DE862317C - Circuit for frequency modulating a carrier oscillation - Google Patents

Description

In circuits for frequency modulating a carrier wave often occurs in addition to the desired one Modulation in the rhythm of the modulating oscillations due to secondary influences is an undesirable one Frequency modulation on. It affect z. B. Temperature changes the vote of the frequency-determining Oscillating circuit of the carrier wave oscillator, so that the frequency of the generated Carrier wave changes. Changes in supply voltages and changes in properties, namely the steepness, as a result of the aging of the oscillator tube, lead to undesirable frequency modulation come here. The invention aims to suppress this phenomenon as far as possible.

According to the invention this purpose is achieved by means of a circuit in which at least one of two Subcarrier oscillations generated by separate oscillators from the modulating ones Oscillations is modulated, the oscillators are formed in the same way, so that the generated Frequencies are the same and are influenced by secondary influences in the same way, whereupon one of the Subcarrier oscillations with an oscillation of the frequency of the desired carrier oscillation and the difference or sum frequency obtained in this way is mixed with the other hip beam oscillation, whereupon the frequency-modulated sum or difference frequency continues to be used.

The circuit according to the invention can also be of this type be arranged so that both subcarrier waves are modulated. In this case. should the modulating Vibrations modulate the subcarrier waves out of phase. An unwanted frequency modulation can also arise from changes in the facilities that are used for the purpose of .Modulation of the frequency of the oscillator provided are. Is z. B. as a modulator a reactance tube

ίο used, so cause changes in the supply voltages and contact potentials as well as aging of the discharge tube a change in reactance, ' which causes an undesired frequency modulation.

Are in a circuit according to the invention, in which both subcarrier oscillations from the modulating Vibrations are modulated; the two frequency modulators, which · the frequency modulation accomplish the subcarrier oscillations, formed in the same way, so that the mentioned, on the modulators acting side effects the same unwanted frequency modulation of the associated Cause oscillator; so it follows that in the frequency-modulated carrier wave obtained this unwanted frequency modulation is suppressed.

The invention is explained in more detail in the drawing.

In Fig. Ι two oscillators 1 and 2 are shown,

which each generate a subcarrier oscillation with the frequency f _m , the frequency of which is modulated by means of modulators 3 and 4. The one from a source 5

The modulating vibrations caused are counteracted by a transformer 6 against the modulators

f ^s = / 2 + fo - fi = fm + A Δ

are written, from which it follows that the oscillation obtained is a frequency-modulated carrier wave with the desired frequency f ₀ and. the instantaneous desired 'frequency deviation Δ fy + Δ f ₂ and an undesired frequency deviation n ₂ - W ₁ . If both oscillators are formed in the same way and so from secondary influences, such as temperature changes, etc., in the same way

4-5 are influenced in a way, n ₂ = M ₁ and the undesired frequency deviation is suppressed. In this case, there is a frequency-modulated carrier oscillation with the frequency f ₀ , which exclusively produces the desired frequency modulation Δ f _x

So + Δ f ₂ carries. ...

It is readily apparent that a corresponding result would be obtained if only one of the two subcarrier oscillations were modulated. The difference would only be that in the expression for f _s , Δ f _x or Δ f ₂ disappears, depending on which of the two subcarrier oscillations is being modulated.

In Figure 2 the oscillator modulator is part of the circuit according to the scheme given in Fig. 1 in more detail

elaborated,.

The oscillators consist of fed back discharge tubes ι and 2, their frequency-dependent oscillation circuits 12 and 13, which are fed to the same phase. The instantaneous frequency deviation caused as a result of this modulation is Δ f _x or Δ f ₂ , so that the oscillations occurring in the output circuit of oscillator 1 or 2 have the frequency f _m - Δ f _x or f _m + Δ f ₂ . As a result of the causes mentioned above, however, the frequency of the subcarrier oscillations generated by the oscillators runs, namely _{by an amount M 1} in the case of the oscillator _{1 and by an amount M 2 in the case of} the oscillator 2. In this case, the frequency f _{x is} the oscillations in the output circuit of the oscillator 1

and the frequency f _{& of} the oscillations in the output circuit of the oscillator 2

The oscillations in the output circuit of the oscillator are now mixed according to the invention in a mixer 8 with an oscillation of the frequency f _{0 of} the finally desired carrier oscillation, which is generated by an oscillator 7. This oscillator is z. B. controlled by a crystal so that the frequency f _{0 is} constant. In the output circuit of the mixer 8, oscillations occur with the sum and difference frequencies f ₀ -f- f _x and f _{0 -Jp 1} 2 supplied subcarrier oscillation mixed. The sum frequency f _a = f ₂ + f ₀ - f _x is finally filtered out by means of a filter 11 and used further. By substituting equations 1 and 2, f _s can be in the form

! + »2 + fo - fm + -Af ₁ -M ₁

Frequency matched, with reactance tubes 3 and 4 are connected. The supplied by source 5, modulating vibrations are fed to the reactance tubes in antiphase. The ones from Oscillator modulator 1, 3 and 2, 4 generated frequency-modulated Auxiliary carrier vibrations are transmitted to mixer stages 8 and 10 in FIG. 1 via lines 14, 15 fed. The two mixer stages 8 and 10, the filters 9 and 11 and the oscillator 7 are shown in FIG. 2 not shown, as the circuitry of these parts is known. A circuit according to the invention, in which both subcarrier oscillations are modulated out of phase by the modulating oscillations, has the property that an undesired frequency modulation by secondary causes in the Modulators themselves is suppressed.

If, for example, the supply voltages of the reactance tubes 3 and 4 change in the circuit according to FIG. 2, an undesired frequency modulation m _x or m _{2 of} the subcarrier oscillations f _m occurs. These unwanted frequency modulations cancel each other out in the same way as _{discussed above with respect to the unwanted frequency modulations M 1} and M ₂ in oscillators 1 and 2 when the modulators are formed in the same way so that M ₁ and M ₂ are equal to each other are, a major advantage of the circuit after the

The invention is that it is not so particularly important what the level of the frequencies of the two subcarrier oscillations is; It is only important that both frequencies always correspond to one another. Even if the two oscillators that generate the subcarrier oscillations are designed in the same way, there will always be a more or less small difference between the two frequencies. In order to minimize this difference as much as possible, a circuit for automatic frequency checking can be used, e.g. B. a circuit of the type shown in Fig. 3. In this circuit, the oscillations generated by the oscillators 1 and 2 in Fig. 1 or 2 are supplied to limiters 16 and 17, which are set so that those in the output circuits of the limiters occurring vibrations have the same amplitude. The output circuit of the limiter 16 is connected via a capacitor C ₁ to two two-pole tubes 18, 19 connected in opposite directions and the output circuit of the limiter 17 is connected via a capacitor C ₂ to two two-pole tubes 20 and 21 which are also connected in opposite directions. The two-pole tubes 18 and 19 each have a negative bias voltage E, which are supplied by the voltage sources 22 and 23. The connection point of these voltage sources is connected to the connection point of the two-pole tubes 19 and 21 _{via a capacitor C 3.} It is also assumed that capacitor Cg is substantially larger than capacitors C ₁ and C ₂ .

The operation of the circuit is as follows: During the first half of the positive half cycle of the output voltage of the limiter 16, the capacitor C ₁ charges through the two-pole tube 18. During the following half of the positive half cycle and the next following first half of the negative half cycle, C _{1 discharges} via the two-pole tube 19 and the capacitor C ₃ , as a result of which a certain charge is transferred to the latter. This is repeated during each subsequent period, so that the capacitor charges more and more, namely the charge transferred to the capacitor per unit of time is proportional to the frequency of the output voltage of the limiter 16, ie proportional to the frequency of the oscillator 1. Transferred in exactly the same way As a result of the output voltage of the limiter 17, an opposite charge occurs on this capacitor, since the output voltage of the limiter 17 charges the capacitor C ₂ via the two-pole tube 20, which then discharges via the two-pole tube 21 and the capacitor C _3. The charge transferred to the capacitor C ₃ per unit of time is proportional to the frequency of the oscillator 2. The charging current of the capacitor C ₃ via the two-pole tube 19 is now opposite to the charging current of the capacitor C ₃ via the two-pole tube 21, so that the capacitor C ₃ remains de-energized when the charge that has flowed in via the two-pole tube 19 per unit of time corresponds to the charge that has flowed out via the two-pole tube 21 per unit of time, which is the case when the frequencies of the oscillators 1 and 2 are the same. If they deviate from one another, _{a positive or negative voltage to earth arises across C 3} , depending on whether the frequency of oscillator 1 is lower or higher than the frequency of oscillator 2. This voltage is now fed via a line 24, for example to the modulator 4, which regulates the frequency of the oscillator 2 in such a way that the frequency difference between the isolators is reduced.

Claims (4)

Patent claims: 1. Circuit for frequency modulating a carrier wave, characterized in that at least one of two subcarrier oscillations generated by separate oscillators, is modulated by the modulating oscillations, the oscillators in the same way are designed so that the frequencies generated are the same and of secondary influences in the same Way are influenced, whereupon one of these subcarrier oscillations with an oscillation on the frequency of the desired carrier oscillation and the difference or Sum frequency is mixed with the other subcarrier oscillation and whereupon the frequency-modulated Sum or difference frequency continues to be used. 2. A circuit according to claim 1, wherein the two subcarrier oscillations from the modulating Vibrations are modulated, characterized in that the modulating vibrations are in phase opposition to the subcarrier vibrations modulate. 3. A circuit according to claim 2, characterized in that the two frequency modulators, which cause the frequency modulation of the subcarrier oscillations in the same way are trained. 4. A circuit according to claim 1, 2 or 3, characterized in that the circuit comprises a device for the automatic frequency check contains at least one of the two oscillators controls in such a way that there is a difference between the frequencies of the two oscillators is reduced. 1 sheet of drawings I 5615 12.52