DK145899B - CLUTCH TO DISCOVER A PAL COLOR REMOTE SIGNAL - Google Patents

Description

FAS

(19) DENMARK

lp (12) PUBLICATION MANUAL mi 145899 B

DIRECTORATE OF THE PATENT AND TRADEMARKET SYSTEM

(21) Application No. 4152/72 (51) lnt.CI.3 H 04 N 9/36 (22) Filing date 22 Aug. 1972 (24) Running day 22 Aug. 1972 (41) Aim. available Feb 24 1975 (44) Posted 5 Apr 1985 (86) International Application No. - (86) International Filing Day (85) Continuation Day - (62) Master Application No. -

(30) Priority Aug 25 1971 o 64201/71, JP

(71) Applicant SONY CORPORATION (SONY KABUSHIKIKAISHA), Tokyo, JP.

(72) Inventor Hideki Miura, JP: Klyoshl Yaraakawa, JP.

(74) Plenipotentiary Danish Patent Office ApS.

(54) Coupling for decoding a PAL color television signal.

The invention relates to a coupler for color television receivers for decoding a PAL color television signal, in which a line delay circuit and a line frequency switching circuit produce a modified color information signal, alternating between each one of the that from one

<D

(j) the reference signal generator is supplied with reference signals with a specific phase bearing, and a control means for generating the correct phase-j relationship between the color information component utilized and the demodulators' reference signals.

*

ISLAND

In the PAL system, a composite color television signal comprises two color signal components, usually as color difference signals containing color information, which are simultaneously encoded by cross-phase amplitude modulation with a suppressed carrier on a color-sub carrier within the video frequency band one of the color signal components is turned 180 ° for each line period. Ie the color television signal of the PAL system has two different types of oscillation alternating for successive line periods.

For decoding 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. However, these common systems decode the PAL signals with poor quality of the rendered image or greatly increase the complex nature of the system.

The description of Danish patent application No. 6612/70 discloses a new system for decoding the PAL signals in such a way that some of the limitations of the existing PAL decoding systems are avoided. The new system is theoretically also capable of receiving signals transmitted either by the PAL system or by the so-called NTSC system, although the current color subcarrier frequencies used in these two television systems make it difficult to take advantage of this latter property.

This known decoding system comprises an arrangement of switching circuits and associated delay means for receiving the incoming color information signal. This color information signal is first transmitted directly to demodulators in one line time interval, and then the same information is delayed one line time interval by the delay means again through the switching circuit to the demodulators in the next line time interval. The color information transmitted by the television station during the second line interval is not utilized by the receiver. The signal transmitted during the third line interval goes without delay to the demodulators and is repeated in delayed form during the time line of the fourth line. The result is that the color information signal, in which both modulation axes for two color signal components are held in a fixed phase relationship during all the line intervals, is received and supplied to the demodulators. In this case, it is necessary that the phases of the two modulation axes in the color information signal supplied to the demodulators for proper demodulation, respectively, have the same phases as the phases of the corresponding reference subcarrier signals coming from a local oscillator which is phase controlled. the composite color television signal contained color synchronization signal and is used for demodulation of the two color signal components. One of the ways to achieve this is to detect the phases of the color information signal modulation axes, in other words, to detect the type of the color information signal and to control the switching circuit which is blinded to receive the incoming color information signal so that the color information signal is transmitted to the correct type information signal. the demodulator, or controlling the phase of the reference subcarrier signal from the local oscillator.

The color information signal transmitted in accordance with the PAL system contains a color synchronization signal which takes two phase positions alternately offset 90 ° relative to the hand for each line interval. These two synchronization phases occur alternately according to the phase of the one modulation axis which is turned 180 ° for each line period.

The object of the present invention is to further develop said decoding system and to provide a coupling of the kind mentioned in the preamble which ensures in a circuitry simple manner the correct phase of the reference signals for the demodulation.

This is achieved with the coupling according to the invention, characterized in that the input of the reference signal generator is connected to the output of the line frequency switching circuit, and that the inputs of the control means are connected partly to the two inputs of the line frequency switching circuit and partly to at least one output of the reference signal generator.

In the coupling according to the invention, the phase of the color synchronization signal used to generate the reference signal in the reference signal generator always remains the same, since at the output of the line-frequency switching circuit only one line of the color information signal occurs. Therefore, the phase of the reference signal changes with the switching state of the line frequency switching circuit. Accordingly, it can be utilized to monitor the switching state of the line frequency switching circuit. For this reason, at least one output signal from the reference signal generator is used at the same time as the input signal for the controller.

Suitable embodiments of the invention are set forth in claims 2 to 5.

The invention will be explained in greater detail in the following by some embodiments with reference to the drawing, in which 1 and 2 are vector diagrams for explaining a color television signal according to the PAL system; 3 is a block diagram of an embodiment of the coupling according to the invention; FIG. 4 and 5 are vector diagrams to explain the coupling of FIG. 3, FIG. 6 is a block diagram of a modified form of the coupling of FIG. 3, FIG. 7 is a vector diagram for explaining the coupling of FIG. 6, FIG. 8, 10, 11, 12 and 13 block diagrams of various exemplary embodiments of the coupling according to the invention; 9 is a circuit diagram of a portion of the coupling of FIG. 8 and FIG. 14 and 15 are vector diagrams for explaining other modifications of the coupling according to the invention.

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 relationship is shown in FIG. 1. One of the color information components, Εβ-Εγ, contains information about blue components in the television image. The other, Er-Ey, contains information related to red components. Both of these color information components are modulated on the same carrier or, more specifically, the same sub carrier, but the modulation is performed separately and in such a way that, for a given time interval corresponding to one line nine of the color television image, the color information component Εβ-Εγ is modulated by the carrier against the f p Q.

In the same time interval, the second color information component Eg-Ey is modulated on the carrier with a modulation axis of phase 9? Q ~ 2 ', therefore, the color information component (Eg-Ey) representing blue information in the given line interval n is shown. as a horizontal arrow, and the red color information component (Eg-Ey) in the same line interval n is shown as a vertical arrow. The vector sum of these two color information components gives a resultant signal F, which is a complex voltage that can be determined by the expression (Eg-Ey) n + j (Eg-Ey) n, hereinafter referred to as the plus line signal.

The phase relationship of the following line n + 1 is also shown in FIG. 1. In this case, the color information component Eg-Ey on the carrier is also modulated with the axis of modulation with the phase fQ ^^> ° S accordingly, the color information component (Eg-Ey) n + y for the line n + 1 is shown in the same direction as the component (Eg-Ey) n · However, the color information component Εβ-Εγ is modulated in accordance with the PAL system on the carrier with a modulation axis having a phase γ? 0 - P0), ie phase inversion relative to the preceding line n, and therefore the color information component (ER-Ey) n + y for the line n + 1 is shown in the opposite direction of the component (ER-Ey) n. The signal Fn + y can therefore be determined by the expression (Eg-Ey) n + y - j (Eg-Ey) n + y, hereinafter referred to as the minus line signal.

The color information signal comprises a color synchronization signal which occupies different phases in the two signals FR and Fn + y. I.e. as shown in FIG. 2, the phase of the color synchronization signal in the signal Fn is 45 ° prior to the phase pQ> which is shown as B +, and the phase of the color synchronization signal in the signal Fn + y is 45 ° posterior to the phase pQ - ΠΤ '(= -fQ), which is shown such as B-.

In connection with FIG. 3, an embodiment of the invention will be explained. Reference numeral 1 denotes a bandpass amplifier which separates the color information signal from a composite color television signal. The color information signal thus separated is applied to a switching circuit 2 directly to its one input terminal and also to its other input terminal through a delay circuit 3 which delays an input signal with the time period of a horizontal line. The switching circuit 2 is switched by means of a switching signal from a multivibrator circuit 5, which is triggered for each line interval by a pulse 4 from a horizontal deflection circuit not shown, to the position shown in FIG. a plus line signal is applied but to the opposite position when a minus line signal is applied. The output of the switching circuit 2 is applied to a first and a second demodulator 6 and 7. signals F, F »n, Fn + 2, FTn + 2j · · · ·, repeating the same signals twice. In other words, the direct plus line signal and the delayed plus line signal to replace the minus line signal are supplied to demodulators 6 and 7. The labeled signals thus represent the signals supplied through the delay circuit 3. In addition, the output of the switching circuit 2> is provided with an opening circuit 8 to produce a color synchronization signal B + contained in the plus line signal, which is applied to a generator circuit 9 with a quartz crystal resonance circuit. The generator circuit 9 produces a carrier signal having the same phase as the color synchronization signal B +, which is then used to drive an oscillator 10 to produce a reference signal of the same phase. The reference signal from the oscillator 10 is applied to a phase shift circuit 11 which delays an input signal 45 ° · The phase shift circuit 11 emits as shown in FIG. 4 shows a reference signal S1 with a phase in line with the R-Y axis. The reference signal S- is applied to the first demodulator 6. The reference signal from the oscillator 10 is also applied to a phase shift circuit 12 which delays an input signal 135 ° to produce a reference signal S2 having a phase in line with the B-Y axis, as shown in FIG. 4 · The reference signal S2 is applied to the second demodulator 7 · In the demodulators 6 and 7, successively supplied plus-line signals are demodulated in these by the signals and S2 with "the same axes as the modulators, so that a first and a second predetermined demodulated color information signal are obtained from the demodulators.

However, there is a danger that for some reason the triggering of the multivibrator circuit 5 is reversed relative to its normal triggering of the supplied color information signal, and that the switching circuit 2 is switched to the opposite position upon arrival of the plus line signal while switched to the FIG. 3 on the arrival of the minus line signal. In such a condition, only the same minus-line signals as the signals Fn + 1> Frn + 1, ..... are sequentially fed to the demodulators 6 and 7 through the switching circuit 2 in a twice repeated manner. In other words, the signals in the 7 1Λ 5 S 9 9 which the plus line signals are replaced by the minus signals a horizontal line's time period prior to them, are then applied to the demodulators 6 and 7. In this case, a color synchronization signal B- is obtained in the minus line signal. the opening circuit 8, and therefore a reference signal with the same phase is output from the oscillator 10. This results, as shown in FIG. 5, a reference signal with the phase aligned with the - (B-Y) axis is applied to the demodulator 6, while a reference signal with the phase aligned with the R-I axis is applied to the demodulator 7. The demodulators 6 and 7 cannot output the desired demodulated color information signals.

To avoid this disadvantage, the color information signal from the band-pass amplifier 1, as shown in FIG. 3, supplied with a third demodulator 13; and the color information signal from the delay circuit 3 is applied to a fourth demodulator 14. The demodulators 13 and 14 are also fed to the reference signal from the phase shift circuit 12 for demodulation of the color information signals. The demodulated outputs of the demodulators 13 and 14 are applied to a comparison circuit 15 and, for example, subtracted therein. The subtracted output signal from comparison circuit A 15 is applied to a generator circuit 16 which produces a control signal when the comparator circuit 15 outputs a predetermined output signal. The control signal is supplied to the multivibrator circuit 5.

When the demodulator 13 is applied to the plus line signal, the demodulator 14 is applied to the minus signal a line period prior to the plus line signal. Conversely, if demodulator 13 is applied to the minus signal, demodulator 14 is applied to the plus line signal a line period prior to the minus signal.

Since successive plus and minus line signals are approximately of the same amplitude and symmetric in phase with respect to the BY axis, demodulators 13 and 14 in the case where switching circuit 2 is in its proper position to supply demodulators 6 and 7 plus line signal, and the phase shift circuit 12 generates the reference signal Sg with a phase in line with the BY axis, and the reference signal Sg is applied to demodulators 13 and 14, generating demodulated outputs which are similar in amplitude and polarity, with the result that the comparison circuit 15 or subtraction circuit does not produce the signal. In this case, the generator circuit 8 also generates no control signal, so that the multi-vibrator circuit 5 keeps its trigger unchanged and keeps the switching circuit 2 in proper condition. This results in demodulators 6 and 7 continuing to output the desired demodulated color information signals.

In the case where the switching circuit 2 is switched to an incorrect: state and sequentially delivers minus signals to the demodulators. 6 and 7j and the phase shift circuit 12 generates the reference signal with the phase in line with the EY axis applied to demodulators 13 and 11 to obtain demodulation, demodulators 13 and 11 will always output signals which are equal in amplitude, but opposite, in polarity. Consequently, if the comparison circuit 15 is designed such that the input signal is subtracted from the second input signal, it will produce an output signal which is reversed in polarity at each line period. When such an output signal is applied to the generator circuit 16, it will produce a control signal. If the multivibrator circuit is triggered opposite when it receives the control signal, the switching circuit 2 immediately switches to its proper state with the result that the demodulators 6 and 7 produce the desired demodulated color information signals.

Furthermore, it is possible to make use of the phase shift circuit 12 to supply the demodulators 13 and 14 with reference signals which deviate from 180 ° in phase from the signals Sg or S1.

The reference signal or or reference signals that deviate 180 ° in phase from these may be supplied to demodulators 13 and 14. However, in contrast to the former cases, demodulators 13 and 14, when the switching circuit 2 is in its proper position, . the modulators 6 and 7 are periodically fed to the plus line signal, and demodulators 13 and 14 are applied to signal S1 or signal 180 ° offset therefrom as reference signal for demodulation, producing demodulated outputs which are equal in amplitude but of opposite polarity. Similarly, if the switching circuit 2 is changed to the wrong position, the demodulators 13 and 14 will supply the minus line signal and the demodulators 13 and 14 are applied to the signal or 180 ° from this offset signal as the reference signal for demodulation. demodulated signals, 9 145899 which are similar in amplitude and polarity. In this case, the comparison circuit 15 must therefore be designed to add the demodulated output signals from the demodulators 13 and 14, so that when the switching circuit 2 is in its wrong position, the comparison circuit 15 produces a predetermined output signal, thereby allowing the generator circuit 16 to produce the signal.

Furthermore, one of the demodulators 13 and 14 may be supplied with the reference signal Sg or from the phase shift circuit 12, while the other demodulator may be supplied with signals displaced 1B0 ° in phase from signal S2 or S1, and the comparison circuit 15 may add the output signals from demodulators 13 and 14, or one of the demodulators 13 and 14 may be supplied with the reference signal S1 or from the phase shift circuit 11, while the other demodulator may be supplied phase-shifted from the signals or by lBO °, and the comparison circuit 15 may subtract the demodulated output signals 13 and 14 · In the example of FIG. 3, the demodulators 13 and 14 are supplied with the signal containing the color synchronization signal, but it is also possible to supply. the demodulators signal without the color sync signal.

Furthermore, since the color synchronization signal B + in the plus line signal and the color synchronization signal B- in the minus line signal are symmetrical with respect to the axis - (B-Y), the demodulation can be performed by applying only the color synchronization signal to the demodulators 13 and 14 · In the example in fig. 6, where similar reference numerals indicate similar elements as in FIG. 3, the color information signal from the band-pass amplifier 1 and the color information signal from the delay circuit 3 are both applied to an addition circuit 17 which then adds the color information signals. The output of the addition circuit 17 is applied to a demodulator 1B, which also receives the reference signal from the phase shift circuit 12 for performing demodulation. The demodulated output signal is applied to a generator circuit 19 which generates a control signal when the demodulated output signal from demodulator 1B is substantially equal to 0. The output or control signal from generator circuit 19 is then supplied to the multivibrator circuit 5.

In the example of FIG. 6, successive plus line and minus line signals are always added in the addition circuit 17. Since successive plus and minus lines in this case are similar in amplitude and symmetric in phase with respect to axis B-Y, as shown in FIG. 7, a signal is always obtained with the phase coinciding with the axis B-Y from the addition circuit 17, which is then applied to the demodulator 18.

Therefore, in the case where the switching circuit 2 is operating properly so that the demodulators 6 and 7 are supplied with the plus line signal and the demodulator 1fi is supplied with the reference signal S2 with the phase coinciding with the axis B-Y of the phase shift circuit 12, the demodulator 18 therefore always produces a positive demodulated signal. Therefore, if the generator circuit 19 is designed to produce no control signal when a positive-demodulated signal is applied, the multivibrator circuit 5 maintains its function and maintains the switching circuit 2 in its proper state with the result that predetermined, color-modulated color information from demodulators 6 and 7 is obtained. .

On the other hand, if the switching circuit 2 is changed to its wrong state so that the demodulators 6 and 7 are applied to the minus line signal and the demodulator 1a from the phase shift circuit is applied to the reference signal with the phase coinciding with the axis R-Y, then the demodulator 18 produces no output signal. If the generator circuit 19 can produce a control signal when no signal is applied, and the multivibrator circuit 5 is triggered with the control signal, the multivibrator circuit 5 will act opposite and cause switching circuit 2 in proper condition with the result that the demodulators 6 and 7 deliver the predetermined demodulated color information signals.

However, it may also be possible for the demodulator 18 to receive signals that phase in phase deviate from the reference signal Sg or by £ 0 °, or that the demodulator 18, if the generator circuit 19 produces a control signal, when the demodulator IS produces a positive or negative demodulated output signal may be supplied to the reference signals S1 or from the phase shift circuit 11 or signals that are phase offset 180 ° from these.

145899 11

Further, it may also be possible for the addition circuit 17 to be supplied with color information signals from which the color synchronization signals have been removed, or that only the color synchronization signals are added, since the signal added by the color synchronization signal B + in the minus signal signal and the color line signal and the color line signal and the color line signal and the color line signal as the axis - (BY).

FIG. 8, 10, 11, 12 and 13 show other exemplary embodiments of the present invention in which means are provided for increasing the sensitivity of the one in the examples of FIG. 3 and 6 used to detect that the switching circuit 2 is in the wrong state. In other words, when the switching circuit is brought to the wrong state, this state is detected flawlessly and a control signal is generated regardless of the content of the information and the magnitude of the color information signals amplitude. In these figures, the same reference numerals as in FIG. 3 and 6, similar elements, and their description has been omitted for brevity. B, the output of the demodulator 13 which demodulates the color information signal of the bandpass amplifier 1 and the output of the demodulator 14 which demodulates the color information signal passed through the delay circuit is applied to both an addition circuit 20 and a subtractor output signal 14. the addition circuit 20, whose output signal is applied to a detector circuit 21. The detector circuit 21 performs envelope detection of the input signal. The output of detector circuit 21 is then applied through an DC amplifier 22 to an input terminal of a differential amplifier 23. Subtraction circuit 25 subtracts the demodulated output signal from e.g. the demodulator 14 from the demodulated output of the demodulator 13. The subtracted output of the subtraction circuit 24 is applied to a detector circuit 25 which also performs envelope detection of the input signal. The output of the detector circuit 25 is applied through a DC amplifier 26 to the second input terminal of the differential amplifier 23. The output of the differential amplifier 23 is applied to a generator circuit 27 for generating a control signal when differential amplifier 12 produces a predetermined signal 23. The control signal is then applied to the multivibrator circuit 5 to control its function.

An example of the portion comprising differential amplifier 23 and generator circuit 27 will now be described with reference to FIG. 9 · In the example of FIG. 9, the output of the DC amplifier 22 is applied to the base of a transistor 28 which is one of the transistors of the differential amplifier 23, while the output of the DC amplifier 26 is applied to the base of another transistor 29 of the differential amplifier 23. The collector of the transistor 28 is connected to a resistor 30. a transistor 31, while the collector of the transistor 29 is connected through an output diode 32 to the base of the transistor-31. The signal Vs for vertical synchronization is applied through a resistor 33 the collector of the transistor 31, whose collector output signal is differentiated by a differentiation circuit 34. differential output signal is applied to the base of a transistor 35, whose collector output signal is supplied to the multivibrator circuit 5 through a diode 36.

In case the plus line signal is periodically applied to the demodulators 6 and 7 when the switching circuit 2 is functioning properly and the reference signal Sg with the phase coincides with the axis B-I of the phase shift circuit 12, as described in connection with FIG. 3, if demodulators 13 and 14 are applied, demodulators 13 and 14 will thus always produce demodulated outputs which are equal in amplitude and of the same polarity. As a result, in this case, the addition circuit 20 will always produce a predetermined output signal, while the subtraction circuit 24 produces no output signal. Therefore, the output of the addition circuit 20 is envelope-detected in the detector circuit 21 and supplied through the DC 22 base of the transistor 28 of the differential amplifier 23 as a positive DC voltage while no positive voltage is applied to the base of the second transistor 29 of the differential amplifier 29. In this case, the transistor 31 in the generator circuit 27 is consequently made conductive, and the signal Vs for vertical synchronization passes through the collector-emitter line of the transistor 31 to the frame, so that the transistor 35 is not supplied with any output voltage from the differentiation circuit 34, which therefore generates some control signal on its collector.

As a result, the multivibrator circuit 5 retains its previous function, and the switching circuit 2 is therefore kept in its proper function so that demodulators 6 and 7 deliver predetermined demodulated color information signals.

However, if the demodulators 6 and 7 are periodically applied to the minus signal when the switching circuit 2 is changed to incorrect function, the phase shift circuit 12 produces the reference signal with the phase coinciding with the axis R-Y, as mentioned in connection with FIG. 3 and 6, and the reference signal is applied to demodulators 13 and 14 which produce demodulated outputs which are equal in amplitude but of opposite polarity. Accordingly, in this case, the addition circuit 20 does not output any output signal, while the subtraction circuit 24 outputs signals of opposite polarity for each horizontal period. As a result, the DC amplifier 22 does not output to the transistor 28 in the differential amplifier 23, but the DC 26 provides a positive DC signal to the second transistor 29 in the differential amplifier 23 and makes the transistor 31 in the generator circuit 27 non-conductor. Accordingly, the vertical synchronization signal Vs applied to the transistor 31 is differentiated by the differentiation circuit. 34} and transistor 35 are made conductive by the positive polarity of the differential output signal and output a control signal 37 from the collector. The control signal is then supplied through the diode 36 multivibrator circuit 5 to change its triggering. As a result, the switching circuit 2 immediately returns to its proper function, and the demodulators 6 and 7 output the predetermined color information signals.

In the example of FIG. 10, the color information signals from the bandpass amplifier 1 and from the delay circuit 3 are added to the addition circuit 20 but subtracted into the subtraction circuit 24 · The output signals from the addition and subtraction circuits 20 and 24 are demodulated in the demodulator 12 and 13 . The demodulated outputs are detected by the detector circuits 21 and 25. The outputs of the detector circuits 21 and 25 are processed as in the previous case, so as to understand that the example of FIG. 10 performs the same function as the example of FIG. 8th

Although the added and subtracted output signals of the above examples are obtained by an addition and a subtraction circuit 20 and 24 and then compared in the differential amplifier 23, if signals which are phase-shifted 90 ° can be used as reference signals for the demodulators 13 and 14 relative to each other, to detect the function of the switching circuit 2, two added output signals or two subtracted output signals are obtained, which are then compared in the differential amplifier 23 *

FIG. 11 shows an example of this case. In this example there are four demodulators 3δ to 41 · The color information signal from the band-pass amplifier 1 is applied to the demodulators 38 and 40, while the color information signal passed through the delay circuit 3 is applied to the demodulators 39 and 41 · The demodulators 38 and 39 are supplied with the reference signal from the phase offset 12. demodulators 40 and 41 are fed to the reference signal from the phase shift circuit 11 which is offset 90 ° in phase from the aforementioned. The demodulated output signals from demodulators 38 and 39 are applied to an additional circuit 42, whose output signal is applied to the detector circuit 21, while the demodulated output signals from demodulators 40 and 41 are applied to an additional circuit 43, whose output signal is applied to the detector circuit 25, 25 and then treating them are essentially the same as described above.

In this example, if the plus line signal is applied to the demodulators 6 and 7, when the switching circuit 2 has its proper function, the demodulators 38 and 39 are applied to the reference signal Sg with the phase coinciding with the BY axis of the phase shift circuit 12, and demodulators 40 and 41 are applied to the reference signal S coincide with the RY axis of the phase shift circuit 11, therefore demodulators 38 and 39 will always produce demodulated outputs equal in amplitude and of the same polarity, while demodulators 40 and 41 will always produce demodulated outputs equal in amplitude but opposite in polarity. Accordingly, in this case, the addition circuit 42 will always produce a predetermined output signal, but the second addition circuit 43 produces no output signal. As a result, the multivibrator circuit 5 will retain its triggering function to keep the switching circuit 2 in its proper state, as in the previous case.

On the other hand, if the demodulators 6 and 7 are fed to the minus line signal when the switching circuit 2 is changed to its wrong function, the phase shift circuit 12 produces the reference signal with the phase coinciding with the RY axis, which is then applied to the demodulators 38 and 39, and the phase shift circuit 11 signal coincide with the - (BY) axis, which is then applied to demodulators 40 and 41, so that demodulators 3¾ and 39 output the demodulated output signal in amplitude but of opposite polarity, while demodulators 40 and 41 output demodulated output signals in amplitude and of the same polarity. unlike the previous one. Accordingly, in this case, the addition circuit 42 will not produce any output signal, but the second addition circuit 43 will always produce the predetermined output signal with the result that the multivibrator circuit 5 is applied to the control signal which reverses its triggering function to bring the switching circuit 2 to its proper state.

FIG. 12 shows a modification of the example of FIG. 11. In this example, the color information signals from the band-pass amplifier 1 and from the delay circuit 3 are applied to the addition circuits 42 and 43, respectively. ♦ the detector circuit 21. At the same time, the output of the addition circuit 43 is applied to a demodulator 45 which demodulates this with the reference signal from the phase shift circuit 11, the demodulated output of the demodulator 45 being applied to the detector circuit 25. .

It will therefore be clear that the function of this example will be the same as in the example of FIG. 11th

FIG. 13 shows another modification of the example of FIG. 11, in which there are subtraction circuits 46 and 47 in place of addition circuits 42 and 43 in Figs. 11 and 12. Subtraction circuit 46 subtracts e.g. the demodulated output of the demodulator 39 from the output of the demodulator 38, and its output is applied to the detector circuit 21, while the subtraction circuit 47 subtracts e.g. the demodulated output of the demodulator 41 from the output of demodulator 40, and its output signal is applied to the detector circuit 25.

With such a circuit design, demodulators 3 # ° g 39, if the coupling circuit 2 is in its proper state, will always produce demodulated outputs which are similar in amplitude and of the same polarity, and demodulators 40 and 41 will always produce demodulated outputs which are the same in amplitude, but of opposite polarity, which is why the subtraction circuit 46 does not produce any output signal, but the second subtraction circuit 47 produces an output signal which changes its polarity for each horizontal period. On the other hand, if the switching circuit 2 is changed to its wrong state, the demodulators 3S and 39 produce demodulated outputs which are similar in amplitude but opposite in polarity, and demodulators 40 and 41 produce demodulated outputs which are similar in amplitude and of the same polarity 46 produces an output signal which changes its polarity for each horizontal period, while the subtraction circuit 47 produces no output signal.

If the circuit of FIG. 9 is used in the example of FIG. 13 as part of the differential amplifier 23 and the generator circuit 27, the output voltage of the DC amplifier 22 is accordingly applied to the transistor 29 of the differential amplifier 23, while the output voltage of the DC amplifier 26 is applied to the transistor 28 of the differential amplifier 23. The example in FIG. 13 can thus perform the same function as in the previous examples.

Of course, it is also possible to use subtraction circuits instead of addition circuits 42 and 43 in the example of FIG. 12 with the same effect.

In the preceding examples, the multivibrator circuit 5 is controlled in such a way that the demodulators 6 and 7 are always supplied with the plus line signal, but the multivibrator circuit 5 can be controlled so that the demodulators 6 and 7 are supplied with the minus line signal. In this case, of course, it is necessary that the phase shift circuit 11 in phase is 45 ° ahead of the reference signal from the oscillator 10, while the phase shift circuit 12 in phase is 135 ° ahead of the reference signal from the oscillator 10, and when the switch circuit 2 is in its proper state and emits the minus line signal. to the demodulators 6 and 7, the demodulator 6 is supplied with a reference signal S 1, as shown in FIG. 14, with the phase coinciding with the - (R-Y) axis while supplying the demodulator 7 with a reference signal S 14, with the phase coinciding with the B-Y axis. Accordingly, if the switching circuit 2 is changed to its wrong state and outputs the plus line signal to demodulators 6 and 7, then demodulator 6 is supplied with a reference signal Sy with the phase coinciding with the - (B-Y) axis, as shown in FIG. 1, while the demodulator 7 is supplied with a reference signal Sg with the phase coinciding with the - (R-Y) axis as shown in FIG. 15-

If the switching circuit 2 is changed to its wrong state and outputs the plus line signal to demodulators 6 and 7, then demodulators 3 $, 39 and 44 are then applied to the reference signal S g with the phase coinciding with the - (RY) axis instead of the reference signal having the phase coinciding with RY. axis, or if the switching circuit 2 is in its proper state and delivers the minus signal to the demodulators 6 and 7, the demodulators 40, 41 and 45 are supplied with the phase signal corresponding to the - (RY) axis instead of the reference signal Sj axis. With this exception, this case is essentially the same in function as the previous ones, and the circuit works by always supplying demodulators 6 and 7 with the minus line signal.

In the present invention explained above, the predetermined demodulated color information signal is always obtained with a particularly simple circuit. Furthermore, if there is a color tone control and a color strength control between the switching circuit and the color tone and color strength demodulators 6 and 7, the signals according to the invention can always be applied to the demodulators and the addition and subtraction circuits for detection with equal levels, regardless of color tone and color. to really detect if the

Claims (2)

The circuit 2 is in its proper state or not, regardless of whether the hue and hue control is stable. Especially in the examples in FIG. δ to 13, to detect the state of the switching circuit 2, two comparative output voltages are obtained, which are further compared to provide a detection output voltage. However, one of the comparative output voltages is always 0 due to the fact that their signal components delete one another, so that comparison of the two output voltages with the color information and color synchronization signals contained in amplitude or phase is always detected, regardless of noise voltages. produce a control signal for real control. Since the switching circuit 2 is alternately passed by the original color information signal and the color information signal which is delayed by a horizontal period in relation to the original color information signal, the signal from the switching circuit 2 or the color synchronization switching signal of the switching mode switching subsystem or the addition of the demodulator switching in addition to the signal from the delay circuit 3 · The color information signal from the band-pass amplifier 1 can also be applied to the demodulator 7 as is. It is also to be understood that the present invention may be used in cases where the color signal is I and Q signals. Claims. A circuit for color television receivers for decoding a PAIL color television signal, wherein a line delay circuit and a line frequency switching circuit produce a modified color information signal, alternating one another from the original color information signal, including the two signal input signals, and their precursor components, reference signals are provided with a specific phase bearing, and a control means for producing the correct phase relationship between the color information component utilized and the demodulators reference signals, characterized in that the reference signal generator