DE1009731B - Tilting vibration generator with means for linearization - Google Patents

Description

GERMAN

In the case of breakover wave generators, especially those for line or image deflection on television receiving tubes, it is often observed that the linearity of the breakover oscillation is unsatisfactory, especially at the beginning of the rising branch of the breakover voltage. This non-linearity can be seen in the diagram in FIG. 1: A line tilting oscillation generated in the usual tilting generators and consisting of the rising part α and the recoil part 2 is shown. The first part of the curve part a, which is denoted by a ' , has the frequently observed non-linearity, which consists in the fact that the slope of the curve α in this part a' is considerably steeper than the rest of the course of the part o. The time component this part, which is too steep in comparison to the rest of the curve of the tilting curve, is approximately V ₅ to V _{10 of} the total period of the tilting oscillation. Is shown in Fig. 1, the case that the nonlinear part a? about Ve of the entire dump period.

The invention serves to solve the problem of correcting the described non-linearity of a breakover voltage at the beginning in such a way that practically the entire course of the curve part α becomes straight, in particular that the excessively steep rise at the beginning ceases to exist. Up to now, auxiliary coils with variable self-induction have been provided for this in the actual deflection circle, in particular in the line deflection circle, for the variation of which movable mass cores were usually used. The disadvantage of these known means is that in particular the line breakover voltage is thereby reduced and thus the line width is also reduced, so that in many cases the diameter of the existing picture tube is not completely filled with the given means.

The difficulties mentioned are eliminated by the present invention in the following way: In the tilt generator circuit, in particular in the line tilt section of a television receiver, for example, a compensation oscillating circuit is arranged in the anode circuit of the generator tube in front of the tilt output transformer, which is tuned to a multiple of the frequency of the tilting oscillation to be linearized . This compensation oscillating circuit is preferably arranged in such a way that it is also located in the working circuit of the rectifier (the so-called booster diode) connected to the breakdown transformer. The purpose and effect of this ■ - as much as possible damped -Kompensations resonant circuit are first explained also to the diagram in Figure 1: The return part s of the relaxation oscillation of the compensation oscillating circuit is triggered h to a vibration whose first half-wave to the start. of the curve part α is opposite. the

Tilting vibration generator with means
for linearization

Applicant:

Loewe Opta Aktiengesellschaft,
Berlin-Steglitz, Teltowkanalstrasse. 1-4

Heinrich Reger, Düsseldorf,
has been named as the inventor

The frequency of the compensation oscillating circuit is expediently dimensioned so that when the non-linear

Part a! of the tilting oscillation curve - of the entire tilting period, the compensation oscillation frequency = - = - is. In this case the first one works

Half-wave of the compensation oscillation h with on the rising part a! of the tilting curve, so that during this first half period the amplitudes of the rising part of the tilting oscillation take roughly the course of the dashed curve part a " . The dotted second half-wave of the compensation oscillation h and its subsequent periods are practically no longer effective , because the positive half-waves are suppressed by the booster diode and the later periods due to the damping of the compensation oscillating circuit are so small that they no longer appear.

A circuit is known in which, in order to solve the same problem, i. H. for linearizing the long part of a relaxation oscillation, a resonance circuit is used. In this case, however, the The frequency of this resonance circuit corresponds approximately to the frequency of the relaxation oscillation to be corrected. With such a circuit, it is true that a curvature in the beginning of the long part of the relaxation oscillation can be achieved compensate, but this is done at the expense of an increase in second part of this breakdown voltage curve, which in this way compared to its otherwise straight line Course experiences an undesirable curvature. - ■ Im

- .. ■■ 709 547/338

10

In contrast, when dimensioning the resonance circuit at a frequency that is multiple the tilt frequency is, to a greater extent, the guarantee that only the particularly strongly curved Initial part of the long breakover voltage curve in the desired sense of the voltage the resonance circuit is influenced, d. H. is made straight, while the rest of the breakdown voltage curve hardly undergoes any change due to the damping of the resonance circuit.

Fig. 2 of the drawing shows an embodiment of the circuit used to implement the inventive concept, which only the Understanding of the invention belonging parts of a relaxation generator, e.g. B. the line tilt generator a Television receiver, contains: The output tube 1 of the line tilt generator is initially in the anode side usually connected to the breakdown transformer 2, from which a branch to the line deflection coil 3 leads. Another branch leads from the winding of the flyback transformer to the booster diode 4, the anode of which is in the anode lead to the tilting tube 1. In this anode lead is now According to the invention, an auxiliary oscillating circuit 5 is provided, for example from one in the anode line lying coil 6 and a capacitor 7 arranged parallel to this coil. Further a parallel damping resistor 8 can be provided. The one connected to the anode voltage source The point of the compensation oscillation circuit 5 is at the same time as the screen grid Tube 1 connected. The other end point of the compensation circuit 5 leads via a capacitor 9 to the end of the flyback transformer winding 2 remote from the anode.

The self-induction of the coil 6 of the compensation oscillating circuit 5, for. B. by Attaching a mass core movable in a known manner, designed to be variable, so that the frequency the compensation oscillation can be set continuously in such a way that the best correction of the linearity arises. In addition, the damping resistance 8 can be made variable so that the The amplitude of the compensation oscillation can also be measured in such a way as to achieve a corresponds to optimal linearity correction.

Depending on the given conditions, it can also be used in conjunction with the compensation oscillating circuit an additional rectifier can be provided instead of the booster diode. With very strong attenuation of the Compensation oscillation circuit, in which practically only the first half-wave occurs, is sufficient it may also be possible to dispense with the rectification of the compensation oscillation.

Favorable values for the data of the compensation oscillation circuit are: L = 4mHy, C = 600OpF, R = 3 kiloohms.

In addition to television receivers, the invention is also suitable, for example, for oscilloscopes.

Claims (7)

Patent claims: 1. Breakdown vibration generator with means for linearizing the long breakdown voltage flank, especially for the line tilt in television receivers, using the breakover voltage curve influencing compensation oscillating circuit, the one in the anode circuit of a tube in front of a breakover output transformer is arranged, characterized in that the compensation oscillating circuit on a multiple, preferably three times the sweep frequency is tuned. 2. Tilting vibration generator according to claim 1, characterized in that the compensation oscillation circuit at the same time in series with the one connected to the breakdown output transformer Rectifier (booster diode), namely connected to its anode, is arranged. 3. Tilting vibration generator according to claim 1 or 2, characterized in that the frequency of the compensation resonant circuit is dimensioned so that, if the breakdown voltage of the linear course deviating part temporally - the entire tipping period, the compensation frequency is about - is dimensioned. 4. Tilting vibration generator according to claim 1 or the following, characterized in that the Compensation resonant circuit is so strongly damped that practically only the first half-wave of each in the oscillation triggered by the return line comes into effect. 5. tilting vibration generator according to claim 1 or the following, characterized in that the Compensation oscillation circuit from a coil located in the anode line to the tilting tube with a parallel capacitor and, if necessary, a parallel damping resistor. 6. tilting vibration generator according to claim 1 or the following, characterized in that the Coil of the compensation oscillation circuit and, if applicable, its damping resistance are designed to be changeable for continuous regulation of the linearity. 7. tilting vibration generator according to claim 1 or the following, characterized in that the Self-induction of the compensation oscillation circuit about 4 mHy, its capacity about 6000 pF and its damping resistance is about 3 kiloohms. Publications considered: German Patent No. 895 175. 1 sheet of drawings © 709 547 / 33S5.57