DE1011003B - Multi-channel generator for high frequencies - Google Patents

Description

The invention relates to a multi-channel generator for generating oscillations of high and stable end frequency (for example, stability better than 10- ⁶ / ° C) in coarse, fine and Interpolationsschrittan of example 10 and 1 or 0.1 MHz adjustable and in which the final frequency is taken from a final frequency oscillator which is stabilized by means of automatic frequency correction (AFC) with reference to a crystal-controlled coarse step generator, a crystal-controlled fine step generator and an interpolation oscillator. Such multi-channel generators are particularly important for multi-channel telecommunication devices for very high frequencies (VHF) and ultra-high frequencies (UHF).

In a known device of this type, in the three-decade generators. Use that ever are provided with ten crystals (see Proc. I.E.E., Part III, March 1954, pp. 85 to 90), becomes the automatic Frequency correction of the final frequency oscillator required control voltage achieved in that the final frequency in three successive mixer stages with filters connected in between Mixing with the frequency from the series after the coarse step generator ^ the fine step generator and the Interpolation step oscillator is transposed down.

Although in such a so-called frequency analyzer as a result of the use of the usual low-pass filter for sieving the control voltage, disturbing secondary frequencies in the signal of the final frequency oscillator are significantly limited, yet a relatively large number of channels have strong interference whistling tones on. It also turns out that other side frequencies are insufficiently suppressed, so that a significant number of the selectable. Channel frequencies can practically not be used.

There are also frequency generators of the type mentioned are known in which the end frequency oscillator The final frequency taken from a frequency analysis or synthesis in. Successive Frequency decades is subjected and a separate AFC loop with an auxiliary oscillator for each decade is used, with the various. Auxiliary oscillators in a cascade arrangement the final frequency oscillator act. By using a special AFC loop every decade and as a result of the use of several band filters, each with a narrow, decadically graduated pass band however, the circuit complexity is relatively high.

The invention has an advantageous embodiment of a multi-channel generator of the type mentioned at the beginning Art on the subject; in which the disadvantages mentioned are avoided with a simple and clear construction will.

Multi-channel generator for high frequencies

Applicant:

NV Philips' Gloeilampenfabrieken,
Eindhoven (Netherlands)

Representative: Dr. P. Roßbach, patent attorney,
Hamburg 1, Mönckebergstr. 7th

Claimed priority:
Netherlands 14 December 1954

Marius Robert Mantz, Jaap Starreveld
and Henri Jacques Suermondt, Hilversum

(Netherlands),
have been named as inventors

Another object of the invention is that, on the one hand, few or even only one crystal is used, on the other hand but it is possible to make the interpolation oscillator continuously variable, without encountering difficulties as a result of practically disturbing secondary frequencies.

According to the invention, the multi-channel generator described at the outset contains an auxiliary oscillator for this purpose, which ^{forms part of an auxiliary AFC circuit for automatic frequency correction with respect to the coarse step generator 1} and the interpolation oscillator, which is connected to a first mixer stage coupled to the auxiliary oscillator and the coarse step generator Obtaining a low interpolation frequency compared to the auxiliary oscillator frequency and a second mixer stage which is coupled to the interpolation oscillator and via an interpolation frequency filter to the output of the first mixer stage, from which a control voltage is taken from the second mixer stage, which controls a frequency corrector coupled to the auxiliary oscillator via a low-pass filter ; while the final frequency signals are taken from a main oscillator, which forms part of a main AFC circuit for automatic frequency correction with respect to the auxiliary oscillator and the crystal-controlled fine-step generator, which is connected to a first mixer stage coupled to the main and auxiliary oscillator to obtain a low frequency compared to the main oscillator Intermediate frequency and is provided with a second mixer that is connected to the. crystal controlled fine

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Step generator and coupled to the output of the first mixer via an intermediate frequency filter is, the second mixing stage is a control voltage is taken, which is coupled to the main oscillator via a low-pass frequency corrector controls.

The invention is explained in more detail below with reference to the drawings.

Fig. 1 shows a block diagram of a multi-channel generator according to the invention for a range of 120 to 170 MHz with five coarse step crystals, ten fine step crystals and a continuously adjustable, Interpolation oscillator;

In the block diagram, FIG. 2 shows a particularly upstream oscillator which can meet the requirements placed on the interpolation oscillator with regard to stability be met in practice.

If the frequency fed to the mixer 10 via the interpolation frequency filter 9 and the frequency of the interpolation oscillator 11 are equal to one another are, as is known, there is a DC beat voltage at the output of the mixer 10, which as Control voltage for the automatic frequency correction of the auxiliary oscillator 3 can be used. In which The auxiliary AFC circuit shown is the DC voltage taken from the output of the mixer 10 via a regulating tube 12 and a low-pass filter 13 following this.

Partial variant for a range from 100 to 200MHz 15. supply circuit of the auxiliary oscillator 3 coupled and of

with ten coarse step crystals, one fine step crystal and a continuously adjustable interpolation oscillator ;

3 a and 3 b represent advantageous detail switching Regulating tube current controlled frequency corrector 14 supplied.

To suppress interfering secondary frequencies in the output signal of the auxiliary oscillator .3 when described

pictures of the auxiliary circle or the main AFC circle 20 plan AFC circle system with the elements 3, 4, 5, 9,

of the in Fig. 2 in. Block diagram shown multi-channel generator dar;

FIG. 4 shows a block diagram of a further embodiment of a multi-channel generator according to FIG Invention in which the coarse step frequencies, the fine step frequencies and certain interpolation frequencies are taken from a single crystal will.

The multi-channel generator according to FIG. 1 contains a 10, 12, 13 and 14, it is desirable to select the blocking frequency of the sieve filter 13 to be relatively low, for example to about IQ to 25 kHz. With such a choice of the blocking frequency of the filter 13 in the Regelas line, however, the desired automatic stabilization, the so-called "catching", of the frequency of the auxiliary oscillator 3 is only obtained if it is initially set so that the resulting interpolation frequency by no more than approximated

Main AFC circuit 1 and an auxiliary AFC circuit 2. 30 5 kHz from the set lüterp0lationsireqiuenz des

First, the auxiliary AFC circuit will be described.

The auxiliary AFC circuit 2 is with an auxiliary oscillator3 provided, which by means of a step mechanism, for example a switch, to five each Frequencies separated by 10 MHz can be tuned. The exact choice of these tuning frequencies is explained in more detail below.

The output signal of the auxiliary oscillator 3 is fed in the auxiliary AFC circuit via an isolating amplifier 4 to a mixer in order to transpoe the auxiliary oscillator frequency down to the interpolation frequency selected in the present case between 2 and 3 MHz. For this purpose, an input of the mixer 5 differs from the output of a coarse step oscillator 6 ge-InterpolationsQszJllatQrs 11. '' A setting accuracy of ± .5 kHz of the auxiliary oscillator monitor 3. Is in the. Difficult to achieve in practice, especially when there are significant changes in the ambient temperature, for example between -30 and +6O ⁰ C.

To reduce the adjustment requirements for the auxiliary oscillator 3 when using a sieve filter 13 .with relatively lower Blocking frequency - can, as shown in Fig. 1 is shown,

to the mixing stage ID to be bridged by a absfci'mjnbaren Frequenzdiskrdminator.15 .are ,, .dessen Al> stim medium as -is shown in phantom, mechanically -with the Abstimmittaln of InterpolationsosziUa-'tosrs 11 -gekoppelt. If now the initial ab

couples, the tuning of the auxiliary oscillator 3 at the output -des

Supplies frequencies, .that by means of a coarse step switch 7 can be selected, by means of which .one. Of the five provided Coarse step crystals 8 selected who can. For the sake of simplicity, the selectable frequencies are for the: coarse step generator; for the, crystals; as 104, 114 ... 144MHz specified, although in -der Practice mostly crystals for lower frequencies are used, for example overtone crystals for preferably 30 to 50 MHz, and by frequency interpolation frequency filters 9 brings about an interpolation frequency whose difference with that with Interpolation frequency set with the aid of the interpolation oscillator 11. To cause catching, the frequency discriminator supplies 15 is a DC control voltage that sets the frequency of the auxiliary oscillator 3 in the direction of the • Correct tuning forces up through automatic catching as a result of: the output voltage of the mixer

Multiplication of the desired coarse step generator 55 10 the frequency of the / auxiliary oscillator exactly the same as the frequency is achieved. Sum of the frequency of the coarse step generator 6 an4

The output signal of the mixing stage is via .ein Interpolation frequency filter 9 with a pass band of 2 to 3 MHz of a second mixer stage 10 fed to which an interpolation oscillator 11 -connected is. The Ittterpölationsoszillator 11 is continuous adjustable between 2 and 3 MHz. This oscillator should be compared with, for example, the ■ crystal controlled coarse step generator -stable enough to prevent that the shift of the output frequency of the auxiliary oscillator-3 predominantly due to the instability of the interpalation oscillator is determined. As a result of the considerable difference in size between the frequency of the Grobder Frequency of the interpolation oscillator 1Ί wir.d.

If desired, the tuning means -of the interpolation oscillator .11 -and the -with these; coupled tuning means of the frequency discriminator .15 not only 'coaitinttieirlich, but also by means of a pure ■ ratchet mechanism to, for example, 100 or 5.0 kHz apart fixed interpolation frequencies> be adjustable Interpolation oscillator 11 can be stabilized on any frequencies from five frequency bands of 1 MHz, which bands are -10 MHz! Apart. This Fpe-

step generator and those of the interpolation 70 frequency bands are: 106 to 107 MHz, 116 to 111 = M-Hz,

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126 to 127MHz, 136 to 137 MHz and. 146 - to 147 MHz. To the frequency corrector 14 frequency correction to be brought about by the local oscillator 3 to a minimum is the local oscillator, as shown in the figure, -5 by means of a ratchet mechanism (not shown), a switch or by means of a tuning motor to those in the middle of the 1 MHz bands mentioned lying frequencies 106.5, 116.5. . . 146.5 MHz adjustable.

In the case of the auxiliary AFC circuit, with a simple design, the filters provided result from the frequencies at the input and output of the mixer 5 which differ by an order of magnitude or more and the low mean frequency and the relatively small bandwidth of the interpolation frequency filter 9 (only approximately 10 ° / o of a coarse frequency step) no practically disturbing interference whistling tones, even if the signal supplied by the overtone crystal oscillator 6 has a frequency equal to, for example, one third of the desired frequency of 104, 114 ... or 144 MHz, for example 34 ² / s, 38 ... or 48 MHz, and some of the desired harmonics are created in the mixer. It is particularly important to choose the frequencies fed to the mixer 5 so that there are no disturbing interference whistling tones, because these whistling tones in an AFC circuit of the type in question with a second mixer 10 acting as a phase detector with the aid of the filters 9 and 13 provided cannot be suppressed. Therefore, they bring about an unwanted modulation of the local oscillator signal via ^one frequency corrector 14th During the "successive" mixing processes, undesired frequencies generated which exceed the cut-off frequency of the sieve filter 13 or fall outside the pass band of the interpolation filter 9 are attenuated. AFC circuit in order to be able to use simple and consequently cheap filter media.

Another difficulty with AFC circuits of the present type is the occurrence of so-called Incorrect synchronization, d. H. in the occurrence of stabilization of the local oscillator 3 on another. than on the intended frequency.

If, for example, to stabilize the local oscillator 3 on 107 MHz the coarse step generator on 104 MHz and the interpolation oscillator on 3 MHz are set, such an incorrect synchronization can arise as follows. It is assumed that the local oscillator 3 is due to inaccurate adjustment © delivers a frequency of 105.5 MHz. A frequency is then obtained at the output of the mixer 5 of 1.5 MHz, which if there is insufficient attenuation in the interpolation frequency filter 9 in the mixer 10 twice the frequency, d. H. 3 MHz. These 3 MHz voltage gives together with the 3 MHz voltage of the interpolation oscillator 11 a Auxiliary oscillator regulating voltage stabilizing at 101.5 MHz.

With the one described! "Auxiliary AFC Circle lies the Do not risk such an incorrect synchronization. First, even with a simple design of the interpolation frequency level 9, the frequency mentioned becomes of 1.5 MHz is suppressed enough (for example by - 10 db) to produce an effective To prevent control voltage.

Second, if the frequency discriminator is appropriately trained, it delivers 15 of these, if a frequency of 1.5 MHz is fed to it, a control DC voltage, the stabilization of the auxiliary oscillator 3 on the unwanted · frequency of 105.5 MHz. Third, the mentioned mis-synchronization be excluded by the fact that the initial setting of the local oscillator 3 to 106.5 MHz takes place with an accuracy of, for example, 0.3 MHz, which presents practically no difficulties.

Tests have shown that with a simple design of the interpolation frequency filter 9, its damping ¹ for a frequency of 1.5 MHz. was already enough to prevent the mentioned incorrect synchronization.

Another possibility for incorrect synchronization results from higher harmonics of the interpolation oscillator 11. For example, if this is set to 2 MHz, a Interpolation frequency of 4 MHz at the mixer 10 this together with that generated in the mixer generate a control voltage twice the interpolation frequency. As prevented in the previous case the bottleneck interpolation frequency filter 9 such an incorrect synchronization.

A third possibility of incorrect synchronization arises when the coarse step signal contains secondary frequencies which exceed the intended coarse step frequency of, for example, 104 MHz and differ from it by about twice a possible interpolation frequency (for example, 3 MHz). This can be the case if the 104 MHz signal is obtained by frequency multiplication from a signal of 6 ¹⁴ As MHz, because in this case a secondary frequency of HO ¹ * / «MHz is mixed with an auxiliary oscillator signal of 107 ¹⁴ as MHz instead of a difference frequency of 3 MHz, the 3 MHz of Interpolationsoszillators provides together with dam signal 11 is a control voltage, and so a stabilization of the auxiliary oscillator to 107 ¹⁴ / i5 MHz, as intended, brings to 107 MHz. With regard to incorrect synchronization of this type, it is advisable to give the frequency occurring in the coarse step generator a minimum value of at least 10 MHz, preferably even 30 MHz, which is possible when using overtone crystals.

In the foregoing, various possibilities have been suggested The development of incorrect synchronization, secondary frequencies in the local oscillator signal and under-reference whistling tones listed. It is important to note that the various Possible origins, -not dealt with exhaustively became. After the already mentioned possibilities of the creation of undesired frequencies is sufficient it is worth mentioning that it is advantageous, at an output frequency in the coarse step generator, which is less than approximately five times the highest interpolation frequency, for example

10 MHz is to choose the interpolation frequency band so that half or a third of this output frequency is not included in it, so 'in the present case, for example, 2 to 3 MHz or -3-V-a up to 4V2 MHz. You must continue with the choice of the Interpolation frequency band should be considered that an interpolation frequency of less than approximately 1.5 MHz leads to practically questionable stability requirements for the auxiliary oscillator and interpolation frequencies, for example 4.5 MHz and more, to the interpolation oscillator

11 to be set, increase requirements in terms of stability in an undesirable manner.

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forms as long as no stabilization has taken place. This search voltage occurs in the control line and causes a slow rate via the frequency corrector 28. Frequency modulation of, for example, ± 0.5 MHz 5 of the main oscillator 16 until the synchronization point, the 122.7 MHz is reached. As soon as this synchronization point is reached, the search voltage generator stops 26, 29 as a result of the stabilization of the main oscillator that occurs in the main AFC circuit 1 in this case

The block diagram of the main AFC circuit 1 will now be explained. This circle is exhaustive treated, auxiliary AFC circuit 2 similar. What with regard to the auxiliary AFC circle regarding the Occurrence of interference whistling tones, disturbing secondary frequencies and incorrect synchronization said applies accordingly to the main AFC group.

The main AFC circuit 1 of FIG. 1 contains one

Main oscillator 16, which oscillates between 120 and 170 MHz io gate frequency. The detailed adjustable is. The signal from the main oscillator forms the guide and the mode of operation of such the output signal of the multi-channel generator after search voltage generator 26, 29 is based on a Fig. 1 and can be taken from an output terminal 17 detailed embodiment yet to be explained will. discussed in more detail. At this point it should only be emphasized

The stabilization of the main oscillator 16 on the 15 that results in a search voltage, as long as no state is desired Frequency is as follows. The main bilization takes place, and that this search voltage full oscillator signal will come through an isolation amplifier 18 disappears as soon as the main oscillator is in common The input of a mixer 19 is supplied, which is caught and stabilized.

the output signal of the case of the main AFC circuit 1 described can also be used via a line 20

Auxiliary oscillator 3 is supplied. The intermediate frequency filter 21 is shown in FIG. 20 as being permanently tuned Intermediate frequencies resulting in mixer stage 19 are band filters with a pass band from 14 to in the illustrated embodiment, between 14 and 23 MHz, if only the choice of ge-23 MHz are selected and are clearly defined by the sifrequency filter via an intermediate, - desired intermediate frequency 21 taken from mixer 19. The gnal of the fine step generator 23 on the one hand and this Intermediate frequency filter is determined in ten steps, each of which is 25 pass bands. The latter 1 MHz to whole multiples of 1 MHz, namely to is the case, for example, when the crystals 24 14, 15. . 22 and 23 MHz tunable. The overtone crystals obtained are the ones you want immediately Intermediate frequency will supply a second mixer stage 22 frequency. If, however, the one at the Kristalle fed, at the input of which a fine step-specified frequencies by frequency multiplier generator 23 is connected. The fine step generation can be generated, for example by Verdreitor 23 is crystal controlled and with ten crystals. 24 times a lower crystal frequency, so · are provided; which is switched on by means of a switch 25 as desired in the signal of the fine step generator 23 except for the can be. Depending on the selected desired frequency, also undesired harmonica Crystal, the fine-step generator delivers a frequency frequencies of the output frequency available. That from 14, 15 ... 22 or 23 MHz. The fine step 35 intermediate frequency filter 21 is generator frequency in this case supplies together with a freely tunable, because when using a fixed quenzgleicheti, the intermediate frequency filter 21 un-tuned band filter the possibility of a mistake Intermediate frequency a control voltage, the synchronization of the main oscillator 16 and the Via a control tube 26 and a low-pass filter from the occurrence of undesired secondary frequencies in its formed screen filter 27 consists of a frequency corrector 28 40 output signal. As indicated in the figure is indicated by the dashed lines determining the frequency, the tuning means of the

Intermediate frequency filter 21 to be coupled to the selector switch 25.

It was described above how an auxiliary

uiti a given by the fine step generator 45 oscillator frequency of 106.7 MHz and a fine amount greater than the frequency of the over the line step frequency of 16 MHz of the main oscillator 16 20 of the first mixer 19 supplied signal of the stabilized at a frequency of 122.7 MHz will. Local oscillator 3 is. If, for example, if the frequency of the auxiliary oscillator setting of the coarse step generator 6 remains constant at 104 MHz gate 3, the fine step generator supplies a frequency of and the interpolation oscillator to 2.7 MHz of the 50 17 MHz, the main oscillator 16 with pas auxiliary oscillator 3 has a frequency of 106.7 MHz supplies, transmitter initial setting stabilized at 123.7 MHz, while the fine step generator 23 is set to 16 MHz. 122.7 MHz stabilized. Before this stabilization of the given frequency of the auxiliary oscillator 3 takes place to ten each via the main AFC circuit 1, the main oscillator 16 should be stabilized by 1 MHz different frequencies to approximately the desired frequency. The selection of the fine step of 1 MHz each can be set, for example with an accuracy of approximately 0.3 MHz by means of the fine step generator 23. If, however, the main selector switch 25. In the above, the frequency 122.7 deviates from the desired refinement of the auxiliary AFC circuit 2 by 0.3 MHz at the oscillator frequency, for example to ⁶ ° that by means of the coarse step generator 6 is set with the selection 122.4 MHz, there is no self-switch 7 of the desired coarse stabilization amounting to 10 MHz, if the filter 27 is selected a step and that the interpolation oscillation blocking frequency of 10 to 25 kHz, similar. lator 11 sweeps over a band of 1 MHz. With the same means as the filter 13 for auxiliary AFC circuit 2. In order to enable the main oscillator to automatically catch in 65 16 at any frequency between 120 and main AFC circuit 1 under these circumstances. 170 MHz in coarse steps of 10 MHz each, femoral tube 26 coupled to an auxiliary tube 29, which stepped together at 1 MHz each and, by setting the interpolation oscillator with the control tube 26, a search voltage oscillator, possibly in interpolation, to generate a very low-frequency search voltage step within a band of 1 MHz stanung of approximately 5 to 30 periods per second 70 can be bilized. In summary, the be

Circuit of the main oscillator 16 is coupled.

The main AFC circuit 1 is intended to stabilize the frequency of the main oscillator 16 at a value that

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wrote system with the main AFC circuit 1 and the auxiliary AFC circuit 2 a three-decade multi-channel generator, with selection of the first and third decade in auxiliary AFC circuit 2 and the second decade in the main AFC circle 1. By splitting the decade selection into two AFC circles in the described Way the important advantage is achieved that in both circle systems the input and output frequencies of the first mixing stages, in the present

Pass band from 2 to 3 MHz connected. The filter 37 taken from the mixer 33 is used Interpolation frequency of a second mixer 38 of the auxiliary AFC circuit 30 is supplied. The mixed S Stage 38 is similar to that in FIG. 1 and also to an interpolation oscillator 39, which can be set continuously or in steps from 2 to 3 MHz. If the frequency of the signals applied to the mixer 38 is the same, it supplies a regulating direct current,

the cases 5 and 19, by at least an order of magnitude io of a control tube 40 and a sieve filter 41 a are different from each other, and that otherwise with the frequency-determining circle of the auxiliary stepping Difficulties in the form of interference oscillator 32 coupled frequency corrector 42 such controls that the local oscillator frequency is exactly equal to the difference of the coarse step generator

whistling sounds, unwanted secondary frequencies and incorrect synchronization even with simple training

the filter 9, 13, 21, 15 34 supplied in the AFC circuits and the frequency of the inter-

27 should be avoided.

Another advantage of the multi-channel generator described is that, if necessary, in the output signal of the auxiliary oscillator 3 existing un-

polarity oscillator 39 is.

The sieve filter 41 for the control current again preferably has a blocking frequency of 10 to 25 kHz, so that generally after the selection desired secondary frequencies, those of the desired 20 of the coarse step generator frequency and after the one frequency by more than the blocking frequency of the control setting of the interpolation frequency if the voltage filter in the main AFC circuit 1 is not completely different, the more precise initial setting of the auxiliary oscillator 32 does not occur due to the control voltage filter 27 and, if applicable, automatic catching. In order to achieve catching also weakened by the intermediate frequency generator 21, the auxiliary AFC circuit is with a seek becoming. Tests have shown that the device is provided with a voltage generator which, as in FIG consists. If the local oscillator is going to be suppressed, namely down to a level not at the desired level. Frequency stabilized, so from -80 to -90 db compared to the desired, the search voltage generator 40, 43 supplies a search output signal. In contrast to known voltage. the one th adjustable via the frequency corrector 42 according to a three-decade method
Multi-channel generators, the multi-channel generator described has no unusable or only partially usable frequency channels in the VHF range
from 100 to 200 MHz.

Because in practice a suppression of secondary frequencies down to -60 db is usually sufficient, there are still to be explained possibilities to simplify the apparatus, tube savings and substantial

Fig. 1 without

frequencies or interference whistling tones and some frequency channel not or only partially becomes useful.

Frequency modulation of, for example, approximately ± 0.8 MHz of the auxiliary oscillator 32 causes until the Synchronism is achieved. As soon as this is the case, the search voltage generator stops oscillating, and there is a permanent stabilization of the local oscillator 32 on that of the coarse step generator 34 and the interpolation oscillatoc 39 determined frequency. As detailed with reference to FIG has been described is in the auxiliary AFC circuit 30

Crystal savings compared to 40 of the auxiliary oscillator 32 on any frequency practically interfering secondary from ten bands of 1 MHz each can be stabilized, each are separated by 10 MHz. The middle frequencies of these 1 MHz bands are at given to the auxiliary oscillator <r 32. As in Fig. 1, he

AFC circuit 31. This contains a main oscillator 44, which can be set between 100 and 200 MHz.

Fig. 2 shows in the block diagram a multichannel 45 thus follows in Fig. 2 the number of the first and third generator according to the invention for sweeping over the decade in the auxiliary AFC circuit.

entire VHF range from 100 to 200 MHz, where the second decade is selected in the main

the selection of the desired frequency again
a three-decade procedure is carried out and in which to
The fine-step generator does not save crystals, as does 50. The main oscillator signal is provided via a single crystal that can be tuned to the one in FIG. 1 with ten crystals, but with only one main oscillator. fed to a mixer 46, to which a line

The multi-channel generator according to FIG. 2 contains a device 47 and that supplied by the auxiliary oscillator 32 Auxiliary AFC circuit 30 and a main AFC circuit 31. Signal is applied. The difference frequency of the mixer der Contains auxiliary AFC circuit 30, as well as signals fed in 55 stage 46 lies in the band from 13 to Fig. 1, an auxiliary oscillator 32, which stepwise each to 22 MHz and must be a whole multiple of the IMHz

amount of fine increment. To screen out the desired difference frequency, hereinafter referred to as Designated intermediate frequency, the output is the 97 to 98 MHz. . . 167 to 168 MHz and 177 to 60 mixer stage 46 connected to an intermediate frequency filter 48 MHz. In the auxiliary AFC circuit 30, that is closed by the one that moves in steps of 1 MHz to 13 MHz,

14th . .21 and 22 MHz is tunable. The initial signal of the tunable intermediate frequency filter 48 is fed to a special mixer 49 which is connected to crystals 36 is connected. The coarse step generator 65 has a fine step generator 50 with a 1 MHzrator 34 delivers, depending on the selected overtone crystal, crystal 51 is connected. The fine step generator a frequency which is a whole multiple of 10 MHz 50 delivers a sinusoidal signal with a frequency and is 90, 100 ... 170 or 180 MHz. of 1 MHz. This signal is in mixer 49,

At the output of the mixer 33 there is a fixed output, the so-called one to be explained in more detail below Tuned interpolation frequency filter 37 with a 7 ° pulse mixer tube, in sharp anode current pulses

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the mean frequency of ten bands of 1 MHz each is tunable, which are separated from each other by 10 MHz. The 1 MHz bands are: 87 to 88 MHz,

Auxiliary oscillator 32 is supplied to a mixer 33, which is fed to a coarse step generator 34 with overtone to be selected by a switch 35

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converted, the higher harmonic frequencies, from 1 MHz to at least 22 MHz. In the pulse mixer tube 49, the 1 MHz pulses are transmitted the output signal of the tunable intermediate frequency filter 48 is amplitude-modulated, this mixture the pulses with the intermediate frequency signal provide a DC voltage component that can be used as a control voltage, as soon as the frequency of the intermediate frequency signal equals one in the frequency amplifier Needs to find application. In the output signal of the local oscillator 32 then occurs from Coarse step generator 34 on the frequency supplied as a secondary frequency, which depends on the frequency of the auxiliary 5 oscillator signal only deviates by 2 to 3 MHz and, for example, only 40 db weaker than the desired one Output signal is. However, this secondary frequency becomes practically complete in the main AFC circuit suppressed by the screen filter 53, while the

Spectrum of the 1 MHz pulses containing frequency i ₀ selectivity of the tunable intermediate frequency filter is component. This is the case when the 48 contributes to the weakening. In this way, the intermediate frequency signal has a frequency which is an integral multiple of the crystal saving shown in FIG. 1 MHz, for example 19 MHz Fig. 1, is permissible without practical difficulties. When first in the output represents mixer stage 46 with reference to FIG. 3 a and a voreine intermediate frequency is 3 b now yields of 19 MHz, the auxiliary AFC circuit 30 is obtained i ₅ part embodiment in the output of the pulse mixing tube 49 only a or the main AFC circuit 31 in FIG. 3a and 3b are detailed darschenf requenzfilter 48 tuned to 19 MHz. In the case of parts that correspond to FIG. 2 and which are tuned to a different intermediate frequency, framed as dashed lines and with the same 19 MHz, the 19 MHz output signal of the mixer ₂ o reference numbers is designated.

stage 46 in this way in the intermediate frequency filter. The auxiliary oscillator 32 contains a triode 57 with

weakens that in the output of the pulse mixer tube between the anode and. Control grid switched 49 does not result in a usable control voltage. In the tunable oscillator circuit 58, in steps of The manner described is therefore tunable by tuning each 10 MHz, for example with the aid of the intermediate frequency filter 48 to one of the ten 25 of a ratchet mechanism, not shown, possible tuning frequencies determines which one center tap of the coil of the oscillator circuit Intermediate frequency, a 58 suitable for stabilization is connected to 150 V via a series resistor 59 Control voltage supplies. As a result, the fine, - leading anode voltage line 60 is connected, step selection by coordinating the intermediate frequency The mixer 33 of the auxiliary AFC circuit 30

filters 48, instead of, as in the main AFC circuit 1 after 30, holds a pentode 61 used as a mixing tube. In Fig. 1, by choosing one of ten fine lines, the cathode lead of this pentode is a cas-step crystal 24. 'method resistor 62, which is created by a coupling

As in FIG. 1, the capacitor 63 and a resistor 64 in the main AFC circuit 31, which in FIG 35 is bridged. At the connection point of the coupling frequency corrector 54 of the main oscillator 44. With capacitor 63 and the resistor 64 is one of the regulating tubes 52 is coupled to an auxiliary tube 55, which
together with the control tube 52, a search voltage
to change the tuning frequency of the main oscillator 44 by approximately +0.5 MHz provides as long as 40
the main oscillator 44 is not stabilized.

The main oscillator 44 stabilizes as soon as its frequency is exactly that
Sum of the frequency of the main oscillator 32 and the
by tuning the intermediate frequency filter 48 to 45 circle 67, whose end facing away from the anode at a selected higher harmonic frequency of 1 MHz, an anode voltage line 68 carrying 250 V via

a decoupling network with a resistor 69 and a shunt capacitor 70 connected is.

The interpolation frequency taken from the mixing pentode 61 is set via a coupling capacitor 71 of the second mixer 38 of the auxiliary AFC circuit. The input circle of this second Mixing stage consists of an interpolation

penetrates, because otherwise an undesirable phase frequency 55 tuned, damped circuit 72, its modulation of the main oscillator signal at 1 MHz and one end connected to ground. About that higher harmonics would occur. Desired interpolation frequency band from 2 to 3 MHz half must be screened in the control line of the main AFC circuit, the circuits 67 and 72 to 2.7 31 must be sifted particularly carefully. For example, or be tuned to 2.3 MHz. Already with one If the filter 53 can be a π-element with a notch 60, such a simple interpolation frequency filter is used of approximately 0.5 MHz and one aimed at frequencies that are around 0.5 MHz or more from

Signal supplied by the triode oscillator 32, which is sent to a cathode resistor 65 of the oscillator triode 57 is removed.

The signal supplied by the coarse step generator 34 is transmitted to the control grid of the mixing pentode 61 a coupling capacitor 66 is supplied. In the anode circuit of the mixing pentode 61 is a Interpolation frequency more coordinated, dampened

is equivalent to. The output signal of the multi-channel generator shown in FIG. 2 can be sent to the Main oscillator 44 connected output terminal 56 can be taken.

In the case of the multi-channel generator according to FIG. 2, care should be taken to ensure that it is in the pulse mixer tube 49 resulting pulses, in particular their basic frequency, not in the frequency corrector 54

1 MHz tuned trap circuit included to cause these unwanted spurious frequencies in the The output of the main oscillator 44 is approximately 70 to 80 db weaker than the output 6g signal are.

Another advantage of the improved embodiment of the screen filter 53 is that it is in the auxiliary AFC circuit 30 between the local oscillator 32 and

deviate from the interpolation frequency band of 2 to 3 MHz, weakened by at least 12 to 15 db, which is sufficient in the present case.

With the circular coil of the circuit 72, a secondary winding 73 is coupled, the ends of which from Resistors 74, 75 bridged rectifiers 76, 77 are connected to an output capacitor 78. A center tap of the secondary winding 73 is

the mixer 33 coupled to it does not have an isolating 70 via a coupling capacitor 79 with the stable one

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Interpolation oscillator 39 connected, which is tunable between 2 and 3 MHz. The mixer 37 described is a push-pull mixer and, when the frequency of the interpolation frequency fed to the circuit 72 and the frequency of the interpolation oscillator 39 are the same, delivers a direct voltage at the output capacitor 78 , which is dependent on the phase ratio of the alternating voltages supplied. The mixer 37 is thus effective as a phase detector

The output voltage of this phase detector is fed via a line 80 to the control grid of a triode 81 which acts as a control tube 52. The anode current of this triode controls the frequency corrector 42 via the filter 41 , because the anode of the triode 81 is connected to the anode voltage line 68 via the filter 41 and the frequency correction 42 .

The filter 41 contains an i? C element with a series resistor 82 and a shunt capacitor 83, and a series-connected parallel circuit with a coil 84 and a capacitor 85. The output side of this filter is provided with a termination resistor 86 , which has a DC blocking capacitor 87 is on earth. The filter 41 is dimensioned so that the cut-off frequency is approximately 15 kHz and additional attenuation occurs for the interpolation frequency band of 2 to 3 MHz.

The output line 88 of the filter 41 is connected to the frequency correction 42 via a series resistor 89. This frequency corrector contains two capacitors 90, 91, which are connected on the one hand to one end of the oscillator circuit 58 and on the other hand are connected to one another via a bridge circuit. This bridge circuit is for decoupling the oscillator circuit of the control circuit and consists of two rectifiers 92, 93 and two at their anodes connected coils connected 94 to one another, 95. The junction of the coils 94, 95 is located on the anode voltage line 68, while the connection point of the Rectifier 92, 93 is connected to the anode of the regulating triode 81 via the series resistor 89, the line 88 and the filter 41 .

The anode triode of the control triode 81 forms the control current for the frequency corrector 42. A change in this control current causes a proportional change in the alternating current resistance of the rectifiers 92, 93 and consequently a change in de; The effective parallel capacitance of the oscillator circuit 58 consisting of the capacitors 90 and 91.

When the frequency of the oscillator 32 stabilizes at the control frequencies of the coarse step generator 34 and the interpolation oscillator 39 , the control DC voltage resulting in the output of the mixer 37 in the line 80 controls the effective capacitance of the frequency corrector 42 via the control triode 81.

As long as the oscillator 32 is not stabilized at the desired frequency, if its frequency deviates too much from the desired frequency to reach the synchronization point, a search voltage generator, which consists of the control triode 52 and an auxiliary tube 43, is automatically activated. This auxiliary tube consists of a triode 96 which, together with the triode 81, forms a double triode with a common cathode resistor 97 . The anode of the triode 81 is fed back to the control grid of the triode 96 via an IC network which determines the search voltage frequency. This .RC network consists of the series connection of a resistor 97, a capacitor 98 and a resistor 99 with a capacitor 100 connected in parallel.

In this way, the control triode 81, the auxiliary triode 96 and the .RC network 97 to 100 together form a Wien bridge generator that acts as a search voltage generator. The .RC network is preferably dimensioned such that the search voltage generator generates a frequency between, for example, 3 and 25 Hz.

The search voltage generator only oscillates when the HF oscillator 32 is not locked to the control frequencies of the coarse step generator 34 and the interpolation oscillator 39. In the locked state, the AFC circuit stabilizes the anode current of the control triode 81, which prevents the search voltage generator from oscillating. As long as there is no locking, the search voltage leads to a change in the tuning of the oscillator circuit 58 over a frequency range of, for example, ± 0.8 MHz on both sides of the random oscillator frequency until the synchronization point is reached, so that the auxiliary oscillator 32 is caught and its frequency is stabilized.

Fig. 3 b shows an advantageous one in the detailed diagram Embodiment of the main AFC circuit 31 of FIG. 2, in which, as already mentioned above, in Fig. 3b shown in more detail and the Fig. 2 corresponding parts framed with dashed lines and are denoted by the same reference numerals as in Fig. 2. ·

The main AFC circuit according to FIG. 3b contains a main oscillator 44 with a triode 101 and a tunable oscillator circuit 102 connected in its anode circuit. This triode oscillator is of the same type as the triode oscillator 32 in FIG. 3a.

The oscillator signal taken from a cathode resistor 103 of the triode 101 is fed via a coupling capacitor 104 to the control grid of a pentode 105 serving as an isolating amplifier 45. The anode line of the pentode 105 contains an anode circuit 106 which can be tuned together with the oscillator circuit 102 and which has a circular coil with a center tap; this tap is connected to a 150 V anode voltage line 108 via a decoupling network 107 .

The signal taken from the anode circuit 106 of the isolation amplifier 45 is fed via a line 109 to the first mixer stage 46 of this AFC circuit. The mixer stage 46 contains a mixer triode 110 with a cathode resistor 111. The signal supplied by the isolating amplifier 45 is fed via the line 109 to the triode control grid. Signals coming from the auxiliary AFC circuit (see FIG. 3 a) are fed to the cathode of the mixer triode via line 47 and a coupling capacitor 112. The anode of the mixer triode 110 is connected to a 250 V anode voltage line 115 via a tunable intermediate frequency circuit 113 and a decoupling network 114 . The tunable intermediate frequency circuit 113 forms part of the intermediate frequency filter, denoted by 48 in FIG. 2 and tunable in steps of 1 MHz between 13 and 22 MHz.

The intermediate frequency signal taken from the anode of the mixing triode 110 is fed via the line 116 to a tunable intermediate frequency amplifier 48 with a pentode 117. For this purpose, the anode of the pentode 117 is connected to the anode voltage via a second, tunable intermediate frequency circuit 118 and a decoupling network 119.

line 108 connected. The intermediate frequency circuits 113, 118 can be jointly tuned to the desired intermediate frequencies in order to carry out the fine step selection, as has been explained for the main AFC circuit 31 according to FIG.

The intermediate frequency signal thus obtained is fed via a line 120 to a special mixer 49 which is provided with a pulse mixer tube 121 .

The pulse mixing tube 121 contains a cathode system, shown only schematically in the figure, for generating a band-shaped electron beam and is provided with deflection plates 122 for deflecting the electron beam. Screen grids are arranged on both sides of the deflection plates 122 and are connected to the anode voltage line 115 via a decoupling network 123 . The pulse mixing tube 121 is further provided with a strip-shaped collecting anode 124 , which supplies voltage shifted by 90 ° in phase by the swiveled voltages, whereby an anode current pulse can only occur during one of the two zero crossings per period of the 1 MHz deflection voltage. The amplitude of these anode current pulses is, however, dependent on the intermediate frequency voltage supplied to the intensity control grid 127 via the line 120. In this way, the intermediate frequency voltage is mixed with the 1 MHz pulses generated in the pulse mixer 121. Contains the resultant to the collecting anode 124 output voltage of the pulse mixing tube when the intermediate frequency and a higher harmonic of the 1 MHz pulses are equal to each other, a DC voltage component which occurs at a part connected to the collecting anode 124 filter capacitor 134th The thus obtained ^r DC voltage across capacitor 134 is the control voltage used for frequency stabilization of the Plauptoszillators 44th For a more detailed explanation

Electron beam is hit, causing this 20 of pulse mixing tubes of the type described and for

Collecting anode sharp pulses occur in the rhythm of an applied deflection voltage.

The pulse mixer tube is further provided with an electrode 125 which normally suppresses the electron beam by means of a suitably dimensioned bias voltage and only releases it when a forward voltage is supplied to it via a line 126.

Finally, the pulse mixer tube is provided with an intensity control grid 127 connected to line 120 . ■

Before the mode of operation of the pulse mixer tube 121 is explained, the detailed design of the fine step generator 50 used will first be explained. This consists of a crystal oscillator of a known type with a pentode 128 and a frequency-determining 1 MHz crystal 51, which is placed between the screen grid and the control grid of the pentode

128 is switched.

The anode circuit of the pentode 128 , which supplies a sinusoidal voltage of 1 MHz, contains a band filter that is matched to the oscillator frequency and has a primary circuit 129 and an inductive circuit with the circuit

129 coupled secondary circuit 130. As is well known, in such a bandpass filter, the voltage on the primary circuit 129 is shifted by approximately 90 ° compared to the 45 'voltage on the secondary circuit 130. A center tap of the secondary circuit 130 is high-frequency grounded via a decoupling capacitor 131 and also connected to an anode voltage divider 132 . The ends of the secondary circuit 130 are connected by leads 133 to the baffles 122 of the pulse mixer tube 121 . The voltage resulting at the primary band filter circuit 142 , which is shifted in phase by approximately 90 ° with respect to the deflection voltage, is fed via a line 126 to the forward electrode 125 of the pulse mixer tube 121.

The operation of the pulse mixer tube 121 is as follows. When an electron beam occurs, the deflection plates cause the electron beam to periodically pivot as a result of the 1 MHz voltage fed to them in push-pull mode, so that it strikes the collecting anode 124 in the vicinity of a zero crossing of the deflection voltage. As a result, a sharp anode current pulse occurs twice per period of the 1 MHz deflection voltage. The forward electrode normally suppresses the electron beam, and this beam is only released when a positive forward voltage occurs. The mode of operation of the passage electrode 125 is referred to in German Patent 816271.

The control voltage so generated controlled via a line 135, the control tube 52 and the mesh filter 53 to the frequency corrector 54 44. of the main oscillator to the control tube 52 is coupled to an auxiliary tube 55 which, together with the control tube 52 a search voltage generator which is effective only as long as the Main oscillator 44 is not stabilized. The control tube and the auxiliary tube are designed as triodes 136 and 137, respectively, with a common cathode resistor 138 .

The detailed design of the control tube 52, the auxiliary tube 55 , the sieve filter 53 and the frequency corrector 54 corresponds essentially to the corresponding and already explained parts of the control line circuit of FIG. 3a, so that only the differences from the embodiment described above are explained below.

The control voltage line 135 has the anode potential of the collecting anode 124, so that a considerable DC voltage must be present at the common cathode resistance of the triodes 136, 137 in order to achieve a suitable operating point for the triode 136 . For this purpose, a positive bias voltage is applied to the control grid of the triode 137 , which is taken from a voltage divider 139 connected between the anode line 115 and earth.

The screen filter 53 is provided with an additional filter element with resistors 140 and capacitors 141, 142 to prevent instabilities in the AFC circuit.

In the embodiment according to Fig. 3b, the frequencies of 1 MHz and higher harmonics of this frequency contained in these are suppressed by suitable dimensioning of the time constant of the filter network with the output capacitor 134 and the anode resistance of the pulse mixer 121 to achieve a special screening of the control voltage and the control current . This time constant is selected, for example, in such a way that the blocking frequency is approximately 100 kHz. In addition, the ini screen filter 53 series-connected parallel circuit 143 is tuned to a frequency of 1 MHz. The output signal of the main AFC circuit shown in FIG. 3 b is taken from the oscillator circuit 102 of the main oscillator 44 via a coupling coil 144 and a cable 56 .

In Fig. 3 a and 3 b in the detailed circuit diagram

a PIiIf s or main AFC circuit positioned opposite the deflection 7 ° can be accessed via line 126 without

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Danger of disturbing secondary frequencies and interference whistling tones so-called double tubes are used, in particular triode-pentode tubes, as shown in the figures, which is particularly useful in practice can be important.

Fig. 4 shows a further embodiment of a multi-channel generator according to the invention, in which the Coarse step generator, the fine step generator and the interpolation oscillator all from a single one Crystal can be controlled.

This multi-channel generator again contains an auxiliary AFC circuit 145 and a main AFC circuit 146.

The auxiliary AFC circuit is with a local oscillator as long as the local oscillator 147 is not stabilized.

If the local oscillator is set to any of the -1 MHz bands, for example 167.5 MHz, and the interpolation frequency amplifier is tuned to any of the interpolation frequencies, for example 2.1 MHz, the local oscillator is stabilized at 167.9 MHz, because after the selection of the setting of the auxiliary oscillator and the choice of the tuning frequency of the amplifier 154 , the search voltage generator initially causes a frequency modulation of the auxiliary oscillator with a rejection of, for example, ± 0.8 MHz until the synchronization point 167.9 MHz is reached. At this moment

147 and a frequency correlator connected to this 15 supplies the mixing of the local oscillator signal with the

rector 148 provided. Similar to the above-described embodiments of the multi-channel generator, the auxiliary oscillator can be tuned to ten bands of 1 MHz each, for example by means of a pawl mechanism, which are spaced apart by 10 MHz. The middle frequencies of these bands are given for the local oscillator.

The local oscillator signal is in the auxiliary AFC circuit 145 of a mixer .149 with a pulse mixer tube

of the 25 control DC voltage described in detail with reference to FIG. 3 b.

In the spectrum of the 10 MHz coarse step pulses, the 170 MHz component has a difference frequency of 2.1 MHz, which is passed on to the pulse mixer 155 ao by the amplifier 154 that is tuned to the pulse. In this pulse mixer tube, mixing this interpolation frequency with the 21st harmonic of the 0.1 MHz interpolation pulses required to stabilize the local oscillator 147 at the intended frequency of 167.9 MHz

Type (121 in Fig. 3 b) supplied. The pulse mixer is fed with a 10 MHz control voltage, which determines the size of a coarse frequency step and is generated by a multiplier 151. In the auxiliary AFC circuit system 145 described , the first and third decade for the frequency setting are selected by tuning the auxiliary oscillator 147 or the Interpola

is supplied via a further multiplication frequency amplifier 154, while the coarse

stage 152 is connected to a 1 MHz crystal oscillator 153 .

When setting the local oscillator 147 to the mean frequency of any one of the step frequencies to be selected and the interpolation frequency, one and the same control crystal 153 can be taken. The block diagram of the main AFC circuit 146 corresponds to the block diagram of the main AFC circuit.

1 MHz bands, for example at 97.5 MHz, provides 35 ses 31 of FIG. 2, so that below only the elements and the differences are explained.

The main AFC circuit 146 contains in turn a main oscillator 161, one with this main

Polation frequency amplifier 154 is supplied. The 40 oscillator tunable isolation amplifier 162, one

the auxiliary oscillator frequency when mixed with the tenth harmonic of the 10 MHz pulses generated in the pulse mixer tube 149 has a difference frequency of 2.5 MHz, which gives a tunable inter-

first mixer 163, a tunable intermediate frequency amplifier 164, a second mixer 165 with a pulse mixer tube, a control tube 166 and an auxiliary tube 167 coupled to this, a sieve of one of ten interpolation steps within a 45 filter 168 and a frequency corrector 169, which

This interpolation frequency amplifier can be tuned in steps of 0.1 MHz between 2 and 3 MHz and is used, in a manner similar to that of the tunable intermediate frequency amplifier 48 in FIG. 2, for selection

1 MHz band.

The output signal of the interpolation frequency amplifier 154 controls a second mixer 155 of the auxiliary AFC circuit 145; this mixer 155 is also coupled to the latter with the frequency-determining circuit of the main oscillator 161.

The first mixer 163 of this AFC circuit is the output signal of the via a line 170

provided with a pulse mixer tube. In this mixer 50 auxiliary oscillator 147 is supplied. The pulse mixer tube produces pulses with a fundamental frequency 165 that determines the fine frequency steps

Voltage of 1 MHz is supplied via a line 171 , which is at an output of the 1 MHz crystal

of 0.1 MHz in that a sinusoidal voltage of 0.1 MHz is fed to it via line 156. This voltage is taken from an oscillator 157 which determines the interpolation steps and consists of an LC oscillator tuned to 0.1 MHz , which is synchronized with the crystal oscillator 153 in that a 1 MHz voltage supplied by this crystal oscillator is fed to the control grid of the oscillator tube will.

In the pulse mixer tube 155 , pulses with a fundamental frequency of 0.1 MHz are produced, which, when mixed with an interpolation frequency supplied by the tunable amplifier 154 , is connected in the output oscillator 153.

The main AFC circuit 146 provides frequencies that can be set between 70 and 170 MHz. The intermediate frequency amplifier 164 can therefore be tuned in steps of ie 1 MHz over a range from 17 to 8 MHz.

The output voltage of the main oscillator 161 can be taken from an output terminal 172. Its frequency can be set in three decades within the selected frequency band from 70 to 170 MHz, in coarse steps of 10 MHz each,

The output circuit of the pulse mixer tube supplies a control voltage 65 which, by setting the auxiliary oscillator 147, delivers as soon as the interpolation frequency is equal to one bar, in fine steps of 1 MHz each, which is due to the higher harmonics of the 0.1 MHz pulses. Setting the tuning frequency of the intermediate frequency

With the control tube 158 an auxiliary tube frequency amplifier 164 can be selected and coupled in interpolation 160 , which together with the control tube forms steps of 0.1 MHz each through the selection of a search voltage generator, the effective 7 ° tuning frequency of the interpolation frequency amplifier

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kers 154. Because all of the stabilizing frequencies are crystal controlled, the output frequency of master oscillator 161 also has crystal stability. Because all the stabilizing frequencies are taken from one and the same crystal and this is the only crystal in the system, special attention can be paid to the temperature stabilization of this crystal frequency, for example; so it is possible to make the stability of the earth frequency at the output terminal 172 better than 10 ^7/0 C.

It should be evident that within the scope of the invention, some modifications of the described Apparatus, some of which are described below.

In the execution forms described in detail, for example, is always for the sake of simplicity a frequency corrector provided with rectifiers has been described. Of course you can too one suitable for the intended frequency ranges Find reactance tube circuit application.

Furthermore, in most of the described AFC circuits, a special search voltage generator, which consists of a control tube and an auxiliary tube, is used to achieve trapping. Such a search switching arrangement can be replaced in each AFC circuit by a tunable frequency discriminator bridging the second mixer stage, as shown at 15 in FIG. 1. Such a tunable frequency discriminator can, as is known per se, for example, from German patent specification 807 826, be combined in a suitable manner with the associated mixer stage.

Not only can the interpolation frequencies be stabilized at a crystal frequency in the manner shown in Fig. 4 using a pulse mixer tube, but this can also be done in other ways. For example, an oscillator can be used which can be tuned over a frequency band of 2 to 3 MHz and is synchronized to the given interpolation frequencies by frequency division. For this purpose, the frequency of 5 MHz taken from the multiplier 152 of FIG. 4 can be modulated with a pulse-shaped voltage of 0.1 MHz to achieve a spectrum which extends from 4 to 6 MHz and contains spectrum components at intervals of 100 kHz. If such a spectrum voltage is fed to the control grid of the oscillator, which can be tuned between 2 and 3 MHz, it becomes automatic if it is initially approximately correctly tuned to frequencies of 2, 2.05, 2.10 ... 2.90, 2.95 and 3 MHz synchronized on the component of twice the frequency contained in the spectrum. This last modification can be advantageous in view of the requirements to be placed on the sieve filter in the control line of the auxiliary AFC circuit 145.

Claims (11)

Claims: 60 1. Multi-channel generator to generate vibrations with a high and stable end frequency, which can be set in coarse, fine and interpolation steps of, for example, 10 or 1 or 0.1 MHz is, especially for use in VHF and UHF multi-channel telecommunications equipment from which the end frequency is taken from a main oscillator, which is automatically corrected by frequency (AFC) with reference to a crystal controlled coarse step generator, a crystal controlled Fine-step generator and an interpolation oscillator is stabilized, characterized in that that an auxiliary oscillator (3) is provided for automatic frequency correction with reference to the coarse step generator (6) and the interpolation oscillator (11) a part of an auxiliary AFC circuit, which forms with one with the auxiliary oscillator and the coarse step generator coupled first mixer (5) to achieve a low compared to the auxiliary oscillator frequency Interpolation frequency and is provided with a second mixer stage (10) with the interpolation oscillator and, via an interpolation frequency filter (9), which is coupled to the output of the first mixer stage, the control voltage is taken, which is coupled to the auxiliary oscillator via a low-pass filter (13) Frequency corrector (17) controls, the final frequency signals being taken from a main oscillator (16) become, the automatic frequency correction with respect to the auxiliary oscillator and the crystal-controlled fine-step generator (23) forms part of a main AFC circuit, which with a first mixer stage (19) coupled to the main and auxiliary oscillator for generating a against the main oscillator frequency low intermediate frequency and a second mixer stage (22) is provided with the crystal-controlled fine-step generator and, via an intermediate frequency filter (21), is coupled to the output of the first mixer stage, the second Mixing stage, a control voltage is taken, which via a low-pass filter (27) with the Main oscillator-coupled frequency corrector (28) controls. 2. Multi-channel generator according to claim 1, characterized in that the interpolation oscillator can be tuned via a frequency band corresponding to a frequency fine step. 3 ·. Multi-channel generator according to Claim 2, characterized in that in the auxiliary AFC circuit the interpolation frequency filter between the first and second mixer from a fixed Band filter with an approximately one frequency fine step corresponding bandwidth. 4. Multi-channel generator according to claim 1, 2 or 3, characterized in that the auxiliary AFC circuit for the approximate adjustment of the auxiliary oscillator to the desired frequency between the interpolation frequency filter and the sieve filter are connected to a frequency discriminator that can be tuned to the desired interpolation frequency whose tuning means are preferably connected to the tuning means of the interpolation oscillator are coupled. 5. Multi-channel generator according to claim 1, 2, 3 or 4, characterized in that the auxiliary oscillator equal frequency steps in a coarse frequency step by means of a step mechanism to a mean frequency of a frequency band equal to a frequency fine step is tunable. 6. Multi-channel generator according to one of the preceding claims, characterized in that In the auxiliary AFC circuit, the coarse step generator from a crystal-controlled oscillator for generating a sinusoidal voltage with a coarse frequency step of the same frequency and the 1 Oil first mixing stage of the auxiliary AFC circuit consists of a cathode ray tube with means for generating an electron beam, an intensity control electrode connected to the auxiliary oscillator, deflection means connected to said coarse step generator for pivoting the electron beam and one periodically is provided output anode hit by the pivoting electron beam. 7. MehrkanalgeneratOT according to one of the preceding Claims, characterized in that the fine step generator in the main AFC circuit from a crystal controlled oscillator for generating a sinusoidal voltage with a Frequency fine step of the same frequency and the second mixer stage of the main AFC circuit a cathode ray tube with means for generating an electron beam, a with the output of the intermediate frequency filter coupled intensity control electrode, to the mentioned Fine-step generator connected deflection means for pivoting the electron beam and an output anode struck periodically by the pivoting electron beam is. 8. Multi-channel generator according to claim 7, characterized in that to choose the desired Intermediate frequency the intermediate frequency filter can be tuned in fine frequency steps. 9. Multi-channel generator according to claim 8, characterized in that the main AFC circuit a search voltage oscillator is coupled to the control line, which controls the tuning of the main oscillator changes until the latter is synchronized. 10. Multi-channel generator according to one of the preceding claims, characterized in that the coarse and fine step frequency can be taken from a single crystal oscillator. 11. Multi-channel generator according to claim 10, wherein in mutually equal frequency intervals lying interpolation step frequencies are used, characterized in that means are provided to take the interpolation step frequencies from the same crystal oscillator, from which the coarse and fine step frequency can be taken. Considered publications:
Funkschau 1953, pp. 284, 285. For this purpose 2 sheets of drawings © 709 550/291 6.57