DE2017199A1 - Television signal transmission system - Google Patents

Description

television signal transmission system The invention relates to a television signal transmission system, in which a VSB or residual side tape transmission system is used.

The television picture is generally with respect to the horizontal center line of the screen is asymmetrical, and the picture becomes compared with the vertical synchronization period kept quiet for a relatively long period of time. The image signal therefore contains many waveforms that repeat with the vertical synchronization period and its spectral distribution is densely concentrated in the low frequency range. at a vestigial sideband transmission system, the television signal is amplitude modulated. This leads to a concentration of high-energy sidebands in the spectral distribution the modulated oscillation in the vicinity of the carrier, on the receiving side the synchronized demodulation carrier must be reproduced. When the television signal is transmitted with a degree of modulation of less than 100%, the sideband no Cause polarity reversal of the carrier. The signal, "'that is obtained by passing the modulated oscillation through the bandpass filter for extraction of the carrier conducts, therefore, as is known, has no phase change and is a Carrier which only changes in amplitude. When you get this signal through a suitable limiter leads, a demodulation carrier can be obtained, which has a constant amplitude and phase.

However, if the signal has a modulation depth of more than 100, d. H. is transmitted overmodulated, there is a polarity reversal of the carrier due to the side ligament. In this case it is impossible to use the demodulation carrier in the manner described above.

There is also the sideband, which occurs when the polarity of the carrier is reversed plays the main role, is close to the wearer, it is not possible that Separate high-energy sideband from the carrier by a filter. To get the synchronized Demodulation carrier according to the conventional vestigial sideband transmission method reproduce, a complex Sohaltungsanordnung is required in which the carrier having a constant level in the horizontal synchronization signal must be taken periodically from the modulated oscillation.

The aim of the invention is to provide an economically favorable television signal transmission system indicate at which 'the direct current and low frequency components contained in the television signal are suppressed and the demodulation carrier on the receiving side by means of a simple circuit arrangement ^ is reproduced.

The invention provides a television signal transmission system in which asymmetrical side ligaments created by removing part of one of the side ligaments obtained by overmodulation of the transmission signal (amplitude modulation) generated with a degree of modulation higher than 100% using a carrier will.

whose frequency is greater than the maximum frequency of one to be transmitted Television signal, are transmitted along with the carrier. Be on the sending side the received asymmetrical sidebands and the carrier using a Demodulation carrier. demodulates which of the received asymmetrical sidebands and the carrier. In this way the watch signal is reproduced. According to the invention is a device for generating the transmission signal in which the television signal is converted, and for suppressing the low frequency component. of the television signa provided. Another facility is used to regenerate the Demodulation carrier by obtaining the demodulation carrier together with the symmetrical one Part of the asymmetrical side bands from the given asymmetrical side bands and the wearer. There is also a facility for regeneration.

ration of the transmission signal by demodulating the received asymmetrical sidebands and the carrier using the regenerated demodulation carrier and means for regenerating the television signal from the transmission signal intended.

The invention will now be explained in more detail with the aid of the drawing. They show: FIGS. 1a to d representations of waveforms which show how a Television signal is converted into a transmission signal according to the invention; Fig. 2a to'c representations to explain the difference the spectral distribution when comparing the television signal with the transmission signal; Fig. 3 is a block diagram of an embodiment according to the invention; Fig. 4a to h representations for Explanation of various frequencies of the embodiment according to FIG. 3; Fig. 5 shows an example of a direct current superposition circuit for the embodiment according to FIG., 3; Fig. 6 shows an example of a ring modulator; and FIG. 7a the behavior of the carrier recovery filter according to FIG. 3, the vector diagram of which is shown in FIG. 7b is.

In Fig. 1a is an example of a waveform of the to be transmitted television signal shown. Its spectral distribution is based on the image frequency fp and the horizontal sync frequency fH is concentrated. The whole is the distribution concentrated in the low frequency range.

Fig. 1b shows a signal with a certain DC level, namely the television signal from Fig. ia on which a direct current component is superimposed. In Fig. Ic shows a square wave, the frequency of which is equal to half that Repetition frequency of the horizontal synchronization of the television signal according to FIG. 1a is. The spectral distribution has its fundamental wave at fH / 2, as shown in FIG. 2b is. It only has high harmonics of odd order. Pig. 1d shows a waveform, which arises when the signal according to Pig. 1b using the control signal modulated with a ring modulator according to FIG. If-in Fig. 1b a DC level, the half is as large as the maximum amplitude of the television signal (calculated from peak to peak), is added to this, the amplitude in Fig. 1a become the same as that in Fig. 1b. If, however, as shown in Fig. 1b, a DC level is added which is half the size of the video signal Except for the synchronous signal of the television signal, that shown in Fig. 1-g will be Resulting waveform, with only the synchronization signal protruding. The vibration 1d is modulated at a high frequency, and the resulting 'signal being transferred. On the receiving side, the received signal is demodulated, see above d.that the same oscillation as in Fig. id results. The synchronization signal part is then separated from the demodulated signal and used to reproduce a square wave as used in Fig. 1c, whereby the television signal is reproduced.

The spectral distribution of the vibration according to FIG. 1d is shown in FIG. 2c shown, whereby both the direct current and the low frequency component (in near fF) are suppressed in strong wet, and the spectral distribution is too concentrated on the frequency fH / 2.

The vibration according to FIG. 1d, its direct current component and low frequency component have been suppressed in the manner described is by a carrier with high frequency amplitude modulated. As a result, only the suppressed is weak Sideband component distributed near the carrier frequency, while the sideband compo- + flente is distributed at a high level away from the carrier frequency. When the strong Sideband component of the modulated signal that is more than fH / 2 apart, is suppressed by using the carrier acquisition filter is located in near the carrier as the sideband only the low frequency component which the is weak spectral component. When the signal is near the carrier from the Send side sent using both sidebands will and then again a carrier is inserted with a level higher than that in the vicinity of the The weak spectral component present in the carrier can be considered a continuous one Carrier without phase change as a synchronized demodulation carrier from the carrier extraction filter received on the receiving side.

The illustrated in Fig. 3 and explained in Fig. 4 on the support system according to the invention includes a sending part 8, a receiving part 8 'and a transmission line 9, which leads from the transmitting part to the receiving part. A signal source is generated in the transmitting part 8 10 a television signal to be transmitted, as shown in Fig. Ia. These Vibration according to rig. As has been described, FIG. 1a has the spectral distribution according to FIG Fig. 2a. In simplified terms, this spectral distribution in FIG. 4a is uniform in the frequency band shown distributed. A direct current superimposition circuit is denoted by 11 in FIG. 3, which is to superimpose a direct current level on the television signal. A divider 12 only separates the synchronization signal from the television signal. This circle is for Television receivers are used in a well known manner. 13 is a band pass filter, by which the repetition frequency component of the horizontal sync signal is obtained from the separate synchronization signal. A flip-flop circle 14 generates a pulse train with the repetition frequency fH / 2. At 15 there is an amplifier and 16 denotes a ring modulator. An oscillation is generated from the superposition circle 11 1b applied to one of the input terminals of the modulator 16, and an oscillation 10 is fed from amplifier 15 to its other input terminal. At the An oscillation appears at the output of the modulator 16, i.e. its direct current and low frequency components are suppressed. Your distribution is shown in Fig. 4b. A Oscillator 17, which generates a carrier fC, is coupled to a modulator 18, which the two sidebands and continuously the constant carrier FC according to Fig. 4c provides. Since the degree of modulation of the modulator 18 is greater than 100%, the level of its output carrier fC is less than the television signal level, such as is shown in Fig. 4c. This means that there is a polarity reversal of the carrier fC due to the television signal.

The carrier fC and its two side bands are or low pass filter 19 passed so that the entire lower sideband and part of the upper sideband are sent to the transmission line 9, as shown in Fig. 4d, as a result, both sidebands are near the Carrier fC, and the DC and low frequency components are determined by the Circles 11 to 16 suppressed. Therefore there is only the weak spectral component near This means that the phase change component of the carrier fC is distributed in the single sideband area away from f0, and the strong Spectral component which causes the riarity reversal of the carrier c is also distributed away from'f0.

The bandpass filter 31 shown in Fig. 3 is used to derive the Carrier. As shown in FIG. 4e, its sideband component is reduced to one Level pushed down below the carrier level. An example of the characteristic of the filter 31 is shown in Fig. 7a, where the curve 71 the damping behavior and curve 72 shows the phase behavior. According to the damping curve 71 results a sufficient damping value at fc # fH.

Perner can be seen that this characteristic curve is symmetrical to 2 fc is. Consequently one can use as output signals of the band pass filter relatively high-energy fc component and the two sideband components relative -Energy low 'received. Fig. 7b shows the output signals of the band pass filter in vector form. 73 is the fc component, 74 is the upper sideband of fc and 75 the lower sideband of fc. If the combined vector 76 of the vectors 74 and 75 has the same direction as the vector 73 of the fc component and the vectors 74 and 75 have the same phase angle in opposite directions, so will the two Sidebands do not disturb the phase of the wearer. To achieve this it is necessary to d.ass that the 'phase' characteristic of the bandpass filter 31 (curve 72) is point-symmetrical with respect to the carrier fc, as shown in Fig. 7a. With 32 in Fig. 3 denotes a limiting element which is generated by the bandpass filter 31 with unchanged phase only receives output signal that changes in terms of amplitude and limits the amplitude.

In this way one obtains a carrier fc (for demodulation), whose amplitude and phase do not change.

Of course, the bandwidth of the filter 31 is in the bandwidth of the bandpass filter 19, and the narrower its bandwidth centering the carrier frequency is, the narrower the value of the output sideband components becomes, and the lighter it becomes the amplitude can be limited.

A VSB or residual sidewall shaping filter (33) to 3) is with a Input of a demodulator 34 coupled. The demodulator 34 effects a homodyne demodulation of the residual sideband modulated signal according to FIG. 4f by means of the carrier for the Demodulation that it receives from filter 31 via limiter 32. That I The resulting output signal is shown in Fig. 4g and. corresponds to the waveform according to Fig. 1d. With the output of the demodulator 34 is a waveform converter 35 coupled. A reproduced television signal appears at its output terminal 36 including the direct current component, as shown in Fig. 4h is.

The circuit diagram shown in Fig. 5 shows an example of a direct current superposition circuit according to FIG. 3. A negative voltage is applied from a direct current source. If the values of the resistors Rl, R2 and R3 are dimensioned accordingly, results in the form of oscillation according to Fog. 1b.

The circuit arrangement according to FIG. 6 is an example of the ring modulator 16 according to FIG. -3. With 161 and 162 are in Pig. 6 denotes the input terminals, which are connected to the direct current superposition circuit 11 according to FIG. 163 and 164 are control input terminals coupled to amplifier 15 of FIG -are. 165 and 166 are the output terminals. If the signal at terminal 163 is positive and at terminal 164 is negative, the shown diodes Di to D8 are blocked, while diodes D9 through D16 are forward biased. Consequently terminal 161 is connected to terminal 165 'and terminal 162 is connected to terminal 166. The waveform of the signal to the input terminal - that is, the same as at the output terminals .. If on; the control terminals 163 and 164 one-reverse or reverse voltage is applied, the diodes D1 to D7 become conductive and the diodes D9 to D16 blocked. Thereby the clamp 161 with the clamp 166 and the clamp 162 connected to terminal 165. The result is' that the signals at the input and output terminals have mutually inverse waveforms.

So if there is an oscillation at the input terminals 161 and 162 according to 1b and an oscillation according to FIG. 1c is applied to the control terminals 163 and 164 an oscillation is obtained at the output terminals 165 and 166, as shown in FIG Fig. 1d is shown.

The waveform converter 35 according to FIG. 3 can be represented by the circles 11 to 16 are formed.

A preferred embodiment of the invention has been explained. Briefly summarized, the invention is characterized by the following features: 1) A DC level is superimposed on the television signal as shown in Fig. 1b is, the transmission signal of FIG. 1d being obtained without the amplitude im Compared to the television signal according to Fig. 1a excessively increase.

2) The degree of modulation of the modulator 18 according to FIG. 3 is greater than 100. The amplitude of the signal sent on the transmission line 9 is to be pressed down in such a way that the amplifier circuit is not overloaded.

3) Since there is no phase change component in the vicinity of the carrier is present, it is easily possible to select the synchronized demodulation carrier the transmitted signal. reproduce with a degree of modulation of more than 100%. This allows an economically favorable transmission system to be created.

Claims (4)

P a t e n t a n s p r ü c h e 1. television signal transmission system in which asymmetrical sidebands, obtained by removing part of one of the side ligaments, which generated by overmodulation of the transmission signal using a carrier whose frequency is greater than the maximum frequency of one to be transmitted Television signal, are transmitted together with the carrier, and in which on the Receiving side using the received asymmetrical sidebands and the carrier of a demodulation carrier, which consists of the received asymmetrical Sidebands and the received carrier is obtained, and in this way the Television signal is reproduced, characterized by a device (11 to 19) for generating the transmission signal (Fig. Ld) into which the television signal (Fig. 1a) is converted, which suppresses the low frequency component of the television signal; a device (31,32) for regenerating the demodulation carrier -by separation of the demodulation carrier together with the symmetrical part, the'asymmetrical Sidebands from the given asymmetrical sidebands and the carrier; one Means (3,4) for regenerating the transmission signal by demodulating the received asymmetrical sidebands and the carrier using the regenerated Demodulation carrier; and means (35) for regenerating the television signal from the transmission signal. 2. A television signal transmission system in which asymmetrical sidebands by removing a part of one of the side ligaments won obtained by overmodulating the transmission signal using a first carrier generated. whose frequency is greater than the maximum frequency of a television signal to be transmitted, transmitted together with the first carrier and at which on the receiving side the received asymmetrical sidebands and, the carriers are demodulated using a demodulation carrier, which is segregated from the received asymmetrical sidebands and the first carrier and in this way the television signal is reproduced by means for generating a heterodyne signal which corresponds to the television signal superimposed on a DC level; a device for generating the second carrier, its frequency equal to half the horizontal sync frequency of the television signal is; a ring modulator for generation. of the transfer sign, as, which under Using the second carrier amplitude modulates the beat signal; one Means for regenerating the demodulation carrier which is the first carrier along with the symmetrical part of the asymmetrical; Sidebands from the received asymmetrical sidebands and the first carrier segregates; a facility for Regenerating the transmission signal by demodulating the received asymmetric signals Sidebands and using the first carrier, the demodulation carrier; a unity for separating the second carrier from the demodulated transmission signal; and a ring modulator for obtaining the television signal by means of amplitude modulation of the transmission signal using the second carrier. 3. Transmitter for a television signal transmission system, marked by means for generating a - television signal to be transmitted; means for generating an overlay signal corresponding to the television signal superimposed a direct current component; means for generating the first Carrier whose frequency is higher than the maximum frequency of the television signal; -one : Means for generating the second carrier, the frequency of which is equal to half that Is the horizontal sync frequency of the television signal; a ring modulator for generating a transmission signal by ring amplitude modulation of the superimposition Si, gnals using d, it second vehicle; a facility to win both Sidebands by overmodulating the transmission signal using the first carrier; and means for sending out the first carrier and asymmetrical Sidebands ,. which are achieved in that a part d: it one of the two side bands of the first carrier is eliminated. 4. Receiving part for a television signal transmission system, characterized through a filter for generating one of the modulation carriers by segregating one first carrier together with a symmetrical part of asymmetrical side bands from the first carrier and the. asymmetrical sidebands by a transmitting part in which a carrier with a frequency greater than the maximum frequency of a television signal to be transmitted as the first carrier is used, a carrier whose frequency is equal to half the horizontal synchronization frequency of the television signal is, when the second carrier is used, the modulated oscillation, that by amplitude ring modulation by superimposing the television signal signal formed at a DC level using the second carrier is generated as a transmission signal is used, the transmission signal is overmodulated, with the two sidebands of the first carrier being achieved, and the asymmetrical sidebands by removing part of one of the Sidebands are obtained; a device for regenerating the transmission signal by demodulating the received asymmetrical sidebands and the first Carrier using the demodulation carrier; a device for secreting the second carrier from the demodulated transmission signal; and a ring modulator for amplitude modulation of the transmission signal using the second carrier, whereby the television signal is obtained. 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