DE2720733A1 - East-west pincushion correction of TV receiver deflection system - superimposes correction pulses on flyback pulses, so that their amplitude is constant - Google Patents

Abstract

Line deflection current and the line transformer load are modulated at vertical deflection frequency. HV for the picture tube is generated by a rectifier from fly-back pulses and fly-back correction pulses are superimposed on the fly-back pulses applied to the rectifier. The pulses are collected from an inductance in the deflection circuit and so amplitude modulated by the vertical deflection frequency, that the amplitude of fly-back pulses at the rectifier input is constant. Correction pulses (14) are collected from an additional winding (13) coupled with the inductance (10).

Description

Circuit for east-west pillow correction of the distraction in one

Color television receiver is known to arise in a color television receiver without special corrective measures a so-called east-west pillow error, i.e. the Image width is too large at the top and bottom of the image compared to the center of the image. To the To eliminate this error, it is known to increase the vertical frequency of the line deflection current to modulate the amplitude so that it decreases at the top and bottom of the picture will.

For this pillow correction it is known (DT-PS 10 23 078), in parallel to switch the working winding of a transductor to the line deflection coil, whose Control winding is spcisted by a vertical frequency voltage. At this The solution, however, changes the load and coordination of the line transformer the amplitude of the flyback pulses and thus also the high voltage. This modulation The high voltage causes a pillow correction that is dependent on the beam current.

To eliminate this disadvantage, it is known (DT-OS 19 38 158), in series with the parallel connection of the M> steering coil and the named transducer to switch the working winding of another transductor, its control winding is also fed with a vertical frequency voltage. the steering of the two transducers takes place in opposite directions in such a way that the load on the Zeilcntransformators and so the amplitude of the return pulses remains constant. This solution is however relatively expensive because two transducers are required.

It is also known (Telefunken spokesman February 1976 page ii) in the input base point of the hole voltage rectifier cascade fed by the flyback pulses Coupling return pulses with such an amplitude that the amplitude of the Return pulses at the inputs of the cascade and thus the high voltage generated remains essentially constant.

In this solution, the correction pulses are generated by an inductance taken in the circuit for pincushion equalization. It is not always straightforward possible, the correction pulses with the correct amplitude for an optimal compensation and polarity, as the amplitude of the flyback pulses at the inductor is usually determined by other requirements.

The invention is based on the object of developing this circuit in such a way that that the correction pulses always have the correct amplitude for optimal compensation and polarity can be obtained.

This object is achieved by the invention described in claim 1 solved. Advantageous further developments of the invention are described in the subclaims.

With a corresponding number of turns of the additional winding In any case, the one for optimal compensation, i.e. keeping the high voltage constant achieve the necessary amplitude of the correction pulses. On the other hand, the Achieve correct polarity only by polarizing the additional winding. Even there is a galvanic separation between the high-voltage circuit and the circuit for pillow equalization achieved. The superposition of the correction pulses with the actual return pulses used to generate the high voltage be done additively or subtractively. An additive overlay occurs, for example, by that the correction pulses in the base point, that is, in the still voltage rectifier remote end of the high voltage winding with the same polarity as the flyback pulses at the input of the high voltage rectifier or with opposite polarity be coupled into the input base of a perforated voltage rectifier cascade. A subtractive superposition is for these two cases by an opposite one Correction pulse polarity possible. Basically, there are both types of overlay possible to the amplitude effective at the inputs of the high-voltage rectifier to keep the return pulses constant. The additive overlay has the advantage that the amplitude of the effective at the inputs of the high voltage rectifier Return pulses compared to the return pulses derived from the high-voltage winding is enlarged by the correction pulses.

The invention is based on the drawing of an exemplary embodiment explained. FIG. 1 shows a basic circuit diagram of the invention and FIG. 2, 3 two variants of the circuit according to FIG. 1.

FIG. 1 shows that controlled by the line-frequency switching voltage 1 Output stage transistor 2, the flyback transformer 3 with the primary winding 4 and the High voltage winding 5, the high voltage rectifier 6, the picture tube 7, the Line deflection coils 8 and the coupling capacitor which is also used for tangent equalization 9. In series with the deflection coils 8 is the controllable inductance 10, namely the working winding of a transductor. The inductance 10 is made by the vertical control circuit 11 modulated by the vertical frequency voltage Uv so that they are at the top and bottom The edge of the picture is large and the center of the dild is small. Then the line deflection current becomes iH desirably at the top and bottom Image border reduced. Because the inductance 10 is larger at the top of the picture, the flyback transformer is there tuned to a lower frequency of the return oscillation and thus the return pulse longer. However, since the energy stored at the end of the line is constant, this means the amplitude of the return pulses 12 generated on the winding 5 is smaller.

In the figure there are symbolically three return pulses for the upper edge of the picture, the center and the lower edge of the image are shown.

So if the pulses 12 generated in the winding 5 alone on the Penetration voltage rectifier 6 arrive, the result is a vertical frequency modulated hole voltage and thus a beam current-dependent cushion equalization, since small Beam currents flow the hole voltage from the parabolic tips or depending on the influence taken from the center of the parabola, which, however, increases relatively quickly with increasing Load collapses.

The additional winding 13 is now coupled to the inductance 10, that between the base point of the winding facing away from the hole voltage rectifier 6 5 and ground lies. At the top and bottom of the picture, the inductance 10 is large, so that there the return pulses 14 lying above the winding 13 are relatively large, while in the center of the image the inductance 10 is small and thus also the return pulses 14 are small. The sum is now at the input of the high voltage rectifier 6 of the pulses 12.1 effective. The winding 13 is now dimensioned so that this sum is constant and thus at the input of the hole voltage rectifier 6 return pulses 15 stand with constant amplitude. Then one also becomes independent of the pillow equalization constant high voltage generated and the beam current-dependent cushion equalization avoided. What is involved here is the additive superimposition of the correction pulses mentioned with the actual return pulses 12. In practice, the amplitude of the Correction pulses relative to that of the return pulses 12 be smaller than it is in FIG 1 is shown.

The circuit according to FIG. 2 works in principle like that according to FIG 1. The winding 13 is an additional winding of the transductor 16, its working winding 17 corresponds to the inductance 10 of FIG. The change in the inductance of the Working winding 17 takes place by means of the control winding 18, which is of the vertical frequency Voltage IJ is fed. The beam current v also flows here via the additional winding 13 against Nasse, namely via the RC element 19. A jet current-dependent can be connected to the ItC element 19 Control voltage UR can be taken for control purposes. This tension is used e.g. for a stabilization or strail current limitation.

FIG. 3 shows a circuit with a hole voltage rectifier 6 in the form of a cascade. Such a cascade has two entrances. Dns offers the possibility to couple the correction pulses 14 into the base of the cascade. This coupling takes place in the example shown with opposite polarity to the return pulses 12. So it is again an additive superposition, because of the correction impulses 14 the effective amplitude of the flyback pulses at the inputs of the rectifier 6 is enlarged. A subtractive elongation can be achieved in that the correction pulses 14 at the base of the rectifier 6 have the same polarity as have the return pulses 12 at the upper input of the cascade.

Claims (4)

Claims 1 <circuit for east-west pillow correction of the Distraction in a color television receiver where the line deflection current and load of the line transformer are modulated vertically in a rectifier from the Line return pulses the hole voltage for the picture tube is obtained and the The return pulses fed to the rectifier are superimposed on the return correction pulses are picked up by an inductance in the deflection circuit and so in amplitude are modulated vertically frequency that the amplitude of the return pulse at the input of the rectifier is constant, characterized in that the correction pulses (14) are removed from an additional winding (13) with the inductance (10,17) is coupled. 2. A circuit according to claim 1, characterized in that at one Pillow correction with a transducer (16), its working winding (17) in series or parallel to the deflection coils (8), the correction pulses (14) from one Additional winding (13) of the transducer (16) are removed (Fig. 2,3). 3. A circuit according to claim 1, characterized in that the additional winding (13) between the end of the lIo chspannungswi facing away from the Iloch voltage rectifier (6) ckluiig (5) and mass lies. 4. A circuit according to claim 1, characterized in that at one High-voltage rectifier (6) in the form of a cascade, the correction pulses (14) in the input base of the cascade (6) are coupled (Fig. 3).