DE755844C - Circuit for regulating the fidelity of reproduction when receiving modulated carrier waves - Google Patents

Description

Circuit for regulating the reproduction fidelity when receiving modulated Carrier waves The invention relates to a circuit for receiving modulated carrier waves, at which means for regulating the fidelity in, depending on the reception conditions are provided.

The previously known methods for regulating the fidelity in Depending on the strength of the received vibrations can be divided into two groups classify; namely in a group in which the control in the carrier frequency part the circuit takes place (selectivity control) and a second group in which the regulation takes place in the low frequency part (tone regulation). The circuits of the first Kind with a regulation in the carrier frequency part are relatively complex and expensive, because in order to achieve a sufficient control effect, must in these circuits the transmission characteristics of several stages or several successive stages Selection circles are changed because the cutoff frequencies of the individual filters or circles because of: the only slight edge steepness of the transfer curve can be precisely determined. So it is always necessary to have the rule influence on a. to expand a larger number of circuit stages. The circuits of the of the second type with a regulation in the low frequency part all suffer from the need to in the associated high-frequency section transmission circuits with extraordinarily wide selection curves to be provided. It is clear that an extension of the transmitted modulation band in the low-frequency part can only take place up to the limit of the band that of the high-frequency part is transmitted. With consideration for the rather sloping flanks. the usual high-frequency circuit, the transmitted bandwidth must therefore be particularly wide be measured, which leads to the undesirable interference tones and proportionately many atmospheric and other disturbances enter the receiver. Furthermore are the previously known devices for regulating the low-frequency part passed through Modulation bandwidth is also not flawless in that it is because of the Regulation linked change of the fitting conditions very often non-linear distortions cause.

It is the purpose of the invention to provide a circuit for direct regulation to provide the fidelity of a receiver for modulated carrier waves which circuits of normal selectivity can be used in the high-frequency section. and in which the unevenness of transmission and amplification of various Modulation frequencies is completely balanced. The whole arrangement should which preferably a regulation depending on the intensity of the desired Reception carrier causes it to be simple and cheap. These demands are thereby fulfilled that in a circuit for receiving modulated carrier waves for the purpose the automatic control of the fidelity depending on the reception conditions according to the invention means are provided to in a carrier frequency stage of the receiver to modulate the modulated signal carrier once more with a modulation oscillation, which are derived from the modulated signal carrier by a demodulator stage and so distorted by the use of frequency-dependent transmitting elements is that with her the oscillation amplitudes of different frequencies in, essential have different relationships to one another than in the case of the primary modulation oscillation.

The repeated modulation is expediently carried out by means of the gain change a discharge tube in a carrier frequency stage, which the modulated carrier wave reinforced before their final defect. You have it in your hand now, with this one repeated 'modulation the higher modulation oscillations compared to the lower ones to be preferred or weakened so that the reproduction character istik as desired can be changed without affecting the selection properties of the filter circuits of the Recipient is changed #, ii must. The second modulation can be from your load resistance of the normal demodulator intended for filtering out the low frequency will. It is also possible to regulate the extent of this modulation in a simple manner, whereby the desired change in fidelity is achieved. This regulation can be exercised by the user by hand by resizing the button again Modulation used iNIodulationvoltage regulated by a regulating resistor will; however, it can also take place automatically as a function of the reception amplitude.

The regulation preferably extends to an amplifier stage in a relatively less selective input part of the receiver; it causes then that for the subsequent levels of higher selectivity, the modulation depth of the modulated carrier changes depending on the reception conditions, and Although this can happen to different degrees for high and low modulation frequencies, as will be explained later.

The invention will later be applied to an overlay receiver described in more detail. In this embodiment, the regulation takes place in the high-frequency amplifier of the recipient, which is usually relatively unselective. The main part the overall selectivity is achieved in the intermediate frequency channel of the receiver. the Attenuation of the outer sideband frequencies resulting from the high selectivity of this Channel results, caused. that the amplitude ratio of the outer sideband frequencies to the sideband frequencies close to the carrier frequency behind the selectors is less than the corresponding ratio for the received modulated oscillation. By regulating the gain of one or more high-frequency amplifier stages Conversely to the instantaneous value of the low frequency voltage, one can now use the sideband frequencies in. attenuate near the carrier frequency without amplifying the outer sideband frequencies to influence significantly. The result is a flattening of the frequency characteristic of the receiver and a significant improvement in reproduction. The automatic Control is expediently dependent on the intensity of the receiving carrier carried out. If the receiver contains an automatic backward regulation, which always is accompanied by an increase in the output amplitude, this change in the Output amplitude as a control influence for regulating the reproduction quality as a function on the intensity of the receiving carrier. However, if there is an advance regulation in the recipient is provided for gain control, the output amplitude is also for large Fluctuations in the input amphthude kept almost constant. Then become the scheme the rendering quality requires additional funds.

In this case, too, the amplitude of the second modulation is dependent To be able to regulate the intensity of the received vibrations must be a special one Regulatory voltage can be derived from a point in the receiver where the amplitude the carrier frequency has not yet been leveled by the gain control.

In the figure, the circuit of a superheterodyne receiver is shown, which includes fidelity control means according to the invention. The input of the receiver is a tunable high-frequency selector ro, whose Input circuit with the antenna circuit. z r is connected. The output terminals of the Selector ro are connected to the input terminals of a high-frequency amplifier stage Connection containing the discharge tube r2. The output electrodes of the tube 12, are connected to the transposition stage 13, to which the two intermediate frequency amplifiers 14 and 15, the demodulator 16, the low frequency amplifier 17 and the loudspeaker 18 follow. The demodulator 16 consists essentially of a diode rectifier r9, in whose load circuit there is a resistance 2o, which through. the Capacitor 2 r is bridged for carrier frequency oscillations. The hodulation components of the voltage developed across the resistor 2o are fed to the input circuit of the low-frequency amplifier 17 fed through the coupling capacitor 2.2.

To the input amplitude of the demodulator 16 within narrow limits to hold. if the amplitude of the received oscillations changes, is a automatic gain control provided, which by one of the. Diode rectifier 23 developed control voltage is operated. The diode rectifier 23 is with the output of the intermediate frequency amplifier 1q. coupled and works on one. Load circuit, which the resistors 2q. and contains z5 connected in series, which are bridged by the capacitors 26 and 27 for carrier frequencies @ zschwingengen are. The connection point between the two resistors and the associated ones Capacitor is grounded. The rectified voltage generated across resistor 24 is through a filter with the series resistor 28 and the bypass capacitor 29 freed from modulation components and the gain control electrodes one or several tubes of the intermediate frequency amplifier 1q. and 15 and the transpose level 13 and the tube r2 via the line 30 'in negative Poleng. One recognises, that this gain control in relation to the high frequency amplifier with the tube 12, the intermediate frequency amplifier 14 and the transposing stage 13 as a backward control is to be addressed while in relation to the intermediate frequency amplifier 15 as Forward control works. This type of gain control tightly adjusts the input amplitude to the demodulator 16 even with large. Fluctuations, the reception amplitude almost constant remain.

The fidelity control according to the invention acts on the tube 12, and. on the third grid of this tube. A device 30 for phase shifting is provided in the supply line for the control voltage, as is an amplifier tube 31, the control electrode of which is connected to a tap 37 of the resistor 20. The same control grid of the tube 12 to which the received oscillations are fed can of course also be used to regulate the reproduction fidelity. The separation of the two functions and their distribution on two different grids is preferable, however, because the circuit parts for the reproduction control are then better separated from the high-frequency part of the receiver.

The amplifier tube 3r is provided for automatic actuation of the playback control so that the receiver is sharply selective l @ i with low reception intensity and relatively little selective with high reception intensity, which receives control voltages on its grid from two sides and its anode circuit to the High frequency amplifier roar: re 12 acts. The control grid of the tube 3i is connected to a tap on the resistor 20 via the capacitor 32. The voltage source 33 generates a negative initial bias voltage for the control grid of the tube 31 of such a magnitude that the anode current is almost suppressed and no transmission takes place in the tube. In order to change the amplifier power of the tube 31 as a direct function of the strength of the modulated signal carrier as soon as the intensity of the carrier exceeds a predetermined value, the rectified voltage generated at the resistor 2 3 of the control electrode of the tube 31 has a positive polarity via a filter resistor 36 fed. It is clear that the rectified voltage across resistor 25 changes directly with the fluctuations of the selected signal carrier and that, because of its positive palunation, it makes the tube 31 effective when it has become large enough as a result of the increase in the carrier amplitude. From this limit onwards, further. Carrier rise increases the gain of the tube 31 further, and there is a transmission of the low-frequency AC voltage from the resistor 2o to the phase shift circuit 3o. The size of the low-frequency voltage applied to the input of the tube 31 depends on the position of the tap 3; adjustable at the resistor 2o, so that the extent of the control effect can be selected at will.

In a receiver of the type shown, the selectivity becomes primary in the intermediate frequency part generated by the intermediate frequency selectors proportionately are sharply selective. This: is necessary to avoid unwanted interference oscillations with strong transmitters on adjacent channels. But the consequence is that the Carrier and its neighboring sideband frequencies are amplified much more than the outer sideband frequencies., and distortions result as a result playback.

This undesirable disadvantage of the outer sideband frequencies is prevented in the circuit described by the control device for the reproduction fidelity, in that the gain of the tube 12 is controlled in inverse dependence on the instantaneous amplitude of the low frequencies. For this purpose, a voltage, which corresponds to the instantaneous amplitude of the modulation frequency envelope, is taken from the resistor 2o of the demodulator i6, amplified in the amplifier tube 31, brought into the correct phase position by the phase shifting circuit 30 and the control electrode of the tube 12 has a negative polarity supplied so that it is exactly in phase opposition to the modulation frequency component of the modulated carrier amplified in this tube. The. The phase shift circuit naturally only compensates for the small phase shifts that result in the selection circuits of the individual receiver units between the tube 12 and the demodulator 16; the necessary phase reversal of 180 ° is effected in tube 3i. The control voltage supplied to the third grid reduces the gain of the tube 12 by an amount which is determined by the instantaneous amplitude of the current voltage; In this control voltage, however, the side band frequencies that are closest to the subcarrier frequency are most strongly represented; this is due to the sharp selectivity of the intermediate frequency channel. In the tube 12, therefore, those sideband frequencies are weakened the most, which are allowed to pass through the selectors of the intermediate frequency channel the strongest. The carrier amplified in the tube 12 is therefore rapidly modulated under the influence of the regulation, namely with regard to the individual sideband frequencies in the opposite proportion to the disadvantage of individual sideband frequencies by the selection circuits of the intermediate frequency channel.

This demodulation of the carrier in the tube 12 only then occurs on when the intensity of the signal carrier fed to the rectifier 23 is greater as a certain limit which is sufficient to make the amplifier tube 31 effective close. For carrier amplitudes above this limit value, the transmission efficiency of the tube 31 changed in direct dependence on the carrier intensity, so that in the case of a high carrier intensity there is a considerable gain in the tube 31 of the low frequency voltages and the incoming carrier in the tube 12 in is demodulated to a large extent; the width of the transmitted frequency band is thus regulated in this way depending on the carrier intensity, without that an influence on the selection properties of the oscillation circuits used is exercised.

It has already been mentioned that the configuration of the arrangement for Playback control in some ways depends on whether through the automatic Gain control a complete or only approximate ion constant maintenance of the Output amplitude is effected. In the present case, the circuit is with a Feedforward control: see so that the input amplitude to demodulator 16 is practical remains constant. For this reason, the use of the tube 31 is associated with the Circuit for the gain control of this tube as a function of the carrier intensity necessary. However, if a receiver with the playback control according to the invention should be ", armed" -earth, in which as a result of the use of a backward control the The input amplitude of the demodulator corresponds to the changes in the high-frequency input amplitude at the antenna changes to a certain extent, the tube 31 may under certain circumstances fall away; in this case the increase in the modulus frequency voltage is sufficient, which results when the input intensity is increased by the desired Effect regulation.

In the circuit just described, the control of the playback quality, caused by a control voltage, which according to the decrease behind the selection circles of the intermediate frequency channel, the sideband frequencies corresponding to the low tones contains stronger, in a gain-reducing sense of the high-frequency amplifier tube 12 was fed. The same result can also be achieved if the control voltage in a gain-increasing sense, d. H. in positive polarity, supplied is, where in the transmission line for the control voltage, for example in the phase shift, iebungs. circuit 30, selection means are provided which transmit the higher sound vibrations more strongly than the lower ones. In this case is the control voltage with the modulation frequency envelope of the in the tube 12 amplified, carrier in phase, and it preferably contains the high: frequencies of the modulation band. In this case, too, there is an expansion of the transmitted Bandwidth at. an increase in reception intensity.

In the described embodiment of the invention, the gain control only exercised on a single amplifier stage to influence the reproduction quality. In order to increase the effect, you can of course also use several amplifier stages to be used for this purpose. Also the use of the intermediate frequency amplifier stages to a regulation within the meaning of the invention is readily available with the same results possible..

Claims (1)

PATENT CLAIMS: i. A circuit for regulating the fidelity of reproduction when receiving modulated carrier waves, characterized by means for repeated (secondary) modulation of the already (primarily) modulated signal carrier transmitted in a carrier frequency stage within said carrier frequency stage by means of a modulation oscillation curve which is generated from the modulated signal carrier by a demadulator stage is derived and distorted by the use of frequency-dependent transferring elements in such a way that the vibration amplitudes of different frequencies are in significantly different relationships to one another than in the case of the primary modulation vibration. z. Circuit according to Claim i, characterized in that the repeated modulation. is caused by the change * in the gain of a discharge tube which is provided in the carrier frequency stage for the transmission of the modulated carrier. 3. A circuit according to claim i, characterized in that a preference for the low modulation frequencies is effected by the distorting transmission means and that then the modulation voltage of the carrier frequency stage for subsequent modulation, preferably in a phase shift of about 1800 compared to the modulation.shüllkurve of the amplified in this stage Carrier is fed. q .. Circuit according to claim i, characterized in that the distorting transmission means a preference for the high modulation frequencies is brought about and that the modulation voltage of the carrier frequency is then fed in for repeated modulation, preferably in approximately the same phase as the modulation envelope of the beam reinforced at this stage. Circuit according to Claim 1 or one of the subsequent claims, characterized in that the modulation voltage generated by the demodulator stage for the repeated modulation is amplified before it is supplied to the carrier frequency stage. 6. A circuit according to claim 5, characterized in that the amplification of the modulation voltage is controlled as a function of the reception conditions, preferably by increasing the degree of amplification of the discharge tube used to amplify the modulation voltage when the amplitude of the desired signal carrier increases. 7. A circuit according to claim 6, characterized in that the discharge tube serving to amplify the modulation voltage in the idle state, ie when no signal carrier of sufficient amplitude is present, receives such a high negative grid bias that there is practically no transmission of the modulation voltage and only at transmission begins at a certain limit value of the carrier amplitude. Circuit according to Claim 1 or one of the subsequent claims, characterized in that the demodulator present in the receiver, which generates the modulation oscillations intended for reproduction, serves at the same time to generate the modulation voltages for the repeated modulation. 9. A circuit according to claim i or one of the subsequent claims, characterized in that the size of the modulation voltage used for repeated modulation can be regulated manually by a regulating resistor. ok Circuit after the. Claims i and 6, characterized in that a rectifier present in the receiver from the desired signal carrier simultaneously generates two oppositely polarized control voltages, one of which is fed in negative polarity to at least one tube in the main transmission channel for the purpose of automatic gain control, while the other is positive Polarity of the discharge tube used to amplify the returned modulation voltage is supplied. To distinguish the subject matter of the invention from the state of the art, the following publication was considered in the granting procedure: Austrian patent specification No. 139 25o.