DE3107737C2 - - Google Patents

Description

State of the art

The invention is based on a method according to the genus Main claim, which in principle from DE 28 21 183 B1 emerges.

To reduce color crosstalk, that is to say crosstalk of luminance signal components in the chromaticity channel (so-called cross-color interference) when transmitting a Color television signal, it is conceivable that in the frequency range of Color carrier lying, causing the interference Signal components of the luminance signal either already in the Reduce the amplitude of the luminance channel of a encoder or the interfering signals in the color channel in the decoder remove. It is already known in the luminance channel of a PAL coder to switch on a notch filter [(Schönfelder, H: Farbfernsehen 2, p. 111)]. By the Notch filter, however, is part of the focus information lost, so that the image resolution is reduced. Farther arises through  Group runtime error of overshoot notch filter in the luminance signal, which reduces the image quality. It was also found that the reducing effect of the notch filter for certain image templates is not sufficient.

An improvement comes with one in the UK Patent 8 59 081 method described achieved. In this process, components of the Luminance signals at the points in the frequency spectrum, which of the components added later of the modulated color beard signal are taken, lowered with a comb filter. Because comb filter but are very expensive and loss of resolution the image reproduction in the vertical direction this method has not proven itself in practice.

From DE 28 21 183 B1 a circuit arrangement for recognizing and possibly suppressing cross-color interference in color television signals, in particular in a coder, is already known, a filter in the luminance channel being able to be switched on by means of a control signal. The control signal is generated with the aid of a chain circuit consisting of a bandpass matched to the color carrier, an integrator adapted to the bandwidth of a picture element of the interference source and a delay chain storing a field of television, with a logic element connected only switching through if there are n successive lines of the Luminance signals are present as luminance components with frequency of the carrier. Due to the integrator, with which the color carrier-frequency luminance components are added up over the length of a picture element of the cross-color interference source in the order of 2 to 5 s, and the connected logic element with the above-mentioned mode of operation, the interference can only be suppressed imprecisely and broadband . This has the disadvantage that luminance signal components which do not have any interference may also be suppressed.

In addition, this circuit arrangement is because of the Use of a television field storing Runtime chain relatively complex.

The present invention is in contrast Task based on a method of the aforementioned Specify type for a decoder, which by exploitation of those already available for decoding Circuit parts much easier and also frequency selective works.

The solution to this problem is with the in the indicator of the main claim specified features achieved.

Advantages of the invention

The inventive method with the characteristic Features of claims 1 and 4 has the Advantage that cross-color interference in the decoder is optimal be eliminated. One can in the luminance channel Coders on a notch filter or similar measures for cross-color suppression, which means that full range of luminance signals guaranteed is. The invention has been particularly advantageous Procedures when playing complex Image templates, e.g. B. with moving, sloping Patterns, which causes flat cross-color interference be proven.

By the measures listed in the subclaims are advantageous further developments and improvements of the method specified in the main claim possible. In addition, are useful in further subclaims Circuits for performing the invention Procedure specified.

drawing

Exemplary embodiments for carrying out the invention Procedures are shown in the drawing and explained in more detail in the following description. In the same parts appearing in the figures are the same Provide reference numerals.

It shows

FIG. 1a is a block diagram for carrying out the process using a comb filter arrangement,

FIG. 1b is a vector diagram for explaining the block diagram of Fig. 1a,

FIG. 2a is a block diagram for carrying out the method of the invention using a standard PAL signal splitting,

Fig. 2b is a vector diagram for explaining the block diagram of Fig. 2a,

Fig. 3 is a block diagram for carrying out the method according to the invention for the NTSC system,

FIGS. 4 and 5 embodiments of the occurring in the preceding figures connected Tiefpaßglieder.

FIG. 1a shows the part of a comb filter PAL decoder which is important for the explanation of the invention. This essentially consists of a luminance and a color type channel. A color image signal (FBAS _PAL ) present at terminal 1 is separated into a signal that can be removed at terminal 2 for generating the luminance signal and two signals that can be removed at terminals 3 and 4 for generating the color-tone signal components U and V. This separation takes place with the aid of a delay line 6 , the delay time of which is exactly one line duration (64 μs), and an adder 7 , at whose inputs the undelayed signal c _{n + 1} (see FIG. 1b) and the signal c _n delayed by one line duration _galvanized (see Fig. 1b) of the previous line. These signals, which are also removable at terminals 3 and 4, are fed to a standard PAL signal splitter 8 , in which the carrier-frequency color difference signals U and V are generated. These color difference signals U and V are then each fed to a synchronous demodulator 9 or 10 , in which they are demodulated with the aid of the color carrier generated in the generator 11 . The color carrier generator 11 is synchronized with the color synchronizing signal present at terminal 12 . The video-frequency color difference signal (BY) can be removed at the output of the demodulator 9 and the video-frequency color difference signal (RY) can be taken off at the output of the demodulator 10 . Both signals still contain the interfering cross-color components.

To eliminate these cross-color interference, a circuit arrangement 13 is provided according to the invention for detecting the signal components causing cross-color interference, which essentially consists of the already existing delay line 6 , the adder 7 and a synchronous demodulator 14 . The synchronous demodulator 14 is supplied to a signal to be demodulated, which consists of the voltage applied to terminal 1, undelayed c _{n + 1} and the delayed through the delay line 6 by a line signal c _{n galv.} after additive superposition in the adder 7 . With an additive superimposition of the undelayed color signal, which is delayed by exactly one line period (64 µs), a complex color beard signal is created. According to FIG. 1b all color vectors in a straight line a come to lie. This special feature is PAL-specific and is caused by the line-by-line switchover of the V component. In order to demodulate this signal, the synchronous demodulator 14 is supplied with a carrier signal with the line b (in FIG. 1b) that is rotated by 90 ° with the aid of the phase rotation stage 15 with respect to the complex chromaticity signal lying on the line a . This synchronous demodulation only detects the signal components which lead to cross-color interference. This signal demodulated in this way is then passed via a low-pass filter 16 to a switching signal shaping stage 17 , in which it is converted into a switching signal sequence for controlling switches 18 and 19 . These switches 18 and 19 are each connected to a low-pass element 21, 22 and 23, 24 arranged in the chromaticity channel. If interference signals occur, switches 18 and 19 are closed, that is to say connected to ground, so that higher-frequency components in the (BY) and (RY) signals are suppressed. Accordingly, video-frequency color difference signals without cross-color interference can be removed at the output of the color type channel.

In Fig. 2, a PAL transit time decoder for signal splitting of the color beard signal is shown. The color-beard signal (CHROM _PAL ) is present at terminal 1 , which leads via a delay line 26 with a delay time τ _{H *} of 56 ns shorter than a line duration (63.943 μs) to a first input of an adder 27 and a subtractor 28 ( c _n in Fig _galv.. 2b). The undelayed signal c _{n + 1} at terminal 1 is fed to the second inputs of these stages 27 and 28 . A carrier-frequency color difference signal U or V can be removed at the output of stages 27 or 28 . These color difference signals are then demodulated in the synchronous demodulators 9 and 10 , so that the video-frequency color difference signals (BY) and (RX) can be removed at their outputs.

A circuit arrangement 13 is likewise provided for detecting the signal components causing cross-color interference, which essentially consists of the already existing parts 26, 27 and 28 as well as a phase shifter 29, 30 and the synchronous demodulator 14 . Between the outputs of stages 27 and 28 , the phase shifter with capacitor 29 and resistor 30 is arranged, to the output (connection point 31 ) of which the input of the synchronous demodulator 14 is connected. The output signals of stages 27 and 28 are rotated and added by the phase rotator 29, 30 by ± 45 ° in the color carrier phase, as a result of which the original U and V vectors are again in a phase direction ( a 'in Fig. 2b). The synchronous demodulation takes place with a carrier signal (direction b 'in Fig. 2b), which is rotated by 90 ° compared to a resulting signal (A') . The further processing of the signal which can be taken off at the output of the synchronous demodulator 14 is carried out as in the circuit according to FIG. 1.

The phase rotator 29, 30 can also be arranged between the inputs of the stages 27 and 28 , the connection point 31 also being connected to the input of the synchronous demodulator 14 .

A further possibility for interference signal detection is that the signals which can be taken off at the outputs of stages 27 and 28 are fed to further U and V demodulators which, however, are demodulated and combined synchronously with color carrier signals which are in quadrature with the chromaticity components.

In Fig. 3, the chrominance channel of an NTSC decoder is illustrated. As is known, the color image signal (FBAS _NTSC ) present at terminal 1 is fed to a bandpass 32 , the output of which is connected on the one hand to the synchronous demodulators 33 and 34 for the I or Q signal and on the other hand to the delay line 6 . The synchronous demodulators 33 and 34 (like those in the PAL decoders described above) generate video frequency color difference signals I and Q.

In the inventive circuit 13 for detecting leading to cross-color interference signal components the detachable from the bandpass filter 32 signal after delay is supplied to the other input of a multiplier 35 by one line in the delay line 6 to one input and the undelayed signal. At the output of stage 35 , the signal components representative of cross-color interference can be removed. These signal components are further processed as in the circuit according to FIG. 1.

FIG. 4 shows another embodiment of the switched low-pass elements 20 according to FIGS . 1 to 3. This consists of a low-pass filter 36 and a delay 37 corresponding to this and a corresponding delay. At the input terminal 38 there is one of the two low-pass filtered color difference signals. Depending on the occurrence or non-occurrence of the signals causing cross-color interference, the switch 39 is switched to the output of the low-pass filter 36 or to the output of the delay element 37 , so that an undisturbed signal can be removed at the output terminal 40 of the switched low-pass element is. Instead of the switch 39 , a cross-fading device can also be used.

In Fig. 5 a further embodiment is a switched daragestellt Tiefpaßgliedes. This essentially consists of the parallel connection of a notch filter 41 with a zero at approximately 0.5 MHz and a bandpass filter 42 complementary thereto. The output of the notch filter is connected to the one input of an adder 43 , the other input of which can optionally be connected to the output of the bandpass filter 42 via a switch 44 . The color difference signal present at the input terminal 45 , possibly with interference signals, is thus passed either only via the notch filter 41 (in the case of cross-color interference) or when the other input of the adder 43 is connected to the output of the bandpass filter 42 via both filters (in the case of signals without interference), so that an interference-free color difference signal can be removed at the output 46 of the adder 43 .

Claims (11)

1. A method for reducing interference by crosstalk of the luminance signal in the chrominance channel of a decoder, the interference signals contained in the chrominance signal being detected and converted into switching signals, with the aid of which low-pass elements in the chrominance channel can be switched on after demodulation, thereby reducing the interference signal components that occur in the useful signal are characterized in that for the detection of the interference signal components, the carrier-frequency color-beard signal delayed by one line duration is either added to the undelayed carrier-frequency color-beard signal of the following line and the signal thus obtained is synchronously demodulated with a carrier signal of a suitable phase or is multiplied by the undelayed carrier-frequency color-key signal of the following line . 2. The method according to claim 1, characterized in that in a PAL decoder that was delayed by a line, in Carried-frequency color beard signal contained in the color image signal first line and the instantaneous, in the color image signal included carrier frequency color beard signal of the second Line can be added and the generated carrier-frequency complex color-beard signal with a quadrature is synchronously demodulated to this lying carrier signal.   3. The method according to claim 1, characterized in that for detecting the interference signal components of an NTSC beard signal, the product of the delayed carrier frequency color beard signal of the first line and the undelayed carrier frequency beard signal of the second line is formed. 4. A method for reducing interference by crosstalk of the luminance signal in the chrominance channel of a decoder, the interference signals contained in the chrominance signal being detected and converted into switching signals, with the aid of which low-pass elements in the chrominance channel can be switched on after demodulation, thereby reducing the interference signal components that occur in the useful signal are characterized in that for the detection of the interference signal components of a PAL color-bearer signal, the carrier-frequency chrominance components ( U and V ) generated with the aid of the signal splitting of the color-bearer signal are added either after a phase shift of ± 45 ° and the thus obtained carrier-frequency complex color-bearer signal with a quadrature thereto lying carrier signal is synchronously demodulated or synchronized demodulated and combined with color carrier signals lying in quadrature with the chromaticity components ( U and V ). 5. The method according to claim 4, characterized in that for detecting the interference signal components delayed in the signal splitting using a delay line ( 26 ) with a delay differing by a quarter of a period of the color carrier and the undelayed carrier-frequency color-beard signal after phase rotation by ± 45 ° are added and the thus obtained carrier-frequency complex chrominance signal is synchronously demodulated with a carrier signal lying in quadrature. 6. A circuit for performing the method according to claim 2, characterized in that a delay line ( 6 ) is provided with a line delay, whose input fed with the color image signal (terminal 1 ) and whose output (terminal 4 ) to an input of an adder ( 7 ) are connected that the output of the adder is connected to one input of a synchronous demodulator ( 14 ), at the other input of which is the carrier signal lying in quadrature with the carrier-frequency chrominance signal, that the output of the synchronous demodulator via a low-pass filter ( 16 ) the input of a switching signal shaping stage ( 17 ) is connected, the output of which is led to the switchable low-pass elements ( 20 ) arranged in the video-frequency chrominance channel. 7. Circuit for carrying out the method according to claim 4, characterized in that a delay line ( 26 ) is provided with a delay time of 63.943 microseconds, the input ( 1 ) fed with the chrominance signal and the output thereof to an input of an adder ( 27 ). and a subtractor stage ( 28 ) are connected so that the output of the adder stage is connected to the output of the subtractor stage via a phase rotating element, in particular an RC element ( 29, 30 ), that the output ( 31 ) of the phase rotating element is connected to the input of a synchronous demodulator ( 14 ) is connected, at whose other input the carrier signal lying in quadrature with this carrier-frequency chrominance signal is present, that the output of the synchronous demodulator ( 14 ) is connected via a low-pass filter ( 16 ) to the input of a switching signal shaping stage ( 17 ), the output of which is connected to the im video-frequency chromaticity channel arranged switchable low-pass elements ( 20 ) is guided. 8. Circuit for carrying out the method according to claim 3 with a bandpass filter, at the input of which the color image signal is present and at the output of which the carrier-frequency chrominance signal can be removed, characterized in that the output of the bandpass filter ( 32 ) on the one hand via a delay line ( 6 ) with a Delay time of one line duration is connected to the one input and on the other hand directly to the other input of a multiplier stage ( 35 ), that its output is connected via a low pass filter ( 16 ) to the input of a switching signal shaping stage ( 17 ), the output of which is connected to the color frequency channel in the video frequency arranged switchable low-pass elements ( 20 ) is guided. 9. Circuit for performing the method according to claim 1, characterized in that the low-pass elements ( 20 ) each consist of an RC element ( 21, 22; 23, 24 ), the capacitors ( 22, 24 ) with the help of one each by the Switching signal controlled electronic switch ( 18, 19 ) can be switched to ground. 10. Circuit for performing the method according to claim 1, characterized in that the low-pass elements ( 20 ) consist of the parallel connection of a low-pass filter ( 36 ) with a cut-off frequency of approximately 0.5 MHz and a correspondingly adapted delay element ( 37 ), of which one each can be switched on by means of an electronic switch ( 39 ) controlled by the switching signal. 11. Circuit for performing the method according to claim 1, characterized in that the low-pass elements ( 20 ) from the parallel connection of a notch filter ( 41 ) with a zero at about 0.5 MHz and a bandpass filter ( 42 ) with a characteristic inverse of the notch filter exist, and that with the help of an electronic switch ( 44 ) controlled by the switching signal either the notch filter or both can be switched on via an adder ( 43 ).