DE1226651B - Frequency divider arrangement for obtaining carrier frequencies for carrier frequency systems - Google Patents

Description

Frequency divider arrangement for obtaining carrier frequencies for carrier frequency systems The invention relates to a frequency divider arrangement for obtaining carrier frequencies for carrier frequency systems, essentially consisting of a frequency divider unit, capable of delivering a pulsed current to the output circuit, and one associated recording device on the carrier frequency racks in which the frequency divider is retractable.

As is known, the transmission bands are different carrier frequency systems composed of uniform groups of channels with a specified number of channels and frequency position. The procedure is such that the frequency band of each channel has a carrier frequency is implemented, several such frequency bands are combined and again implemented with a common carrier frequency, etc., until finally gives a desired transfer band. The generation of the required for implementation Carrier frequencies are carried out in such a way that a basic frequency of 4 kHz can be reached Frequency multiplication and subsequent filtering out of the respective channel carrier frequencies 12, 16 and 20 kHz. By further multiplying that derived from 4 kHz The base frequency of 12 kHz is then obtained again for the conversion into the next one Level necessary group carriers with the frequencies of 84, 96, 108 and 120 kHz. In systems in which several channels are combined per transmission line are then still to be implemented in a next transmission level Carrier frequencies required. Because the absolute frequency accuracy of each Carrier frequencies is ± 2 Hz, the relative frequency accuracy increases with increasing frequency Frequency. However, the frequency accuracy of the individual carrier frequencies is from the frequency constancy of the basic crystal, with which the basic frequency, in particular Example therefore 4 kHz, is generated, depending. At very high carrier frequencies, such as she z. B. are required for the creation of a 2700 channel system, but is sufficient the accuracy with respect to the frequency constancy at frequencies in the kilohertz range no longer off. However, for the frequency range from 1 MHz, crystals can be used as Manufacture thickness-shear-transducers, which are characterized by a very high frequency constancy and characterized by temperature coefficients approximately equal to zero. Of this Based on knowledge, circuits have been developed in which one can derive of the required carrier frequencies from a base frequency of 4.4 MHz, which with a Quartz oscillator is generated, goes out, and by frequency division the corresponding, receives carrier frequencies below 4.4 MHz. As in the individual carrier frequency systems sometimes different carrier frequencies are required, therefore results for each System has its own frequency divider that can only be used for the system in question. A large number of frequency dividers are therefore necessary for different systems.

There are carrier frequency systems and assemblies for such systems known, which is easy to switch both for use in four-wire operation as well as for use in two-wire operation.

The invention is now based on the particular object of a frequency divider arrangement to create that can be used for different carrier frequency systems.

To solve this problem, according to the invention, the divider arrangement designed so that the frequency 1368 kHz is fed to the input of the frequency divider is and the frequency divider is designed with several outputs at which directly or the frequencies by means of downstream filters and / or frequency multipliers 114, 228, 342, 456 or 684 kHz can be taken, which at the same time have different carrier frequencies Carrier frequency systems are that the downstream filters and / or distortions, those for the extraction of the respective carrier frequency system belonging to the outputs the frequency divider removable carrier frequencies are used in the recording device are combined and in the receiving device means for short-circuiting the for the respective carrier frequency System not required outputs of the frequency divider are provided.

Furthermore, the divider arrangement can also be designed so that in Output circuit of the frequency divider several broadband transmitters as output transmitters are connected in series through which the pulsed output current flows.

Through these measures it is achieved that the frequency divider of the teher arrangement according to the invention can also be used for different carrier frequency systems. By simply inserting the frequency divider into the respective, for a carrier frequency system appropriately equipped recording devices are used for this carrier frequency system required carrier frequencies to the corresponding outputs of the frequency divider taken. By the means provided in the receiving devices, in each case unneeded outputs of the frequency divider short-circuited, so that their share at the total output power for the other outputs of the frequency divider stands. The frequency 114 kHz of the fundamental wave of the pulsed output current of the Frequency divider is advantageously chosen so that this from the harmonics pulsed output current carrier frequencies of different carrier frequency systems can be won.

Furthermore, the plate arrangement can also be designed in such a way that the frequency divider is a single-stage backmixing divider and at the output of this backmixing divider contained frequency multiplier transmitter are connected in series and to the The carrier frequencies 114, 228, 342 and 456 kHz can be taken from the transmitter outputs. It is useful here that the divider stage of the backmixing divider is used at the same time to multiply the frequency serves and at the outputs of the output transformer the frequencies 114, 228, 342 and 456 kHz can be extracted. This divider arrangement can then advantageously be used if the frequency divider is designed as a backmix divider, since that is in a frequency divider always present frequency multiplier, which is responsible for the generation of the synchronization necessary harmonic is used, at the same time carrier frequencies in the form of further harmonics are removable.

In a further embodiment of the invention, the frequency divider can be designed as a two-stage backmix divider and the division ratio of the first divider stage is 3: 1 and the division ratio of the second divider stage is 4: 1; in addition, several output transformers, each tuned to a carrier frequency, can be connected in series in the output circuits of both divider stages This output transformer can be tuned in such a way that the frequency 456 kHz can be taken from the first divider stage and the frequencies 114 and 228 kHz can be taken from the second divider stage.

Furthermore, the divider arrangement can also be designed so that the frequency divider is designed as a two-stage backmix divider and the division ratio the first divider stage 4: 1 and the division ratio of the second divider stage 3: 1 is that in the output circuits of both divider stages to one carrier frequency each Matched output transformers are connected in series and the output transformers are tuned in such a way that the frequencies 684 and 342 kHz and the frequency 114 kHz can be taken from the second divider stage. The breakdown the division ratio of 12: 1 in two stages has the advantage that the take-away area of the backmix divider is very large, so that such a circuit arrangement according to the invention can be used advantageously wherever there is a very large take-up area is required. Due to the formation of the secondary windings connected in series Transformer to resonant circuits results in the further advantage that one because of this Prescreening for those installed downstream of the backmix divider in the receiving device Filters get by with a lower edge steepness, so that the structure of the filter simplified and manufacturing costs can be reduced. With lower requirements With regard to the accuracy of the frequency of the carrier, the filters can even be entirely omitted. It is also advantageous that by interchanging the division ratios Different carrier frequencies can be taken from each of the two stages.

The invention is illustrated with reference to the FIGS. 1 to 4 shown schematically Embodiments described and explained in more detail.

F i g. 1 shows a divider arrangement which can be used universally for several systems; F i g. 2 shows a divider arrangement in which the frequency divider is a single-stage The backmix divider is designed with the division ratio 12: 1 and the one to be divided Frequency 1368 kHz and the fundamental wave of the pulsed output current 114 kHz amounts to. The removable carrier frequencies 228, 342 and 456 kHz are harmonics the pulsed output current; F i g. 3 shows a divider arrangement in which the frequency divider is designed as a two-stage backmix divider and the division ratio the first divider stage 3: 1 and the division ratio of the second divider stage 4: 1 is. The input frequency to be divided is also 1368 kHz and the frequency divider the frequencies 114, 228 and 456 kHz can be taken; F i g. 4 shows a divider arrangement, in which the frequency divider is also designed in two stages, but the division ratio the first divider stage 4: 1 and the division ratio of the second divider stage 3: 1 amounts to. With an input frequency of 1368 kHz, these dividers are the carrier frequencies 114, 342 and 684 kHz can be removed.

In the exemplary embodiment of the circuit arrangement according to FIG. 1 is within the dashed line a section of the output stage of a transistorized Frequency divider shown. The circuit parts - outside the dashed line belong to the receiving device and are permanently built into it.

In the collector circuit of the transistor T 1, the broadband transmitters_Ü1 ... Ü3 are connected in series. The pulse-shaped output current I flows through the primary windings p 1 ... p 3 of these transformers. The input of the filter F 1 is connected to the secondary winding s 1 of the transformer U 1. The amplifier V 1 is connected downstream of the filter F 1. The input of the filter F2 is connected to the secondary winding s 2 of the transformer Ü 2. The amplifier V2 is connected downstream of the filter F2. The secondary winding s 3 of the transformer Ü3 is short-circuited with the shorting clip KB. The filters F1, F2 are used to filter out the desired carrier frequencies at the outputs I and II of the frequency divider and amplify them by the amplifiers V 1 and V 2, respectively. In this case, the output of the transformer U3 is short-circuited because another frequency is not required.

If the frequency divider of the teher arrangement is a backmixing divider, the circuit arrangement according to FIG. 2 can also advantageously be used. The part of the circuit arrangement shown within the dash-dotted line belongs to the backmixing divider and the assemblies outside this line are permanently installed in the receiving device. The main parts of the output circuit of the frequency multiplier contained in this backmixing divider are shown within the dashed line. In the collector circuit of the transistor T2, the transformers ü4 ... U7 are connected in series. The pulsed current flows through the primary windings of these transformers to the negative pole of the supply voltage source. The capacitor C1 is parallel to the output of the secondary winding s 7 of the transformer U 7. Via the secondary winding s7 of the transformer U7, a voltage with the Frequenq (n -1) f is fed back to the input of the modulator M of the backmix divider and mixed with the frequency nf = 1368 kHz to be divided, which is also fed to the input of this modulator, so that on Output A of the backmix divider, the frequency of 114 kHz can be taken. The transformers U4 ... U6 are each followed by the filters F4 ... F6 and these in turn are followed by the amplifiers V 4 ... V 6. The filters are tuned so that the frequency 228 kHz can be found at the output of amplifier V 4, the frequency 342 kHz at the output of amplifier V 5 and the frequency 456 kHz at the output of amplifier V6. The frequency of 114 kHz can be picked up directly at output A of the backmix divider. This circuit arrangement has the advantage that the harmonics that are always present by the frequency multiplier can be used at the same time to generate carrier frequencies.

While in the embodiments according to F i g.1 and 2 divider arrangements have been described, in which at the outputs of the transformers connected in series different carrier frequencies depending on the frequency of the downstream filter can be found in the circuit arrangements according to FIGS. 3 to 4 each shows an embodiment in which the individual transformers are connected in parallel corresponding capacitors are tuned to a desired frequency in each case, so that only one frequency is taken from the output of each transformer can. The frequency division is used in the circuit arrangements according to FIGS. 3 and 4 made in two stages.

In the circuit arrangement according to FIG. 3, the frequency division takes place in the first stage with the division ratio 3: 1 and in the second stage with the division ratio 4: 1, so that overall the division factor 12 is again obtained for the entire divider arrangement. The frequency to be divided of 1368 kHz is fed to the input of the first divider stage. The transformers VS and Ü9 are connected in series in the output circuit of the first divider stage. The frequency 456 kHz can be taken from the secondary winding s $ of the transformer Ü8. The secondary winding s 9 of the transformer U9 is connected between the base of the transistor T3 of the subsequent second divider stage and the positive pole of the supply voltage source B. The primary windings p10 and p11 of the transformers V 10 and U 11 are in series between the emitter of the transistor T 3 and the positive pole of the supply voltage source B. The secondary windings s 10 and s 11 of the transformer f110 and Ü 11 are also connected in series in the collector circuit of the transistor T 3. The secondary winding s 10 of the transformer 0 10 has the capacitor C 2 connected in parallel and is dimensioned in such a way that a resonant circuit is created that is tuned to 22 kHz. This frequency is decoupled via a tertiary winding t10 of the f: I carrier k10. The transformer 611 also consists of three windings p11, s11 and t11. The capacitor C 3 is connected in parallel to the secondary winding s 11. It is dimensioned in such a way that an oscillating circuit is created that is tuned to 1.1.4 kHz. The frequency of 114 kHz can then be taken from the tertiary winding t11.

In the circuit arrangement according to FIG. 4 are the division ratios of the two divider stages compared to the circuit arrangement according to FIG. 3 swapped, so that the first divider stage has the division ratio 4: 1 and the second divider stage has the division ratio 3: 1. The individual divider stages are analogous to the Divider stages in the circuit arrangement according to FIG. 3 built. The entrance of the The frequency 1368 kHz is fed to the first divider stage. At the exit of the first divider stage the frequencies 342 and 684 kHz can then be taken from and the second at the output In the divider stage, the frequency 114 kHz can be removed. The circuit arrangements according to the F i g. 3 and 4 have the advantage that the carrier frequencies of different carrier frequency systems can be taken directly at the output of the frequency divider, so that generally downstream Filter assemblies can be dispensed with. By simply reversing the order The division ratios make it possible to use different frequencies at the same time Carrier frequencies are to be generated.

The divider arrangement according to the invention is not limited to that in the invention specified frequencies are limited, but can also be advantageous for extraction use other frequencies.

Claims (6)

Claims: 1. Frequency divider arrangement for obtaining carrier frequencies for carrier frequency systems, essentially consisting of a frequency divider unit, capable of delivering a pulsed current to the output circuit, and one associated recording device on the carrier frequency racks in which the frequency divider is inserted, characterized in that the input of the frequency divider Frequency 1368 kHz is supplied and the frequency divider is designed with multiple outputs is to which directly or by means of downstream filters and / or frequency multipliers the frequencies 114, 228, 342, 456 or 684 kHz can be taken, which are also carrier frequencies different carrier frequency systems are that the downstream filter and / or Distortion devices, which belong to the extraction of the respective carrier frequency system, from the outputs of the frequency divider removable carrier frequencies are used in the Recording device are combined and in the receiving device means for Short-circuit the for the respective carrier frequency system not required outputs of the frequency divider are provided. 2. Frequency divider arrangement according to claim 1, characterized in that in the output circuit of the frequency divider several broadband transmitters are connected in series as output transmitters, the are traversed by the pulsed output current. 3. Frequency divider arrangement according to claim 1, characterized in that the frequency divider is a single-stage Backmixing divider is and at the output of the frequency multiplier contained in this backmixing divider Transformers are connected in series and the carrier frequencies at the transformer outputs 1.14, 228, 342 and 456 kHz can be taken. 4. Frequency divider arrangement according to the Claims 1 to 3, characterized in that the divider stage of the backmix divider at the same time serves to multiply the frequency and at the outputs of the output transformer the frequencies 114, 228, 342 and 456 kHz can be taken. 5. Frequency divider arrangement according to claim 1, characterized in that the frequency divider is designed as a two-stage backmix divider and the division ratio of the first divider stage is 3: 1 and the division ratio of the second divider stage is 4: 1, that in the output circuits of both divider stages several matched to one carrier frequency each Output transformers are connected in series and these output transformers are tuned in such a way that the frequency 456 kHz can be taken from the first divider stage and the frequencies 114 and 228 kHz can be taken from the second divider stage. 6. Frequency divider arrangement according to claim 1, characterized in that the frequency divider is a two-stage Backmixing divider is formed and the division ratio of the first divider stage 4: 1 and the division ratio of the second divider is 3: 1 that in the Output circuits of both divider stages, output transformers each tuned to a carrier frequency are connected in series and the output transformers are tuned such that from the first divider the frequencies 684 and 342 kHz, from the second divider the frequency 114 kHz can be taken. Publications considered: German Auslegeschriften Nos. 1028 620, 1041092, 1052 463; "TFT" magazine, Vol. 28, H. 8/1939, pp. 301 and 302.