes positive Polarity fed to the control grids of the filter control tubes -25 and 26, namely the Tube 25 over resistor 48 and the filter with resistor 48 "and your capacitor q.8b, while the supply of the control voltage to the tube 26 via the resistor So and the filter with the resistor 50 "and the capacitor Soj, takes place; in addition The high-ohm resistors28 are still in both supply lines. The ones of your resistance The voltage developed in 48 is, however, in negative polarity, i.e. H. opposite to of the positive voltage developed by the rectifier 43 to the grid of the tube 25 fed; the algebraic sum of these two biases is given to the lattice the tube 25 is applied. In an analogous way, the voltage developed across the resistor So in negative polarity and opposite to that supplied by the rectifier q.3 positive voltage is applied to the grid of the tube 26.

To explain the mode of operation of the filter 1I and the control circuits 31, it is assumed. that the filter circuits are first set so that they only allow a narrow band to pass through for the reception of a weak signal; tubes 2S and 26 then have grid biases so high that they are blocked. When a relatively strong signal is received without significant interference, the amplitude of the desired oscillations fed to the auxiliary selection circuits increases. Since the auxiliary circuit 37, -to is tuned to the intermediate carrier frequency, a larger control voltage is developed by the rectifier 43 at the associated resistor .I9. This voltage fed to the control grids of the tubes 25 and 26 in a positive sense causes an increase in the apparent capacitance de: filter circuit 19, "2o and a decrease in the apparent inductance of the filter circuit 21. 22. Therefore, the resonance frequency of the circuit 19. 2o is lower Frequency and the resonance frequency of the circle: = 1.22 shifted to a higher frequency. The two filter circuits are therefore detuned to the same extent, but in opposite directions with respect to the mean subcarrier frequency; this results in a symmetrical expansion of the frequency band passed through the filter A further increase or decrease in the amplitude of the desired signal oscillations at the filter 1.1 results in corresponding symmetrical expansions and contractions of the baud that has passed through.

If there is an interfering oscillation on one side of the desired character carrier before a significant amplitude occurs, there is of course a corresponding one Intermediate frequency oscillation on the corresponding side of the intermediate frequency carrier of the receiving vibrations. Is the disturbance transposed to an intermediate frequency close enough to the subcarrier frequency of the desired received oscillation, e.g. B. below, the selection circuit 36. 39 prefers this disturbance oscillation, since it on a frequency is tuned, the io kHz below the desired Intermediate frequency carrier is, therefore, through the rectifier 4.2 to the associated Resistor 48 develops a greater bias voltage and is in negative polarity, d. H. opposite to the control voltage generated by the rectifier 43 to the grid the tube 25 is supplied. Since now a reduction in the bias of this tube the Has the effect of reducing the apparent capacity of the filter circuit 19, 2o results there is a shift in the resonance frequency of this circle upwards to the subcarrier frequency there. So the band that has passed through the filter will be in such a direction contracted that the spurious oscillations within the intermediate frequency channel avoided «.

In an analogous manner, the selection rice 38, 41 prefers disorders, which result in an intermediate frequency close to the normal subcarrier frequency, because it is tuned to a frequency that is 10 kHz above the desired subcarrier frequency lies. In this case, therefore, by reducing the prestress on the grid of the tube 26 a reduction in the apparent inductance of the filter circuit 21, 22 causes and the resonance frequency of this circle downwards in the direction of the subcarrier frequency shifted towards so that a shift in the mean resonance frequency of the band passed through the device in a direction away from the existing one Disturbance results.

In Fig. 2 is a modified embodiment of the automatically adjustable Band filter and the control arrangement shown. In this filter are also Discharge tubes used to change the impedances of the resonance circuits. That The filter of FIG. 2 is contained in an intermediate frequency amplifier 14a which is connected to can take the place of amplifier 14 of FIG. The control device 31a can in essentially the same way as the corresponding control device of Fig. i are switched on.

In this embodiment of the invention, amplifier 14 "includes an amplifier tube 17 ', whose input circuit is connected to a preceding amplifier the device is coupled. The output circuit of the tube 17 ″ can be connected to the input circuit a subsequent amplifier coupled via a bandpass filter according to the invention will. This filter contains in Fig.2 an intermediate frequency transformer with a Primary coil 5 i, which is tuned to the intermediate frequency by the capacitor 52 is; Likewise, the secondary coil 53 is set to the intermediate frequency by the capacitor 54 Voted. As in FIG. I, the bandpass filter therefore contains two resonance circuits 51, 52 and 53, 54, both of which are tuned to the desired intermediate carrier frequency. The coils of this transformer are also loosely coupled together so that the filter when both resonance circuits are tuned to the subcarrier frequency only allows a relatively narrow frequency band to pass.

In this example, the control tubes 55 and 56 are coupled with their input circuits to the filter circuits 51, 52 and 53, 54 via the capacitors 57 and with the aid of the high-ohmic resistors 58. The bias batteries 59 and 6o are located in the cathode circles of the tubes 55, 56. In the anode circuit of each tube there is an impedance, which is formed by a resistor 61 and an inductance 62, in series with the anode voltage source + B. A small capacitor 63 each causes a feedback between the anode and the grid in both tubes. The circuit elements are dimensioned so that the phase shift of the current fed back from the anode circuit to the grid circuit via the capacitors 63. Input impedances of the grid circuits gives the character of capacitors with a low loss factor. These input impedances of the tubes, which are parallel to the filter circuits, can now be regulated by changing the control grid bias voltages, whereby the tuning of the filter circuits can be influenced in the desired manner. The tubes 5, 5 and 56 receive such a bias voltage in the idle state that the operating point is a good deal ob @ erhally the cut-off point of the grid voltage and current characteristic.

A control device is used to regulate the action of the tubes 55 and 56 31a, corresponding to the arrangement 31 of FIG Intermediate frequency amplifier is connected. This connection can be made via the input circuit of the tube 32 ″, the output circuit of which contains a coil 64 through which the Tube an anode voltage -f- B is supplied. The coil 64 forms the primary winding a transformer provided with two secondary coils 65 and 66. The coil 65 is through the capacitor 67 to a frequency io kHz below the subcarrier frequency and coil 66 through capacitor 68 to a frequency 10 kHz above that Subcarrier frequency matched. So in this embodiment there are two matched Circles exist, both to some extent also on the subcarrier frequency address, however, on the Neighboring frequencies below and above respond better to this carrier frequency.

The diode rectifiers 69 and 7o are connected to the tuned circuits 65, 67 and 66, 6 8, and their load circuits each have a capacitor; 1 and a resistor 7.2 eDhold. The biases developed at the resistors 72 of the diodes 69 and 7o are fed to the control grids 55 and 56 in the opposite sense via the filters, the t @ 'i resistors 73 and the capacitors 7- @. In the operation of a receiver of this embodiment of the invention, when a relatively strong desired character is received without disturbances of substantial strength, the amplitude of the desired intermediate frequency oscillations fed to the selection circuits 65, 67 and 66.68 all increases. If the intermediate frequency carriers respond, both rectifiers 69 and 70 connected to them develop increased control voltages. The bias voltage developed by the rectifier 69, which is applied to the control grid of the tube 55 in negative polarity, causes a decrease in the feedback of this tube and therefore a reduction in the capacitance of the filter circuit 51, 5 = and causes the - @bstirnniurlg of this filter circuit to be adjusted a higher frequency. It also causes the rectifier at the same time; o Developed bias voltage, which is fed to the control grid of the tube 56 in positive polarity, an increase in the feedback of this tube and therefore an increase in the capacitance of the associated filter circuit 53, 54 and causes the alignment of this circuit to be adjusted to a lower frequency. This detuning of the filter circuits in opposite directions causes a synchronous expansion of the frequency band passed through the filter.

If a neighboring disturbance shows up to a full extent on one side of the desired character carrier, a corresponding disturbance oscillation results from a frequency close to the difference; If the intermediate-frequency disturbance oscillation is below the intermediate frequency carrier, the selection circuit 65, 67 prefers this disturbance. Therefore, the vote of the filter price 51: @; It influences, in such a sense, that the mean frequency of the band passed through the filter is shifted towards higher frequencies. If, however, a disturbance is present which results in an intermediate frequency disturbance above the frequency of the normal intermediate frequency carrier, the selection circuit 66, 68 prefers this disturbance. Therefore only the part of the filter circuit 53, 54 is influenced, the mean frequency of the band passed through the filter being shifted in the direction of lower frequencies.

When two faults at the same time on both sides of the desired Carrier is present, the mean frequency of the country allowed through will be in shifted the direction, dal .; the interference with your larger interference value avoided will.

It is clear that in the embodiment of the invention just discussed the coordination of the filter circuits with the simultaneous occurrence of strong interference signals be changed in opposite directions on both sides of the girder, thereby reducing the bandwidth as well as receiving a strong desired character is enlarged without interference. However, this effect is enhanced by the action of the automatic circulation regulator 30, which is equipped with a broadband intermediate frequency amplifier cooperates, compensates. Because this amplifier is the crude desired character carrier neighboring disturbances preferentially, the occurrence generates before, disturbances on both Pages of the desired carrier a substantial increase in the associated Rectifiers generated control voltage, which the tubes of the first receiver stages is fed. As a result, the subsequent stages of the receiver are fed _lmplitudeli both of the desired signs and of the disturbances diminished. One However, a reduction in the amplitude of the desired part of the character causes a contraction of the water allowed through the filter in the manner described above. @@ hen there is severe interference on only one side of the desired carrier. a control effect corresponding to the interference value of this disturbance is produced.

Fig. D - shows schematically a Sul) Erlieterodyneempfänger. the one contains forward-acting automatic selectivity control according to the invention. The receiver of Fig..l corresponds in many parts to your receiver of Fig. I; Corresponding "files" are therefore provided with the same reference symbols.

The receiver according to Fig..4 contains an intermediate frequency amplifier 14r, riding an adjustable filter and a control device 31r ,. This filter and this device can be either your amplifier 14 and the control device 31 of Fig. I or your N "intensifier 14" and the control device 3r "of Fig.? correspond to or may contain any other arrangement for regulating selectivity, in which the control device changes in reception conditions responds in the input to regulate the selectivity according to these conditions. In contrast to the embodiments of the invention already described here, however, the input of the control device 34 with the output of the amplifier 13 coupled so that the selectivity control of the following amplifier i.46 as feedforward control. The scheme according to the arrangements of Fig. i and 2 can be described as acting backwards because the circles, their selectivity is regulated in these arrangements, the coupling point of the control device precede in the circuit. The forward-acting arrangement of FIG achieved various advantages. If z. B. as in Fig. I, the control device responds to the disturbances, the filter of the amplifier 1d6 can be set so that it does not let this interference through. It is clear that with a backward control as in Fig. I in the output of the controlled Amplifier still have to have significant interference amplitudes in order to avoid the To effect selectivity control, and they therefore become the subsequent receiver stages transfer.

Since the selectivity control in this arrangement also controls the amplitude of the desired character transmitted through the filter can change. one additional automatic gain control is used to compensate for this effect. As can be seen from FIG. 4, a control voltage line of the usual type is connected provided with the detector 16. The control voltage is the control grids of the tubes fed in the amplifiers 14.b and 15 and controls their gain, so that the The output amplitude of the amplifier 15 is kept within relatively narrow limits will.

It is readily apparent that many changes have been made to the described Embodiments of the invention are possible without departing from the spirit of the Invention must remove.

Claims (18)

PATENT CLAIMS: i. Circuit for receiving modulated carrier waves according to patent 687 374., in which the transmitted modulation bandwidth increases with increasing Reception strength of the desired signal is automatically increased and with a organ responding to the disturbances, with the help of which the bandwidth automatically is reduced if the reception strength of the interference increases, characterized in that that simultaneously with the reduction in the bandwidth passed due to a The disturbance occurring on one side of the band affects the center of the band that has passed is shifted in the frequency scale, in a direction away from said Disturbance. 2. Circuit according to claim i, characterized by such a dimensioning of the switching elements that the displacement caused by the center of the tape is approximately the same is half the amount of tape contraction. 3. Circuit according to claim i and 2, characterized in that the regulation is dependent on the interference value a disturbance occurs, which is caused by the amplitude and the frequency difference of the Disturbance is determined by the desired carrier oscillation. Circuit according to claim i or one of the subsequent ones, characterized in that when Disturbances on both sides of the belt simultaneously with the reduction in the transmitted Bandwidth corresponding to the interference value of the interference a shift of the Ribbon center of the size of half the difference between those on each side of the ribbon caused contractions. in one direction away from that Interference with the larger interference value. 5. A circuit according to claim i or one the subsequent one, characterized in that as a means for regulating selectivity a filter with at least two resonance circuits is used, which in the setting to the smallest width of the frequency band allowed to pass both to the one to be transmitted Carrier frequency are matched and which for the purpose of expansion and displacement of the tape can be out of tune. 6. Circuit according to claim 5, characterized in that that the resonance frequencies of at least two oscillation circuits as a function of the reception strength of the desired signal in the opposite sense and essentially be shifted by equal amounts compared to the carrier frequency to be transmitted. 7. A circuit according to claim 5, characterized in that the scheme as a function of a disturbance occurring on one side of the belt practically only on the Resonance frequency acts on at least one oscillating circuit, while one on the disturbance occurring on the other side of the belt practically only the Resonance frequency at least one other circle moves, in both cases in such Meaning that the resonance frequency of the circle moves away from the frequency of the disturbance. B. Circuit according to claim 3 and; . characterized in that the facility for the separate regulation of the resonance frequencies of the two circuits as a function of the interference value of a disturbance contains a selection circle, which the desired reception frequency on one side opposite adjacent vibrations other frequencies, especially preferred over the desired receiving frequency, and that this selection circuit leads to one of the vibrations to be transmitted Part of the receiver is coupled. G. Circuit according to claim B. characterized in that There are two selection circles, one of which is the disturbances above and the other prefers the interference below the desired carrier frequency absorbs, and that the tensions arising in each individual circle for regulation serve the resonance frequency of each filter circuit. ok Circuit according to claim g, characterized in that each of the two is preferably responsive to the disturbances Selection circuits finitely connected to a rectifier whose output voltages serve as control voltages. i i. Circuit according to claim 5 and io, characterized in that each of the two filter circuits is assigned a discharge tube serving as a regulating tube, which acts as an impedance element in the circuit, so that by changing its grid bias through the regulating voltage generated by the associated rectifier, a change in the output tuning of the filter circuit takes place. 12. Circuit according to claim g to i i, characterized in that in the auxiliary device for Control voltage generation is another auxiliary circuit connected to a rectifier is provided which is tuned to the desired carrier frequency, and that the control voltage derived from this circuit for both control tubes of the filter circuits is fed at the same time. 13. Circuit according to claim g to 12, characterized in that that the control voltages of the three auxiliary circuits are combined in two groups in such a way are that the control voltage of the auxiliary circuit tuned to the desired carrier frequency each with a control voltage of an auxiliary circuit that preferably responds to the disturbances is connected in series in the opposite sense and that the resulting both voltage differences are fed to the grids of the control tubes. 14 .. Circuit according to claim r to 13, characterized in that the coupling point for the auxiliary selection circuits within the circuit before the one for the selectivity control serving filter is, so that there is a forward control. 15th Circuit according to claim r i. characterized in that in a filter circuit the Regulating tube the character of a capacitance and in the other filter circuit the character an inductance. 16. Circuit according to claim g and i i, characterized in that that two selection circles are used as auxiliary circles, which on the two sidebands are matched so that they are preferred to those of the carrier wave neighboring disturbances, but also to a significant extent the carrier wave itself record, and that the control voltages generated separate the grids of the two Control tubes are fed. 17. Circuit according to claim 16, characterized in that that an automatic gain control is provided, the control voltage over a selection device from the transmitted vibrations including the Interference is obtained, which the interference with respect to the desired carrier frequency preferred, so that simultaneously with an increase in the amplitude of the disturbance, there is a decrease the amplitude of the desired carrier frequency at the input of the filter. 18. Circuit according to claim 17, characterized in that a further automatic Gain control is provided which is controlled by the selectivity control compensates for conditional and other amplitude changes. ig. Circuit according to claim ig, characterized in that the second gain control is behind the selectivity control serving filter is effective.