DE1240919B - Circuit arrangement for synchronizing a line-frequency switch in a color television receiver - Google Patents

Description

Circuit arrangement for synchronizing a line-frequency switch in a color television receiver In color television systems in which the transmission takes place with a suppressed color carrier, it is necessary to generate a reference carrier with a color carrier frequency in the receiver in a reference carrier oscillator with which the demodulation can take place. To synchronize this oscillator, it is known to transmit a color sync signal from a few color carrier-frequency oscillations of constant phase at the beginning of each line. For example, these color sync signals are sampled from the color signal in the receiver and compared with the output voltage of the reference carrier oscillator in a phase discriminator.The output voltage of the phase discriminator controls the frequency of the oscillator via a reactance stage so that this oscillator always has a reference carrier with the frequency of the color carrier and is more constant, more defined Phase generated.

There are now color television systems known (PAL, SECAM), in which im Transmitter a line-frequency switchover takes place and a corresponding line-frequency Switching must also be carried out in the receiver. The frequency of such Changeover switch in the receiver can easily be controlled by the line sync pulses be synchronized. In addition, however, the correct switching phase of this switch must be assured. There are a number of suggestions for determining the switching phase known. For example, additional color burst signals are generated during the vertical retrace time transmitted, or it is a signal from the vertical synchronous mix itself for definition derived from the switching phase.

It is also known (Telefunkeii-Zeitung, 1964, H. 2, pp. 112 to 115), in the case of a color sync signal transmitted at the beginning of each line, which consists of several color carrier frequency oscillations, the phase of these oscillations from line to line by ± 45 ' to switch to a fixed modulation axis. The color sync signal consists of an oscillation component of constant phase in the direction of this fixed modulation axis and an oscillation component with a phase switched by 180 ' from line to line perpendicular to this modulation axis. For evaluation in the receiver, this color sync signal can be broken down into the two oscillation components by adding and subtracting the color sync signals from two consecutive lines. The addition results in an oscillation component with a phase that remains constant from cell to row, which can be used to generate a reference carrier of constant phase. By subtracting a vibration component resulting from line to line 180 'changed phase for generating a reference carrier with from line to line 180' may be used alternating phase. In this case, however, a delay line with the delay time of a line duration is required for the evaluation of the color sync signal. In addition, the oscillation components at the output of the subtraction stage cannot easily be used to synchronize a switch because they differ from line to line only in the phase of their oscillations and therefore still have to be demodulated by means of a reference carrier.

The invention is based on the object in a receiver for a color tele-signal with zeilQnfrequent phase-switched color sync signals synchronization in the simplest possible way without using a delay line of the line-frequency toggle switch.

The invention is based on a circuit arrangement for synchronization a line frequency switch in a color television receiver (PAL, SECAM), in a color sync signal from several color carrier frequencies received at the beginning of each line Vibrations, the phase of which is line-frequency for the purpose of synchronizing the switch is switched, in a phase discriminator with one generated in an oscillator color carrier frequency reference carrier is compared.

The invention consists in that the output voltage of the discriminator with a time constant for synchronization that is so large compared to the line duration of The oscillator is used to ensure that it oscillates with a constant phase despite the phase switching, and that the output voltage also has no or a relatively small time constant is used to control the switch.

The output voltage of the discriminator acts z. B. with or without a very small time constant on a bistable generator whose output voltage controls the line rate toggle switch. The multivibrator is expedient additionally synchronized in frequency by the line sync pulses of the receiver, to ensure safe work. Or it becomes a bistable generator (Flip-flop) used by each line pulse or by a flywheel circuit from disturbances freed return pulses of the line deflection is reversed. This one bistable generator are then additionally obtained according to the invention pulses supplied to force the correct switching phase. Such a circuit works particularly trouble-free.

A major advantage of the invention is that practically no additional switching elements are required for the task of defining the switching phase of the changeover switch. The stage for sampling the color sync signal and the discriminator, which are necessary for synchronizing the oscillator in any case, are used at the same time to obtain the control signal for the switch. Additional switching elements are not required, or only to a small extent, because the control signal for the changeover switch only needs to be picked up directly at the output of the discriminator in front of the integrator located in front of the reactance stage. The output voltage of the discriminator thus simultaneously fulfills both tasks, namely the synchronization of the oscillator and the determination of the correct switching phase of the line-frequency switch. Means for separating the two vibration components are also not required. The discriminator is at the same time a synchronous demodulator, always automatically set correctly in phase, for demodulation according to the 1-axis, if the mean value of the phase of the two color sync signals from successive lines is Q as shown in FIG. This is because if the color sync signals have the middle phase Q , a reference carrier with a 90 ' shift, i.e. phase I, appears on the discriminator because the discriminator outputs control voltage 0 when the oscillations compared in the phase are 90' against each other are out of phase.

The invention is explained in more detail below with reference to the figures.

F i g. 1 shows a basic circuit diagram of the invention; F i g. Fig. 2 shows a phasor image of the burst signals and F i g. 3 waveforms of the circuit according to FIG. 1 and 4; F i g. 4 shows a practical embodiment of the invention.

The same parts are given the same reference symbols in the figures Mistake.

In Fig. 1 , the color signal containing the modulated color carrier and the color sync signal is fed from a terminal 1 to a key stage 2, which is opened by line-frequency pulses 3 from a terminal 4 during the duration of the color sync signal. The output of the phase discriminator 5 is connected via an integrator 6 to a reactance stage 7 which controls a reference carrier oscillator 8. The output voltage of the reference carrier oscillator 8 is fed to the phase discriminator 5 via a line 9. In addition, the output voltage reaches the oscillator 8 once directly via a line 10 and on the other via a 180' phase rotator 11 to the two inputs of a changeover switch 12. Depending on the position of the changeover switch 12 is connected to a terminal 13 a reference carrier with a phase of 0 or 180 ' available. Such a reference carrier is z. B. required in the PAL color television receiver for demodulation. The output voltage of the phase discriminator 5 is also fed via a capacitor 14 to a bistable multivibrator 15 whose half-line frequency output voltage controls the changeover switch 12. Another synchronization input of the multivibrator 15 is connected to terminal 4.

The mode of operation of this circuit is illustrated below with the aid of FIGS. 2 and 3 explained in more detail. According to FIG. 2, the color sync signals 16 and 17 are received in two consecutive lines, the phase of which is switched in mirror image to the axis Q at line frequency. The oscillation component of constant phase is therefore in the modulation axis Q and the oscillation component of line-frequency switched phase in the modulation axis L. It is assumed that the oscillator 8 has a reference carrier with constant phase with respect to the axis Q, z. B. Phase I supplies. During line 1 , the color sync signal 16 is compared with the reference carrier of phase Q in the phase discriminator 5 . This creates a positive pulse 18 at the output of the phase discriminator 5. During line 2, the phase discriminator 5 compares the color sync signal 17 with the reference carrier, so that a negative pulse 19 now arises because the I component of the color sync signal 17 is switched. At the output of the phase discriminator 5 , a voltage according to FIG. 3, a. In the integrating element 6 , the voltage according to FIG. 3, a is now freed from the alternating voltage component, so that a voltage according to FIG . 3, b arises, which acts on the reactance stage 7. Due to the integrator 6, the time constant of which is large compared to a line duration, the phase of the output voltage of the oscillator 8 is set to an average value of the phase of the color sync signals 16, 17 . In this case, the reference carrier oscillator 8, a reference carrier 17, so the constant phase L The output voltage of the phase discriminator 5 is above the multivibrator 15 is formed with a 90 'phase shift in relation to the average of the phase of the signals 16, now without insertion of a time constant of a capacitor 14, respectively. At the input of the multivibrator 15 there is thus a voltage according to FIG. 3 c, in which the alternating voltage pulses 18, 19 are contained. Since the negative pulse 19 occurs only in the phase of the color sync signal 17 and the positive pulse 18 only in the phase of the color sync signal 16 , the signal shape is shown in FIG. 3, c is a clear measure of the correct switching phase that the line-frequency changeover must have. 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 FIG. 3, f arises. This signal form is the desired half-line frequency switching meander of the correct switching phase, which can be used to control the line-frequency switch 12. The multivibrator 15 is also synchronized in frequency with the line sync pulses 3 via the line 20. This additional synchronization is not absolutely necessary because the pulse shape according to FIG. 3, c contains both information about the frequency and information about the correct switching phase. The additional synchronization via the line 20 is advantageous for reasons of operational safety.

A bistable generator (flip-flop) will always work properly, even in the event of malfunctions. The pulses 18, 19 are only required to force the correct switching phase. They can fail without causing a malfunction. The color signal and the color sync signal can be removed for a short time without having to change the direction when the color is switched on again.

Since the pulses 18, 19 are provided with the carrier frequency, it is advantageous to make them pure direct current pulses. There is an integration with a small time constant; a sawtooth-shaped signal remains in accordance with curve d in FIG. 3, which is good for syncing. The synchronization then takes place with the peaks occurring at the beginning of every other line.

F i g. 4 shows a transistorized embodiment of the circuit according to FIG. 1. The discriminator 5 is tapped here on one side. Via a filter element 21 with a small time constant, at the output of which the voltage according to curve d in FIG. 3 stands, the bistable generator 15 is synchronized. Another time constant element 6 of high time constant leads to the reactance stage 7 to control the color carrier oscillator 8. The transistor stage 22 is used to achieve a sufficiently high-resistance load for the discriminator 5. Output voltages of opposite polarity can also be taken at the two ends of the discriminator 5 and one each of the transistors of the multivibrator 15 are supplied. Then one transistor is always conductive while the other is blocked. The discriminator 5 can also be used as a synchronous demodulator for demodulating the color carrier along the ± I axis, because the phase of the reference carrier on the line 9 automatically adjusts to the I axis.

The Bezu carrier oscillator 8 is z. B. a crystal oscillator. The negative pulse 19 (or the positive pulse 18) in the pulse shape according to FIG. 3, c can also be omitted if the synchronization takes place via the line 20. The positively directed pulses 18 (or 19) then alone ensure the correct switching phase. Curve e in FIG. 3 shows the component I of the signals 16, 17 switched from line to line by 1801 , which causes the pulses 18, 19. List of reference numbers 1 clamp, 2 key step, 3 line sync pulses, 4 clamp, 5 phase discriminator, 6 integrating link, 7 reactance level, 8 beverage carrier oscillator, 9 management, 10 line, 11 phase rotator, 12 switches, 13 clamp, 14 capacitor, 15 multivibrator, 16 color sync signal of line 1, 17 color sync signal of line 2, 18 positive pulse, 19 negative pulse, 20 management. 21 sieve element, 22 transistor stage, Q phase of the output voltage of the reference carrier oscillator, 1 modulation axis.

Claims (2)

Claims: 1. A circuit arrangement for synchronizing a line-frequency switch in a color television receiver (PAL, SECAM), in which a color sync signal received at the beginning of each line consisting of several color carrier-frequency oscillations, the phase of which is switched line-frequency for the purpose of synchronizing the switch, in a phase discriminator with one in one is compared oscillator generated farbträgerfrequenten reference carrier, d a d u rch g e - indicates that the output voltage of the discriminator (5) is used with a with respect to the line period so large time constant for synchronizing the oscillator (8) that this vibrates in spite of the phase switching with constant phase , and that the output voltage is also used with no or with a relatively small time constant to control the switch (12). 2. Circuit arrangement according to claim 1, characterized in that the output voltage acts with a small time constant on a bistable multivibrator (15) , the output voltage of which controls the changeover switch (12). 3. A circuit arrangement according to claim 2, characterized in 'that the multivibrator (15) through line sync pulses (3) of the receiver is synchronized in frequency additionally. 4. Circuit arrangement according to claim 3, characterized in that the output voltage (18, 19) with a small time constant is used to force the desired switching phase of a bistable generator (15) switched over by the line sync pulses (3) or line return pulses. 5. Circuit arrangement according to claim 2, characterized in that the output voltage of the discriminator (5) the multivibrator or bistable generator (15) directly or via a time constant element with a low time constant and a reactance stage (7) controlling the oscillator (8 ) via an integrating element (6 ) high time constant is supplied. 6. A circuit arrangement according to claim 1, characterized in that on the two sides of a symmetrical discriminator (5) output voltages of opposite polarity are taken and each of the two transistors (or tubes) of a multivibrator (15) controlling the switching (15) are supplied so that the one transistor is conducting, while the other is operated in the reverse direction. 7. The circuit arrangement according to claim 1, characterized in that the output voltage is converted by an integrator (21) in a sägezahnförinige voltage (d), the steep flanks are used to synchronize a switching controlling the multivibrator (15), 8. The circuit arrangement according to claim 1 , characterized in that the discriminator (5) also serves as a synchronous demodulator for the color signal.