DE720583C - Method of mixed synchronization in television - Google Patents

Description

To a television receiver with the transmitter Keeping in step is known to send in addition to the actual image content in certain At intervals, impulses that trigger tilting devices in the receiver, for example. As soon if disturbances occur along the transmission path, the run becomes synchronous of the recipient slightly disturbed. So- cause atmospheric discharges, or

ίο taking ignition sparks from motor vehicles Under certain circumstances, a premature triggering of the tilting device, while on the other hand shrinkage phenomena, which the pulse amplitudes reduce, 'a failure of the tipping process have as a consequence. One has to fix such FeHsynchronization in this way tried to let the synchronizer of the receiver work independently and the impulses from the transmitter only to Correction of synchronism used, z. B.

became the phase difference between the. transferred and the locally generated pulses are used to regulate the synchronization of the drive motor of the receiver.

On the televisions with. Sawtooth ■ shaped Working breakdown vibrations, this method of mixed synchronization is not readily applicable because the The sawtooth-shaped tilting pulses required by the receiver are not the same Farm to be delivered by the transmitter. Rather, this radiates, as is known, rectangular Synchronization character.

In order to now also with a difference in the shape of the curve of the transmitter impulses on the one hand and of the vibrations generated by the receiver's synchronizer, on the other hand, the mixed To be able to perform synchronization, according to the invention, the transmitter pulses are in their shape (i.e. their

Time-amplitude curve) the given internal impulses of the synchronizing device (e.g. Tilting device) in the receiver. Only then do both types of impulse interact on, and the phase difference between the two pulse trains then brings the local tilting device with the transmitter exactly in frequency and phase. This forces a DC voltage which is the phase difference between the to local tilting impulses and the reshaped. Corresponds to correction pulses from the transmitter. First of all, one of the two pulse trains whose shape is matched to one another is expedient (e.g. the one generated by the local tilting device) converted into its mirror image and only then superimposed on the other (in the example the one supplied by the transmitter). By Regeiao results from rectification of the active current that arises during the superposition DC voltage, for example on the frequency and phase of the local tilting device can act by changing the bias of a gas discharge tube.

Ih the accompanying figures is the application of the invention to a tilting device shown., which lead the scanning beam of a Braun tube across the screen target. Fig. Ι and 2 show the shape of the currents in the various depending on the time Sharing the circuit; Fig. 3 gives the scheme of the circuit itself.

In Fig. Ι are marked with 1 rectangular synchronization symbols (shown in dashed lines) after they have been screened out in the receiver. Using a circuit with a certain time constant, this character sequence can be converted into a sawtooth-shaped curve 2 (shown in solid lines). According to the solid curve 3, the voltage supplied by the local tilting device has the same profile. The curve 3 shows a phase correspondence with the curve 2 derived from the transmitted syncbronization characters 1. The also solid curve 4 shows the span for the case that there is a substantial phase difference between the two oscillation trains. If one now converts the locally generated pulse trains 3 and 4 into their mirror image, one obtains the curves drawn in dash-dotted lines. By superimposing these mirror image curves with the pulse train 2, into which the synchronization pulses of the transmitter were converted, there are - as Fig. 2 shows - rectangular alternating currents 5 and 6 respectively The mirror image of 4 was superimposed on curve 2 of the reshaped transmitter pulses. After rectifying the active currents 5 and 6, control DC voltages 7 and 7 'are obtained, the amount of which ^{depends on the width of the square-wave pulses and thus on the phase difference between the pulse trains 2 and 3 6} S or 2 and 4 to be compared: the control DC voltage increases with the Phase difference between the local tilting pulses and the control pulses of the transmitter, which have been matched to their shape. The DC control voltage obtained is now allowed to act on the local tilting device, thus forcing it to adapt to the transmitter rhythm.

If the tilting device consists of a gas discharge tube in a known manner With a charging capacitor and bleeder resistor, the breakover frequency can be set within sufficient further limits can be varied by acting on the grid prestress · of the tube: With with increasing preload, the frequency of the tilting oscillations decreases. This regulation is carried out automatically by the phase shift between external and internal pulses: As soon as the phase difference between the impulses of the local generator and the impulses matched in shape of the transmitter increases, the oscillation frequency shifts as a result of the sliding Grid bias until the phase shift is balanced again.

Fig. 3 illustrates the details of such a circuit. In this picture 8 shows the cathode of the gas discharge tube 9 and 10 its anode. The capacitor 11, which is charged via the resistor 12 from the DC voltage source 20, Together with this resistor and the gas discharge tube, it forms the local tilting device, which deflects the cathode ray in the Braun tube 22. The one from the recipient 23 recorded Syn.chronisierimpulse of the transmitter are by means of the amplitude filter tube 24 separated from the pixel pulses and with the help of a resistor 15 and a capacity 19 in sawtooth Converted voltage surges. Applies to the primary winding 16 of a transformer one now the alternating voltage, which results from the difference of the voltage drops along the Resistors 12 and 15 results. From the Seno secondary winding 17 of this transformer becomes the capacitor via a rectifier 18 14 charged, which slowly discharges through resistor 13. If you combine that Grid the tube 9 via a resistor with the capacitor 14, so the grid potential fluctuates according to the terminal voltage on circuit 13-14. The grid tension is thus a function of the phase shift between the oscillations of the local Tilting device and the synchromesh of the transmitter. This phase shift controls

as a result, indirectly the frequency of the tilting device.

As can be seen, the two tilting circles 19, 15 and 11, 9 work in opposite directions. Of the Capacitor 19 is charged intermittently and gradually discharges through the resistor 15. On the other hand, the capacitor 11 continuously fed by the battery 20 until its voltage across the tube 9 collapses.

As a result, the transformed transmitter pulses with the mirror image are in the transformer the local tilting pulses are interconnected.

Usually the tilt tube discharges shortly before the synchronizing tip arrives. This results in the rectified current for the current in the transformer 16, 17 Current and accordingly .also the bias of the grid 9 according to a certain value the lines 7 and 7 'of Fig. 2. Accelerates the local one for some reason If the device tilts its rhythm, the phase difference between the sawtooth currents increases in resistors 12 and 15. So the current in the transformer 16, 17 increases and with it the bias of the grid 9. This increase acts in the sense of a decrease in the tilting frequency. The contrary occurs when the local vibrations lag behind the transmitter pulses. That The tilting device always remains in phase with the control pulses from the transmitter.

Claims (5)

Patent claims: i. Television synchronization method, at the synchronizing device that works independently and is roughly adjusted to the synchronization frequency of the "receiver generates vibrations that match those of the transmitter transmitted synchronization characters are compared, and in which the the phase differences resulting from this comparison effect the synchronization correction, characterized in that if the farm is different, on the one hand the synchronization transmitted by the transmitter (e.g. B. square) pulses and on the other hand that from the synchronizer of the receiver triggered (e.g. sawtooth) vibrations take on the shape of the former that of the latter before their action on each other with regard to the course of the curve is adjusted. 2. The method according to claim 1, characterized in that the synchronization of the local tilting device is forced by a control DC voltage, which is the phase difference between the local Tilting pulses and the transformed control pulses of the transmitter corresponds. 3. The method according to claims 1 and 2, characterized in that the ■ one of the two impulse trains that are aligned with one another in terms of their shape (e.g. that of the local tilting device generated) - converted into his mirror image and only then the other (e.g. the one supplied by the transmitter) is superimposed. 4. The method according to claims 1 to 3, characterized in that the Control DC voltage is formed by rectifying an active current that results from the superposition of the two pulse trains. 5. The method according to claim 1, characterized in that frequency and phase of the local tilting device by changing the pre-tension of a gas discharge tube be managed. 1 sheet of drawings