DE2205839A1 - CIRCUIT ARRANGEMENT TO AVOID CROSS MODULATION INTERFERENCE IN A COLOR TELEVISION RECEIVER - Google Patents

Description

Circuit arrangement to avoid color cross-modulation interference in a color television receiver The invention relates to a circuit arrangement for Avoidance of color cross-modulation interference in a working according to the PAL method Color television receiving apparatus, with a chrominance signal of a signal splitting circuit is supplied, which supplies two color components, from which in the downstream Synchronous demodulators with the supply of the regenerated from the color synopsis signals Color carrier color difference signals are obtained.

As is known, in color television, the chrominance signal is in the luminance channel switched in. It follows that within the frequency range of the chrominance channel Luminance and chrominance components are included. In a color television receiver now penetrate into the chrominance channel lminance components on the display tube Cause color disturbances. This color disturbance is commonly called color cross modulation or Oross Color. Especially when transferring higher images As a result, the detail resolution can noticeably influence the ear dominance signal there are pronounced luminance components in the frequency range of the chrominance channel are. The visibility of these colored interfering components can be reduced if a suitable precision offset is selected for the bar carrier. So they are Effects of the spurious components in the chrominance channel from the bar transmission system addicted.

A quarter line offset was chosen for the PAL system, which means that the Spectrum of the chrominance signal around a quarter of the line frequency compared to the spectrum of the luminance signal is offset.

By using a delay line in the signal splitter circuit, in which the two color components are obtained from the chrominance signal As is well known, gammfilter curves (see: Telefunken-Zeitung 1965, Issue 1, pages 14-22, Fig. 16). The interference spectrum resulting from the Luminance components exist, lowered by 9 db, thereby reducing the influence of the spurious components is significantly displaced in the playback tube. Despite this lowering, the interference in the chrominance channel caused by the luminance signal is still relative big and noticeable.

The invention is therefore based on the object of a circuit arrangement to avoid this interference, assuming a circuit becomes, in which two color components from an ear dominance signal in a signal splitting circuit are obtained in synchronous demodulators by supplying the from the color synchronous signals regenerated color carrier are demodulated.

This object is achieved according to the invention in that the Synchronous demodulators delivered color difference signals in an adding stage geometric addition are assembled into signals, each perpendicular to the interference components of the luminance signal and that these signals on the one hand via a delay line and, on the other hand, fed directly to an electric switch are controlled by a Zeilensequentiel len switch so that in a downstream dematrix stage through geometric addition or subtraction of the signals free of the original color difference signals Interfering components develop.

A circuit arrangement according to the invention is particularly advantageous and simple build up if, according to a development of the invention, the line-sequential receiver-side Switching back one synchronous demodulator to obtain a color difference signal not applicable.

An example of the invention is shown below with the aid of a drawing explained in more detail.

1 shows a block diagram of a circuit according to the invention and FIG. 2 shows the associated diagrams of the signals in the coordinate system.

l The circuit shown in Fig. 1 consists of a known per se Signal splitting circuit for the chrominance signal, which results from a delay line 10, a phase shifter 11 and two adding stages 12, 13 composed. The two Adding stages 12, 13 are each followed by a synchronous demodulator 14, 15! tet, their Outputs are connected to a further adder 16. The adder 16 is now on the one hand via a second delay line 17 and on the other hand directly with Contacts of a cross switch 18 connected by a line-sequential Switch 19, for example the PAL switch, is controlled. Behind the trigger switch 19 is then followed by a dematrix stage 20. One from the burst color signals The generated color carrier FT is the synchronous demodulator 14 di-At md the synchronous demodulator 15 supplied via a phase element 21. In this circuit is the There is no line-sequential downshift before the synchronous demodulator 15.

A chrominance signal is applied to the input 22 of the signal splitting circuit F supplied. On the one hand, this chrominance signal F is sent directly to the adder 12 and on the other hand supplied via the phase shift element 11 to the adder 13. Farther the chrominance signal F arrives via the delay line 10 by one line duration delayed, to the two adding stages 12, 13, at their outputs the two color components arise that are fed to the synchronous demodulators 14, 15. In both Synchronous demodulators 14, 15 are supplied from the color sync signals regenerated color carrier FT the two color difference signals U and V obtained. Here the color difference signal arises at the output synchronous demodulator 14 in each line + U, while the color difference signal per line at the output of the synchronous demodulator 15 + V or -V occurs because the receiver-side, line-sequential downshift is not required is. These color difference signals U and V are fed to the adder 16, in to which they are added geometrically. This then results in line n the Parbdifferenzsignalen + U and + V a signal T which is perpendicular to the interference component Y 'is (Fig. 2), while in line n + 1 from the color difference signals + U and -V gives a signal S, which is also perpendicular to the interference component Y ' of the luminance signal Y stands. The two signals S and T, which are now free of interfering components Y 'of the luminance signal Y are now on the one hand directly on a contact of the cross switch 18 and on the other hand by a delay line 17 to one Line duration delayed on the other contact of the cross switch 18. This is ensures that a signal S and a signal T at the cross switch in each line 18 is present. Through the line sequential Control of the cross switch 18 only the signal reaches one input of the dematrix stage 20 in each row S, while only signal 2 reaches the other input. The originals Parb difference signals U and V are recovered in the dematrix stage, where the Color difference signal U by geometric addition of the signals S unS T and the color difference; signal V are created by geometrically subtracting signals S and 2. The color difference signals U and V, which are free from interference components Y 'of the luminance signal Y, are sent to the Outputs 23, 24 of the dematrix stage 20 and the subsequent stages of the not shown color channel of a color television receiving device supplied.

If the receiver-side, line-sequential downshift before the Synchronous demodulator 15-maintained for the color difference signal V is one Circuit according to the invention for avoiding gross color interference in a color television receiver also possible, but with a little more effort.

With this solution, it is then necessary to line-sequential switch back at a suitable point in the signal path to undo.

Claims (2)

Pat ent claims 1. Circuit arrangement to avoid Disturbances in a color television receiver operating according to the PAL method, a chrominance signal being fed to a signal splitting circuit which supplies two color components from which color difference signals are obtained in the downstream synchronous demodulators with the supply of the color carrier regenerated from the color sync signals, characterized in that the Color difference signals (U, V) delivered by the synchronous demodulators (14, 15) are combined in an adder (16) by geometric addition to form signals (S, T), each perpendicular to the interference components (Y ') of the luminance signal (x ) and that these signals (S, T) are fed on the one hand via a delay line (17) and on the other hand directly to a cross switch (18) which is controlled by a line-sequential switch (19) in such a way that in a downstream dematrix stage (20) geometric addition or Subtract the signals (S, T) the original color difference signals (U, V) free of interfering components (Y ') arise. 2. Circuit arrangement according to claim 1, characterized in that the receiver-side, line-sequential downshift before the one synchronous demodulator (15) for obtaining a color difference signal (V) is omitted.