DE1270600B - Circuit for correcting the switching phase of the line-frequency switch in a PAL color television receiver - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. Cl .:

H04n

German KL: 21 al-34/31

Number:
File number:
Registration date:
Display day:

P 12 70 600.2-31
7th August 1964
June 20, 1968

In a PAL color television receiver, a line rate switch is known to be required to to switch the phase of a color carrier frequency reference carrier or color signal from line to line by 180 °. Such a switch or a generator controlling this switch can be generated locally by line-frequency pulses, e.g. B. line retrace pulses are synchronized. In addition, the correct switching phase of the switch must be ensured or checked.

To set the correct switching phase of the switch, it is known (German Auslegeschrift 1164 466), the constant phase of the known in Way at the beginning of each line transmitted bursts after a certain number of To change fields temporarily. In the receiver it is then possible to compare the phases with a reference carrier constant phase, a pulse is obtained from the brief phase change and used for control of the switch can be used in its correct switching phase.

To set the correct switching phase, it has also been suggested to set the phase of the beginning of each To toggle transmitted color sync signal from line to line by + 45 ° to the fixed modulation axis (Q). The color sync signal then has a component in the direction of the switched modulation axis (7), which has a polarity switched from line to line, is evaluated in the receiver and can be used to set the correct switching phase of the switch.

The invention solves the problem, with little circuitry complexity from the color sync signal with a phase switched from line to line to obtain a manipulated variable that is necessary for the on position can serve the correct switching phase of the switch.

The invention is based on a circuit for correcting the switching phase of the line frequency Pulses synchronized switch in a PAL color television receiver by means of received color sync signals, whose phase is switched from line to line by + 45 ° to the fixed modulation axis, wherein the modulated color carrier and the color burst signal are fed to a color demodulator which supplies the two video-frequency color signals at the outputs of two color output stages.

The invention consists in the fact that the demodulation of the color sync signal is produced Voltages at the outputs of the color output stages are added with such an amplitude that if the switching phase is correct, a voltage with on-connection to correct the switching phase

of the line rate switch

in a PAL color television receiver

Applicant:
Telefunken

Patentverwertungsgesellschaft mb H.,
7900 Uhu, Elisabethenstr. 3

Named as inventor:

Werner Scholz, 3000 Hannover-Linden

approaching the value zero and, if the switching phase is incorrect, an identification pulse is generated which is used to correct the Switching phase of the switch is used.

The circuit complexity is low because the color signals Color demodulators and color output stages that are already present in addition to generating the identification pulse can be used for the switch. The circuit works particularly trouble-free because of the The identification pulse only appears when the switching phase is incorrect and this is then corrected. If the switching phase is correct the identification pulse is not available and the switch is only activated by the no reception interference subject to locally generated line-frequency pulses with constant correct switching phase synchronized.

The invention is explained with reference to the drawing for an embodiment in which the in the Phase synchronous signal switched from line to line only during blank lines in the Vertical return time is transferred. In the drawing shows

Fig. 1 is a vector image of the received burst color signal,

F i g. 2 and 3 basic circuit diagrams to explain the extraction of the identification pulse,

4 voltage curves for explaining the correction of the switching phase and

Fig. 5, 6 two embodiments of the invention.

According to FIG. 1, the received color carrier is modulated with two color signals according to the mutually perpendicular modulation axes I and Q. The modulation axis I is switched line-frequency by 180 ° to a modulation axis -I . The signals corresponding to the RY and BY axes

809 560/346

3 4

are wrong at the beginning of the receiver's color output stages. The larger amplitude available is missing in the first line. During the vertical delayed color sync signal, so that at the output of the return time, color sync signals A with a transit time demodulator are transmitted with an identification pulse 10 with half a few oscillations of the color carrier. Amplitude arises. It is assumed that the phase of these oscillations is in relation to the 5 pulse does not have sufficient amplitude to shift the correct axis BF by 12 °, ie it is to produce the switching phase. In the next line there are always two modulation axes Q and -Z or Q on the bisector between the undelayed and delayed color sync signal. If the switching phase is wrong then z. B. and + /. the / component has a different sign, so that

In Fig. 2, the color output stages for the signals io / component and ß-component are no longer

(RY) and (BY) of the receiver through the extinguish, but to an identification pulse 11 with

Generators 1 and 2 shown, which add the signals of greater amplitude. This identification pulse

can also not yet have the correct switching phase

Create ~ sin 12 ° and _cos 12 °, because a pulse always creates the positive polarity of the switching meander 6. In the next

However, the line arises because of the still wrong

deliver. The values 0.877 and 0.493 are the well-known switching phase of a large identification pulse 12, the now th reduction factors, The Phasphprkpefnzienten produces the correct switching phase of the meander 6,
of the picture tube are assumed here for red and blue as Fig. 5 shows an application example of the same. That of the two generations. The farbträgerfrequente modulated signal is tpren delivered 1 and 2, * obtained by Synchrondemodula by a clamp 30, two Synehrondemodulatoren tion of the burst signal A chip 13 is supplied to 14 which are identifications according to the Demodulationsachgen with resistors 3 and 4 in an R-Y and BY demodulate so that at the output such an amplitude ratio is composed that the color signals /? - Y and BY are available from color output stages 32, 33 at terminals 15, 16 in the phase indicated by A according to FIG. With and correct switching phase of the Demodulatipnsachsen an opened by line-frequency pulses 17 at an output terminal S a Kennimpulsspan- gate circuit 18 will arise for synchronization voltage Uz with the value zero. This color pulse voltage, which is used by Kennsine's reference carrier oscillator 20, would not change the correct switching phase of the synchronizing signal from the color carrier-frequency signal changeover switch.

Fig. 3 shows the case in which the switching phase of the honorization is assigned to the reference carrier oscillator 20

line-frequency switch in the receiver leads incorrectly. This creates a reference beam that over

is. The color output stages for- (RY) and (BY) of a phase splitter device 21 with the in Fig. 1

Receiver (G. erieratpr 1 ud 2) deliver cjajnn the jn shown phase positions via lines 22, 23, the F i g. 3 signals indicated, that is, the color syncronous 35 synchronous demodulators 13 and 14 is supplied,

signal ^ then takes aps viewed by the receiver.

die LageZ gin (Fig, 1) · Die. Addition of these signals tion axis according to FIG. 1, both de-

durcji cüe resistors 3 and 4 result in a line-frequency changeover at tier iiuss- mgejulatignsaehsen

output terminal 5 now "a Kennjnipiüsspgnnung the phase splitting unit for this purpose * -

from that indicated in FIG. Size. Dig identifier21 can be switched over and is accessed via a

impulse voltage is no longer equal to zero, you line 24 by a half-line frequency switch «

has a finite value and is switched to the correct meander 25 line frequency. The task

position of the Sqhaltphase exploited. the invention consists in the correct visual

Fig. 4 applies to (In the case that the color | ynehrgnr phase, the signal frequency switching to be determined, signal'mit "the phase already discussed, enwec.hs, el 45 Ζμ this time the output voltages of the in each of the empty lines are transmitted If un <3 color output stages 32, 33 is also provided to an adder 26, a delay demodulator is also supplied, which ^{has a structure in the lines shown in FIGS. 2 and 3 in which fffl TO v} §f? ögerj; and as a matrix for each identification pulse there is a delayed color sync signal and which serves. With the correct holding phase the switchable holding phase is correct (Fig. 4 a), the result is kjin KLenn- 50 phase splitting device 21, ie correct phase pulse. A wrong phase of the subsequent pull - d.er the synchronous demodulators 13, 14 supplied translated Bezugstr ^ gers Sigh acts on pie, J ^ Kqmpor Bezuggträger, the adder 26 supplies whose from ne.nte ^ and ^ ä ^ß component s Kennimpiilses gear while a d.. The vertical retrace time with evenly off, sp that with the same pulse 27 generated Tgrsghaltung 28 with again with the correct switching phase no identification pulse 55 of the phase splitter ring 21 is connected, only occurs in the first line during the no Kermirapulse, so that the retention of the vertical retrace time, in which a color synchronous signal phase gap 21 is transmitted with unchanged ₃ missing d, a delayed color synchronous switching phase continues. Signal if the switching phase is incorrect. In the event of a phase error, the adder stage 26 delivers an identification pulse (11, 12 then takes place again as a control pulse 7, the 60 in FIG. 4), which over the gate circuit 28 to the correct switching phase in Fig. 4a not verr Ph.as§numsc ^ altginjightiJng 21 comes Md changes there because he has no, aiisrgiehend.e Am.pUtude according to Fig. 4 established the right switching phase _t this resp. because ap this S, teUe with an identification impulse happens, for example, that the Kermphnin the positive, ie at this moment impulse ^ on eja grid of an ear, a multivibr.a, tprs correct polarity is established. p§r equal § remaining 65 e has an effect on us there, always gjgstimme balanced phase impulse 7 creates a goal, nagl). the last Kejn> feg must:

impulse, because then the instantaneous identification impulse is missing, F i S-. & shows a circuit example for the case

In Fig. 4b, the switching phase is dgs. gch ^ ltniäanciers ß that the identification impulses additionally with one opposite

the color subcarrier frequency low frequency signal, e.g. B. 350 kHz, are amplitude modulated. The two tubes 32 and 33 form the color output stages which deliver the video-frequency color signals RY and BY to terminals 15, 16. As an adder 26 according to FIG. 8 resistors 3 and 4. A parallel resonant circuit 31, which is tuned to the frequency of the low-frequency signal with which the identification pulses are amplitude-modulated, for example to 35OkHz, is used for further interference suppression. It ensures that only signals with this frequency can reach the gate circuit 28. The gate circuit 28 is gated with a vertical opening pulse 27 during the vertical retrace time and, if the switching phase is incorrect, delivers an identification pulse U ^ to the terminal 5 for correcting the switching phase.

Claims (1)

Claim: Circuit for correcting the switching phase of the ao switch in a PAL color television receiver, synchronized by line-frequency pulses, by means of received color sync signals, the phase of which is switched from line to line by + 45 ° to the fixed modulation axis, the modulated color carrier and the color sync signal being fed to a color demodulator, the supplies the two video-frequency color signals at the outputs of two color output stages, characterized in that the voltages resulting from demodulation of the color sync signal (A) are added at the outputs of the color output stages (32, 33) with such an amplitude that a voltage is added with the correct switching phase approximately zero and, if the switching phase is incorrect, an identification pulse (11, 12) is produced which is used to correct the switching phase of the switch (21). Considered publications:
German publication No. 1164 466. 1 sheet of drawings 809 560/346 6.68 © Bundesdruckerei Berlin