DE716030C - Arrangement for retuning an oscillation circuit - Google Patents

Description

Arrangement for Nachstinunung an oscillation circuit There are already Overlay receiver with automatic sharpening by retuning the local oscillator by means of a tube lying parallel to the oscillation circuit known. The invention relates to an arrangement for readjusting an oscillating circuit by means of a wattless feedback tube lying parallel to the oscillation circuit. It is particularly applicable to overlay receivers, but it can also apply to others tunable oscillating circuit arrangements are used in which on electrical Ways a certain re-tuning of the oscillation circle is to be made possible.

For recipients with auto-sharpening, it has turned out to be Desirably highlighted the maximum possible detuning caused by the tube mentioned can be achieved, constant over the whole tuning range to keep. Compared to the amplitude differences of the different incident One becomes largely independent of the station that .man with a sufficiently large Excess of frequency control voltage works, which is also a proportionate weak transmitters the frequency control tube between amplification O and maximum amplification able to steer completely. It is more difficult to change the frequency deviation (i.e. the greatest possible detuning caused by the control tube) as a function to compensate for the frequency of the received transmitter. It has been established that in the case of voting by variable capacitors of the Frequency deviation changes over the tuning range with the third power of the frequency when the Control tube is connected as a capacitance, on the other hand only with the first power. the Frequency when the tube is connected as an inductance. One therefore uses inei #; t the latter circuit, in which the degree of wattless feedback and thus the phase-shifted anode current of the control tube decreases proportionally to the frequency. By additional circular arrangements, which cause the degree of wattless Feedback decreases even more with increasing frequency than it does with normal Circuit is the case, one can achieve that the increase in the frequency deviation at higher frequencies is approximately compensated. As a closer reflection shows, is the condition for the frequency deviation to remain exactly constant in the case of capacitive tuning that the through the anode-cathode path of the control tube The reactance shown is not proportional to the frequency (which would be a pure inductance), but proportionally your square the frequency changes. It is also known to achieve this goal in that the control voltage by means of frequency-dependent preloaded rectifiers via the Frequency range is limited to different degrees. With inductive coarse tuning are however, these known means cannot be used because of the frequency dependence of the frequency deviation then is not eliminated.

According to the present invention, in the case of: inductive coarse tuning of a resonant circuit has a constant frequency deviation over the tuning range Nachfestninung achieved by the fact that the wattless feedback at the control grid Tube effective alternating voltage or the amplification of this tube so frequency-dependent , is made that the reactance represented by this tube at any size the control voltage is frequency-dependent. This is achieved in particular by that a fraction of the anode alternating voltage which is approximately constant over the tuning range the control tube is fed back to the grid with a phase shift of approximately 90 ° will.

An embodiment of the invention is shown in Fig. I. The oscillating circuits of the high-frequency amplifier H, the mixer 111 and the oscillator D of the superposition receiver shown are equipped with fixed capacitances and controllable inductances (variometers). The coil L of the frequency-determining oscillating circuit (L, C) of the oscillator is mechanically coupled to the remaining coils of the remaining tuning circuits, as indicated by the dotted line. The change in induction can take place in a known manner by shifting iron cores. In terms of high frequency, the anode-cathode path of the frequency control tube F, which is used for automatic sharpening, and a voltage divider, which consists of the capacitance C "and the ohmic resistance R. The voltage divider is dimensioned so that at the resistor R, its lower end The high frequency connected to the cathode fier control tube produces a voltage which is approximately 90 = phase-shifted compared to the anode alternating voltage.

If there were no funds available which would normally be given to R Also influence the alternating voltage amplitude that arises and is fed to the grid, so would the grid alternating voltage amplitude with a constant anode alternating voltage amplitude be greater at the upper end of the abortion frequency range than at the lower end, namely the grid alternating voltage amplitude and thus the amplitude of the opposite .the anode alternating voltage proportional to the phase-shifted anode alternating current increase with frequency. The control tube would then act as a capacitance. The frequency deviation would also be proportional to the frequency in this case.

In order to obtain a constant frequency deviation, when using the invention, provided that the oscillator alternating voltage has approximately constant amplitude, the grid alternating voltage is limited to a fixed value, namely approximately to the value it has at the lowest tuning frequency. This limitation is brought about by the two rectifiers GI and G. (diode or dry rectifier), one of which is connected to the cathode and the other to the anode at the junction of the resistor TV and the coupling capacitor CK. These are biased so that one rectifier limits one half-wave and the other one limits the other half-wave. The bias voltages are tapped from the divided cathode resistor of the frequency control tube in such a way that the lower end of the voltage divider resistor R is connected to the center tap, the anode of the rectifier G1 to the grounded lower end and the cathode of the rectifier G. to the cathode-side upper end of the cathode resistor . In this case, the frequency control tube acts as a reactance, the magnitude of which is essentially independent of the frequency. The influence of such a resistor on the tuning of a circuit results from the consideration of the circuit diagram shown in fig. If X is a pure reactance without frequency dependence, i.e. if its impedance is represented in the symbolic way of calculating with jX, then the condition for the zero, deterioration of the conductivity, i.e. for the resonance, is: Assuming that the impedance of the organ X in the entire tuning range is large compared to the impedance of the coil and the capacitor, i.e. that: coL <X, the result for the change in natural frequency caused by the parallel connection of the reactance X is: Here, co,) is the natural frequency that is present in the absence of X This relationship applies approximately even if X is a reactive resistance with a frequency-dependent amount, provided that the condition co L << X is maintained in the entire area under consideration.

This change and thus the frequency deviation is therefore in the case of inductive tuning then and only: then constant if the reactance X connected in parallel is frequency-independent is.

The tube F is regulated by the frequency control voltage fed to the grid G via the bleeder resistor RG, which is taken in the usual way from the control voltage generator D, which in turn is connected to the output of the intermediate frequency amplifier Z. The low-frequency amplifier N and the loudspeaker L are also designed in a conventional manner.

Instead of the voltage divider Cr, R one can also use one, which would in itself cause the control tube to act as an inductance by z. B. Replaces CP with a high resistance and R with a capacitor. The amplitude of the alternating grid voltage then has its smallest at high frequencies Value and must be held at this value by the limiting device, so that a reactance of constant absolute value is created.

The limitation of the grid alternation voltage can also be used if necessary caused by the characteristic of the control grid G1 itself. In this case recommends it is, according to Fig. 3, the positive bias of the one following the grid G1 Screen grid S1 to make quite small, so that the dynamic range that after at the top through .the starting grid current and at the bottom through .the which becomes zero Anode current is characterized is sufficiently small. The scheme must be in this Case take place at an additional control grid G.

In the event that the oscillator voltage amplitude exceeds the tuning range changes, the general condition is, changes .. the regulating tube works as a frequency-independent reactance, so that an always constant fraction the anode alternating voltage can be fed back phase-shifted to the control grid got to. This can be done according to Fig. Q. z. B. be done in that with the adjustment knob K, which changes the self-induction L, a displaceable tap A on the voltage divider resistor R is mechanically coupled. The tap is via the blocking capacitor CK with the Control grid connected. Is the tap at the upper end of the tuning frequency range A shifted in the direction of the grounded lower end in a suitable manner, so lets A constant degree of feedback and thus a constant frequency deviation can be achieved.

If necessary, the resistance R can also be used as a temperature-dependent, in particular indirectly heated resistor be formed whose heating current in is changed in a corresponding manner by means of the setting knob K.

If you swap C "and R and, as already mentioned above, write like this It is recommended to design the capacitor as a variable capacitor and in the same direction can be changed with the variometers using the setting button K.

In order to increase the degree of feedback in a circuit according to Fig with respect to amplitude fluctuations between the anode and cathode of the regulating tube F To maintain lying alternating voltage, one can bias the limiting rectifier G1 and G. are automatic depending on the anode alternating voltage amplitude let change by rectifying these tensions for their part generated by the anode alternating voltage. This is z. B. according to Fig. 5 thereby achieves that the series connection between the anode and the lower end of the cathode resistor a resistor Ri, a rectifier Gi and a capacitor Cl, the one Bleeder resistor W1 is parallel, is switched on. The rectifier cathode G1 is connected to the upper assignment of capacitor G, which is negative charges. G, is thereby biased with a direct voltage, the magnitude of which is always a is a constant fraction of the anode AC voltage amplitude, and limits the amplitude the positive half-wave, the alternating grid voltage to this value. The prerequisite is that the voltage divider R1, Gi, 1T71 relatively low resistance compared to the to achieve the phase shift serving voltage divider CP, R is or that the resistance TV is sufficiently large. The rectifier is used in a corresponding manner G2 preloaded. The regulating tube, its amplification by changing the grid bias can be regulated, so acts in a wide amplitude and frequency range as reactance of constant amount.

If one does not provide any means, which the fraction of the fed back, phase-shifted voltage across the tuner the reactance represented by the tube can remain constant to achieve frequency changes in that according to the change in Oscillator frequency the gain of the tube is also changed. This can about happening through it. that with a tube connected as a capacitance at the same time with the vote, the tap of a DC voltage divider is shifted, the the voltage of an additional control grid s changed that at the top of the Tuning frequency range the gain is lower than at the lower end. One can but also rectify the oscillator alternating voltage via a frequency-dependent element and. use the generated DC voltage for gain control. Such The arrangement is shown in Fig.6. In this case there is an additional voltage divider parallel to the tube C '", R'. The alternating voltage occurring at R ', the amplitude of which corresponds approximately to the frequency increases, is rectified. The resulting negative DC voltage regulates the Reinforcement on the grille S.,. The control can also be carried out on the screen grid, whereby the control range for the control voltage is changed.

Of course, you can also switch the tube itself as an inductance and the gain or the dynamic range in the opposite sense as above as a function regulate the frequency, so that the gain or the dynamic range approximately increases in proportion to the frequency.

This frequency-dependent gain control can take place in any case on a second grid, for example on the screen grid. Furthermore can instead of such a frequency-dependent regulation of the gain, a frequency-dependent regulation Control of the limitation of the retuning control voltage step. So it would have to be the last mentioned case in which the tube is connected as an inductance, the effective retuning control voltage at the lower end of the tuning frequency range limited to a lower value (e.g. by means of a rectifier with a frequency-dependent Preload) than at the upper end.

Fig.; shows another circuit that can be used in a fairly simple way it is achieved that within a frequency range which, for. B. the radio wave range corresponds to from zoo to 6oo in, the frequency deviation fluctuates by a maximum of 2o ° Jo. In Series with the voltage divider capacitor Cn is a coil L, which is connected to the coil L 'of a second voltage divider R', L 'is coupled so that the transmitted voltage in phase with the voltage at Cn and greater than the phase opposite voltage is generated at L by the current of the voltage divider R, C ", L. The dimensioning must be done in such a way that the differential voltage at L is for the geometric Mean value of the frequency range is approximately equal to the in-phase voltage across Sn. CK1 and C are blocking capacitors.

Instead of the voltage divider causing the phase shift C ", R can of course also join a more intricate network.

Claims (1)

PATENT CLAIMS: i. Arrangement for retuning an oscillation circuit by means of a wattless feedback, parallel to the oscillation circuit, tube influenced by a control voltage, in particular superimposed receiver with automatic sharpening by re-tuning the local oscillator, characterized in that with inductive coarse tuning of the oscillating circuit the AC voltage that is effective at the control grid of the wattless feedback tube or the gain of this tube is made frequency-dependent in such a way that the through this tube represented reactance independent of frequency for any size of the control voltage is. a. Arrangement according to claim i, characterized in that one over the tuning range approximately constant fraction of the anode AC voltage of the control tube on the Grid is fed back with a phase shift of approximately 9o °. 3. Arrangement according to claim a, characterized. characterized in that at essentially over the tuning range approximately constant oscillator amplitude which is attached to the grating via a phase shifter AC voltage supplied by a limiting device over the tuning range is kept constant throughout. .4. Arrangement according to claim z, characterized in that .that to keep the feedback fraction of the anode alternating voltage constant one or more parts of the network causing the phase shift can be changed and are coupled to the regulator for the tuning inductance. 5. Arrangement according to Claim i, characterized in .that in a per se as an inductance or Capacitance switched tube additional means are provided, which increase the gain the tube up or down with increasing frequency.