DE1142010B - Receiver for a color television transmission system - Google Patents

Description

The invention relates to a receiver for a color television transmission system, the transmitted signal modulated onto a carrier wave contains a component which is named relates to the brightness of a scene, and further contains at least one component that consists of a There is subcarrier wave, which is modulated by at least one signal, which signal is on the The color content of the scene in question relates to the frequency band of the latter component with part of the frequency band of the first-mentioned component covers, and wherein the receiver contains two detectors to which the signal modulated on a carrier wave is fed and one of these detectors the component related to the brightness and the other of these detectors the component consisting of the modulated subcarrier wave is removed, which Receiver also has a suppression filter for at least partially suppressing the second component contained in the signal extracted from the first-mentioned detector.

In a known system of the type mentioned above, there is the first-mentioned component, the brightness signal, from a combination of three signals, the first of which relates to the green color component the scene, the second on the red color component of that scene and the third on the blue Color component of this scene relates.

The second component consists of a subcarrier shaft, which is modulated in quadrature (90 ° phase shift) by two signals which are also Combinations of the three signals are related to the green, red and blue color components, respectively relate to the scene, but which combinations are different from one another and also one Show difference with the combination in the brightness signal.

The receiver for the aforementioned system works as follows:

After demodulation, the brightness signal and the quadrature signal are available in the receiver modulated subcarrier wave. Using a process commonly referred to as synchronous detection This modulated subcarrier wave becomes the two combinations different from the brightness signal derived. These two combinations and the brightness signal finally become the derived three color signals to be fed to the reproducing device.

To achieve the two components, the carrier wave modulated with them can be used, which in practice is the receiver
for a color television broadcast system

Applicant:

NV Philips' Gloeilampenfabrieken,
Eindhoven (Netherlands)

Representative: Dipl.-Ing. E. Walther, patent attorney,
Hamburg 1, Mönckebergstr. 7th

Claimed priority:
Netherlands of September 18, 1959 (no.243 512)

Jan Maximiliaan Olthuis, Eindhoven (Netherlands), has been named as the inventor

is mostly returned to the intermediate frequency position, be fed to a single detector. The two components can be separated from each other by means of filter networks at the output of this detector be separated.

However, it is also known to act on a carrier wave to supply the modulated signal to two detector circuits; the output of one detector circuit becomes the first component related to the brightness and the output of the other detector circuit becomes the second component consisting of the subcarrier modulated by the color signals taken.

The purpose of using two detectors is to create the possibility of the relevant detector circuits better to adapt to the component, which the detector in question from one to the Must recover carrier wave modulated signal.

When using two detectors, the modulated signal on a carrier wave z. B. a Transformer fed, the secondary winding is coupled to a detector to which the first Component is removed while the primary winding is coupled to a detector to which the second component is removed in order to achieve a better separation of the two components.

It has also already been proposed that the signal modulated onto a carrier wave via separate Amplifier feed two detectors, one of these detectors again the first component and the second component is removed from the other of these detectors in order to detect the danger

209 750/72

avoid harmonics of the intermediate frequency image and sound carrier waves generated in such a detector on the last, the two Components common intermediate frequency amplifier section and feed back through the chassis and the wiring and also very disruptive signals from direct radiation in the antenna circuit of the Introduce the recipient.

As already noted, the signals to be supplied to the reproducing apparatus are made by combining the first component, the brightness signal, and that by synchronous demodulation from the second Component derived signals obtained. With regard to the fact that the frequency band of the second component coincides with part of the frequency band of the first component this second component, that is to say a modulated subcarrier wave, is still present in the brightness signal. In practice it has been shown to be desirable to include a suppression filter in the receiver, in order to at least partially suppress the second component in the brightness signal. In the known This suppression filter is located in the output of the video amplifier stage for receivers.

The usefulness of such a suppression filter follows for the following reasons: In the first place, the modulated subcarrier wave causes a noise pattern in the reproduced image. It is true that the frequency is this in the known systems Subcarrier wave chosen so that the influence of this pattern on the image quality is minimal, but already for this reason alone the presence of a suppression filter is desirable.

A second reason is that the non-linearity of the reproduction characteristics of the reproduction apparatus this device has a rectifying effect on the modulated present in the brightness signal Auxiliary carrier wave exerts. This effect causes a naturally undesirable increase in the Brightness in the reproduced image.

The influence of both mentioned effects is reduced by the application of a suppression filter in the The output of the video amplifier stage is significantly reduced.

The invention aims to make the interference suppressing effect of such a filter essential to enlarge.

The receiver according to the invention is characterized in that the suppression filter is between that point of the receiver where the two components modulated onto the carrier wave common channel divides into a channel to the detector circuit, which focuses on the brightness related component is removed, and a channel that leads to the Detektorkreds to which the is removed from the modulated subcarrier wave component, and the detector of the. first detector circuit is switched on.

The suppression range of the filter in the receiver according to the invention lies in terms of localization of the filter in the vicinity of the frequency modulated onto the carrier wave Subcarrier wave, in contrast to the suppression range of the filters in the known receivers, which is in the vicinity of the frequency of the subcarrier wave itself

The invention is based on the following findings.

The bandwidth of the suppression filter mentioned is chosen in practice so that an acceptable Compromise between the visibility of the reproduced image and its presence the modulated subcarrier wave in the luminance signal and the resulting phenomena the suppression necessarily also occurring loss of high frequencies in the brightness signal is achieved, which loss the sharpness of the ίο playback impaired. With the latter fact in mind, the whole is never modulated Subcarrier wave suppressed, rather the suppression is only for the subcarrier wave frequency practically completely, while the sidebands are only partially suppressed.

It could now be expected that, if nevertheless, the entire modulated subcarrier wave is suppressed an image would be generated that is completely free from the disturbing influences of the ao modulated subcarrier wave is, albeit a substantial part, of the higher frequencies of the brightness signal does not participate in the display of images.

It turns out, however, that in this case Image, however, an increase in brightness dependent on the modulated subcarrier wave can be perceived. The first finding on which the invention is based is that the detector is also a rectifying one Effect on the modulated subcarrier wave present in the brightness signal, what effect also cause an undesirable increase in the brightness in the reproduced image gives.

A second finding on which the invention is based is that in receivers where only a single detector is used to recover the brightness signal and the modulated subcarrier wave from the signal modulated onto a carrier wave is used, it is not possible to reduce the influence of the latter effect to suppress the second component in the signal modulated onto the carrier wave before it is detected, because in this case this second component is no longer or at least no longer at the detector output is present to a very lesser extent, but one such when two detectors are used Suppression can take place successfully in which the component related to the brightness delivering detector leading channel, thus reducing the influence of the last-mentioned effect can be reduced significantly without at the same time adversely affecting the second component as such will.

The invention is explained in more detail with reference to the figures of the drawing, for example. It shows 1 shows an embodiment of a receiver according to the invention;

2, 3 and 4 show individual parts of other embodiments of the receiver according to the invention. In Fig. 1, 1 denotes a well-suited antenna system for receiving one of the two mentioned Components modulated carrier wave. In addition, a second carrier wave is received, which is transmitted in the frequency or amplitude is modulated with a sound signal. The antenna system 1 is with a high frequency stage 2 and a mixer stage 3 coupled. The output signal of mixer 3 becomes an intermediate frequency stage 4 is supplied.

The last section of the intermediate frequency stage 4 is shown individually, similar to the two with this one Stage coupled detector circuits 5 and 15. Before these items embodying the invention will be explained in more detail, the general assembly and the mode of operation of the receiver will first be explained described in more detail.

The carrier wave modulated by the audio signal can be in the intermediate frequency stage 4 or in one

no additional suppression filter impairing the brightness signal in the video amplifier needs to be recorded for this sound carrier wave.

The output signal of the band filter 16 is fed to an amplifier 19 which, on the one hand, has a Isolation circuit 18, in which the synchronization signals for synchronous detection from the output signal of the Amplifier 19 can be recovered, and other-

the non-linear elements as detectors containing io side with two synchronous detectors 20 and 21 ver detector circuits 5 or 15 is bound by the television signal.

be separated, it does not matter whether the synchronizing signals for synchronous detection,

Differential carrier principle is used or not. In which occur at the output of the isolating circuit 18, in the illustrated embodiment, these are fed to an oscillator 10, at whose splitting off in the detector circuit 15. The sound carrier wave 15 output two voltages with the same frequencies is fed to the intermediate frequency stage 11, which occur, but whose phases are reversed 90 ° to each other with a tone detector 12 is coupled. That
The output signal of the detector 12 is via a
Low frequency amplifier 13 one or more
Speakers 14 supplied.

The transmitted television signal also contains the necessary synchronization signals, both for the sawtooth generators for horizontal and vertical deflection as well as for the oscillator that drives the Generates voltages that are necessary for synchronous detection. The synchronization signals for the horizontal and the vertical deflection are made in the separation circuit 7 from the output signal of a video amplifier stage 6, which is coupled to the demodulator 5.

The synchronization signals for the vertical deflection are sent to the device 8 for synchronization
of the sawtooth generator forming part of the same; the output currents of the device 8
are equal to the vertical 35 not shown in the figure,
deflection coils fed to the display tube. The outputs from 28 and 23 become one

The synchronizing pulses for the horizontal ab matrix network 25 are supplied from this deflection the device 9 for synchronous output signals three so-called color difference signals Sizing of a part of the same forming sawtooth forms. A color difference signal is a signal that is too generator fed; the output currents of the front 40 added to the brightness signal provides a signal that direction 9, the figure also does not refer to a specific color component of the depicted Horizontal deflection coils for the scene to be reproduced are fed into the output tube. The combination with the brightness signal takes place

The devices 8 and 9 also contain those in the example shown in the display tube any required flywheel switch- 45 26 itself. For this purpose, the output signal of the videogen, while, in addition, from the device 9 to the amplifier stage 6, i. H. the brightness signal, with negative

are shifted. These two voltages are also fed to the synchronous detectors 20 and 21, respectively.

It is assumed that the output signal of the detector 20 is the signal with the larger bandwidth (the I signal) and that the output signal of the detector 21 contains the signal with the smaller bandwidth (the Q signal).

The synchronous detector 20 is provided with a low-pass filter 22 with a relatively large bandwidth and the synchronous detector 21 is provided with a low-pass filter 23 with a relatively small bandwidth tied together.

In view of the fact that the filter 23 has a greater delay in going through this filter introduces outgoing signal as the filter 22, a delay line 28 is present in the output of the filter 22, which make this difference in delay

known way of the flyback of the line sawtooth generator a DC voltage can be obtained can, which can serve as high voltage for the display tube.

The output signal of the video amplifier stage 6 is also fed to a device 29, in FIG which a control voltage for automatic strength control is generated, which control voltage both the

tive polarity of the three interconnected cathodes 30 of those provided with three electron guns Dxei color tube 26 supplied. By also adding the output signals of the matrix 25 to the three control grids 31, 32 and 33 that are not connected to one another are supplied, are those of the electron guns generated electron bundles each with the sum of the brightness signal and a color

Intermediate frequency stage 4 as well as the high frequency 55 differential signal modulated.

stage 2 can be fed. In the known receivers, the message contains

The output signal of the detector circuit 15 is output circuit of the video amplifier stage 6 a suppression

on the one hand a band filter 16, which only the second kungsfilter, through which at least partially the second

Component lets through, apart of course components in the

is suppressed by the brightness signal occurring in the frequency range of this second component,

nent lying frequencies of the brightness signal, For the reasons mentioned above is in the

and on the other hand the audio intermediate frequency stage 11 to receiver according to the invention the suppression Sr-

guided. filter between that point of the recipient,

The removal of the differential carrier audio signal from where the two are modulated onto the carrier wave.

the detector for the second component has the 65 lated components in a common channel

Advantage that in the entrance of the detector for the Hellig channel to the detector circuit 5 and a channel to

Keitssignal the sound carrier is very strongly suppressed the detector circuit 15 separates, and the detector of the

can, so that turned on in the output of this detector or the first-mentioned circle.

The last section of the intermediate frequency stage 4 contains an amplifier tube 40, its output circuit the primary winding 41 of a transformer. 42 contains. The secondary winding 43 of this transformer 42 is connected to the detector circuit 5. The Elements 44 and 45 together with the transformer 42 form the band filter for the carrier wave modulated brightness signal; from the capacitors 46 and 47 and the coil 48

The elements 76 and 77 of the detector circuit 5 form with the transformer 74 a band filter, which is on the first component is matched; the elements 78, 79 and 80 form a series resonance circuit, the 5 is used to suppress the sound carrier wave in this detector circuit; 81 denotes the detector diode, and the capacitors 82 and 83 and the coil 84 'serve to suppress the harmonics of the intermediate frequency signal in the outcome of the mentioned

standing series resonance circuit forms the tone sub-detector circuit. The video amplifier is via a push feed; 49 denotes the detector diode, and delay line 85 with the connection point the elements 50, 51 and 52 form a filter for
Suppression of harmonics of the intermediate frequency

frequency signal in the output of the detector. In the

coil 84 and capacitor 83 are coupled. The delay line 85 again has the purpose of Delays in the demodulation products of the

The output of the detector 5 is directly a delay 15 modulated in quadrature subcarrier wave on the Einrungsleitung 53 introduced to compensate for the brightness signal output of the matrix network 25, The elements 86 and 87 of the detector circuit 15 are given a delay which is equal to the delay

tion, the output signals of the filter 23 and form with the transformer 75 a band filter that Delay line 28 are subject. The output is adapted to the second component; 88 entry signal the delay line 53 is the 20 records the detector diode of the detector circuit 15, Video amplifier 6 supplied. and capacitors 89 and 90 and coil 91

The one above the primary winding 41 of the transformer again serves to suppress the harmonics gate 42 occurring signal is via the coupling of the intermediate frequency signal. The connection point capacitor 54 is supplied to the detector circuit 15, that of the capacitor 90 and the coil 91 becomes the on-off the diode 55, the coil 56 and the elements 25 output signal for the band filter 16 and the Tonzwi-57, 58 and 59 consists of a filter for the frequency stage 11 taken again. Suppression of harmonics of the intermediate frequency - The point at which the two on the carrier

form quenzsignals. The output signal of the Detekwelle modulated components common Katorkreis 15 is on the one hand a band filter 16 in one to the detector circuit. 5 leading and on the other hand the audio intermediate frequency stage 11 30 channel and fed into one to the detector circuit 15, separates the channel is indicated in Fig. 2 by the point 92. According to the invention, the suppression filter of the secondary winding of the transformer 73 is zuzum Suppressing the second component in the HeI- forms. The filter to suppress the second ligkeitssignal between the point at which the component in the brightness signal needs in this The two grain trap modulated onto the carrier wave is not included in the detector circuit 5 ponenten common channel to be in a channel; in the figure this is from the one row Detector circuit 5 and in a channel to the de-resonance circuit forming elements 93, 94 and 95 detector circuit 15 separates, and the detector 49 of the circular filter into the output of the amplifier unit 5 switched on. The mentioned point is in the section 71 parallel to the primary winding of the trans embodiment of Fig. 1 by the primary 40 formator 74 added.

winding of the transformer 42 is formed. According to Fig. 1 The suppression filter can naturally also

the above-mentioned suppression filter is implemented by the in the input circuit of the amplifier section 71 from the capacitors 60 and 61 and the coil 62 are turned on. In Fig. 3, only those in between Series resonance circle formed. The compute frequency stage 4 represents is in the control grid sonance frequency this circle is equal to or almost 45 circle of the amplifier section 71 is a parallel resonance the frequency of the subcarrier wave in the twinned circuit made up of the capacitor 96 and the coil 97 central frequency position. As a result of the above sign-recorded. The mentioned circle is up again th coupling of the detector circuits 5 and 15 with the tuned a frequency that is the same or almost Intermediate frequency stage 4 is a reaction of equal to the frequency of the subcarrier wave in the intermediate suppression filter on the output signal of the 50's frequency position.

Intermediate frequency stage and thus to the input Da in the case described, the sections 71

signal of the detector circuit 15 largely avoided. and 72 are not mutually decoupled, can here Fig. 2 shows in detail the intermediate frequency not in parallel with the input terminals of the stage 4 and the detector circuits 5 and 15. In this section 71, a series resonance circuit is connected is the on the Zwisehen frequency carrier wave 55, since this is also parallel to the input of the modulated signal would be the section 72 via separate amplifier.

fed to two detectors. The penultimate section Fig. 4 finally shows an intermediate frequency

the intermediate frequency stage 4 contains an amplifier stage 4, in which the suppression filter in a tube 70, the output signal of which via a filter network negative feedback circuit of the amplifier section 71 Werk 73 is added to the control grids of two 60 connected in parallel. The filter will in this case Amplifier tubes 71 and 72 is supplied. The ver formed by the parallel resonance circuit, which consists of

a capacitor 98 and a coil 99 .

It should be noted that if the carrier wave modulated by the audio signal is not taken from the detector circuit 5 and, in the cases described with reference to FIGS. 2, 3 and 4, from the amplifier section 71 of the intermediate frequency stage 4
becomes, the suppression filter to suppress

stronger tube 71 is coupled to the detector circuit 5 via a transformer 74; the amplifier tube 72 is coupled to the detector circuit 15 via a transformer 75.

It will be evident that it may also be possible to use the output signal of mixer 3 to be fed directly to a separate amplifier.

the second component in the brightness signal can be assembled and dimensioned such that it can also suppress this carrier wave modulated by the audio signal.

Finally, it should be noted that if the transmitted signal contains more than one component consisting of a modulated subcarrier wave in a manner similar to that described above, Suppression filters attached to that other component or other components can be. In this case, of course, the various filters can be combined into a single filter be combined.

Claims (8)

PATENT CLAIMS: 1. Receiver for a color television transmission system, wherein the transmitted signal modulated on a carrier wave contains a component which essentially relates to the brightness of a scene and at least one component which consists of a subcarrier wave modulated by at least one signal, which Signal refers to the color content of the scene in question, the frequency band of the latter component coinciding with a part of the frequency band of the first-mentioned component, which receiver contains two detectors to which the signal modulated on a carrier wave is fed and one of these detectors which refers to the component relating to the brightness and the component consisting of a modulated subcarrier wave is removed from the other of these detectors, and a suppression filter is also provided by which at least partially the second component in the signal extracted from the first-mentioned detector is suppressed rd, characterized in that the suppression filter between that point of the receiver at which the channel common to the two components modulated on the carrier wave divides into a channel to the detector circuit, from which the component relating to the brightness is taken, and a channel the detector circuit from which the component consisting of a modulated subcarrier wave is taken and the detector of the first-mentioned circuit is switched on. 2. Receiver according to claim 1, characterized in that the suppression filter in the entrance of the first-mentioned circle is inserted. 3. Receiver according to claim 2, characterized in that the suppression filter as Series resonant circuit is formed. 4. Receiver according to claim 1, wherein the modulated onto a carrier wave signal via separate Amplifier stages are fed to the two detector circuits, characterized in that that the suppression filter is inserted in the amplifier stage which leads to the detector circuit leads from which the component relating to the brightness is taken. 5. Receiver according to claim 4, characterized in that the suppression filter as Series resonance circuit is placed parallel to the output circuit of the amplifier stage. 6. Receiver according to claim 4, characterized in that the suppression filter as The parallel resonance circuit is switched on in series with the output circuit of the amplifier stage. 7. Receiver according to claim 4, characterized in that the suppression filter as Parallel resonance circuit is inserted into a negative feedback circuit of the amplifier stage. 8. Receiver according to one of the preceding claims, characterized in that the The suppression filter also serves to at least partially reduce the amount modulated by the audio signal To suppress carrier wave in the signal that the detector circuit for which on the Brightness-related component is taken. Considered publications:
Proceedings of the IRE, March 1956, p. 300;
Radio & Television News, June 1954, p. 49, Fig. 8. 1 sheet of drawings © 209 750/72 12.62