DE2242057A1 - 60 MHZ CARRIER FREQUENCY SYSTEM - Google Patents

Description

60 MHz carrier frequency system The invention relates to a carrier frequency system for the transmission of 10,800 voice channels using the synchronous method, i.e.

the outgoing and incoming transmission band have the same frequency position. The upper limit frequency of this carrier frequency system is about 60 MHz. It is primarily intended for use on two coaxial cables, but in principle not limited to such as the use of smaller carrier frequency systems Shows the number of channels in the same-position method on radio links.

Recommendation G.333 in White Paper III of the Committee 'Consultatif International Téléphonique et Télégraphique - hereinafter referred to as CCITT - is a Carrier frequency system has been recommended for the transmission of 10 800 voice channels, whose upper limit frequency is 60 B52Iz. The transfer belt of this recommended Systems is made up of twelve individual Quaternary groups, which are based on the frequency the basic quaternary group specified by the CCITT and used in systems that have already been implemented with the frequency range 8.516 ... 12.388 MHz brought into their respective frequency position will. A major disadvantage of this 60 IEIz carrier frequency system is that that there is no direct cooperation with the 12 MHz carrier frequency system for transmission of 2700 voice channels, as defined by the CCIq'T recommendation G.332 Plan A. and is referred to below as the transmission band V 2700 for short. It is much more required, the transmission band V 2700 formed from three quaternary groups in three To dismantle basic quaternary groups, these individually via three very complex quaternary group switching filters to lead and to implement in the 60-XEz transmission band.

In the advancing development of carrier frequency technology to date, broader transmission bands have not only been achieved by simply lining up one An increasing number of sub-bands are formed, such as the one in the CCITT recommendation G.333 describes 60-1IIIz carrier frequency system, but one preferably has the took the second, more advantageous way, by combining several smaller ones Sub-bands to form larger sub-bands and a few larger sub-bands to build a wider transmission band. This way are parallel to the larger ones As the transmission bands grew, larger and larger sub-bands emerged, which were used as Secondary, tertiary and quaternary groups are designated and their channel number in each case is an integral multiple of the next smaller subband. In consistent Continuing this development of carrier frequency technology, it is therefore obvious in the case of the 60 MHz transmission band, several of the twelve envisaged quaternary groups are assigned a quintary group and from a few quintaries the 60 MHz transmission band to build.

A collaboration between such a 60 MHz carrier frequency system and a transfer belt V 2700 would be conceivable in the form of the transfer belt V 2700 as a whole in such a way that it is within the frequency range of an even to be determined basic quintary group is without its internal structure with the of the basic quintary group. Then it would still be possible to implement this Transfer belt V 2700 with the quintary group converter device, which is used for the formation of the 60-tUIz transmission band is required to implement further with the line facility of the 60 MHz carrier frequency system, it again after the transmission to implement in the original frequency position of the transmission band V 2700 and to be transmitted on another 12 MHz * connection line. This would be transportation correspond to a locked message bundle, whereby one dispenses with this message bundle with the converter facilities of the 60 MHz carrier frequency system to disassemble and prepare.

However, the invention is not content with this relatively loose and in many cases inadequate cooperation.

Rather, the invention is based on the object of a quintary group established carrier frequency system with the simplest possible frequency and implementation scheme to create for the transmission of 10 800 voice channels in the frequency range up to 60 Iz, not just a tighter and more economical one cooperation with the well-known V 2700 transmission tape allowed without detour via basic quaternary groups, than they are the mere transport of an inaccessible, locked bundle of messages offers, but also, in spite of these stricter requirements, with filters can be realized that are simpler and more economical than the extremely expensive and complicated quaternary group gating filters for the known transmission band V 2700.

This object is achieved by what is specified in claim 1 Invention.

The invention is described in more detail below with reference to FIGS. 1-7 and explained.

They show: FIG. 1 an example of a frequency scheme for a 60 MHz carrier frequency system according to the invention.

2 shows the frequency scheme for the implementation of a transmission band V 2700 in the position of the basic quintary group and vice versa.

3 in a table examples for the generation of the carrier frequencies used from a basic frequency.

4 shows the remnants of the tape when a transmission tape V is switched through 2700 in the 60 MHz band.

Figure 5 is a simplified block diagram of an example of a Circuit arrangement for the construction of a 60 MHz transmission band from basic quaternary groups and a transfer belt V 2700.

6 shows a simplified block diagram of an exemplary embodiment a circuit arrangement for the dismantling of a 60 MHz transmission band.

7 shows a simplified block diagram of a circuit arrangement for carrier frequency generation.

According to Figure 1, the embodiment of the carrier frequency system according to the invention the frequency band 4.332 ... 59.524 Wz is used. For building the carrier frequency system will from those recommended by the CCITT and those already carried out Systems with a smaller number of channels used the basic quaternary group with the frequency position, 8.516 ... 12.388 MHz, hereinafter referred to as the basic quaternary group, assumed.

The carrier frequency system according to the invention is composed of four quintaries together. The quintary group 3 is at the same time the basic quintary group with the frequency range 32.876 ...

44.948 MHz. Three such basic quintary groups are formed by the quintary group bearers 49.280 MHz, 63.800 MHz or 92.400 MHz in the frequency range of quintaries group 1, 2 and 4 implemented.

Another basic quintary group retains its frequency position and becomes quintary group 3 with quintary groups 1, 2 and 4 to the 60 MHz transmission band summarized. Each of the four basic quintary groups is through direct implementation of three basic quaternary groups with the quaternary group carriers 32.560 MHz, 45.264 MHz or the frequencies 49.280 MFIz and through, also used as a quintary group carrier Summarizing these three Quaternary groups formed. The top quaternary group is frequency inverted compared to the other quaternary groups, it arises as the upper one Sideband when implementing a basic quaternary group with the carrier 32.560 MHz.

The frequency gaps between the quintary groups are contrary to in the usual practice of the carrier frequency technology much broader and in particular wider than the only 0.632 MHz wide frequency gap between the two sidebands, the direct implementation of a transmission band V 2700 in the frequency position of the basic quintary group.

The frequency gap between the quintary groups 2 and 3 is 1.952 4Hz wide and thus significantly narrower than the other two frequency gaps, the 2,448 MHz and 2.504 MHz wide. As shown below, these result consciously Frequency gaps of different widths provide optimal conditions for the quintary group switching filter. These optimal conditions make it possible, in conjunction with the aforementioned, contrary to the previous practice of wide frequency gaps, the requirements for the To keep quintary group switching filters lower than the one that has already been carried out Systems used quaternary group switching filters, so that Quintary group switching filters lighter and with less effort than this is realizable.

The narrow frequency gap of 1.952 z determines the implementation of the quintary group 2 in the frequency position of the basic quintary group the distance between the pass band and the lower cut-off range of the quintary group switching filter that is required is when a basic quintary group obtained from the dismantling of the 60-BEz transmission band switched through to another carrier frequency system and used to build larger bands is used.

Determine the other two frequency gaps 2.448 MHz and 2.504 Mflz in the implementation of the quintary groups 2 or 4 in the frequency range of the basic quintary group the distance of the upper blocking range from the pass range of the quintary group through-switching filter.

But now with a bandpass filter, its upper and lower stop range the same in the absolute frequency scale. the distance between the lower stop band and the pass band at a standardized frequency scale greater than the distance between the upper blocking range and the pass range. According to a The feature of the invention is the frequency spacing between the pass band and the lower stop band smaller than between the pass band and the upper restricted area, whereby the following advantages are achieved: 'On the one hand can, with a given width of the transmission band, the frequency gaps that the Determine the distance between the pass band and the upper stop band, made larger and on the other hand the normalized frequency spacings between the pass band and made equal or nearly equal to the lower or upper blocking range and thus the effort to realize the lower and upper filter flank evenly both flanks are distributed.

If the frequency norms given below are used, this results in For example, a normalized frequency spacing of Q = 1.400 for the lower stop band and for the upper blocking range 1 Q = 1.345. These values are many times over cheaper than the value Q = 1.063 at 12.532 MFIz for the already mentioned very complex quaternary group switching filters. When comparing small Q values - about between 1 and 2 - as in the present case, the numerical value after the decimal point is decisive, so that e.g. the value Q = 1.345 is about five times more favorable than the value Q = 1.063.

The frequency normalization can, for example, according to the formula known in filter technology be performed. To simplify the observation, f1 and f2 denote the lower and upper edge frequencies of the pass band and not the cut-off frequencies common with Zobel filters, which lie between the pass band and the lower or upper blocking band.

In principle, it would also be possible to increase the basic quintary group place, e.g. in the frequency range of the quintary group 4.

However, this would and would result in smaller D values more complex filters may be necessary. The choice of quintary group 3 as the basic quintary group rather represents an optimum, because on the one hand their frequency position is high enough, that the modulation byproducts 2T-hI are not in the formation of the basic quintary group disturb and on the other hand it is so low that the best possible Q values result.

2 shows the direct conversion of the transmission belt V 2700 with the frequency range 0.316 ... 12.388 MHz into the frequency range of the basic quintary group. The transmission belt V 2700 is made up of three quaternary groups according to CCITT, the top quaternary group corresponds to the basic quaternary group. The transfer belt V 2700 becomes 32.560 with the quaternary group carrier frequency already used according to FIG z implemented. Of the two sidebands that are created here, the upper one is called Usable sideband used, it has the same frequency position as that shown in Fig.1 Basic quintary group and is completely congruent with it. That has the advantage, that it is possible to use a conveyor belt delivered via a feeder system V 2700 directly into the frequency range of the basic To implement quintary group and to use this for the formation of a 60-BEz transmission band without any this transmission band is differentiated from another, consisting of four basic groups of five was built, which in turn were formed exclusively according to Figure 1. as well it is possible, e.g. from four feeder systems V 2700 without the one mentioned at the beginning complex detour via basic quaternary groups to form a 60 MIz transmission band, which in no way differs from a 60 MHz transmission band constructed according to FIG differs. One or more transmission belts V 2700 are thus according to the Invention incorporated into the 60 MHz transmission band in a simple and homogeneous manner and do not represent any foreign bodies. You can use the converter equipment to do this 60 MHz carrier frequency system will also be reduced.

The direct implementation of the transmission band V 2700 with the carrier frequency 32,560 MFfz and the use of the upper sideband as a useful sideband the following advantages: a) Even with just one implementation, the frequency position of the Basic quintary group reached and achieved complete congruence with this, In addition, despite the use of the upper sideband as a useful sideband, it is guaranteed that that the modulation byproducts 2T-M do not interfere.

b) The frequency of the three quaternary groups of the converted transmission band V 2700 enables the formation of a completely congruent basic quintary group through direct, i.e. one-time implementation of three basic Quaternary groups into the corresponding ones Frequency positions without interfering with modulation byproducts 2T-M.

c) The second sideband to be suppressed with 80 dB - the so-called Missing sideband - lies below the pass band of the filter for separation of the two side ligaments.

In the case of one and the same pair of sidebands, however, one bandpass filter has that sifts out the upper sideband as the useful sideband and the missing sideband below suppressed, a more favorable value for the frequency spacing in the normalized frequency scale between the pass band and the lower stop band as a corresponding one Bandpass filter for filtering out the lower sideband as a useful sideband and for suppression of the missing sideband in this case on top.

In the case of the direct transfer of the V 2700 transmission belt, the problem is that due to its low corner frequency 0.316 MHz the resulting and through a filter The two sidebands to be separated are only 0.632 MHz apart. Intended to the sideband to be suppressed is attenuated by 80 dB, this is the condition Difficult to achieve, especially with high frequencies of the resulting sidebands, as in the present case, which is a carrier frequency system whose Frequency range extends up to 60 MHz. No consideration for speaking through of the modulating band by the modulator, the lower one determined by the CCITT Corner frequency 4.332 MHz of the 60-ISHz transmission band as well as a planned frequency gap from 1 to 2 MHz between the quintary groups, the gap between the two sidebands must be be at least about 30 MHz.

If one compares the bandpass filter used to separate this from an implementation with the carrier frequency 32.560 MHz resulting sidebands is required with the previously mentioned quaternary group switching filter, which is considered to be one of the The most complex and difficult filter applies, and one also takes into account the At 30 Hz compared to 12 Miiz, the coil quality is lower, so you can see that this bandpass filter is used will be even more complex and difficult than the quaternary group switching filter. As will be shown below, the invention provides the prerequisites for a Bandpass filter that is simpler than this quaternary group pass filter.

When converting the transfer belt V 2700 according to FIG The frequency of the basic quintary group arises next to the upper sideband 32.876 ... 44.948 MHz, which is used al8 useful sideband, the lower one as the so-called missing sideband Sideband 20.172 ... 32.244 MHz. The upper margin this The missing sideband falls in the frequency gap between the quintary groups 2 and 3, the largest part falls within the frequency range of groups of quintaries 2. It was up to now Generally common in carrier frequency technology, one that arises during implementation Missing sideband with consideration of the cross-talk with the internationally usual To suppress value of 80 dB compared to the useful sideband in its entire width. According to a feature of the invention, however, there is a departure from this practice the missing sideband with this value only from the gap center frequency 31.900 MHz suppressed by 80 dB. The edge area between the corner frequency of 32.244 MHz and the Bridge center frequency 31.900 MHz is only used with a much smaller value, for example suppressed with only 20 dB. This determines the distance of the filter effort 80 dB stop band to pass band increased by more than 50. In the standardized Frequency scale results at 31.900 MHz an a = 1.200. This value is about three times more favorable than the value g = 1.063 of the aforementioned quaternary group switching filter at 12.532 MHz. The increase in the frequency gap between the expense-determining The 80 dB blocking range and the transmission range thus create a more favorable condition for the bandpass filter (BP4 in Fig.5 and Fig * 6). However, this is the only advantage enables the frequency gaps between the individual groups of quintaries to be wider are made as the frequency gap between the above mentioned two sidebands.

This prevents the incomplete suppression of the edge area of the Missing sideband is harmless and the remainder of the ligament is negligible.

Compared to the quintary group switching filter with its values of 1.400 and 1.345 are the requirements for the bandpass for the implementation of the transmission band V 2700 in the frequency position of the basic quintary group with Q = 1,200 higher, its implementation more complex. However, it is in the interest of standardizing devices easily possible, this bandpass also as a quintary group switching filter to be used, although there are fewer requirements for this filter.

In Fig. 4 are the level values of the above-mentioned band remnants and the quintary groups readable, the level scale is entered at the bottom at the edge. The read level values are according to CCITT levels at a point of the system with the relative level zero, as is made clear by the designation dBmO. On the left in Fig. 4 is that in places interrupted absolute frequency scale is shown. The increase in attenuation of the filter flanks was assumed to be straight for ease of viewing. In practice if this is not the case, this does not change the principle of reflection. Of the Attenuation curve of the bandpass filter BP4 for the implementation of the transmission band V 2700 is shown in dashed lines; the deviating part of the attenuation curve of the The quintary group switching filter is shown in dotted lines.

Further tape remnants occur in addition to the already mentioned tape remnant 32,244 .. .31,900! Ez between the quintary groups 1 and 2, or above the quintary group 4 if the converted transmission band V 2700 from the frequency position of the basic quintary group is implemented in the frequency range of the quintary groups 1 or 4. When implemented in the frequency position of quintary group 2 results in the remainder of the band 31.556 ... 31.900 MHz. Its level is a little lower compared to the original tape remainder, which is evident from the Attenuation edge of the bandpass filter 12 in Fig. S results, with the one after the implementation the quintary group 2 is screened out as useful sideband. The attenuation curve of the Bandpass filter BP12 is shown in phantom in FIG. 4, as is the attenuation curve of the low-pass filter TP11 and the band-pass filter BP14.

The rejection of the sideband missing at 80 dB from the gap center frequency 31.900 MHz prevents the two remnants of the tape between the quintary group 2 and the basic quintary group or the quintary group 3 with an impermissibly high Overlap levels and when converting one with two remnants of tape Band in the frequency position 0.316 ...

12.388 MIIz of the transmission band V 2700 impermissibly high crosstalk cause.

In this reverse conversion, for example from the frequency position the Basic quintary group, the band remnants occur in the range of 32.244 ... 31.900 MHz as Mirror frequencies that depend on the phase position between useful and mirror frequencies cause frequency-dependent amplitude distortions. However, these are negligible, if the level of the image frequencies is at least 40 dB below the level of the useful frequencies lies. This is guaranteed because of the implementation of a transmission band V 2700 in the frequency position of the basic quintary group to filter out the useful sideband The bandpass filter used is also passed through during the reconversion (BP4 in FIG. 6), see above that the mirror frequencies are suppressed by at least 2x20 dB = 40 dB.

The measure, incompletely suppressed band remnants in frequency gaps to be neglected, is in principle not on the upper edge of the lower Missing sideband is limited and not even to the fact that the original tape remnant occurs below the basic quintary group or generally below half a basic group. Rather, this measure is always applicable when there are frequency gaps between bundles of communication channels are wider than the frequency gap between a useful sideband and a missing sideband or any frequency band to be suppressed.

In Fig. 1 are also the various line pilots used, Quintary group pilots and measuring frequencies under the 60-1Hz transmission band 4,332 .. .59,524 WEz drawn in.

The line pilots 4.287 MHz and 61.160 MHz are already from the CCITT designated line pilots. In contrast, the line pilot 18.040 MlIz is a new one Line pilot with regard to the quintary group structure of the invention 60 MHz transmission band. As Figure 4 shows, this line pilot is in a almost 1.5 NEz wide frequency gap between the quintary group 2 and a band remainder.

The quintary group pilot 40,920 KEiz lies exactly in the middle of the Frequency gap between the middle and the upper quaternary group of the basic quintary group. It has the same frequency as the CCITT line pilot 40.920 MHz, which is used by the CCITT for an unused 40-IfEz carrier frequency system is provided was.

The measurement frequencies are partly within the different groups of quintaries and partly in the frequency gaps between the individual groups of quintaries. For the last ones Measurement frequencies are selected such frequencies that either directly to the already required Meet carrier and pilot locks of the quintary group switching filter, e.g. the measuring frequencies 32.560 tZHz and 45.760 MHz or after the implementation of the Quintärgalppen- into the basic quintary group position, e.g.

the measuring frequencies 16.720 IGHz and 59.840 MHz. These four measurement frequencies therefore do not get into a different system with quintary group connections, no additional measures are required to suppress them.

The line pilot 18p40 MHz offers a similar advantage.

When converting group 1 into the frequency range of the basic group, the line pilot also converted occurs at 31.240 MHz. The 61.160 MHz line pilot is also converted into the same frequency range when converting group 4 into the basic group position. Both pilot residues occurring at 31.240 MHz are not affected by the lower flank of the quintary group switching filter or the band pass for the direct conversion of the transmission band V 2700 into the frequency position of the basic quintary group Pilot locks / suppressed.

As FIG. 4 shows, there are still sequence gaps in spite of the remnants of the tape with a width of at least 0.632 MHz for pilot and measurement frequencies. These frequency gaps are even wider than the mostly only 0.528 MHz wide frequency gaps between the quaternary groups of the above known from the CCITT recommendation G.333 60 MHz transmission band.

Despite the leftover tape, the conditions for the transfer are still there by pilots and also their blocking cheaper than with this well-known 60-tEz carrier frequency system.

It should also be mentioned that you then of course do not transfer the remnants of tape if filters can be used to suppress them completely with reasonable effort are realizable.

Fig. 5 and Fig. 6 show a simplified block diagram as an embodiment of a circuit arrangement for forming a 60-Mfiz transmission band from basic quaternary groups via basic quintary groups and / a transmission band V 2700 in the transmission direction or the reduction of the 60 MHz transmission band into basic quintary and basic quaternary groups and into the transmission band V 2700 in the reception direction.

These block diagrams are limited to the pure converter devices. For reasons of clarity, e.g. amplifiers, controllable attenuators, A devices for feeding and evaluating pilots and measurement frequencies, equalizers etc. not shown. The quaternary group converter facility QGUslerden over the inputs El, E2 and E3 are fed to three basic quaternary groups, which by means of the Modulators M1, M2 and M3 with the carrier frequencies 32.560 MHz, 45.264 WEz and 49.280 BEHz implemented. With the bandpass filters BP1, BP2 and BP3, the useful sidebands sifted out of the resulting modulation products and through the decoupling network Nl combined into a basic quintary group 32.876 ... 44.948 margin no. Four basic quintary groups are sent via the inputs E11 ... E14 of the quintary group converter device QiGUs and processed to the 60 MHz transmission band as will be described.

Each of these four basic quintary groups kana through either of the above Direct implementation of three basic Quaternary groups formed or from the direct Implementation of a V 2700 transmission belt into the basic quintary group position as shown in Fig. 5 as an example. The transfer belt V 2700 is the Input E4 and implemented in modulator M4 with the carrier frequency 32.560 Miz. With the bandpass filter BP4, the upper sideband is screened out as the useful sideband, with according to the previous statements, the upper edge area of the lower one Sideband is not completely suppressed. In the example shown becomes the basic quintary group resulting from the direct implementation of the V 2700 transmission belt fed to the input E14 of the following quintary group converter device QiGUs.

However, it could just as well be one of the other inputs Ell, E12 or E13, like the 60 MHz transmission band in general, exclusively from converted transfer tapes V 2700 built up or else exclusively from basic quintary groups via the shown quaternary group converting device QGUs are formed, can be built up.

Four basic quintary groups are set up in the following quintary group limsetzer facility Adds QiGUs to a 60 MHz transmission band, including the via the inputs Ell, E12 and E14 supplied basic quintary groups by means of the modulators M11, M12 and M14 implemented with the carrier frequencies 49.280 MHz, 63.800 MHz and 92.400 MHz and from the resulting sidebands by means of the low-pass filter TP11 and the Bandpasses BP12 and BP14, the quintary groups 1, 2 and 4 screened out as useful sidebands will. No implementation is necessary to form quintary group 3, because the Basic quintary group already has the frequency of quintary group 3, so that only an adapter D13 is inserted, with which any level differences are compensated will. With the decoupling network N2, the quintary groups become the 60 MHz transmission band 4,332 ... 59,524 MHz combined, which is transmitted in the SR direction.

6 shows the breakdown of the 60 MHz transmission band. From the Receipt ER, it is fed to the decoupling network N2X, which feeds the 60 MHz transmission band to both the low-pass filter TP11 and the band-pass filters BP12 and BP14 as well as the attenuator D13. With the filters mentioned, the individual quintary groups are screened out in a rough preselection and then fed to the subsequent modulators Mli, M12 and M14. This rough preselection protects the modulators from stress across the entire band. This also applies analogously to the amplifiers that are not shown. The modulators Mil, M12 and M14 convert the individual quintary groups back into the frequency range of the basic quintary group. The basic quintary groups obtained are sifted out of the other modulation products by means of the BP10 bandpass filters. For quintary group 3, again, no implementation is required, only an adaptation element is inserted. The filtering out of the transmission band takes place here by the bandpass filter BP10. At the outputs All, A12, A13 and A14, the four basic quintary groups can be picked up for further processing.

In the example shown, there is, for example, one at the output All Quaternary group converter facility QGUe attached, which is a basic quintary group breaks down into basic quaternary groups, while output A14 with a converter device for the implementation of a basic quintary group in the frequency position of the transmission band V 2700 is connected. These arrangements are only exemplary; several or all basic quartet groups broken down into basic quaternary groups or according to the corresponding Implementation as V 2700 transmission belts will be continued.

With the decoupling network N1 of the quaternary group converter device QGUe is given a basic quintary group on the bandpasses BP1, BP2 and BP3. here a similar preselection takes place as in the receiving device of the quintary group converter device QiGUe. The modulators M1, M2 and M3 set the individual quaternary groups with the respective carriers 32.560 Hz, 45.264 NHz and 49.280 MHz in the frequency range of the Basic quaternary group around. The following low-pass filters TPl seven from the other modulation products the obtained basic quaternary groups, which at the outputs Al, A2 and h3 for To be available.

When implementing a basic quintary group in the frequency range of the transmission band V 2700 this is first fed to the bandpass filter BP4. This suppresses all harmful ones Remnants of the tape except for the image frequencies occurring at a distance of> 0.632 MHz with at least 80 dB. The attenuation curve of this bandpass is shown in dashed lines in FIG drawn.

However, these image frequencies of the own band are affected by the two passes through the bandpass filter BP4 - once each in the sending direction and once in the receiving direction -um => 40 dB suppressed and therefore harmless. The modulator M4 sets the basic quintary group with the carrier 32.560 l; Hz in the frequency position of the transfer belt V 2700 um. The low-pass filter TP4 suppresses unwanted modulation products. The bandpass filters BP10 of the exemplary embodiment in FIG. 6 do not need such a sharp selection like that in context with Fig.1 mentioned quintary group switching filter have, since any remnants of tape from neighboring quintary groups, which during the breakdown of the 60 MHz transmission band were not completely suppressed by the selection means the subsequent quaternary group converter device are dismantled.

The carrier frequencies used are with the exception of the quaternary group carrier 45.264 MHz integer multiples of those often used in systems that have already been implemented Control frequency fst = 440 kHz, as indicated in the table in FIG. To the generation of the carrier frequencies through frequency multiplication and division becomes the basic frequency here fg = 1.76 MHz = 4x440 kHz used, also the basic frequency 420 MHz = 5x440 kHz would be usable. Carrier frequencies that are not integer multiples of the basic frequency fg are relatively easy to follow with the necessary accuracy according to the known Phase-locked-loop method generate and also carrier frequencies that are like the quaternary group carrier 45.264 IvEz are not integer multiples of the control frequency fst = 440 kllz. A block diagram for a circuit arrangement operating according to this method FIG. 7 shows the generation of the carrier frequency.

The required frequency ft is generated by an individual generator G. This generator does not have to have the prescribed high frequency stability of the respective carrier frequency ft and can therefore be easily implemented. To achieve the control frequency fst is supplied to the arrangement to achieve the necessary frequency constancy. This is multiplied in a first multiplier W1 to the basic frequency fg = 4x fst.

In parallel with this, the control frequency fst is increased in a second multiplier VV2 multiplied by the factor m. The frequency ft delivered by the generator G is modulated with the frequency m x f st formed by the multiplier VV2. That included The resulting modulation product is converted to the fundamental frequency fg = 4xfst with the divider T. divided down, fed to the phase discriminator PD and here with the directly generated base frequency fg 4xfst compared, their accuracy the corresponds to the usual very high frequency stability of the control frequency. In the event of deviations the generator G is corrected accordingly by the phase discriminator.

The circuit arrangements shown are only examples of possible ones Embodiments for carrying out the invention. This also applies to the Numbers of the frequency scheme with which the favorable conditions for the filters explained 'that result from the application of the invention. The invention is not limited to this example, but also carry out with other figures bar. The invention is also not limited to voice transmission, it can also other messages such as 'television' are transmitted in this system. For example a TV tape can be inserted in a quintary group instead of two quaternary groups and the remaining third quaternary group can be used for voice transmission

Claims (6)

Claims 1. 60 lHz carrier frequency system with quintary group structure for the transmission of 10 800 voice channels in the same position method, in particular on two coaxial cables, characterized in that the basic quintary group is the Frequency position of the third quintary group has and through direct implementation of three CCITT basic quaternary groups are formed so that this basic quintary group is congruent is with the direct conversion of a transmission band V 2700 in the frequency position of the basic quintary group resulting upper sideband that the frequency spaced between the quintary groups are greater than the distance between those in the case of the direct Implementation of a V 2700 transmission band in the frequency range of the basic quintary group resulting two sidebands that the edge area adjacent to the upper sideband of the lower sideband in the gap between the third and the second quintary group only partially suppressed from its upper corner frequency to the gap center frequency and this tape remainder when the transferred transfer tape is transferred again V 2700 from the frequency range of the Glund quintary group to the frequency range of others Quintary groups is also transmitted and that the frequency spacing between the basic quintary group and the lower adjacent quintary group is smaller than the rest of the frequency distances between the quintary groups. 2. Carrier frequency system according to claim 1, characterized in that with the direct implementation of a transmission band V 2700 that of the upper sideband adjacent edge area of the lower sideband in the gap between the third and the second quintary group from its upper corner frequency to the gap center frequency is suppressed by 20 dB and from then on by the usual value of 80 dB. 3. Carrier frequency system according to claims 1 or 2, characterized thereby met that for the implementation of the basic quintary group in the frequency range of the quintary group 1 the same carrier frequency is used as for the implementation of the CCITTGflnd quaternary group in the frequency range of the middle quaternary group in the basic quintary group. 4. Carrier frequency system according to claims 1-3, characterized in that that with a, frequency position 32.876 ... 44.948 I <Ez of the basic quintary group of Quintary group pilot has the frequency 40.920 MHz. 5. carrier frequency system according to one of claims 1-4, characterized in that that for the line pilot between the quintary groups 1 and 2 such a frequency it is used that after implementation of the quintary group 1 in the basic quintary group position the same frequency results as the CCITT line pilot 61.160 MMz after implementation of the Quintary group 4 in the basic quintary group position. 6. carrier freedom system according to any one of claims 1-5, characterized in that that the measurement frequencies that lie between the various groups of quintaries are those Frequencies used immediately or after implementation of quintary groups into the basic quintary group position on carrier and / or pilot locks of the quintary group through-filter meet. Blank page