DE743022C - Arrangement for controlling the line train deflection generator when receiving television broadcasts according to the interlaced process - Google Patents

Description

Arrangement for controlling the line train deflection generator at reception of interlaced television broadcasts When interlaced television as a result of a slight offset of the two grids, the two rows are not coincide exactly, then the picture appears as if it consisted only of the half the number of lines. This phenomenon is called the pairing of the lines. It is mostly due to an inaccuracy in the use of the Zejlenzug deflection device. Namely, in a known way, the line train or picture change pulses from the Reception mixture through a frequency sieve. (Charging a capacitor through a Resistance, d. H. Integration of the line train pulse), which only for themselves, e.g. B. for the longer pulses of lower frequency, permeable is, the shorter and higher-frequency pulses of the _Zeilensynchrordsierung however suppressed, so the forehead of the image change or v. Line train pulse greatly flattened. It can then no longer be acquired that the point of action of the two Line change to a few pixels exactly at the end or in the middle of the last one Line of each line. The flatter the wave front of the impulse is, the greater the inaccuracy of the line drawing or. Be change of image and with it also the uncertainty of the position of the two lines in general.

The inaccuracy of the bet is increased by the well-known Appearance that with the two-line jump there are also residual effects of the line impulses occur at the time of the line train change, since it is generally known that the line train pulse only with the one line change: el arrives synchronously with a line pulse, at but the second is exactly in the middle between two line pulses, that will Zeilenzugablenkgerät by the line pulses preceding at different time intervals influenced in various ways. To eliminate this last-mentioned phenomenon one introduced impulses or oscillations of the double line frequency and this frequency from Transmitter transmitted along with it, so with every line train the same distance between the line train pulse and the previous line pulse is ensured is.

The invention now relates to a circuit, is avoided with w = hich that a flattening of Zeilenzugimpulses a Ung e # j accuracy the use of the lines acts train loading. In a known way, the line synchronization pulses are sent by the transmitter in an uneven sequence, ie also during the line change characters, via the same channel. As with the acquaintance, the moment at which the line-pull deflection generator is triggered is determined by an amplitude value that results from the superimposition of the line-pull pulses with the oscillation of an auxiliary voltage, which has twice the line frequency for two line lines per whole image. According to the invention, however, these auxiliary oscillations are generated by an auxiliary voltage generator which is arranged on the receiving side and is controlled by the line frequency. Since the characters supplied by the auxiliary voltage generator are much shorter and therefore steeper than the line pull change characters, there is a precisely defined starting point for the line pull breakover voltage. With this arrangement, on the one hand, the transmission of the double line frequency is unnecessary; on the other hand, measures and devices are superfluous which, for example, have the effect that of the characters sent at the double line frequency only controls the line deflection generator intended for this purpose Line change generator is blocked for a line duration g $ after it has been triggered. When the receiver is put into operation, measures are also required to select the correct one from the signals received. All of these difficulties are eliminated when using the invention.

In the case of the interlace method with two lines, the auxiliary voltage generator tuned to double the line frequency. Signs are thus generated through him, which coincide with the beginning of the actual line pulse, and those which fall exactly in the middle between two line pulses. The required The accuracy of use is therefore guaranteed for both trains. This auxiliary tension generator expediently consists of a oscillation circle, which is set to the desired auxiliary frequency is tuned and controlled by the line frequency. This can be done by that: he with .the separating means for the line pulses or with the output of the line toggle generator is coupled. On the other hand, he has to tilt the generator with the input circuit stay in contact. The figures explain the invention using an exemplary embodiment.

Fig. I shows the coupling of the line tilt device and the image change tilt device shown. From the receiver 16 in a known manner, in addition to the image signals also the short line and the j2-nge image change resp. Draw symbols added. An Amphtudensieb separates in well-known Reject the icons. After that, the synchronization signals come through simply illustrated frequency sieves 17, 18 in the two channels for the line or image: d @ alternate tilting device i or 2. The filter 17 only lets through (he higher-frequency short bursts of lines, while i S has an integrating effect to change the image to get the tilting device 2. The picture change impulse now hits there as a result the flattening effect of the filter .with a flattened forehead. That on this However, synchronic characters that are flattened in a wise manner do not result in a precisely defined starting point for the Bild- or Zeillen.zu-ivechsel. Rather, it must have a certain range of fluctuation be expected, even the smallest of deviations will disturb the image impression Grid shift results.

The tilting devices for generating the deflection voltages are shown in the simple embodiment, each with a tilting capacitor 3, 4, a charging resistor 5, 5 'and an elite charging tube 6, 6'. One post amplifier each;,; ' in connection with a push-pull transformer 8, 8 'each provides the deflection voltages for the beam movement in the fier Braun tube 9. The two tilting devices i and 2 are connected to one another via the circuit io tuned to double the line frequency. D'eser circle is excited inductively by i by means of the excitation coil ii, which is located in the anode circle of the line tilt device i; it is bridged by a parallel resistor 12 in such a way that the excitation takes place with an appropriately low energy. The circuit io is tuned with the aid of the capacitor ioa. Dicc damping of circle io is chosen to be as small as technically possible so that the two oscillations, the line frequency and its octave, do not have any noticeable difference in amplitude during and after the excitation by 12.

The double line frequency is now also decreased inductively via the coupling coil 13. The voltage of this frequency is set by the regulating resistor 14 to a value still to be discussed. If the thus regulated line octave voltage is added to the image change signal flattened in FIG. 1 8 via the line 15 and fed to the tube 6, the grid-controlled discharge tube 6 receives a precisely defined starting point for the ignition, whereby the line change is precisely fixed is.

In the Fig.2a to 2d is a graphical representation of the time The course of the signs given; namely are the transmitted and received @ sync pulse @ e for the line with 19, for the picture change with 2o. The voltage curve is shown in Fig.2b shown behind the low-pass filtex 18. It only contains the pulse change, with a strongly flattened wave front. Fig. 2 c shows the almost undamped Row octave shrinkage, as shown on the variable resistor 14 behind .dem resonant circuit 1 o, is removed. Finally, in Fig. 2 d is the superposition of the stresses drawn according to 2b and 2c, with the amplitudes as they are used to ensure synchronization are required. The setting of the amplitude at 14 is to be carried out in such a way that that the auxiliary oscillation 2c alone is not enough to the discharge tube 6 to To bring ignition. In the: Fig.2b and 2d the ignition voltage is entered with s. It can be seen that the image change characters only lead to ignition at point Z in Fig. 2b would, but recognizes that because of the flat course the required goodness cannot be expected. In Fig. 2 d, on the other hand, the over: superimposition of this signal 2b with the Zeüenoctave 2c in point Z @ eän essential steeper curve achieved.

The setting of the Ssgnalamplitwden at resistor 14 are after initial adjustment after changes to the recipient setting no more changes required because the level of the auxiliary voltage is twice as high Line frequency does not depend on reception at all, but on constant Amplitude adjusted line tilt part is always supplied with constant strength. A regulation of the line jump grid is therefore against changes within wide limits insensitive to the reception amplification by the operator.

Claims (1)

PATENT CLAIMS: 1. Arrangement for controlling the line train deflection generator when receiving television broadcasts according to the Zei: enspr ung method, in which the cell train pulses and in uninterrupted sequence the line pulses are transmitted over the same channel and separated from each other on the receiving side and the outlook of the triggering of the line train generator is determined by an amplitude value which results from superimposed on the line train pulses with the oscillation of an auxiliary voltage, which has twice the line frequency for two cell trains per picture, characterized in that this auxiliary oscillation is provided by one on the receiving side, by the Line frequency controlled generator is generated. , 2. Arrangement according to claim 1, characterized in that .the auxiliary voltage generator consists of an oscillating circuit which is coupled on the one hand to the output of the line deflection generator, on the other hand to the input of the Zei: lenzwg deflection generator. -3. Arrangement according to claim 2,. characterized in that the coupling is inductive. 4. Arrangement according to claims 1 to 3, characterized in that means are provided for adjusting the amplitude of the auxiliary system. To distinguish the subject of the application from the state of the art, the following publications were considered in the granting procedure: German patent specification ...... No. 566 663; Swiss - ...... - 181 929; French - ...... - 773 485; British patents. . . . - 443 699, 448034 448o66, 455858.