DK145710B - COUPLING FOR DECODING A COLOR INFORMATION SIGNAL COMPONENT - Google Patents

Description

145710 i

The invention relates to a coupling for decoding a color information signal component in a color television signal composed by the PAL system and having two demodulators for demodulating the color information signal component and two generator circuits for generating a first and a second reference sub-signal signal according to a different color signal signal according to the for two consecutive line periods of the color information signal component, and supplying this first and second reference subcarriers to the demodulators.

In the PAL system, a composite color television signal contains a color information component consisting of two color information signals, usually in the form of color difference signals, which are simultaneously encoded by cross-phase amplitude modulation with suppressed carrier wave on a color subcarrier within a video frequency band of the video frequency band. is turned 180 ° for each line period. Ie in the color information signal component of the PAL system, one of the color information signals, e.g. the color difference signal composed of a red information signal and a brightness signal emitted with the phase of the modulation axis reversed for each line period. Another of the color information signals, e.g. the color difference signal composed of a blue information signal and the brightness signal is emitted with the phase of the modulation axis fixed in each line period.

For demodulation of such a composite color television signal, various systems have been proposed in the past, e.g. the so-called simple PAL system and the standard PAL system. In these systems, each of the color information signals for decoding the color information signal component is demodulated by synchronously detecting it with a reference subcarrier signal of the same frequency as the frequency of the color subcarrier suppressed by the modulation of the color information signals. In this demodulation, it is necessary that the phase of the reference subcarrier signal is the same as the phase of the modulation axis and therefore the reference subcarrier signal for one of the color information signals emitted with the phase of the modulation axis alternating for each line period must be phased in accordance with the change in the phase of the modulation axis.

145710 2

For this phase reversal of the reference subcarrier, in the known demodulators, control systems must be provided for detecting the phase of the modulation axis in the modulated color information signal and for controlling the phase of the reference subcarrier so that it coincides with the phase of the modulation axis. Such control systems are complicated in structure and function, which is a disadvantage of the known demodulator systems.

The object of the present invention is to provide a coupling for decoding PAL color television signals, whereby, by simplified construction and function, a reference subcarrier is automatically generated for demodulation of the color information signal and with proper phase relationship to it without separate phase control.

This is achieved by the coupling according to the invention, characterized in that one of the generator circuits comprises a first switching circuit which alternately for each line period derives the color synchronization signal in its original phase and its inverted phase, one of the derived color synchronization signals phase controlled a reference subcarrier signal and a second switching circuit which alternately for each line period of the subcarrier auxiliary signal alternately derives the reference subcarrier signal in its original phase and its reverse phase.

Other advantages of the invention will become apparent from the following explanation with reference to the drawings, in which: FIG. 1 and 2 show vector diagrams for explaining PAL system color television signals; FIG. 3 is a block diagram of a color television receiver with an example of a coupling according to the invention; and FIG. 4A to 4F are vector diagrams for explaining the embodiment of the invention in FIG. Third

The distinctive feature of the PAL color television system lies in the phase relationship between the two color difference signals modulated on a common subcarrier to form the color information signal. This phase ratio 3 is shown in FIG. 1. One of the color difference signals Εβ-Ε ^ contains information about blue components in the television picture, while the other color difference signal ER-Ey contains information about red components. Both of these color difference signals Eg-Ey and ER-Ey are modulated on the same carrier, or more specifically the same sub-carrier, but the modulation is carried out separately and in such a way that in a certain time interval corresponding to one line nine the color television image, the color difference signal ER-Ey is modulated by the carrier. a modulation axis of phase 9q. In the same time interval, the second color difference signal Εβ-Εγ is modulated on the carrier by a modulation axis of the phase cpQ - That is why the color information component (ΕΒ ~ Εγ) η representing blue information in the given line interval n is shown as a horizontal arrow in FIG. . 1, and the red color information choron (E 1 -E 1) in the same line interval n is shown by a vertical arrow in FIG. 1. Vector addition of these two color information components (Εβ-Εγ) η ° 9 (ER-Ey) n gives a resultant signal F, as shown in FIG. 1, and which is one. complex voltage that can be determined by the expression (Εβ-Εγ) n + j (ER-Ey) n.

The phase relationship between the subsequent two color information components ^ FB_FY ^ n + l (Ε ^ ~ Εγ) η + ι ^ or the subsequent line n + 1 is also shown in FIG. 1. In this case, the color diffraction signal Eg-Ey on the carrier is also modulated by the modulation axis of the phase cpQ- -g, and hence the color information component (Eg-Ey) n + 1 for the line n + 1 is shown in the same direction as the color information component (Eg-Ey ). However, in accordance with the PAL system, the color diffraction signal Eg-Ey on the carrier is modulated by a modulation axis of the phase Φο ~ π (= -Φ0), i.e. phase inversion with respect to the previous line n, and therefore the color information component (Eg-Ey) n + ^ for the line n + l is shown in the opposite direction of the component (Eg-Ey) The resulting signal Fn + ^ for the two color information components (Eg-Ey ) n + ^ and (Eg-Ey) n + y can therefore be determined by the expression: (ΕΒ-Εγ) n + 1- j (% "Εγ) n + 1> which signal Fn + y is also shown in Fig. 1.

The color information signal contains a color synchronization signal. The color synchronization signal has different phases in the two signals Fn Fn + 1 * E, v * s * as shown in Fig * 2, the phase of the color synchronization signal in signal F is 45 ° prior to phase φ, which is shown by B +, 'and the phase of the color synchronization signal in the signal Fn + ^ is 45 backward for the phase φ -tt (= —cpQ), which is shown by B-. The color synchronization signals B + and B- will hereinafter be referred to as plus and minus color synchronization signals, respectively, and the signals Fn and Fn + ^ are referred to as plus and minus line signals, respectively.

FIG. 3 is a block diagram of a color television receiver in which an embodiment of a coupling according to the invention has been used. In FIG. 3, a composite color television signal is received by an antenna 1, converted to a mid-frequency signal by a tuning circuit 2, and then applied to an MF amplifier 3. An audio signal in the output of the MF amplifier 3 is supplied to a speaker 6 through an audio signal circuit 5, while a video signal is output from the MF amplifier 3 is detected by a video signal detector 4 · The output signal from the video signal detector 4 is applied to a brightness signal circuit 7 to output a brightness signal to its output terminal, which brightness signal is applied to a matrix circuit é. The output of the video signal detector 4 is also applied to a coupling 10. The coupling 10 has a bandpass amplifier or filter 11 to which the output signal of the video signal detector 4 is applied. The bandpass amplifier 11 outputs a color information signal from the output signal of the detector 4, and the color information signal is then applied to unmodified demodulators 12 and 13. the negative line signal alternately which color synchronization signals B + and B- are unchanged applied to one input terminal of a first switching circuit 15 and the second input terminal thereof through a phase transceiver 16. The first switching circuit 15 is switched for each horizontal line period by means of a switching motor signal from a switching switch signal. 17, which is alternated for each horizontal line period by an impulse from a horizontal deflection circuit not shown. The output of the first switching circuit 15 is applied to a carrier signal generator 1 $ with a crystal oscillation circuit to produce a carrier signal applied to a local oscillator 19 for its operation. The reference subcarrier signal appearing at the output of the local oscillator 19 is applied to one input terminal of another switching circuit 20 unchanged and its other input terminal through a single displacement circuit 21. The second switching circuit is alternately switched for each horizontal line period by the first switching cycle with 15 the switching signal from the multivibrator 17. The reference subcarrier signal from the second switching circuit 20 is applied to the demodulator 12. The output of the phase switch 16 is also applied to a carrier signal generator 22 to produce a carrier signal on its output terminal, which is applied to a local oscillator 23. The reference subcarrier signal emerging from the output of the local oscillator 23 is applied to the second demodulator 13. In this case, the two switching circuits 15 and 20 are switched in such a way that the second switching circuit 20 when the first switching circuit 15 is switched to the FIG. 3 is also switched to the position shown in FIG. 3.

If the first switching circuit 15 is switched to the one shown in FIG. 3, upon receiving the plus line signal, but to the opposite position upon receiving the minus line signal, alternately color synchronization signal B + is obtained in the plus line signal and a signal B- which is phase-turned relative to the color synchronization signal B- in the minus line signal. 4A. Accordingly, from the carrier signal generator ld a carrier signal is obtained with the phase between the phase of signals B + and B-, i.e. with the phase cpQ. This results in the output side of the local oscillator 19 generating a reference subcarrier signal with the same phase as the carrier signal from generator 1S, as shown in FIG. 4D. Since the second switching circuit 20, like the first switching circuit 15, is switched to the one shown in FIG. 3, when the plus line signal is applied to demodulators 12 and 13, but in the opposite position when the minus line signal is applied to demodulators 12 and 13, in this case the reference subcarrier signal with phase <PQ will be applied to demodulator 12 unchanged from local oscillator 19 when both plus line signal is applied. 12 and 13 · When the minus signal is applied to the demodulators 12 and 13, on the other hand, a reference subcarrier signal Sg with the phase -cpo, as shown in FIG. Z | E, which is obtained by applying the reference subcarrier signal to the phase shift circuit 21, the demodulator 12. At the same time, a phase signal B + produced by phase reversal of the color synchronization signal B + in the plus line signal is alternately obtained. 4C, and the signal B-, which is generated by phase reversal of the synchronization signal B- in the minus line signal, and which is also shown in FIG. 40, such that a carrier signal having a phase between the phases of the signals B + and 1-, i.e. the phase cpQ- is emitted by the carrier signal generator 22. Accordingly, from the local oscillator 23, a reference subcarrier signal with the same phase as the signal from the generator 22, which is. shown in FIG. I + F, which reference subcarrier signal is continuously applied to demodulator 13. The result is that the demodulators 12 and 13 are sequentially supplied with the reference subcarrier signals of a predetermined phase to provide predetermined, demodulated color information signals to demodulator signals. The demodulated color information signals from demodulators 12 and 13 are applied to the matrix circuit S, which then produces, for example, three primary color signals on its output terminals by matrix processing of the signals from demodulators 12 and 13 and from the brightness signal circuit 7. The primary color signals are then applied to a color signal for the reason that the switching function of the multivibrator 17 for the color synchronization signal from the opening circuit 14 is for some reason opposite to the above and the first switching circuit 1 $ is switched to the position opposite to that of FIG. 3 when the plus line signal is received and to the one shown in FIG. 3, when the minus line signal is received, from the first switching circuit, the signal B + is obtained with the phase opposite the phase of the color synchronization signal B + in the plus line signal and the color synchronization signal B- in the minus line signal alternately. Accordingly, from the carrier signal generator 18, a carrier signal is obtained with the phase between the phases of signals B + and B-, as shown in FIG. 4B, i.e. with the phase -coq, and therefore the reference subcarrier signal with the same phase as shown in FIG. 4E. When the plus line signal is applied to the demodulators 12 and 13, the second switching circuit is also switched to the position opposite to that shown in FIG. 3, like the first switching circuit 15, while the second switching circuit 20 is switched to the one in FIG. 3, when the minus line signal is applied to demodulators 12 and 13 · This causes the demodulator 12, when the plus line signal is applied to demodulators 12 and 13, to the reference subcarrier signal with phase φο, as shown in FIG. 4Β, and obtained by supplying the phase shift circuit 21 with the signal S ^ from the local oscillator 19. On the other hand, when the minus line signal is applied to the two demodulators 12 and 13, the reference subcarrier signal with phase -cpQ unchanged to the demodulator 12 is fed from the local oscillator 19. At the same time, the reference subcarrier signal S1 is generated with the phase cpQ- as shown in FIG.

4F, always at the output terminal of local oscillator 23 and always supplied to demodulator 13 as in the above case. The result is that the signal supplied to the demodulators periodically is always demodulated with reference subcarriers of predetermined phase to produce predetermined, demodulated color information signals on their output terminals.

With this invention explained above, regardless of how the function of the multivibrator 17 is changed, and consequently, regardless of whether the first and second switching circuits l1 and 20 are switched to the one in FIG. 3 or when the plus line signal or minus signal is applied to demodulators 12 and 13, the signal applied to demodulators 12 and 13 is always demodulated with reference subcarrier signals of predetermined phases to produce the predetermined demodulated color information signals.

The present invention can be adapted to a demodulation system, the so-called standard ONL system, in which respective demodulated color information signals are obtained based on signals produced in such a way that the original color information signal excreted by the bandpass amplifier and the signal obtained by delay the previous color information signal one horizontal line period, add or subtract. Since the demodulator 12 for demodulation of the red color difference signal with the inverted modulation axis is fed to the signal - ^ (Ε ^ -Εγ) obtained by the function "| (Fn _] _- Fnl upon receipt of the plus line signal F, but the signal which is obtained by function 2 <W1> 'upon receiving the minus signal Fn + Y> in this case it may be sufficient to change the second switching circuit 20 to the opposite of the above.

With the coupling described above according to the present invention, the signal to be demodulated can always be demodulated with the predetermined reference subcarrier signals simply by providing the two switching circuits which with the switching signal from a single multivibrator are synchronously switched for each horizontal line period , demodulated color information signals are really obtained from the demodulators.