DE1537526B2 - Circuit for correcting the switching phase of the line-frequency switch in a SECAM color television receiver - Google Patents

Description

In a SECAM color television receiver, a line rate switch is known to be required to to route the received color carrier to the color channel assigned to it. One such switch is controlled in a known manner by a generator with a switching voltage that is half the line frequency swings. The frequency of such a generator can be determined by locally generated line frequencies Impulses, e.g. B. line retrace pulses are synchronized. Since these return line pulses do not If the reception is subject to interference, this results in a stable synchronization of the frequency.

Since the synchronization takes place with a voltage with a line frequency, the switching phase is the half-line frequency Switching voltage not clear. To check and, if necessary, to correct the switching phase it is known (DT-PS 12 05 596) to generate a manipulated variable in the receiver that depends on the switching phase. If the switching phase is correct, this manipulated variable leaves the one that is synchronized by the line-frequency pulses Generator unaffected. If the switching phase is wrong, this manipulated variable has the same effect on the generator one that changes the phase of the switching voltage. For example, the manipulated variable can shut down the generator, whereupon the generator starts to oscillate again after the manipulated variable has disappeared. This continues until the switching voltage has the correct switching phase.

With a SECAM system, everyone starts with

ίο line of unmodulated color carrier oscillation trains with Transferred from line to line between two values of switched frequency, which are used to correct the switching phase can serve.

The invention is based on the object of a simple circuit for generating the aforementioned manipulated variable to create from these vibrational trains.

This object is achieved by the invention characterized in claim 1. Further training of the Invention are specified in the subclaims.

The invention is based on the knowledge that by combining the switching voltage representing the switching phase with the output voltage of the frequency discriminator fed by the color carrier oscillation trains a voltage that is dependent on the switching phase arises, which thus serve as the aforementioned manipulated variable can.

The invention is explained in more detail below with reference to the drawing using an exemplary embodiment. It shows

F i g. 1 shows a basic circuit diagram of the invention and

F i g. 2 waveforms to explain the mode of operation of the invention.

A circuit for a SECAM color television receiver is known (DL-PS 57 876, FIG. 2), at which also includes the unmodulated color carrier oscillation trains transmitted at the beginning of each line Line to line switched frequency are fed to a frequency discriminator whose output voltage controls the switching phase of the switching voltage generator for the line-frequency switch. There, however, the half-line frequency output voltage of the frequency discriminator controls the directly Switching voltage generator both in frequency and in switching phase. An additional synchronization due to the line return pulses of the receiver is not provided there. The for the present invention essential phase comparison between the output voltage of the frequency discriminator and the switching voltage generated by the switching voltage generator and the extraction of a Manipulated variable that is only synchronized to the line-frequency pulses generated by the locally generated line-frequency pulses if the switching phase is incorrect line-frequency switch acts. This known circuit is therefore fundamentally different of the circuit according to the invention in the manner of controlling the switching phase. The well-known circuit is relatively sensitive to interference because it only synchronizes from the received signal and any disturbance at the output of the frequency discriminator directly on the switching voltage generator got.

A circuit for a color television receiver of the PAL or SECAM type is also known (DT-PS 12 40 919), in which at the beginning of each line received,

⁽ 15 color sync signals switched from line to line in phase are compared in a phase comparison stage with a locally generated reference carrier. The phase comparison stage regulates higher via a filter element

Time constant the reference carrier oscillator on the frequency and phase of the color sync signals and delivers over a Filter element with low time constant a half-line frequency control voltage for synchronizing the line frequency Toggle switch. This circuit does not work on the basis of the present invention lying circuit principle, in which the switching voltage generator is synchronized by the line sync pulses and is only influenced by a manipulated variable in the event of an incorrect switching phase, which is determined by comparing the Color sync signal is obtained with a voltage representing the switching phase. Rather, this is the case known circuit, the control voltage obtained directly from the burst signal and not below Use of a voltage that indicates the actual switching phase.

F i g. 1 shows a receiver circuit for a SECAM color television receiver with a delay line 1 for a line duration, a line frequency switch 2, two color demodulators 3 and 4 and a generator 5 which controls the switch 2 with a half-line frequency switching voltage 6. At a terminal 7 is a color carrier sequence Fi, F2, Fi, where Fi always with a first color signal, z. B. R-Y, and Fi always with a second color signal, z. B. B - Y, is modulated. The switch 2 is operated so that the color carrier Fi is constantly at an output 8 and the color carrier F2 is constantly at an output 9 and the video-frequency color signals RY and B-Y are constantly at output terminals 10, 11 of the demodulators 3, 4. The generator 5 is synchronized by a terminal 12 with line-frequency pulses 13, which are obtained, for example, from the flywheel-synchronized line deflection circuit. The circuit described so far is known. The switching phase of the switching voltage 6 can be correct or incorrect in such a circuit.

To correct the switching phase, a gate 13 is used, which is driven by line-frequency pulses 14 only during the Duration of the color carrier oscillation trains is open, a frequency discriminator 15, an adder 16, a Rectifier 17 and a filter element 18, the output of which via a line 20 to an input of the generator 5 is connected. The adder 16 is with the output voltage of the frequency discriminator 15 and fed with the switching voltage 6.

F i g. 2 is used to explain the mode of operation of the correction of the switching phase. From the exit of the gate 13, the color carrier oscillation trains 19 arrive as shown in FIG. 2a, the frequency of which is switched from line to line between / i and / 2, to the input de.s frequency discriminator 15 which, because of the frequency switching, supplies a pulse voltage according to FIG. 2b at its output. The phase of the switching voltage 6 is such that the switchover takes place shortly before the start of an oscillating train 19. It is initially assumed that the switching phase of the switching voltage 6 (FIG. 2c) of the generator 5 is incorrect. By adding the switching voltage 6 and the output voltage (FIG. 2b) of the frequency discriminator 15 in the adding stage 16, a voltage according to FIG. 2d, which after peak rectification and sieving a manipulated variable + Us according to FIG. 2e on line 20 supplies. This manipulated variable stops the generator 5. For example, the manipulated variable switches off an operating voltage from the generator or blocks a section of a bistable multivibrator that serves as generator 5. This stop now takes place in such a way that the generator 5 only receives the negative voltage according to FIG. 2c gives off. By adding this voltage with the constant pulse voltage according to Fig. 2b, the positive manipulated variable + Us can no longer result. Since only this manipulated variable can shut down the generator 5, the generator 5 starts to oscillate again. This stopping and resumption of oscillation takes place until the generator 5 has the correct switching phase.

When the switching voltage 6 has the correct switching phase, the generator 5 generates a switching voltage 6 according to FIG. 2f. By adding it to the voltage that remains unchanged in accordance with FIG. 2b results in a voltage according to FIG. 2g, which after rectification and sieving a compared to F i g. 2e smaller manipulated variable + Us according to FIG. 2h delivers. Since only the positive manipulated variable according to FIG. 2e can shut down the generator 5, the generator 5 now continues to oscillate in the desired manner with the correct switching phase, namely synchronized by the line-frequency pulses 13.

The adder 16 and the rectifier 17 can also be replaced by a phase comparison stage. This can depend on the fundamental wave of the output voltage of the discriminator 15 and the switching voltage 6 be fed. The output voltage of this phase comparison stage is then also dependent on the Switching voltage phase. She is z. B. at wrong Switching phase positive, whereby the generator 5 is stopped, and with the correct switching phase and when the generator 5 is stopped, zero or negative, whereby the Generator continues to oscillate or starts to oscillate again. The frequency discriminator 15 can also consist of a / 1 or / 2 tuned resonant circuit with subsequent rectifier exist. This can also the positive (or negative) part of Fig.2d with the wrong switching phase and the positive (or negative) part from F i g. 2g can be obtained with the correct switching phase. Or it can be converted into a half-line frequency sinusoidal voltage can be derived for the purpose of phase comparison with the switching voltage 16.

1 sheet of drawings

Claims (6)

Patent claims: 1. Circuit for correcting the switching phase of the line-frequency switch, which is synchronized by locally generated line-frequency pulses, in a SECAM color television receiver, in which, at the beginning of each line, unmodulated color carrier waveforms are transmitted with a frequency switched between two values from line to line, with a manipulated variable that depends on the switching phase is generated, which only acts in the wrong switching phase on a generator generating the switching voltage for the switch and stops it, as characterized in that the manipulated variable (Us) by phase comparison of the switching voltage (6) with the output voltage (b) of one with the received color carrier oscillation trains (19) fed frequency discriminator (15) is obtained. 2. A circuit according to claim 1, characterized in that the phase comparison takes place in a linear adding stage (16), the output voltage (g, d ) of which is used as a manipulated variable (Us) after rectification (17) and sieving (18). 3. Circuit according to claim 1, characterized in that the generator (5) is a bistable multivibrator and is stopped by the manipulated variable (+ Us) in that of its two switching positions in which the manipulated variable (+ Us) disappears. 4. A circuit according to claim 1, characterized in that a phase discriminator (16, 17) serving for phase comparison is each supplied with the fundamental waves of the output voltage (b) of the frequency discriminator (15) and the switching voltage (16). 5. A circuit according to claim 1, characterized in that the frequency discriminator consists of one An oscillating circuit tuned to one of the frequency values of the color carrier oscillation trains (19) with a subsequent Rectifier consists. 6. A circuit according to claim 1, characterized in that the manipulated variable in addition to the automatic Blocking of the color channel is used.