DE958122C - Television relay system in which television signals are transmitted to a number of receivers via a common cable - Google Patents

Description

ISSUED FEBRUARY 14, 1957

The invention relates to television relay systems in which television signals via a common Cable can be transmitted to a number of receivers.

The object of the invention is to create a system which is different depending on the frequency Attenuation of the cable over which the signal is transmitted, compensates for a received Signal has essentially the same amplitudes for all frequency components within the modulation band.

A television system is already known in which the signals from two television programs which are different from each other each broadcast or distributed in the form of a single sideband, namely so that one program with the upper sideband and the other with the lower sideband the respective associated carrier frequency is transmitted and these two sidebands overlap each other. The line and image scanning frequencies of the two programs are included synchronized, and the difference between the carrier frequencies is made slightly larger than the highest modulation frequency to be transmitted and made equal to a high odd multiple- «5 times half the line scanning frequency or such an odd multiple plus or minus the half the frame rate.

The invention consists of a television relay system, in which the to the recipient Image signals of a single television program with approximately the same to be transmitted via a cable Amplitudes are modulated on two separate carrier frequencies in such a way that the modulated Signals between the horizontal and vertical sync pulses synchronism prevails and the lower carrier frequency with the upper ίο sideband and the higher carrier frequency with the low sideband is transmitted; here the two carrier frequencies differ by a difference frequency that is higher than the highest modulation frequency to be transmitted, but only so high that substantial parts of the two sidebands transmitted have the same frequency band take in. The two carrier frequencies are preferably chosen so that they differ through a difference frequency distinguish which are equal to an odd multiple of half the line scanning frequency or equal to an odd multiple of the latter plus or minus half the frame rate is. With such an arrangement, provided that the line and frame rates applied to are sent to each carrier, are synchronized, practice the frequencies that occur due to interference between the two transmitted sidebands, has a negligible effect on a received television picture, even if the Amplitudes of the interference signal and the image signal are almost the same.

For a better understanding of the invention, an embodiment will now be referred to described on the drawings. It shows

Fig. Ι a and ib the frequency-wise different Attenuation of a single sideband television signal carried on a typical relay cable will,

Fig. 2 graphically shows the type of signal which is transmitted according to the invention,

3 shows the different attenuation of the transmitted signals,

4 shows the characteristics of a filter in the receiver,

5 shows the graphic representation of the output voltage of the image detector,

Fig. 6 is a block diagram of the transmitter; Fig. 7 is a block diagram of the receiver. In a television wire relay system it is advantageous to carry out a single sideband transmission, but this has the particular disadvantage that, as a result of the relatively low carrier frequencies used, very different attenuation of the sideband frequencies occurs, which causes undesirable effects on the received image or which on the other hand makes it necessary to to provide a special device for frequency compensation along the distribution cable. This effect can be seen in FIGS. 1a and 1h, which illustrate an upper sideband television signal of a carrier C of 4 MHz and the different attenuation of such a signal as caused by 2000 m of a typical relay cable.

In order to eliminate this different attenuation, two different carrier frequencies are used according to the invention, which differ by a difference frequency which is slightly higher than the highest modulation frequency and which is equal to an odd multiple of half the line scanning frequency or an odd multiple of the latter plus or minus half the image sampling frequency, and which are transmitted with the upper and lower sidebands. Such an arrangement is shown graphically in Figure 2, where C ₁ and C _{2 are} the two carrier frequencies with sideband overlap. In this case the two carrier frequencies have a frequency deviation of 3.25 MHz, but it is understandable that this representation is chosen only as an example. Both carriers are modulated with the same television picture signal of approximately the same amplitude in such a way that the line and picture signals run synchronously.

An embodiment of a transmitter according to the invention, in which two carrier frequencies are generated which have a frequency separation of 3.25 MHz, as described above, is shown in FIG. In this figure, the "image signal" is fed to an image splitter stage 1, the output voltage of which is fed to a modulator 2, a modulator 3 and a synchronous pulse separator stage 4. An oscillator 5, which _{generates a carrier frequency C 1} of 4 MHz, feeds the modulator 2 and also a mixer stage 6. The Horizon synchronous pulses arriving from the separating stage 4 are sent through a frequency multiplier 7 and a filter 8 in order to generate a frequency of 3.25 MHz corresponding to the nearest odd multiple of half the line frequency where it is mixed at the frequency of 4 MHz from the oscillator to produce a carrier frequency C ₂ of 7.25 MHz which is ultimately fed to the modulator 3. The output signals from the modulators 2 and 3 are passed to a combining filter q , the output of which is connected to the transmission cable of the relay system via an amplifier 10. -As mentioned previously only the upper sideband of carrier C ₁ operating at 4 MHz and only the lower sideband of carrier C ₂ operating at 7.25 MHz are transmitted, and these two thus produce a composite transmitted signal of the form shown in FIG .

As the carrier waves travel through the cable, the frequency dependent attenuation causes the sidebands to be selectively attenuated as shown in FIG. 3 ", the degree of inclination depending on the length of the cable used. Note that in the case of the carrier C ₁ the high sideband frequencies are attenuated the most, while in the case of the carrier C ₂ the same applies to the low sideband frequencies.

At any point on the cable, the transmission can be fed to a receiver unit which operates with a transmission characteristic curve that drops evenly on both sides, as shown in FIG. 4, and which is therefore suitable for receiving both transmissions without significant interference. The receiver treats the signal as a single transmission and uses only one signal amplifier channel,
One form of receiver according to the invention is shown in Fig. 7 in which the image signal arriving from the relay cable passes through an amplifier 11 and is rectified by a single additive detector 12 which adds the two image frequency components. This detector circuit can be, for example, a voltage doubler circuit or a bridge arrangement. Its output voltage is fed to an image intensifier stage 13 and used to modulate the electron beam of a cathode ray tube 14. Since the selective attenuation is reversed once, the image spectra of the two carrier waves are as shown in Fig. 5, and it is readily apparent that the sum of the output voltages gives a flat frequency curve having the same amplitudes of the image components within the image bandwidth. This curve is indicated by dashed lines in FIG. 5. Wherever the selected attenuation is substantially linear, as shown, the compensation provided by the two carrier frequencies will be effective regardless of the length of the cable involved; and thus such a cable, when used in a system according to the invention, can be considered to be essentially free of selective attenuation at all points. The image intensifier preferably has a transmission curve such that the frequency difference between the carriers falls outside their range; this is also the subject of the improvement brought about by the special, above-described relationship between the two carriers and the sampling frequencies. While a particular embodiment has been described, it will be understood that various changes can be made without departing from the spirit of the invention.

Claims (10)

PATENT CLAIMS: i. Television relay system in which television signals are sent to a number of receivers via a common network Cable are transmitted, characterized in that the to the receivers too transmitted image signals of a single television program with approximately the same amplitudes be modulated on two separate carrier frequencies so that the modulated signals for the horizontal and vertical sync pulses there is synchronism and only the upper one Sideband of the low carrier frequency and the lower sideband of the upper carrier frequency is transmitted, the two carrier frequencies at a frequency spacing from one another that is greater than the highest modulation frequency to be transmitted, but only so large that practically the two transmitted sidebands occupy the same frequency band. 2. System according to claim 1, characterized in that the difference frequency between the two carrier frequencies is chosen so that signals caused by interference between the both transmitted sidebands are generated, a negligible one on the received television picture Have an effect. 3. System according to claim 2, characterized in that the two carrier frequencies are mutually exclusive differ by a difference frequency that is equal to an odd multiple of half Is the line scan frequency of a television system. 4. System according to claim 2, characterized in that the two carrier frequencies are mutually exclusive differ by a difference frequency that is equal to an odd multiple of half Line scan rate is plus or minus half the television system frame rate. 5. Transmitter for distributing television signals over a cable to a number of receivers, thereby characterized in that two carrier frequencies are generated which are divided by a difference frequency distinguish which one is greater than the highest modulation frequency that is transmitted is to be, the carrier frequencies are chosen so that the interference the same resulting signals have a negligible effect on a received television picture and further characterized in that image signals of a single television program with essentially the same amplitude on the first and second carrier frequency with mutually synchronous horizontal and vertical sync pulses are modulated, and finally characterized by that the upper sideband of the low carrier frequency and the lower sideband of the upper. Carrier frequency are fed to a combining filter, which is the transmission cable feeds, with practically the two transmitted sidebands the same frequency band take in. 6. Transmitter according to claim 5, characterized in that the second carrier frequency in a mixing circuit is generated to which the first carrier frequency and a frequency are supplied derived from the line frequency contained in the television signal. 7. Transmitter according to claim 6, characterized in that the contained in the television signal Line scanning frequency generated frequency to be derived in a frequency multiplier stage which is fed by the horizontal sync pulses, which from a sync pulse separator are derived, and characterized in that the output voltage of the multiplier to the mixer circuit a filter is supplied. 8. Receiver for television signals from a transmitter according to claim 5 via a cable were transmitted on two separate carrier frequencies, characterized by the use a single amplifier channel including an additive detector for rectification of the image signals which originate from each of the two carrier frequencies and which are in the Detector are added and by an image intensifier fed by the additive detector and a cathode ray tube controlled by the image intensifier. 9. Receiver according to claim 8, characterized in that that the additive detector is preceded by an amplifier which has a residual sideband pass characteristic curve which drops evenly on both sides with Nyquist flanks. 10. Receiver according to claim 8 or 9, characterized in that the image intensifier has a transmission characteristic that represents the difference frequency suppressed between the carriers. Considered publications:
British Patent No. 675,887. Please refer to the sheet of drawings © «09 579/168 8.56 (609 797 2.57)