DD56252B1 - Circuit for synchronizing the reference carrier oscillator and for controlling the switching phase of the line-frequency switch in a PAL color television receiver - Google Patents

Description

116 837

Circuit for synchronizing the reference carrier oscillator and for controlling the switching phase of the line-frequency switch in a PAL color television receiver

The invention relates to a circuit for synchronizing the reference carrier oscillator and for controlling the switching phase of the line frequency switch in a PAL color television receiver by the line-by-line in phase by 90 switched PAL color burst signal.

In color television systems in which the transmission is effected with suppressed color carrier, it is necessary to produce in the receiver in a reference carrier oscillator a reference carrier with color carrier frequency, with which the demodulation can take place. To synchronize this oscillator, it is known to transmit at the beginning of each line, a color burst signal from a few Farbträgerfrequenten constant phase oscillations. For example, these color bursts are sampled in the receiver from the color signal and in a phase discriminator with the output voltage

U 6 8 3 7

of the reference carrier oscillator. The output voltage of the phase discriminator controls the frequency of the oscillator via a reactance stage, so that this oscillator always generates a reference carrier with the frequency of the color carrier and a constant, defined phase.

There are color television systems known (PAL, SECAM) in which the transmitter is a line frequency switching and a corresponding line rate switching must also be performed in the receiver. The frequency of such a switch in the receiver can be synchronized by the line sync pulses. In addition, the correct switching phase of this switch must be ensured. To determine the switching phase has been proposed to switch the vibrations of the transmitted at the beginning of each line burst signal from line to line mirror image to a fixed axis by + 45. Such a phase-shifted burst signal consists of a constant-phase oscillation in the direction of the fixed axis and a line-frequency oscillation of 180 ° phase in the direction perpendicular to this axis. The first oscillation serves to synchronize the reference carrier oscillator and the second oscillation to control the line frequency switch. The two vibrations are e.g. separated from each other by adding and subtracting the burst signals from successive lines. During the addition, the oscillation with the constant phase and with the subtraction the oscillation with the switched-over phase results. For this solution, a delay line with the delay time of a line duration is required.

The invention has for its object to enable with a color burst signal of the latter type in the receiver in the simplest possible way the synchronization of the reference oscillator and the determination of the correct switching phase of the line frequency switch, even if there is no delay line with the delay time of a line duration in the receiver , - 3 -

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This object is achieved in that a color burst signal leading terminal and the output of the reference carrier oscillator are connected via a line to the inputs of a phase discriminator and that the output of the phase discriminator via an integrator with respect to the line time large time constant to the synchronizing input of the reference oscillator and also connected via a sieve member to the synchronizing input of the multivibrator.

The sieve member may be tuned to half the line frequency resonant circuit of such high quality that the harmonics of the line frequency are outside its resonance curve. As a phase discriminator, a demodulation of the modulated color carrier anyway existing synchronous demodulator can be used. The output of the sieve member may be connected to the input of a rectifier, whose output voltage is connected to a serving to open and lock the color channel terminal.

The invention will be explained in more detail below with reference to an embodiment. In the accompanying drawings show:

2 shows a pointer image of the color burst signals, FIGS. 3 and 6 show waveforms for explaining FIGS. 1, 4 and 5,

Figures k and 7 show two practical embodiments of the invention.

According to Figure 1, the carrier frequency color signal containing the modulated color carrier and the burst signal is supplied from a terminal 1 of a Taststufe 2, which is permeable by line frequency pulses 3 from a terminal 4 during the duration of the burst signal. The output of a phase discriminator 5 is via an integrator

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, connected to a reactance stage 7 which controls a reference carrier oscillator 8. The output voltage of the reference carrier oscillator 8 is supplied via a line 9 to the phase discriminator 5. In addition, the output voltage of the oscillator 8 passes once directly via a line 10 and the other via a l80 -Phasendreher 11 to the two inputs of a changeover switch 12. Depending on the position of the switch 12 is at a terminal 13, a reference carrier with a phase of 0 or l80 to disposal. Such a reference carrier is required for demodulation in the PAL color television receiver. The output voltage of the phase discriminator 5 is also fed via a capacitor l4 a bistable multivibrator 15, the half-line frequency output voltage controls the switch 12. Another synchronizing input of the multivibrator 15 is connected to the terminal k .

The operation of this circuit will be explained in more detail below with the aid of Figures 2 and 3. According to Figure 2, the color burst signals l6; 17 are received in two temporally successive lines whose phase is switched line-frequency mirror image to the axis Q. The constant-phase oscillation thus lies in the modulation axis Q and the oscillation with a line-frequency switched phase in the modulation axis I. Let it be assumed that the oscillator 8 supplies a constant-phase reference carrier with respect to the axis Q, eg phase I. During the first line, in the phase discriminator 5, the color burst signal 16 is compared with the phase I reference carrier. This results in the output of the phase discriminator 5 is a positive-directed pulse 18. During line 2, the color burst 17 is compared with the reference carrier in the phase discriminator 5, so that now a negative-going pulse 19 ent.steht because the I component of the color burst 17 switches is. At the output of the phase discriminator 5 thus a voltage according to Figure 3 ^a · In the integrating circuit 6, the voltage is now shown in FIG 3a is formed

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freed from the AC component, so that a voltage according to Figure 3b arises, which acts on the reactance stage 7. Due to the integrator 6 whose time constant is large compared to a line duration, the phase of the output voltage of the oscillator 8 adjusts to an average of the phase of the color burst signals 16; In this case, the reference carrier oscillator 8 forms a reference carrier with 90 phase shift relative to the mean value of the phase of the color burst signals 16, 17 'ie with the constant phase I.

The output voltage of the phase discriminator 5 is then fed to the multivibrator 15 via a capacitor 1A. At the input of the multivibrator 15 is thus a voltage according to Figure 3c, in which the pulses 18, 19 are included.

Since the negative pulse 19 occurs only at the phase of the color burst signal 17 and the positive pulse l8 only at the phase of the burst signal 16, the waveform according to Figure 3c is a clear measure of the careful switching phase, which must have the line rate switch. The pulses 18, 19 at the input of the multivibrator 15 now push the multivibrator alternately into one of its two stable states, so that at the output of the multivibrator 15 a waveform according to Figure 3f arises. This waveform is the desired half-line frequency Schaltmäander proper switching phase, which is used to control the line rate switch 12. The multivibrator 15 is additionally synchronized in frequency via a line 20 with the line synchronizing pulses 3, this additional synchronization is not necessarily required because the pulse shape according to Figure 3c contains both information about the frequency and information about the correct switching phase. However, the additional synchronization via the line 20 is advantageous for reasons of operational safety.

A bistable generator (flip-flop) will always work flawlessly, even in case of faults. The pulses 18, 19 are only

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required to force the correct switching phase. They can fail without causing a disturbance. Color signal and Farbsynchronsignale can be removed for a short time without a reversal must be done when switching the color. Since the pulses 18, 19 are provided with the carrier frequency, it is advantageous to make them pure DC pulses. There is an integration with a small time constant; this leaves a sawtooth-shaped signal according to curve d in Figure 3 »which is well suited for synchronization. The synchronization then takes place with the peaks occurring at the beginning of every second line.

Figure 4 shows a transistorized embodiment of the circuit of Figure 1, wherein the discriminator 5 is tapped. Via a filter element 21 small time constant, at the output of the voltage according to curve d in Figure 3, the bistable generator 15 is synchronized. Another time constant member 6 high time constant leads to the Raktanzstufe for controlling the color carrier oscillator 8. A transistor stage 22 serves to achieve a sufficiently high-impedance load for the discriminator 5 · It can also be taken at the two ends of the discriminator 5 output voltages of opposite polarity and one of the Transistors of the multivibrator 15 are supplied. Then one transistor is always conducting, while the other is blocked. The discriminator 5 can additionally take place as a synchronous demodulator for the demodulation of the color carrier according to the axis +1, because the phase of the reference carrier on the line 9 automatically adjusts to the axis I. The reference carrier oscillator 8 is, for example, a quartz oscillator. The negative pulse 19 (or the positive pulse 18) in the pulse form shown in FIG. Jc may also be omitted when synchronizing via the line 20. The positive-directed pulses 18 (or 19) then ensure the correct switching phase alone. Curve e in FIG. 3 shows the component I of the color burst signals 16, 17, which is switched over by l80 from line to line, which effects the pulses 18, 19.

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According to one embodiment of the invention, the output voltage of the discriminator is supplied to the multivibrator via an integrator which is dimensioned so that its output voltage is a sine wave voltage at half the line frequency. The integrator consists of a high-quality circuit tuned to half the line frequency, which can not be influenced by individual interference pulses and only makes the switching frequency from a larger number of alternating pulses 18, 19 integral. A solution in which a half-line frequency sinusoidal voltage is obtained from the color burst signals with an integrator is shown in FIGS. 5 to 7.

In FIG. 5, the color burst signal 16, 17 from terminal 1, with phase switched from line to line, arrives at the phase discriminator 5 "of a synchronous demodulator. The phase discriminator 5 supplies, on the one hand, a control voltage for the reference carrier oscillator 8 and, on the other hand, the pulse train 18, 19 for a sine integrator 21. The output voltage of the reference carrier oscillator 8 is supplied to the phase discriminator 5 as a comparison variable. The sine integrator 21 includes a circuit for sifting out the fundamental wave 23 from the alternating pulse train 18; 19. To obtain this fundamental wave, a larger number of alternating pulses are required. Individual interference pulses thus contribute little to the formation of the fundamental wave 23, which together with line synchronizing pulses 3 serves to control a multivibrator 15. To set the most favorable phase position of the control, a sine-wave integrator 21 or the line pulse path is not assigned a phase shifter, not shown. The multivibrator is connected to the switch 12, whose changeover contacts are connected to the reference carrier oscillator 8 directly via a phase-rotating member 11, so that at the output terminal 13 is alternately a reference carrier with a phase of 0 and I80 available. For better illustration, the vibrations occurring in the circuit according to FIG. 5 are listed one above the other in FIG.

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FIG. 7 shows a proven circuit according to FIG. 5 in detail. The phase discriminator 5 supplies, on the one hand, a control voltage for the readjustment of the color carrier oscillator 8, which contains eg a reactance stage, and on the other hand a sequence of anternating pulses 18, 19. The alternating pulses 18, 19 are supplied to an amplifier 2k , in the output circuit of which a half-line frequency tuned sinusoidal circuit 25 of such high quality is switched on that only the fundamental wave, ie

a sine wave voltage 23 at half line frequency.

In this way, the sinusoidal circuit 25 acts as an integrator 21, which does not forward disturbances. At the connection of the amplifier 2k to the phase discriminator 5, it may be advantageous to turn on an impedance converter 26 between these circuit parts. The sine circuit shown in Figure 7 is connected in push-pull with respect to the switching generator to be controlled. The sine voltages 23 supplied to the multivibrator are therefore shifted by 180 in phase relative to each other. The position .der of the multivibrator 15 also supplied line sync pulses 3 relative to the tip of the sine wave voltage 23 may affect the operation of the multivibrator 15. To set the optimal operating condition, it may therefore be advantageous to assign the circuit a phase rotator for mutual displacement of these two voltages 3 and 23. The sinusoidal voltage 23 is only applied to the sinusoidal circuit 25 when color-synchronizing signals 16, 17 switched over to the phase discriminator 5 are supplied. According to one embodiment of the invention is rectified by rectifying the sine wave a Gleichgewonnen, which blocks the color channel upon receipt of black and white signals or switches the receiver when receiving NTSC signals, or conversely, when receiving color signals opens the color channel or upon receipt Switched by switched color burst signals.

Claims (4)

claims A circuit for synchronizing the reference carrier oscillator and controlling the switching phase of the line frequency switch in a PAL color television by the line-by-line in phase by 90 switched PAL Farbsynchronsigral, the switch is controlled by a synchronized by line frequency pulses switching voltage generator, characterized characterized in that a color burst (l6,17) leading terminal (l) and the output of the reference carrier oscillator (8) via a line (9) to the inputs of a phase discriminator (5) are connected and that the output of the phase discriminator (5) via an integrator (6) is connected to the synchronizing input of the reference carrier oscillator (8) with a time constant which is large compared with the line duration, and is also connected to the synchronizing input of the multivibrator (15) via a filter element (2l). 2. A circuit according to claim 1, characterized in that the sieve member (21) is tuned to half the line frequency resonant circuit so high quality that the harmonics of the line frequency are outside its resonance curve. 3. A circuit according to claim 1, characterized in that the phase discriminator (5) is a synchronous demodulator used for demodulating the modulated color carrier. 4. A circuit according to claim 1, characterized in that the output of the Siebgliedes (21) is connected to the input of a rectifier whose output voltage is connected to a serving to open and lock the color channel terminal. Horezu., 3 pages drawings η r> nr--