DE1297157C2 - Method and arrangement for the central generation of carrier frequencies of a TF system - Google Patents

Description

The invention relates to an arrangement for generating carrier frequencies of a carrier frequency system using mixing, frequency multiplication and division where the primary and Secondary carrier frequencies are derived from a central basic generator and are in the Center of within the frequency band of a transmission area Carrier frequencies to be generated by mixing and frequency division of carrier frequency derived from the central basic generator with a pulse whose harmonics im Distance of the difference between two carrier frequencies of the respective transmission level successive, is implemented in such a way that in each case the sum and difference frequencies from the respective in the center-lying carrier frequency and the first and second harmonics of the pulse will.

In many newer carrier supplies for TF systems, the basic generator oscillates because of the there

frequency constancy requirement and vibration sensitivity in the frequency that can be better implemented " area <1 MHz.

The fundamental frequencies required for generating the channel group and secondary group carriers 4, 12 and 124 kHz are obtained by frequency division and in decentralized technology, at the subsequent carrier product in the Umsetzergeste'len is fed to the Umsetzergeste'len.

In central technology, where the carriers are taken directly from a central carrier supply frame try, if possible, to use the basic frequency with subsequent multiplication to avoid and forms the frequency divider chain so that as many desired carriers and Pilot frequencies appear as intermediates.

It is already known individual carrier and pilot frequencies derived from a central basic generator.

For example, an arrangement is described in German patent specification 1,156,451, at eggs with the help of a self-starting backmix divider the channel carrier frequencies 12, 16 and 20 kHz and the pilot frequency, of 60 kHz from one frequency of 228 kHz can be obtained.

On the other hand, circuits and methods are also known in which by modulation a single frequency with a pulse train groups of carrier frequencies can be generated. This However, the method of obtaining carrier frequencies is only known in systems with decentralized technology. For example, the German Auslegeschrift 1 196 247 discloses an arrangement for generating of a frequency grid. at the one modulator a carrier frequency and a modulation frequency are supplied, known. With this arrangement However, it is disadvantageous that in addition to the decentralized processing of the Carrier frequencies for each transmission level a separate auxiliary frequency must be generated, which in the The middle of the respective frequency spectrum lies, and that with the help of an impulse that is only odd-numbered Contains harmonics, then the individual required carrier frequencies are generated. The production however, additional auxiliary frequencies mean a corresponding additional expense.

Another idea where the one in the middle The carrier frequency lying in the transmission range as the starting frequency for the generation of the other Carrier frequencies required in this transmission range is taken from the magazine "Elektrisches Nachrichtenwesen", ITT, Vol. 40, No. 1, 1965, p. 37, known; in this arrangement, however, the modulator generating the carrier frequencies in addition to the carrier frequency in the middle of the secondary carrier band, two more Frequencies supplied that are specially screened out of a pulse with the help of two low-pass filters. Besides that this arrangement also belongs to the group of decentralized carrier supplies, with of the frequency of 12 kHz, i.e. a frequency that is lower than the carrier to be generated, is assumed.

The object of the present invention is to provide an arrangement for processing carriers, wherein while avoiding the disadvantages, the advantages of a central carrier preparation with the advantages the generation of the carrier frequencies are retained with the help of a frequency grid.

The arrangement for generating carrier frequencies of a TF system is according to the invention designed such that one derived from the central basic generator in a first oscillator Key frequency is fed to a first modulator, the second input of which is connected to a second oscillator and its output with a first frequency divider, which the difference frequency as to be divided Frequency is fed, is connected to that of the first

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Frequency divider has a divider stage with two sinusoidal output voltages divided in a ratio of 4: 1 or 2: 1 and a further divider stage with a pulse-shaped output voltage divided in a division ratio of 2: 1, that the output delivering the sinusoidal output voltage divided in a division ratio of 2: 1 Divider stage with a second modulator, which supplies the pulse-shaped output voltage of the further divider stage with a third modulator, which is coupled to a synchronization input and a second output of the first oscillator, and which divides the b'.nus-shaped output voltage in a division ratio of 4: 1 delivering output of a divider stage is connected to a second frequency divider, which contains a divider stage with the division ratio 4: 1 with a pulsed output voltage, and that this plate stage is connected to the input of the second modulator and to a synchronization input of the second oscillator.

One embodiment of the invention is that the key frequency taken from the first oscillator 228 kHz, taken from the second output of the first oscillator and the third modulator supplied frequency 516 kHz and the frequency of the second oscillator? 36 kHz, and that the first frequency divider when mixing the key frequency and the frequency of the second Oscillator resulting difference frequency of 192 kHz is fed.

These measures give the advantage of a considerable reduction in the cost of the Generation of the carrier and pilot frequencies compared to the known arrangements. Also be high multiplication factors for carrier generation avoided, so that only low requirements to be placed on the freedom from noise of the fundamental frequency in the circuit arrangement to need.

The input frequency of the central backmixing arrangement is a multiple of the secondary subcarrier base frequency 124 kHz, so that the controller this arrangement can be done by existing and proven basic generators. The circuit arrangement can use active RC filters and multivibrators except in the imported ones Technology with resonant circuits can also be carried out using coilless technology.

A further development of the invention provides that the second frequency divider is a further divider and Multiplier stage with sinusoidal output voltage 4: 5 and an additional divider stage with the Division ratio 4: 1 with sinusoidal output voltage contains that the divider and multiplier stage with the division ratio 4: 5 with a

third frequency divider supplied with the division ratio with double modulation Ol, in one of them

3: 1 is connected and that the input frequency branch is a selective element Fl for 228 kHz and in

of 48 kHz of the second frequency divider a fourth whose other branch a selective element Fl for

Frequency divider with a division ratio of 3: 1 to 144 kHz is provided. This oscillator vibrates

is led. S in the feedback path initially on the frequencies

This allows the channel for which the phase condition Σφ = O is met in a simple manner. Generate the carrier and the pilot frequency 6OkHz. ter the selective element Fl in the 228 kHz branch

The first oscillator may in this case is advantageously a frequency divider 19: be formed eingeschalderart 1 (228/12) kHz that he tet of two with one that aui a starting oscillator 01 36 kHz with Moersten filter connected modulators io dulationsstufe M3 (228 / 36) kHz exists. The difference consists, of which the second is fed back via a second filter reference frequency 192 kHz in two (4: 1) frequencies to the first. It is expedient to divide Γ1, Tl into 12 kHz. The pulse also that the input-side modulator of the shaped output current 12 kHz of the last frequency first oscillator contains both the sum frequency of divider stage Γ2 a frequency component 36 kHz, 516 kHz and the difference frequency of 228 kHz 15 which synchronizes the start oscillator 36 kHz. Furthermore, the mixed product of 372 kHz and 144 kHz ent is this pulse stream in a modulator M 4 are also nominated and that the difference frequency as the frequency obtained in the divider Ti is 96 kHz key frequency for the first modulator that mixes. Sum frequency 516 kHz appears as mixed products of the first order as input frequency for NEN at the output of this modulator in addition to the Freden third modulator. ao quenz 96 kHz the group carriers 72, 84, 108,120 kHz.

This gives an oscillator that is capable of generating the pulse-shaped output current 48 kHz of the first

the generation of the pre-group carrier and the primary frequency divider Γ1 contains a frequency component

group carrier required »key frequencies« 144 kHz, which controls the oscillator with double modulation

supplies. In addition, this oscillator has an oil synchronized. Furthermore, this pulse current becomes

large pull-in range and is self-starting from the modulator MS supplied by a mixture

guided. with the sum mixed product of Ml, 516 kHz,

The one for synchronizing the first generator is obtained from 372 - 144 kHz. is carried out. As ford variable frequency of 372 kHz may also consist of mixed products t rster order of the central generator G 1448 kHz appear at ofa frequency of response of the modulator M5 next to the frequency 516 kHz by dividing in a ratio of 4: 1 gewon- 30, the primary racks 420, 468, 564 and 612 kHz. will be. The 16 and 20 kHz channel carriers and the pilot

To generate the required pilot frequencies frequency 6OkHz are on the divider stages T1

from 84.08 and 4 '. 1.92 kHz can be generated for the purpose and Tl with simple frequency dividers. A

the derivation of these frequencies from the central further great advantage of this central backmixing

Generator proceed in such a way that an auxiliary frequency 35 is arranged that the group converter frequency

of 39.92kHz is generated in such a way that from the 114kHz via a frequency divider 2: 1 T5

central generator derived frequency of 228 kHz and the frequency comparison pilot frequency

248 kHz by division 5: 1, the frequency 49.6 kHz 300 kHz over a further frequency divider 2: 1

arises that this with the frequency 15OkHz, which corresponds to the sum mixed product 372 - 228 kHz in the modul

from a frequency of 600 kHz, which can be obtained in the analyzer M 2,

On the output side modulator of the oscillator by sum-off 372 kHz and 300 kHz, the two can then

This modulator is also used for generating the pilot frequencies 84.08 and 411.92 kHz

led frequency of 372 kHz and the frequency of be.

228 kHz is obtained, the frequency implemented The process for the central generation of traffic

199.6 kHz results, which a frequency divider 5: 1 45 gerfrequenzen is particularly suitable for the

is supplied with a bobbinless structure. The frequency dividers only have

On the basis of the block diagram according to the figure, small division ratios and can, for. b. as bi

the invention is explained in more detail. stable multi \ ibrators with integrated technology

From the central generator G to be performed with the frequency. To the oscillating circuits and oscillating

of 1488 kHz is frequency division with the help of 50 gates, no special requirements are

the frequency divider Tl, the frequency of 372 kHz, so that readily an active i? C-Fijter

generated. The frequency 372 kHz is used for the oscillator or a FLC version.

1 sheet of drawings

Claims (7)

Patent claims: 1. Arrangement for generating carrier frequencies in a carrier frequency system using mixing, frequency multiplication and division, in which the primary and secondary group carrier frequencies are derived from a central basic generator and the carrier frequencies to be generated in the middle of the frequency band of a transmission level lying, by mixing and frequency division derived from the central basic generator carrier frequency with a pulse whose harmonics follow one another in the distance of the difference between two carrier frequencies of the respective transmission level, is converted in this way. that in each case the sum and the DifTerenzfreqiienzen are formed from the respective carrier frequency lying in the middle and the first and second harmonics of the pulse, characterized in that a key frequency derived from the central basic generator (G) in a first oscillator (oil) is a key frequency first mouulator (M 3) is supplied. the second input of which is connected to a second oscillator (O 2) and the output of which is connected to a first frequency divider (Tl), to which the frequency difference Hs to be divided is fed, so that the first frequency divider (Tl) has a divider stage with two in a division ratio of 4: 1 or 2: 1 divided sinusoidal output voltages and a further divider stage with a pulse-shaped output voltage divided in a division ratio of 2: 1, that the output of the one divider stage with a second modulator (M 4 ). the output supplying the pulsed output voltage is the other. Divider stage with a third modulator (M5), which is coupled to a synchronization input and a second output of the first oscillator (01) and which supplies the output of one divider stage, which supplies the sinusoidal output voltage divided in a division ratio of 4: 1, to a second frequency divider (T 2) which contains a divider stage with the division ratio 4: 1 with a pulse-shaped output voltage, and that this divider stage is connected to the input of the second modulator (M 4) and to a synchronization input of the second oscillator (O2). 2. Arrangement according to claim 1, characterized in that the first oscillator (oil) key frequency taken 228 kHz, taken from the second output of the first oscillator and the frequency 516 kHz fed to the third modulator (M5) and the frequency of the second oscillator is 36 kHz, and that the first frequency divider (Γ1) when mixing the difference frequency resulting from the key frequency and the frequency of the second oscillator of 192 kHz is fed. 3. Arrangement according to claim 2, characterized in that the second ficquence divider (TZ) contains a further divider and multiplier stage with sinusoidal output voltage 4: 5 and an additional divider stage with the division ratio 4: 1 with sinusoidal output voltage, that the divider and multiplier stage is connected with the division ratio 4: 5 with a third frequency divider (T 3) with the division ratio 3: 1 and that the input frequency of 4S kHz of the second frequency divider (Tl) is fed to a fourth frequency divider (7 "4) with Cem division ratio 3: 1 is. 4. Arrangement according to one of claims 2 and 3, characterized in that the first oscillator (oil) consists of two modulators (Ml, M 2) connected to one another with a first filter Fl), of which the second via a second filter (F 2) is fed back at first. 5. Arrangement according to claim 4, characterized in that the input side. modulator (Ml) of the first oscillator (oil) both the Sum frequency of 516 kHz as well as the difference frequency of 228 kHz of the mixed product are taken from 372 kHz and 144 kHz and that the difference frequency is used as the key frequency for the first modulator (M3), the sum frequency 516 kHz as the input frequency for the third Modulator (M 5) is used. 6. Arrangement according to claim 5, characterized in that the frequency of 372 kHz from a frequency of the central basic generator of 148 kHz by division in the ratio 4: 1 is won. 7. Arrangement according to claim 6, characterized in that an auxiliary frequency of 39.92 kHz is generated in such a way that the frequency 49.6 kHz arises from the frequency of 248 kHz derived from the basic generator by division 5: 1, that this with the frequency 15OkHz, resulting from a frequency of 600! Hz, which is obtained in the modulator (M 2) on the output side of the oscillator (oil) by adding up the frequency of 372 kHz also fed to this modulator and the frequency of 228 kHz, converted to the frequency 199.6 kHz, which is a frequency divider (T6) 5: 1 is fed.