DE2165003C3 - Circuit arrangement for corner convergence error correction in three-beam picture tubes - Google Patents

Description

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The invention relates to a circuit arrangement for corner convergence error correction in three-beam picture tubes.

In the case of three-beam picture tubes with two line deflection part coils arranged diametrically opposite one another on the picture tube neck the electron beams are focused on the screen so that they are in the plane of the Shadow mask converge and color triples on the screen according to the arrangement of the fluorescent dots depict. In the known three-beam tubes with dynamic readjustment of the convergence and pillow rectification, it is possible to create an image that corresponds to the original without any color deviation due to to reproduce faulty image. For three-beam picture tubes with larger deflection angles, e.g. 110 °, It is difficult to achieve a deflection field in which the aberration is just by distributing the windings in the sub-coils in the corners of the image, taking into account a »landing reserve« for the color unit who are. To correct the corner convergence errors, it is known in such arrangements to use the two line deflection modules to connect in series and feed convergence currents into the center tap in such a way that they add to the deflection current in one coil and subtract in the other coil. This gives the Deflection field in the cross-sectional plane is trapezoidal Shape the corner error by twisting and unevenly shifting the groups of rays compensated in the corners of the image. This well-known "differential current generator" requires two deflection generators a relatively large effort. A differential current control is used for the corner correction of the vertical dimensions extremely difficult in the vertical deflection coils. This is why these errors are over corrected a special radial convergence.

The radial corner convergence is in principle by Modulation of the line-frequency voltage at the horizontal convergence coils with an image-frequency voltage Causes tension. This modulation requires such control of the source resistance the line-frequency control voltage that this can be increased as well as decreased. It's bekanni (TELEFUNKEN speaker 54/1971, p. 40. Fig. 4). for this control two of a push-pull winding of the Vertical deflection transformer derived gegenphusiae Exploiting tensions. However, such voltages are not always available, e.g. B. then not. if the vertical deflection circuit is designed to be "ironless" because there normally only single-phase sawtooth voltages be available.

The invention is based on the object of a job and / or control of the radial convergence even without using a push-pull winding to achieve.

The invention is based on a circuit arrangement for the corner convergence sensor correction Three-beam picture tubes, in which a line rate convergence voltage with a picture rate voltage in can be modulated in both directions, the frame rate voltage being derived from the collector of a transistor is, the separately adjustable at the input between the base and emitter electrode, the first b / w. Corresponding partial voltages are fed to the second half of the run.

The invention consists in that between the base and emitter electrodes of the transistor two parallel gcschaltete Potentiometers with a grounded tap are turned on that the wiper of the potentiometer is over Diodes are connected to a source of single-phase vertical frequency sawtooth voltage, and that the diodes are polarized so that a wiper in the potentiometer pair corresponds to the first half of the trace Part of the saw tooth tension and the other grinder that of the second half of the first half Part of the sawtooth voltage receives. For a more detailed explanation of the invention, an embodiment is given below described on the basis of the drawing. This shows in

F i g. 1 shows a simplified known circuit for corner convergence correction with generation of a two-sided modulation voltage through push-pull winding

F i g. 2 shows a circuit for obtaining the two-sided modulation voltage from single-phase sawtooth voltages and shunt control.

In Fig. 1 is a dynamic correction circuit the convergence of the red and green and blue cathode rays of a color picture tube of the Shadow mask type shown, which has a transistor pair 1, 2 with upstream driver transistors 3, 4 on-

shows. The base electrodes of the transistor pair 1, 2 are connected to one another via a potentiometer 5 and the base electrodes of the two driver transistors 3, 4 are connected to one another via a potentiometer 6. The transistors 1, 2, 3, 4 are provided with emitter resistors 7, 7ü, 8, 8a in order to ensure the operating point instability. In the collector circuit of each of the two transistors 1, 2 a convergence magnet coil 9 or 10 is switched on, to which a capacitor 11 or 12 is connected in parallel. The convergence magnet coils 9, 10 are each part of an oscillating circuit that is damped by a resistor 13 or 14. The wiper of the potentiometer 6 is connected via a diode 18 to the wiper of a potentiometer ΐ9, which is connected in series with a capacitor 20 and a resistor 21 between a sawtooth voltage source 22 and ground. An approximately parabolic increasing sawtooth voltage is therefore available at the wiper of the potentiometer 19, the amplitude of which depends on the wiper sizing. The wiper of the potentiometer 19 is also connected via resistors 23, 24 to a source of approximately constant voltage, with which the opening point of the diode 18 and the operating point of the transistors 3, 4 can be set. The wiper of the potentiometer 5 is connected via a diode 25 to the tap of a potentiometer 26 and via a further diode 28 to a source of line return pulses. The potentiometer 29 is connected in series with a capacitor 27 between ground and the cathode of the diode 28.

In the circuit described so far, the sawtooth voltage comes from the wiper of the potentiometer 19 to diode 18, which only lets through the positive part. This one, assigned to the second upstream part (right half of the picture) Part arrives with a position corresponding to the wiper position of the potentiometer 6 and the input network Amplitude distribution to the base electrodes of the driver transistors 3. 4 and causes after further amplification in the transistors 1. 2 in the convergence magnet coils 9 and 10 correspondingly parabolic increasing currents. At the end of the trailing edge or at the zero crossing of the trailing edge the transistors 1, 2, 3, 4 blocked and so the flow of current in the convergence magnet coils 9, 10 interrupted so quickly, that the stored magnetic energy in turn causes a Sirom flow, the course of which Dimensioning of the oscillating circuit 9, 11. 13 or 10, 12, 14 is equivalent to. The current due to the stored energy charges the capacitor and causes it a parabolic decaying current curve in the convergence coil, which in the first upward part approximately in the middle of the line drops to zero. This current flow is already a close approximation of the desired one Correction process (basic correction). To achieve an optimal correction, the grinder des Potentiometer 5 is supplied with an additional pulse stream which is obtained from the line return pulses. This Additional pulse current increases the during the return run Energy content of the oscillating circuit 9, 11. 13 or 10. 12, 14 and changed with the participation of /? C-members 29. 27 the waveform of the current in the first trailing part.

For corner convergence correction, in this known circuit the connection points A and the diodes 18, 25 are connected to the potentiometers 5, 6 each with the collector electrode of a transistor 30, 31 in an emitter circuit, the base electrode of which is connected to two potentiometers 32, 33 each or 34, 35 are connected. Since each of these potentiometers is connected to the ends of a push-pull winding of the vertical deflection transformer via rectifiers 36, 37, 38, 39, the transistors 30, 31 can be controlled in both directions. They thus form a controllable shunt at points A, ß of the convergence.

E i g. 2 shows a circuit according to the invention with the same output voltage of the corner convection circuit for the terminals AB, but with the extraction of this modulation voltage from a single-phase sawtooth voltage. This is done by two parallel-connected potentiometers 40, 41 and 42, 43 with a grounded center tap 44, 45, 44.7. 45 ;;, the / between the base and emitter electrodes of the transistors 30. 31 are switched on. The potentiometer veils 46. 47. 46.7. 47; i the single-phase sawtooth voltage is supplied via diodes 48, 49, 50, 51 with such polarity that for each potentiometer pair 40, 41 or 42, 43 one potentiometer is supplied with the first and the other potentiometer with the second trace half. Depending on the position of the potentiometer wiper, the sawtooth voltage is fed to the base or emitter electrode and the internal resistance of this transistor is thus increased or decreased. In this way, the four potentiometers 40 to 43 can be used to vary the convergence / in each corner area in both directions.

The invention is not limited to circuits in which - as in FIG. 1 - the convergence tone generated according to the principle of energy recovery. Rather, the circuit according to the invention is also applicable to amplifier convergence formwork, how they z. B. in the magazine Valvo "Development Communications" November 1% 9 about diversion and correction barriers for the 110 'color picture tube are.

The circuit is also suitable for corner convergence of the blue-radial convergence.

For this purpose 2 sheets of drawings

Claims (3)

Patent claims: 1. Circuit arrangement for the corner convergence error correction in three-beam picture tubes, at which has a line rate convergence voltage with a frame rate voltage in both directions can be modulated, the frame rate voltage being derived from the collector of a transistor to the separately adjustable at the input between the base and emitter electrode, the first resp. corresponding partial voltages are fed to the second half of the flow, characterized in that that between the base and emitter electrodes of the transistor (30, 31) two parallel-connected Potentiometers (40, 41, 42, 43) with a grounded tap (44, 45, 44a, 45a) are switched on that the Schleiler (46,47,46a, 47a) the potentiometer (40,41, 42, 43) via diodes (48, 49, 50, 51) with a source a single-phase vertical frequency sawtooth voltage are connected, and that the diodes (48, 49,50,51) are polarized so that in the potentiometer pair (40,41 or 42, 43) a grinder the part of the sawtooth voltage corresponding to the first half of the trace and the other wiper the part of the sawtooth voltage corresponding to the second trace half receives. 2. Circuit arrangement according to claim 1, characterized in that the transistor (30, 31) is switched on as a controllable shunt to the input (A, B) of the convergence circuit. 3. Circuit arrangement according to claim 1 or 2, characterized in that for the separate correction in the right and left halves of the image two independent circuits each with a transistor (30 or 31) and each with a potentiometer pair (40, 41 or 42, 43 ) are provided, the collectors of the transistors being connected to the inputs (A and B) of the convergence circuit which are decisive for the convergence in the first and second half of the line trace.