DE1278494B - Circuit in a PAL color television receiver to correct the switching phase of the line-frequency switch - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. Cl .:

H04n

German class: 21 al-34/31

Number: 1278 494

File number: P 12 78 494.0-31 (T 34350)

Filing date: July 19, 1967

Opening day: September 26, 1968

In a PAL color television receiver, a line rate switch is required to adjust the phase to switch a color carrier line-frequency. The frequency of such a switch can be determined by line sync pulses or line retrace pulses are synchronized. In addition, the correct one must be Switching phase of this switch can be ensured.

To control the switching phase of the line switch from the transmitted signal, it is known (TeIefunken-Zeitung, 1964, Issue 2, pp. 112 to 115), the phase of the color sync signal sent at the beginning of each line to switch from line to line by 90 ° and this phase change in the receiver to use to synchronize the return switch.

It is known (German Auslegeschrift 1 240 919) »from the phase discriminator synchronizing the color subcarrier oscillator one due to the phase change of the color sync signal decrease the voltage fluctuating from line to line and with this voltage, possibly over half the line frequency tuned integrator to control the line rate switch. as

It is also known (radio technology, No. 5, 1966, p. 157), using a quartz filter from the frequency spectrum of the phase-switched color sync signal two against each other by half the line frequency to filter out offset vibrations, to mix them and through the mix a half-line frequency Gain voltage to control the switch.

It has also already been proposed by the inventor, the output voltage of the switch controlling generator and the output voltage of the synchronizing the color subcarrier oscillator Serving phase discriminator to compare in a phase comparison circuit and with the output voltage this phase comparison circuit only changes the frequency if the switch phase is incorrect or the phase of the generator that controls the switch and is synchronized by line-frequency pulses to redirect.

The invention is based on the object of a novel, particularly simple and trouble-free working Circuit for correcting the switching phase of the line-frequency switch in a PAL color television receiver to accomplish.

The invention is based on a circuit in a PAL color television receiver for correcting the switching phase of the line-frequency switch that controls the circuit in a PAL color television receiver
to correct the switching phase of the
line rate switch

Applicant:
Telefunken

Patentverwertungsgesellschaft mb H.,
7900 Ulm, Elisabethenstr, 3

Named as inventor:

Werner Henze, 3000 Hanover;

Burchard Schmidtmann, 3Ö01 Bennigsen;

Dipl.-Ing. Horst Wipperrnann, 3011 Pattensen -

Phase of a locally generated color carrier used to demodulate the color carrier-frequency signal switches from line to line by 180 ° and is synchronized by one of line-frequency pulses Generator is controlled, whereby the received color sync signal from line to line by 90 ° in the phase is switched.

In such a circuit, the invention consists in that the received color sync signal with the color carrier switched by 180 ° in the phase is combined in a stage whose during the duration of the color synchronization signal occurring, rectified output voltage depending on the correctness of the switching phase of the line-frequency switch as a manipulated variable the generator controls.

The invention is based on the knowledge that the phase of the switched color carrier is in one line can serve as a display for the respective switching phase of the switch and through the combination of this Color carrier with the color sync signal with incorrect and correct switching phase voltages of different sizes arise, of which the voltage in the wrong switching phase is used as a manipulated variable, the switching phase can correct.

809 618/371

The circuit according to the invention allows a simple circuit structure because for the synchronization circuit Any voltages or components that are already present in the receiver are exploited. The circuit is particularly immune to interference because in normal operation the generator only uses the line frequencies Pulses is synchronized. Such pulses can be used by the line deflection circuit as flyback pulses are derived and are not subject to interference. Only if the switching phase got wrong is, a manipulated variable acts on the generator for a short time, which corrects the switching phase again. The invention is applicable to both a PAL color television receiver with delay time signal splitting can also be used in a so-called simple PAL receiver without these components. The combination of the switched color carrier with the color sync signal can, for. B. in a linear adding stage, a phase comparison stage or an already existing demodulator for a color carrier frequency Signal.

The invention is explained in more detail below with reference to the drawing using three exemplary embodiments.

1, 4 and 7 show three different exemplary embodiments the invention;

FIGS. 2, 3 and 5, 6 and 8, 9 serve for explanation the operation of the circuits according to FIGS. 1, 4, 7.

In Fig. 1, the modulated color carrier F is fed from a terminal 1 to two synchronous demodulators 2 and 3, which deliver video-frequency color signals BY and RY to terminals 4, S. A color carrier with the constant phase of the axis BY is fed to the synchronous demodulator 2 via a line 6 from an oscillator 7, which is synchronized by a terminal 8 with a control voltage U _{R in a known manner.} At another output, the oscillator 7 supplies a color carrier with a phase shifted by 90 °, which is fed once directly and once via a 180 ° phase error 9 to two inputs of a line-frequency switch 10, the output of which is connected to the input of the synchronous demodulator 3. In accordance with the PAL switchover, the switch 10 supplies the synchronous demodulator 3 with a color carrier 17 with the phase of the RY axis and a phase switched by 180 ° from line to line. The switch 10 is controlled by a generator 11 which is synchronized by line-frequency pulses 12 from a terminal 13. The phase of the switching voltage generated in generator 11 for switch 10 can be either correct or incorrect.

To achieve the correct switching phase, according to the invention, the signal from terminal 1, the contains the phase-switched color sync signals 14, fed to an adder 15, which also The ink carrier 17 switched from line to line is fed via a line 16. the The output voltage of the adder 15 is connected to the input of a rectifier 18, which via a line 20 through the line-frequency pulses 12 only during the duration of the color sync signals 14 is effectively controlled and causes peak rectification. The output voltage of the Rectifier 18 acts via a filter element 19 with a time constant that is large compared to the line duration as a manipulated variable for changing the frequency or the phase on the generator 11. The mode of action this circuit is explained with reference to FIGS.

In Fig. 2 it is assumed that the generator 11 oscillates with the correct switching phase. The color sync signals 14 and the color carrier 17 then have the phase position shown in FIG. 2a and result in oscillation trains according to FIG. 2, b at the output of the adder stage 15. These are equal

J.0 directed and output a manipulated variable U _Sl according to FIG. 2, c to the generator 11. This manipulated variable is chosen so that it does not affect the generator 11 oscillating with the correct switching phase. For example, the manipulated variable serves as a preload of a tube in the generator 11, which enables the generator 11 to operate normally. The generator 11 is now further synchronized by the pulses 12 and continues to oscillate with a constant correct switching phase.

ao In Fig. 3 it is assumed that the switching phase is wrong. The color sync signal 14 and the

"'Tension members 17 then have the phase shown in FIG. 3, α , so that now at the output of the adder 15 oscillation trains according to FIG

As the generator 11 output a manipulated variable U ₃₂ . It can be seen that a smaller manipulated variable now reaches the generator 11. This is dimensioned so that it changes the phase or frequency of the switching voltage generated in the generator 11 for the switch 10. For example, the manipulated variable can severely detune the generator or also put it out of operation, e.g. B. by switching off the pulses 12 from the generator 11. This influencing the generator 11 changes the phase of the switching voltage for the switch 10, for example due to the phase change caused by the detuning or by stopping and restarting until the in the generator 11 generated switching voltage and the switch 10 again have the correct switching phase. If this is the case, the relationships according to FIG. 2 on. The manipulated variable coming from the filter element 19 thus only influences the generator 11 if, for whatever reason, its switching phase has become incorrect. As long as the switching phase is correct, the generator is synchronized by the interference-free line return pulses 12 and is not influenced at all by the color sync signal.

Fig. 4 shows a modification of the circuit according to Fig. 1. The phase-switched color carrier 17 at the input of the demodulator 3 and in the Phase constant color carriers on line 6 are, for. B. according to German patent specification 1183 121, in an adder 30 with such a phase and amplitude that the composite Oscillation 31 on line 16 corresponding to the phase switch of the color sync signal 14 is also switched and is out of phase with this color sync signal. Otherwise So this circuit works like the circuit in i

In FIG. 5 it is assumed that the generator 11 in FIG. 4 has the correct switching phase. The color carrier oscillation 31 formed in the adder 30 on the line 16 is always in phase opposition to the color sync signal 14, so that at the output of the adder 15 according to FIG. 5, b no voltage is generated and an external manipulated variable Z7 _{S t}

is given with the value zero. The generator 11! Is dimensioned in such a way that this manipulated variable U ₃₁ with the value zero has no influence on the generator 11, so that the generator 11 continues to oscillate with a constant correct switching phase, synchronized by the pulses 12.

If according to FIG. 6 the switching phase of the generator 11 and the switch 10 is incorrect, the oscillation 31 is shown in FIG. 6, α shifted by one line duration, so that oscillation trains according to FIG. 6, b occur which, after rectification and sieving, result in a manipulated variable U ₃₂ , which now has a considerable value. The manipulated variable U ₃₂ acts on the generator in such a way that it changes its frequency or phase or is stopped for a short time. The frequency change of the generator 11 or the shutdown and resumption of oscillation now takes place until the generator 11 and the switch 10 have the correct switching phase again and the relationships according to FIG. 5 occur.

Fig. 7 shows a circuit for delay time signal splitting of the PAL signal with a delay line 21, a phase rotator 22 and two Adding stages 23 and 24, which deliver color subcarrier-frequency color signals at their outputs, which are then converted into the demodulators 2, 3 again by means of a color carrier from the oscillator? be demodulated. According to the mode of operation of the runtime signal splitting circuit is only available at the output of the adder 24 the switched component of the burst signal 14, d. H. one from line to line by 180 ° Switched color sync signal oscillation. This is fed to the adder 15, which also The ink carrier 17 is supplied with approximately the same amplitude via an amplitude adjuster 25. at With the correct switching phase, the color sync signal 14 and the color carrier 17 have the same phase. The mode of action this circuit is explained with reference to FIGS. 8 and 9.

In Fig. 8 it is assumed that the switching phase of the generator 11 is correct. The color sync signal 14 and the reference carrier 17 then have the values shown in FIG. 5, a shown phase and cause at the input of the rectifier 18 oscillations according to FIG. 5, b, which feed a manipulated variable U ₃₁ to the generator 11 via the sieve element 19. This manipulated variable is again dimensioned so that it does not influence the correct switching phase of the generator 11, so that the generator 11 continues to oscillate with a constant correct switching phase.

In Fig. 9, the generator 11 has an incorrect switching phase, so that the color sync signal 14 and color carrier 17 at the input of the adder 15 are in phase opposition and cancel each other out. The filter element 19 then feeds a manipulated variable U _{3 2} with the value approximately zero to the generator 11. This manipulated variable influences the generator 11 in such a way that it changes its switching phase. For example, the manipulated variable i7 _{s 2} can detune the generator. As soon as the switching phase is correct again due to the frequency or phase migration of the generator 11, the relationships of F i g occur. 8 again, where the manipulated variable U ₃₁ then no longer acts on the generator 11, which is now oscillating correctly. The rectifier 18 is again conductive due to the pulses 12 only during the duration of the color sync signals, so that the mentioned comparison between the switched color carrier and the color sync signal only takes place during this duration. This keying can also take place in both supply lines to the adder 15 or by the fact that the adder 15 is only effectively controlled with the pulses 12 during the duration of the color sync signals.

Claims (10)

Patent claims: 1. Circuit in a PAL color television receiver for correcting the switching phase of the line-frequency switch, which switches the phase of a locally generated color carrier used to demodulate the color carrier-frequency signal from line to line by 180 ° and is controlled by a generator synchronized by line-frequency pulses, wherein the received color sync signal is switched from line to line by 90 ° in phase, characterized in that the received color sync signal (14) is combined with the color carrier (17) switched in phase by 180 ° in a stage (15) whose during the duration of the color sync signal (14) occurring, rectified output voltage depending on the correctness of the switching phase of the line-frequency switch (10) as a manipulated variable (U ₃₁ or U ₃₂ ) controls the generator (11). 2. A circuit according to claim 1, characterized in that in a receiver with PAL runtime signal splitting circuit, the color sync signal (14) from the output of the adder (24) of this circuit, which supplies the carrier-frequency color signal (RY) corresponding to the switched PAL modulation axis, is removed (Fig. 7). 3. A circuit according to claim 1, characterized in that the manipulated variable ([T _{5 2} ) detuned the generator (11). 4. A circuit according to claim 1, characterized in that the manipulated variable (Z7 _{S 2} ) stops the generator (11). 5. A circuit according to claim 1, characterized in that the rectifier (18) for generating the manipulated variable (U ₃₁ , U ₃₂ ) is effectively controlled only during the duration of the color sync signal (14). 6. A circuit according to claim 1, characterized in that the combination of the color sync signal (14) takes place with the color carrier (17) in a linear adding stage (15). 7. A circuit according to claim 1, characterized in that the combination of the color sync signal (14) takes place with the color carrier (17) in a phase comparison stage. 8. A circuit according to claim 1, characterized in that the combination of the color sync signal (14) with the color subcarrier (17) in a demodulator (2, 3) provided for a color subcarrier-frequency color signal. 9. A circuit according to claim 1, characterized in that the color carrier (17) switched in phase by 180 ° is combined with a color carrier of constant phase in a stage (30) in such a phase and amplitude ratio that a combined oscillation (31 in Fig. 5, d ) arises with the phase switch of the color sync signal (14) and that this Vibration is combined with the burst signal (14) in stage (15) (Fig. 4). 10. A circuit according to claim 9, characterized in that the phase between the burst signal (14) and the combined oscillation (31) is set so that the color sync signal (14) and combined oscillation (31) cancel each other out if the switching phase is correct and at wrong switching phase which affects the generator flow manipulated variable (U ₃₂ ) or vice versa (Fig. 4). Documents considered: German Auslegeschrift No. 1240 919; Telefunken-Zeitung, 1964, no. 2, pp. 112 to 115; Funkechnik, 1966, no. 5, p. 157; Funkschau, 1966, no. 24, pp. 749 to 751; radio mentor, 1965, no. 2, pp. 103 to 108. 1 sheet of drawings 809 618/371 9.68 © Bundesdruckerei Berlin