DE1020691B - Frequency control in receivers for frequency shift keyed broadcasts - Google Patents

Description

GERMAN

There are frequency control circuits are known which have the effect that in a heterodyne receiver Intermediate frequency even with fluctuations in the oscillator frequency or the transmitter frequency on one specified setpoint is maintained. These frequency control circuits fail when receiving frequency shifted telegraphic transmissions the intermediate frequency appears shifted. For this Various special procedures for frequency control have become known in these cases.

In one of these methods, for example, the frequencies that have been keyed are replaced by additional auxiliary oscillators and modulators converted to a certain fixed frequency. From this fixed frequency the control voltage for the frequency adjustment is then derived. The frequency spacing of the additional oscillators depends on the spacing between the frequencies being scanned.

In another known method, the broadcast is placed on a frequency discriminator, wherein an upper and lower threshold value of the voltage is set on the discriminator characteristic. If one of the corner frequencies of the broadcast exceeds these threshold values, the frequency is through an electronic flip-flop circuit via an adjustable capacitor again so that the both corner frequencies of the frequency-shifted broadcast within the set threshold values stay.

In a further known method the frequency shift keying is carried out with a discriminator demodulated, with the largest positive and the smallest negative voltage level on the discriminator characteristic is taken from a peak voltage rectification, in which case the difference of these two voltages is used for frequency adjustment. In the times when there is no telegraph message is transmitted, d. H. if the one frequency position is taken continuously, that would Sequence control circuit can be stressed on one side if there is no counter voltage via a relay circuit would be added artificially, the control circuit in the state of equilibrium in the key pauses and that depends on the hub.

These known methods have the disadvantage that, depending on the hub used the frequency shift transmission, changes must be made to the control circuit. So must in the first method mentioned, the frequency spacing of the converter generators can be changed, In the second method mentioned, the response values of the flip-flop must be adapted to the stroke and in the third method, the DC voltage added in the key pauses is

Frequency control in receivers
for frequency-shifted broadcasts

Applicant:

Rohde & Schwarz,

Munich 9, Tassiloplatz 7

Dipl.-Ing. Klaus Grabe, Munich,
has been named as the inventor

set according to the stroke. Also, the procedures mentioned are either not at all or only with further additional devices for use with two-channel keyed so-called Twinplex or duoplex broadcasts, in which four frequency ranges can be used, can be used.

The above disadvantages are due to the frequency control in receivers for frequency shift keyed Programs in which the frequency to be regulated is controlled by a reactance stage controllable oscillator is converted into an intermediate frequency, using a discriminator according to the invention remedied in that the reactance stage has a control voltage with such a periodic course is supplied that the intermediate frequency in the first part of the period a predetermined frequency is driven and that when one of this limit is reached Threshold value a device responds, the course of the control voltage in the second part of the period changed so that the distance between the intermediate frequency and the limit value increases temporarily and that in repetition of the periodicity the intermediate frequency approaches the limit value again. One According to another inventive feature, the impressed control voltage can be varied in both Change directions at once.

In a particular embodiment of the invention, the frequency control can be characterized by that the predetermined frequency limit is optionally assigned to one or the other corner frequency of the signal is. It does not matter that this frequency is temporarily absent, and it continues to be regardless of whether the frequency is still one or

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occupies several other key positions. It is also irrelevant what the frequency status of the keyed Frequencies, i.e. the hub of the broadcast. In the presence of the frequency shift keying already mentioned of signals can, according to the invention, be the control voltage supplied to the reactance stage The rate of change of frequency caused is greater than the maximum time average of the Frequency drift to be regulated or to be selected at most so large that the during the temporary In the absence of the base frequency, the resulting deviation does not exceed a specified limit.

To carry out the frequency control described so far can serve in a further inventive embodiment, a circuit that is characterized is that a tube trigger circuit controlled by the output voltage of the discriminator when the threshold value is exceeded, the Control voltage via an integrator.

Further features of the invention are explained in the description with reference to the drawing. Thereby there Fig. 1 shows a block diagram of the already characterized control circuit again; in

Fig. 2 shows the tube flip-flop circuit schematically.

According to Fig. 1, the input frequency EF is superimposed in any mixer 1 with the oscillator frequency OF of the oscillator 2 to the intermediate frequency ZF. The intermediate frequency is amplified in the amplifier 3 and fed to the discriminator 4. The direct voltage U generated at this discriminator is fed to the multivibrator, a univibrator 5, which in turn controls the reactance stage 6 of the oscillator 2.

In Fig. 2 the univibrator and its coupling to the reactance stage is shown in detail. It is initially assumed that the input frequency is constant and is not keyed, and it is also assumed that the voltage on the capacitor C ₂ and thus the oscillator frequency is so high that the intermediate frequency at the discriminator generates a voltage which is above the threshold value. In the univibrator, the tube Rö 1 is conductive and the tube Rö2 is blocked. The capacitor C ₂ is discharged through the resistor R ₂ (R ₂ R ₃ ). During the discharge, the voltage at the reactance stage 6 and thus the frequency of the oscillator changes in such a way that the direct voltage U at the discriminator drives up to the threshold value. The rate at which U changes depends on the time constant R ₂ C ₂ .

If the threshold is reached, the univibrator tilts and Rö2 becomes conductive. At the anode of Rö2 , the voltage drops below the battery voltage Uß and also below the current voltage of C ₂ . The charging process of the C i is reversed, so the voltage change at the reactance stage is also reversed, the ZF moves in the opposite direction, and U increases. The flip-flop remains in this position (Rö2 conductive) until C ₁ has discharged via R ₁ , even if U is already above the threshold value again. The univibrator now tilts back and U is again a little above the threshold value. The size of the return stroke is determined on the one hand by the time constant R ₁ C ₁ , which holds the univibrator in its second position, and on the other hand by the time constant R ₂ C ₂ , which determines the speed of the transfer. After tilting back, the battery voltage U _B prevails again at the anode of the Rö2, the direction of charge of the C _{2 is} reversed again, and U is driven back to the threshold value. If the input frequency is frequency shifted, nothing changes in principle in the control process. At the discriminator, voltages U ₁ to U _{n occur} at a constant interval in time with the keying. This voltage group moves towards the threshold value at the speed determined by the time constant R ₂ C _2. This speed is now selected so that in the maximum possible time in which the base frequency and thus the lowest voltage U _{1 of} the pulse group is not sent, the group does not migrate beyond a permissible level. If the lowest voltage then appears and has fallen below the threshold value, the univibrator tilts and the voltage group is driven back, as was already explained for U at the frequency that was not sampled.

The process described ensures that the voltage U oscillates back and forth shortly above the threshold value in the case of non-scanned items and that, in the case of scanned items, the voltage U ₁ , which corresponds to the one corner frequency, oscillates around this threshold value, the oscillation stroke depending on the maximum Time interval between this corner frequency, from the time constant R ₂ C ₂ , i.e. the control speed, Uiid from the time constant R ₁ C ₁ , i.e. the time that the univibrator remains in its second position (Rö2 conducting).

Claims (5)

Patent claims: 1. Frequency control in receivers for frequency-shift keyed broadcasts in which the to regulating frequency with the help of an oscillator controllable by a reactance stage into a Intermediate frequency is converted using a discriminator, characterized in that the reactance stage is supplied with a control voltage with such a periodic course is that the intermediate frequency in the first part of the period to a predetermined frequency is driven and that when a threshold value corresponding to this limit is reached Device responds that changes the course of the control voltage in the second part of the period in such a way that that the distance between the intermediate frequency and the limit value increases temporarily and that in repetition of the periodicity, the intermediate frequency approaches the limit value again. 2. Frequency control according to claim 1, characterized in that the applied control voltage changes at the same speed in both directions. 3. Frequency control according to claim 1 or 2, characterized in that the predetermined frequency limit is optionally assigned to one or the other corner frequency of the signal. 4. Frequency control according to claim 3, characterized in that the by the reactance stage supplied control voltage caused frequency change rate greater than the maximum time average of the frequency drift to be regulated or is at most so large that the a deviation that occurs during the temporary absence of the base frequency does not exceed the specified limit. 5. Circuit for carrying out the regulation according to one of claims 1 to 4, characterized in that that a tube trigger circuit controlled by the output voltage of the discriminator when the threshold value is exceeded, the Control voltage via an integrator. Considered publications: German Patent No. 868,307; British Patent Nos. 599 611, 625 977, 661 082; U.S. Patent Nos. 2,434,294, 2,555,175, 2,594,263; French patent specification No. 1 076 200. 1 sheet of drawings