DE727612C - Device for remote tuning of an oscillator, in particular an overlay receiver - Google Patents

Description

Device for remote tuning of an oscillator, in particular one Heterodyne receiver There is often the task of an oscillator automatically on the frequency, ciie one in the same or in a distant place installed second oscillator ilecitzt. Such a task occurs e.g. B.) unites Single-wave broadcasting or in the l. (- control of a superimposition receiver by a control oscillator that controls the frequency of the local oscillator to bring it into agreement with its own frequency. It's proportionate easy to compensate for coarse frequency deviations by e.g. B. the! Natural frequency of the oscillator to be controlled periodically, for example by means of a motor, and in the eye - ', lick, in which the beat frequency becomes very low, the periodic one Vote change interrupts.

1) he present invention, however, the task of the two To bring the oscillator frequency to exactly the same value, d. H. to reach, that the vibrations remain exactly in step with one another for any length of time. For this purpose it is already known to run the resonant circuit of one oscillator to influence the oscillations of the other oscillator in such a way that the latter is taken. However, this entrainment is generally only a very small one and poorly defined frequency range and only possible if you take it with you Oscillator gives a relatively low frequency stability Often unwanted pulling symptoms.

In a known method for synchronizing single-frequency transmitters If the vibration of this transmitter is in phase with a (ileichrichterpaar and the transmitted vibration of the mother Transmitter fed out of phase. If the two transmitters are already at the same frequency, there may be a change in frequency of the daughter transmitter initially only affect the two oscillations an additional Get phase difference. This causes a at the output of the push-pull rectifier DC voltage, which restores the original phase state and thus prevents a change in frequency of the daughter transmitter. However, this facility can not the frequency of an oscillator, which is initially one of the control frequency, z. B. by several iooo Hz different frequency has to bring to the control frequency.

Furthermore, it is already known from the two initially in frequency vibrations deviating from each other a controlled variable serving for adjustment to gain by mixing the two vibrations and the Differential oscillation (oscillation of the difference frequency) forms. With a well-known Arrangement of this kind, the differential oscillation is rectified and the resulting one DC voltage used to retune the local transmitter. It can also do the Differential oscillation directly to influence the heating and thus to re-tune to serve. However, such devices have the disadvantage that retuning is only ever possible in one direction.

Finally, there is a device for remote control of a heterodyne receiver known, in which the input of the receiver is supplied with a control oscillation becomes, «-which an intermediate frequency with the oscillation of the local oscillator of the receiver forms. If the intermediate frequency deviates from its nominal value, a usual push-pull rectifier circuit a control voltage, which via a motor the receiver readjusts until the intermediate frequency reaches its setpoint Has. If you change the control frequency slowly, you can use the receiver up to the desired setting. In this arrangement, too, is not the initially task solved. an oscillator to the frequency of the control oscillation to bring and to keep in step with this.

According to the present invention, that to be controlled becomes approximate The oscillator tuned to the control oscillation is frequency-modulated with the help of a control tube, in such a way that it is generated in cycles of the difference frequency between control oscillation and Oscillation is constantly changing in frequency. so dali its 1 # reclueiiz briefly coincides with the control frequency and the difference frequency (modulation frequency) reaches zero; the remaining phase deviation between the two oscillations is used to generate a DC control voltage that sets the frequency of the oscillator adheres to the value of the control frequency.

In short, the one created by mixing the two vibrations Differential oscillation that occurs when the frequency coincides with one of the phase deviations dependent DC voltage passes, first frequency modulates the oscillator in the Clock of the difference frequency and tunes it up continuously if the frequencies match the control frequency according to.

In the arrangement according to the invention, one can use the controlled oscillator run with a very stable frequency and still achieve it in a very broad and sharply defined frequency range of z. B. -f- 2o per cent deviation compared to the control frequency is taken along by this. As soon as the distance between the two oscillator frequencies has fallen below the specified value, the oscillator to be controlled becomes practical Immediately brought into step with the control oscillator. The limits of the take away area can be adjusted very easily.

Outside of this area there is no influence if one according to a further feature of the invention, the frequency range in which a Modulation is possible, limited upwards, by going about through appropriate filters only allows difference frequencies up to a certain level arise, and for the upper limit frequency of this range the frequency deviation of the modulation (the largest possible frequency change of the oscillator caused by the tube) at least equal to this Frequency makes. The frequency deviation is even made so large that it is a multiple is the upper limit frequency of the modulation device, it can be achieved that the phase difference that ultimately still remains in the event of a frequency match of the two oscillations is negligibly small.

An embodiment of the invention is shown in Fig. R. The oscillator 0_, the frequency of which is to be taken along by the oscillator 01 that is set up at a distance, is connected in a three-point circuit because the oscillating circuit coil L is between the anode and the grid, while the cathode is connected to the connection point of the variable capacitor C with the one used to shorten the Frequency range serving fixed series capacitor C ',. ; is included. The tube -11, with its anode-I-cathode path parallel to the outside circle, is used for frequency inodulation. By means of the voltage divider 1i, C ' , part of the anode alternating voltage of the tube is fed back to the grid with a phase shift of 0 °. The tube acts The control grid is fed via the filter element R3, C3 with a control voltage from a retuning controller which contains the two push-pull rectifiers Dl, D2 with the load resistors R1 and R2. The two rectifiers (diode) are fed the oscillation of the oscillator 01 via the Transmitter T in push-pull and the oscillation of the oscillator 0 via the capacitance C1 in common mode.

? "Between the cathodes of the rectifiers Dl, D2, the connection path of which is capacitively bridged by the capacitor C2 for the oscillator frequencies, if the frequencies are the same, a DC voltage is created, the value of which depends on the phase shift of the two oscillations Zero. In the event of a frequency deviation, on the other hand, an alternating voltage is produced, the frequency of which is equal to the difference between the oscillator frequencies. If this difference is smaller than the upper limit frequency of the filter R3, C3, the oscillator 02 is frequency-modulated in time with the differential oscillation. The frequency deviation of the modulation should now be immediate be so high that the oscillator frequency f2 of oscillator 02 briefly assumes the value of the frequency f1 of oscillator 0. In this case, the frequency f2 continuously assumes the value of f1, and only such a phase shift remains between the oscillations of the same frequency that the at the cathode of Dl occurring direct voltage the slope of the modulator tube: 1l brings the value necessary for detuning the oscillator 02.

The mode of operation is clarified in detail with reference to Fig. 2. It is initially assumed that the oscillator frequency f2 is already in the vicinity of the Frequency f l is, but initially there is no frequency modulation that the Control grid of the tube 11 so -first, the control voltage zero is supplied. Now the oscillator should be 0., with the differential oscillation of the frequency f1 f = frequency-modulated the modulation sublub should be greater than this difference. 13s should started with such a phase; that the control bitter of the tube 11 iie-atiwer will. The self-induction of the oscillation circuit shown by the tube becomes "rölier. The previously constant frequency j_ is al # o smaller. Hence it moves away even further from the value f1 as in Fig. 2 through the left half-wave of the Sintiskurwe indicated. The oscillation trains of the two oscillations, which so far have only moved slowly pushed past each other, now push past each other even faster, so that the beating that arises at the retuning controller very quickly turns into the opposite Phase occurs, d. H. that the grid of the tube M is now positive. this means a decrease and an increase in the self-induction presented by the tube . the frequency f2. The frequency difference is now smaller. The Sch-wingunbszüge become more similar to each other and consequently push each other more and more slowly until you finally aperiodically at the state of frequency equality approximates. The frequency f2 has so because of the retroactive effect of the frequency change the beating used for modulation is not the one in Fig. z by the dashed line Differential oscillation indicated course, but the one by the solid curve shown.

In the equilibrium state, the two oscillations do not have a phase difference of go °, which corresponds to the control DC voltage zero, but a phase difference which deviates more or less therefrom, which in the present case has such a size that a small positive DC voltage remains at the cathode of the diode Dl, which is transmitted via the resistor R3 to the control grid of the modulator tube A1 and the self-induction represented by the tube gives such a value (which is smaller than the quiescent value occurring at zero control voltage) that the oscillator 0 is retuned to the frequency fl. The condition for the condition of the frequency agreement to be really stable is that for the frequency of the two oscillations and one at the input of the 1; Axial tuning controller's phase difference of oo or r8o ° generated control voltage the achievable detuning of the oscillator 0. is at least equal to f, -f2 .

If the frequency of the oscillator 01 is not fixed, but rather it can be tuned to very different frequencies of a larger frequency range, then it is necessary to move the oscillator 0 to roughly tune the oscillator 0 = initially to the frequency t1, so that the frequency f = falls within the range in which frequency modulation by the differential oscillation is OK. For this purpose, one could periodically turn the capacitor G In, known per se, over the trimming area and interrupt the trimming movement. (Soon the frequency of the beat I of the two oscillations is sufficiently small. In the present case, the relay causing the interruption of the periodic tuning process can be caused, for example, by the alternating voltage occurring in the control grid of the tube NI; for the occurrence of a AC voltage at this point is a sign that 'now the exact tuning can be done by the tube M. It may also be advisable to feed the shutdown relay via a filter whose permeability range is much smaller than the maximum modulation frequency.

It is even more useful to make the arrangement so that also with larger initial detuning, a coarse adjustment takes place in the shortest possible way. This can be done - according to Fig. I, for example, that an additional retuning controller is provided, the one with the variable capacitor C coupled motor Mo depending on the sense of the frequency deviation switches to clockwise or counterclockwise rotation and its frequency-determining Link is also coupled to the engine. This retuning controller contains the two rectifiers D3 and D4, which control the oscillator oscillation via the Transformer T 'is fed in push-pull. The supply takes place at the diode D3 via a voltage divider consisting of the capacitor C4 and the resistor R4, at the diode D4 via a purely ohmic voltage divider R5, R, the size of the resistors as well as the size and the plate section of the capacitor C4 as well as the coupling of this Capacitor with the variable capacitor C are chosen so that with an approximate match of the frequencies t1 and t2 the voltage distribution by the two voltage dividers is the same and the control voltage controlling the motor is equal to zero, so that the engine stops. If there is a frequency deviation to one side or the other on the other hand, the motor is switched to clockwise or counterclockwise rotation. so that the frequencies brought into approximate agreement by the shortest route. The production the exact frequency equality is now closed by the modulator tube _1l. In the event that the oscillator 02 is the superimposition of a remotely controlled l`berla:; crun "senihfänzers is. Of course, the motor also causes the pre-circuit relay capacitors. with your oscillator relay capacitor are coupled. roughly matched.

the greater the modulation range of the upper (@reiizfre (ltieiiz of the filter R "and C3, the smaller the iin (ileicli1, = ewiclitsstatus that is established Deviation of the plias sufficiency from (lein value oo @ '. Will inan on the other hand a certain other plias difference, e.g. B. the Pliasendiiierenz \ rill, achieve, so you have to put an additional phase shifter in the feed of the oscillator 01 to switch on transformer T. Such an arrangement can then, for. B. for homodyne receivers to be used.

For wireless transmission of the control frequency, it is recommended to use the Achieving a sufficiently high control voltage, which is also decisive for the modulation swing, to amplify the control oscillation before it is fed to the retuning controller Dl, D2. If necessary, the generated control voltage can also be amplified, but in doing so a DC amplifier must be used, since the equilibrium is also used The resulting control DC voltage can be used to change the frequency of the oscillator 02 must be done. The control voltage range is expediently made essential larger than the dynamic range of the tube? ll, so works with a sufficient Excess of control voltage, which results in a defined limitation of the frequency deviation attained. In the present circuit, the frequency deviation is over the tuning range across proportional to the frequency. By connecting a suitably dimensioned Inductance to the capacitor C 'can be a constant frequency swing over the entire Achieve the tuning range.

Claims (1)

PATENT CLAIMS: i. Device for remote tuning of an oscillator, in particular a heterodyne receiver, with the help of a in the case of the oscillations which initially diverge in frequency from one another in terms of frequency a controlled variable used for adjustment is derived, characterized in that that the zti controlling, approximately tuned to the control oscillation oscillator is frequency modulated with the help of a control tube, such. that he is in the cycle of the difference frequency The frequency changes constantly between the control oscillation and the oscillation generated so that its Fre- (luen7 coincides briefly with the control frequency and the difference frequency (modulation frequency) reaches the value zero and that the still remaining phase deviation between the two vibrations to the l-rzeugunl; one Control DC voltage is used, which adjusts the frequency of the oscillator to your value of the control frequency. holds on. =. Linrichtung according to claim i, characterized in that (let the largest possible At least reduce the frequency of the oscillator (O =) by means of the control tube (11) as well large, preferably several times the size of the largest possible in the facility for mixing the control oscillation and the oscillator oscillation (Dl, D =, R1, R2, C2) formed and possibly by an additional filter (R3, C.,) upwards limited difference frequency. 3. Device according to claim i, characterized by an additional device, which an automatic coarse adjustment of the to be controlled Oscillator causes the frequency of the controlling oscillator. q .. establishment for automatic coarse adjustment according to claim 3, characterized in that the control oscillation to a rectifier (D4) via an ohmic resistor (RS) and a second rectifier (D3) is fed through a reactance (C4) and that the. Difference between the output DC voltages of the two rectifiers (D3, D4) is used to control a motor (Mo), which is used simultaneously with the High-frequency device (02) adjusts the reactance (C4).