DE2003980C - Frequency division multiplex system for the transmission of telephone and videophone channels - Google Patents

Description

The invention relates to a frequency division multiplex system for single sideband transmission in stages telephone channels converted into the transmission layer. These frequency division multiplex systems are also called carrier frequency systems and usually have a structure in which the individual 4 kHz wide telephone channels through carriers representing integer multiples of 4 kHz, stepwise in the transfer situation will be implemented.

According to the recommendations of the CCITT (Comite Con- Through the selection according to the invention of the carrier result International T616phoniqufc et Telographique) frequencies it is achieved that all non-linear procedures the frequency plans of most broadband products of any order of the videophone carrier sub-carrier frequency systems of the basic primary group multiples of each other Represent 4 kHz and always 60 to 108 kHz with 12 long-distance telephones 5 fall on zero frequencies of the telephony channels. Thus speaking channels from. Five of these primary groups result in the least possible disturbance of the F'-rn to a 60-channel group, the basic secondary group of speech channels from videophone carriers.
312 to 552 kHz combined. Another bundle In a further embodiment of the invention, the delung can, for. B. can be achieved by placing five line frequencies of the videophone signals on 4 kHz or basic secondary groups in the 300 channels comprehensive io an integral multiple of 4 kHz. By basic tertiary group in the position 812 to 2044 kHz this choice of line frequency is achieved that all are implemented. The carriers with which mixed products between the individual carrier frequencies are used to bring the individual channels in one or more stages in the videophone signals to zero frequencies of the remote primary group position are up- ¹ . Speech channels drop and thus long-distance calls do not disturb the porters for further implementation in Gnn.a -5.

Tertiary group position in each case whole-number multiples of A particular advantage is found in the choice of the

⁴ kHz. Line frequency f _{z of} the videophone signals to 8 kHz

The aforementioned choice of carrier frequency is z. B. and at the same time setting the videophone carrier to from the magazine "Frequency", 1968, issue 10, p. 274 to odd multiples of 4 kHz. As a result, 284, in particular Fig. 2, becomes known, which also achieves a grouping of all spectral components of the videophone possibility of transmitting a 5.5 MHz wide channel in the carrier frequency transmission system around television band with a 500 kHz wide residual side frequencies, represent the odd multiples of band in place of five tertiary groups of 12 MHz to represent 4 kHz. Shows all nonlinear mixing products of wide transfer band. The position of the video second ordi .mg are thus in the transmission position carrier is here 6799 kHz, ie 1 kHz lower than the 25 in the vicinity of integer multiples of 8 kHz, the closest integer multiples of 4 kHz. D ^; e ie exactly in half-line offset to the videophone German Auslegeschrift 1 048 952 shows the transmission of useful signals, and therefore only represent a 5 MHz wide television band with a flow that is barely perceptible to the eye, 500 kHz wide residual sideband, with the. Video are.

carrier frequency 7199 kHz, also 1 kHz lower than 30 All converter frequencies of the tertiary and

the closest multiple of 4 kHz is chosen. Quaternary group converters are then - as a whole-

Finally, there are numerous multiples of 8 kHz from the German patent specification - also in Halb-1 021 896 a carrier frequency system known in which the line offset to the Videophon-Nutzsijnalen, d. H., the carriers for the one-step implementation of the main - their carrier residues interfere less strongly in the Videophonbzw. Tertiary groups in the multi-signal transmission position.

times of 4 kHz. In the event of the same- Further details and advantages of the invention

early transmission of a television channel should be in more detail below with reference to the drawing

this system explains the television carrier frequency so chosen. The drawing shows in

be that the modulation products between the F i g. 1, 2 and 4 frequency schemes for four different

Television carriers and television amplitudes in the 40 different ways of constructing the invention

The flanks of the channel beams fall. Frequency multiplex systems,

The F-finding assumes it. that not only remote F i g. 3 a frequency scheme of the non-linear

Voice channels and 5 MHz or 5.5 MHz wide remote mixing products at a line frequency of 8 kHz

video tapes for the purposes of broadcasting but rather and videophone carrier frequencies that are odd

television, telephone and videophone channels are also 45 multiples of 4 kHz. <

Frequency division multiplex systems are to be transmitted. With the two frequency schemes according to FIG. 1 and

However, as long as there are no two further frequency schemes according to FIG. 2 transmission tailored wide area network and 4 is each a frequency multiplex or carrier is available, does it make sense, similar to z. B, assuming the data frequency system is 4 kHz wide Transmission is already the case, existing frequency 50 telephone channels based on the principle of single sideband multiplex systems for the long-distance traffic of videophone transmission with suppressed carrier in several channels to use with. Stages in a transmission range of at least 4 MHz

It is therefore the task of the invention to be implemented on a freeband. Other signals that require narrower quenzmultipiexsystem for single sideband transmission or broader frequency bands than 4 kHz, from 4 kHz wide telephones, anal, which through 55 fit into the step-by-step structure by means of seam-carriers, the integer multiples of 4 kHz darlos that they are delivered beforehand to 4 kHz wide channels, gradually converted into the transmission layer or only at a higher level of the, additional videophone channels with the rest of the page are added step-by-step,
band and Nyquist edge to be transmitted without an additional vciaus is that the gradual disruptive influence of the telephone channels by the 60 structure of the transmission band by carrier before videophone transmission, and vice versa, arises. is taken, the whole multiple of

According to the invention, this task is solved by representing 4 kHz. Considerations in the context of the

that the carrier for the single or multi-stage implementation lead to the fact that videophone channels in the closer

the videophone channels from the video situation in the over-senses, d. H. their videotapes according to the principle of

Tragungslage are chosen such that the frequency 65 single sideband transmission with residual sideband and

Videophon-NyquistPanke corresponding to the video position and with a total bandwidth of

carrier in the transmission position multiples of 4 kHz about 1 MHz should be transmitted and that this

«! ■" Ι video tapes in the frequency division multiplex system the

Place of tertiary groups with 300 telephone channels tertiary groups 812 to 2044 kHz through carriers that

should take. For the four in the drawing represent integer multiples of 8 kHz, in one

The frequency schemes provided are the carriers or several stages in the transmission layer.

for the one or multi-stage implementation of the video set, so that it is sufficient to use the carrier for one or

phonkanäle from the video layer into the transmission layer 5 multi-stage implementation of the videophone channels from the

chosen such that the frequency zero in the video position in the position of the basic tertiary group

To choose the corresponding video carrier / _m in the video position in such a way that the frequency zero in the

Transmission position odd multiples of 4 kHz video position corresponding video phone carrier into the

are. So it is the condition met the position of the basic tertiary group odd multiples

ίο of 8 kHz.

fm = ni 8 kHz + 4 kHz, _{Zw (; i} example for structure schemes of frequency

where m - integer. multiplex systems according to the invention are shown in FIG. 1

Shown in particular when defining the frequencies. Here the z. B. to 0 to 992 kHz beder video carrier in the aforementioned type results in limited video tape of a videophone channel on two a further reduction of possible interference 15 different types in the position 812 to 2044 kHz the basic by choosing the line frequency f _z of 8 kHz. tertiary group GT, implemented in the regular situation.

Apart from the noteworthy smaller specs, the one type of implementation is done directly by means of

The neutral components of the field and frame rate of the carrier is 1052 kHz. The other way of

the frequency mixture of a videophone signal in the setting is carried out in two stages, namely

Carrier frequency transmission layer through components of the 20 zuersl by means of the carrier 3908 kHz in an intermediate

Form frequency position from 2916 to 4148 kHz, which is loaded with IF

fm 4- η ■ fz, with - ζ <η <y (integer), draws ^: -.t, in the inverted position and then by means of the support

4960 kHz in the basic tertiary group position GT. the

given, where fz is the line frequency of the videophone carrier 4960 kHz can be done in a simple manner

signal is. The size ζ determines z. B. the width of the 25 multiplication with a factor of 40 from the basic

Nyquist edge and the size y derive the videophone channel frequency 124 kHz,

bandwidth. In the event that the video carriers are all In both construction schemes according to F i g. 1 becomes the

represent odd multiples of 4 kHz and use Nyquist flank for the first conversion.

the line frequency f _t = 8 kHz is selected, all forms, i.e. in the first case in the basic tertiary group spectral components of the videophone channels in the overlay GT and in the second case in the intermediate frequency

Carrying situation around frequencies, the odd-numbered situation ZF.

Represent multiples of 4 kHz, grouped. All non- The construction scheme according to F i g. 2 is based on a linear mixed product of the second order, so the videophone channel is based on a frequency band from 0 to 1000 kHz or from 0 to multiple multiples of 8 kHz, ie exactly in the half-frequency band of 0 to 1000 kHz in the video position 906 kHz is limited. By means of the carrier 1812 kHz line offset to the videophone useful signals and from the video position directly into the basic tertiary positions, therefore, only influences are shown that are implemented for group GT, namely in the inverted position, whereby the eye is barely noticeable. the frequency band in the first case from 812 to 2044 kHz

All converter frequencies of the tertiary and and in the second from 906 to 2044 kHz goes. Through the Quaternary group converters are then available - as a whole- 40 cropping of the video tape to an upper fre-

numerous multiples of 8 kHz - also in the half-qaenz limit of 906 kHz before the implementation

line offset to the videophone user signals, d. that is, yours is enough for the videotape to match the corresponding,

Carrier residues interfere less strongly in the videophone signal. implemented sub-band in the basic tertiary group

The position of the non-linear mixed products is not overlapped in position GT , so that from this hand of the four partial images of FIG. 3 even more closely, no disturbances can arise,

clearly. FIG. 3 a shows the position of two types of implementation according to FIG. 1

Liebiger carrier frequencies f _m and / ₍ in the over and 2 the formation of a basic tertiary group GT is in

bearing position as well as the associated frequency of the position 812 to 2044 kHz together. These one each

spectrum at intervals of the line frequency fz - 8 kHz. Basic tertiary groups containing videophone channels. Building on this, FIG. 3 b as an example a 50 GT are then like those with telephone channels

Spectrum of mixed products of the second order and occupied basic tertiary groups in the usual way

F i g. 3c the standardized frequency scale. The location of the tertiary rib carriers 10 560.11 880 and 13 200 kHz in

Telephone channels on this frequency scale are in the position 8516 to 12 388 kHz "of the basic quaternary group

Fi g. Indicated in 3d. GQ implemented. In the 12 MHz carrier frequency system

For the offset operation between telephony and 55, the basic quaternary group GQ already forms the upper

Videophone transmission is an accuracy of the line part of the transmission band; the two lower ones,

. ,,.,,. , Af ₁ _ _iri . parts of the transition corresponding to a quaternary group

frequency of the V.deophons.gnale of -j- <2 ■ 10- { _{Γα8ιΙΠξ5} 1 _{αηαε5 of} the 12 MHz system are derived from the

sufficient. The greatest deviation of the interference components of the basic quaternary group GQ is formed by means of the quaternary nipples from the zero frequency for the highest video signal carriers 12 704 and 16 720 kHz. The lowest frequency is then 2 · 10 ~ ⁶ · 1 MHz = 20 Hz. Quaternary group 316 to 4188 kHz of the 12 MHz over-3ei the two frequency transmission bands described below at the same time roughly represents the overplan according to FIG. 1 and two frequency plans according to the transmission band for a 4 MHz system.
the F i g. 2 and 4 is the condition that the video F i g. 4 shows a construction diagram of a frequency phone carrier in the transmission position uneven-numbered 65 multiplex systems, in which three video phone channels represent multiples of 4 kHz. In addition, one or two conversion stages in the position of the will be implemented in the implementation scenarios according to the 4 MHz carrier frequency system. Here-F i g. 1 and 2 in the usual way the basic with it is also possible to use these three tertiary groups as

Insert the lowest quaternary group into a frequency multiplex system with a larger frequency bandwidth. z. B. in the 12 MHz carrier frequency system.

The videophone channels are limited in the video position to a frequency band from 0 to 992 kHz and are converted by means of the carrier 3908 kHz into an intermediate frequency position ZF (2916 to 4148 kHz), << ie the approximate position of the third tertiary group of the transmission band of the 4 MHz or the 12-M Hz carrier frequency system. Under certain circumstances, when transmitting several video phone channels, it is advantageous to use a separate generator for each conversion to the intermediate frequency position ZF and not to synchronize these generators, not even with the basic generator of the remote speech converter. In the case of multiple occupancy with videophone channels, a certain statistical distribution then occurs both for the peak load and for the addition of non-linear mixed products on the route. Favorable conditions for the transmission system are given if the generator for generating the subcarrier frequency 3908 kHz has a relative accuracy of 10 ^β in the present case, which corresponds to an absolute deviation of 4 Hz. This subcarrier frequency is expediently derived from a freely oscillating crystal oscillator.

When converting the videophone channels to the intermediate frequency position ZF , the Nyquis flank is advantageously already formed on the transmission site with a width of 150 to 250 kHz, since this results in the most favorable noise balance. In the present case, a Nyquist flank of { 240 kHz is formed, so that the videophone channels in the intermediate frequency position ZF extend over a frequency band from 2960 to 4148 kHz in the inverted position.

A videophone channel in the approximate position 3 '(29Ί6 to 4148 kHz) of the 4 MHz or 12 M Hz system remains for the transmission; two further videophone channels are brought from the intermediate frequency position ZF by means of a carrier 4464 kHz to the approximate position Γ of the first tertiary group or by means of a carrier 5760 kHz to the approximate position 2 'of the second tertiary group of the aforementioned systems in each case in Regellagc. The Vidcophonkanal Γ takes up the frequency band 316 to 1548 kHz, whereby the video carrier has a frequency of 556 kHz. The second Vidcophonkanal 2 'occupies the frequency band 1612 to 2844 kHz, the video carrier having the frequency 1852 kHz.

The two carriers with which the two last-mentioned videophone channels Γ and 2 'in their transmission position can be brought in a simple manner from existing frequencies of the frequency division multiplex system can be obtained by multiplication in the following way: 4464 kHz = 36 124 kHz; 5760 kHz = 40 x 144 kHz.

The structure of the 4 MHz system according to FIG. 4 can r.n't be compared to the structure of 15 secondary group blocks with pure telephone occupancy. from this "basic quaternary group with 15 secondary groups" can then be made up just like with telephony Build wider systems with the same converter equipment. Thus, this structure offers for Vidcophonkanal transmissions the same requirements for system structures as for pure Telephone occupancy and any mix between videophone channels and telephone groups of 300 can be used be made. In addition, with the 4 M Hz system below 312 kHz, the Secondary group 1 with 60 telephone channels can be transmitted.

never in connection with the construction scheme according to fig. The type of derivation of the carrier described in FIG. 4 for the conversion from the video position into the intermediate frequency position ZF by means of freely oscillating crystal oscillators can also be used in the construction schemes according to FIGS. 1 and 2 are applied. For example, the carrier 3980 kHz can be used in one type of implementation according to FIG. 1 in the same way as in the construction scheme according to FIG. 4 derived with advantage for each reacted Videophonkanal from a suitable, non-synchronized crystal oscillator mii a relative accuracy of 10 ⁶ corresponding to voi -i 4Hz an absolute deviation of this carrier. An absolute accuracy of ± 4 Hz must also be maintained for the different carrier generators that generate the carriers 1052 kHz or 1812 kHz, which are each used for a direct conversion from the video layer into the basic tertiary group position GT in the construction types according to the figures. and 2 are used.

For this purpose 2 sheets of drawings

209 643/3

Claims (17)

Patent claims: 1. Frequency division multiplex system for single sideband transmission of 4 kHz wide telephone channels, which are gradually transferred to the transmission layer by means of carriers that represent integer multiples of 4 kHz and for the transmission of videophone channels with residual sideband and Nyquist flank, characterized that the carrier for the single or multi-stage implementation of the videophone channels the video position in the transmission position are chosen such that the frequency zero in the Video carrier corresponding to the video position in the transmission a ^ e are multiples of 4 kHz. 2. System according to claim 1, characterized in that the line frequency of the videophone signals 4 kHz or an integer multiple of 4 kHz. ao 3. System according to claim 2, characterized in that the line frequency f _{z of} the videophone signals is 8 kHz. 4. System according to one of claims 1 to 3, characterized in that the carriers for the single or multi-stage implementation of the video phone channels from the video system in the transmission! Ige are chosen such that the frequency zero in the video position corresponding V ^: deoträger are odd multiples of 4 kHz in the transmission layer. 5. The system of claim 4, wherein the CClTT basic tertiary groups 812 to 2044 kHz through carriers that are integer multiples of 8 Hz in one or more stages in the transmission layer be implemented, characterized in that the videophone channels in one or more Levels from the video position to the position of the basic tertiary group 812 to 2044 kHz and then how the basic tertiary groups occupied by telephone channels in one or more stages in the transmission layer are implemented and that the carrier for single or multi-stage implementation of the videophone channels are selected from the video position in the position of the basic tertiary group so that the the video carrier corresponding to the frequency zero in the video position in the position of the basic tertiary group are odd multiples of 4 kHz. 6. System according to claim 5, characterized in that the videophone channels in a single Stage with a carrier representing an odd multiple of 4 kHz from the Video position can be converted into the position of the basic tertiary group 812 to 2044 kHz (Figs. 1 and 2). 7. System according to claim 6, characterized in that the conversion from the video position into the position of the basic tertiary group (GT) takes place in the normal position with a carrier of 1052 kHz (FIG. 1). 8. System according to claim 6, characterized in that the implementation from the video location in the position of the basic tertiary group (GT) in the inverted position with a carrier of 1812 kHz (Fig. 2). 9. System according to one of claims 6 to 8, üaJurch characterized in that the Vitleophonkanäle are implemented with a carrier in the basic tertiary group position (GT) , is derived from a freely oscillating crystal oscillator with an absolute accuracy of about ± 4 Hz (F i g. 1 and 2). 10. rSystem according to one of claims 1 to 4, characterized in that the videophone channels are converted from the video position into the approximate position of the third tertiary group (ZF) of the transmission band of the 4 MHz or 12 MHz system in the inverted position and that the third tertiary group serves at least partially as an intermediate frequency position for further conversions (FIGS. 1 and 4). 11. System according to claim 10, characterized in that the first implementation of the videophone channels takes place with a carrier of 3908 kHz (Figs. 1 and 4). 12. System according to claim 11, characterized in that a videophone channel with a carrier of 4464 kHz in a second conversion from the intermediate frequency position (ZF) in the approximate position of the first tertiary group (1 ') of the transmission band of the 4 MHz or 12 -MHz system is brought into the normal position (ri g. 4). 13. System according to claim 11 or 12, characterized in that a videophone channel with a carrier of 5760 kHz in a second implementation from the intermediate frequency position (ZF) in the approximate position of the second tertiary group (2 ') of the transmission band of the 4 MHz or . 12-M Hz system is brought into the normal position (Fig. 4). 14. System according to any one of claims 10 to 13, characterized in that a videophone channel remains in the position of the third tertiary group (3 ') of the transmission belt and transmitted will. (Fig. 4). 15. System according to claim 10 or 11, characterized in that the Videopbc nkanäle in one second conversion from the intermediate frequency position into the position of the CCITT basic tertiary group 812 up to 2044 kHz and then like the basic tertiary groups occupied by telephone channels 812 to 2044 kHz can be converted into the transmission layer in one or more stages (FIG. 1). 16. System according to claim 11 and 15, characterized in that the second implementation with a carrier of 4960 kHz takes place (Fig. 1). 17. System according to one of claims 10 to 16, characterized in that the videophone channels are implemented with a carrier in the approximate position of the third tertiary group of the transmission band of the 4 MHz or 12-M Hz system, which is from a freely oscillating Quartz oscillator is derived with a relative accuracy of about 10 ~ ^e .