DE2365985C3 - - Google Patents

Description

It is known (DE-OS 15 14 896) to achieve an anastigmatic deflection coil device by that the shape of the magnetic field acting on the electron beam for one deflection direction (e.g. horizontal or vertical) depending on the strength of the deflection field for the second deflection direction (vertically, horizontally) is changed. For this purpose, additional pairs of correction coils are on the core the deflection coils provided symmetrically to the deflection directions. Here the deflection coils are like this designed so that anastigmatism in the two deflection directions and astigmatism in the diagonal is available. The correction coil pairs are z. B. fed via active elements with modulated currents. The known deflection coil device requires special modulation circuits and is therefore relative complex and expensive.

It is also an anastigmatic deflection coil device known (DE-OS 19 42 735), in which in Beam direction are provided in front of the deflection coil pairs of correction coils. The deflection coils are like this designed so that anastigmatism in the diagonals of the image and astigmatism in the deflection directions is available. The correction coil pairs generate a correction field, which such a predistortion causes the distortion caused by the deflection coils to be compensated in the two deflection directions will. It is also necessary here to modulate the currents for the correction coil pairs. In the known anastigmatic deflection coil device is the originally circular cross-section of the Electron beam or - with multi-beam tubes

- The individual rays lying on the circumference are deformed into an ellipse before it is removed from the deflection field Deflection coils is deflected. Since the deflection coil, from which the electron beam is then deflected, generates the opposite error, i.e. an ellipse that is 90 ° compared to the first-mentioned ellipse is rotated, the astigmatic error is canceled. In the case of a diagonal deflection, the correction field becomes zero, so that no predistortion by the correction coil pairs occurs

In the last-described deflection coil device, however, has the disadvantage that the or the Electron beams spatially one after the other from the correction field of the correction coil pairs and the field the deflection coils are deflected, so that the correction field and deflection field are spatially one behind the other and their centers of distraction do not coincide. This results in a bad landing of the Electron beams, which is detrimental to color purity

It is also a color television display device comprising a cathode ray tube with a display screen and a deflection coil system known (DE-OS 2031 837), in which a correction in the deflection plane The deflection coil system consists of a first and a second deflection coil unit each unit containing two symmetrical coil halves arranged opposite one another, and whereby the first unit is shifted by 90 ° in the tangential direction compared to the second. For correction jo the so-called isotropic astigmatism is the deflection coil system with at least four windings provided, which are arranged tangentially opposite one another at an angle of 90 °, in such a way that two of these opposite windings at the two gaps between the symmetrical Coil halves of one of the two deflection coil units lie. There are circuits to go through the four windings to send a correction current, which is dependent on a current that is essential to the -ui Square of the deflection current through the first and / or by a current which is essentially the square of the The current through the second deflection coil unit is proportional of the electron beam from the four windings to the 4> called currents proportional four-pole field generated.

On page 3 of DE-OS 20 31 837 it is mentioned that the desired correction in each case must necessarily be carried out with a four-pole field, as it is for example there in FIGS. 4 and 8 is shown. In this case, however, there is the requirement that the in itself error-free deflection in the diagonals by the four-pole field must not be destroyed. That's why the the correction current flowing through the four windings is selected so that its value becomes zero when the The electron beam or the electron beams are due to the deflection straight on the diagonal are located. There is then no four-pole field. This is achieved by a mixing circuit in which the out The portions of the correction current obtained from the deflection currents are mixed according to this requirement will. The complexity of the known deflection system is relatively large due to the complex mixer circuit. Even there is a risk of voltages in the four windings due to the deflection fields of the deflection coils can be induced. This leads inter alia. to an increased power requirement for the deflection coils.

According to the preamble of claims 1 and 2, the invention is based on the last described known device according to DE-OS 20 31 837.

The invention is based on the object in such a deflection device with astigmatism in the Distraction directions and anastigmosis in the image diagonals reduce the effort required for astigmatism to eliminate, in such a way that neither additional correction coils nor modulators for modulating the Amplitude of the deflection current in one deflection direction as a function of the deflection current in the other Direction of deflection are required.

The object is achieved according to the invention by what is stated in the characterizing part of claim 1 or 2 specified measures. An advantageous further development of an embodiment is in claim 3 specified.

Although a deflection device is known (DE-AS 15 37 981), in which the astigmatism is eliminated and the deflection coils themselves are used for this correction. In this known circuit is the Individual coils of one of the deflection coil pairs are supplied with a correction current which the individual coils in opposite directions Direction flows through The correction current is caused by the deflection current in the other pair of deflection coils modulated

Various exemplary embodiments of the invention are explained in more detail therein with reference to the drawing shows

F i g. 1 the deflection errors caused without correction,

Fig.2 an astigmatic and an anastigmatic Color triple,

F i g. 3 toroidal deflection coils through which both the deflection current and the correction current flow will,

4 shows a basic circuit for generating corrected deflection currents within the meaning of claim 2,

FIG. 5 control voltages in the circuit according to FIG. 4 and

F i g. 6 shows a further development of the circuit according to FIG. 4th

F i g. 1 shows the deflection errors of a color picture tube, which are eliminated by the invention. The deflection coils of the deflector (not shown) deflect the three electron beams astigmatically in the two deflection directions, d. i.e., the color triples lie on ellipses 2 and 3 in the horizontal and vertical deflection direction because of the lying ellipses

2 one speaks of horizontal astigmatism in the E-W axis. Accordingly, there is vertical astigmatism in the NS axis. In the diagonals of the screen 1, the color triples lie on circles 4. The deflection takes place here anastigmatically. In order to also achieve anastigmatism in the two deflection directions, it is necessary that from the ellipses 2 and

3 circles become what is achieved through correction.
Fig.3 shows how the toroidal coils for the one

Deflection direction can be used simultaneously for the correction. Care must be taken that the toroidal coils 10 are switched in the opposite direction to the correction current as required for the deflection. This is achieved by feeding the deflection current Iam and the correction _{current / * orr} shown in FIG. The toroidal coils 10 wound on the core 9 are the horizontal deflection coils. It can be seen that due to the superposition of the deflection current with the correction current, in each case when the deflection is made into the associated outgoing or Half of the screen a field reinforcement and in the

field weakening occurs in the other half of the screen. This results in the correction according to Fig. 2.

In the F i g. 4 and 5 shows how such a desired attenuation of the deflection field is achieved in a Allowing distraction to be achieved by having a correspondingly corrected deflection current generated in the deflection coils compared to its uncorrected Size is reduced with increasing deflection.

This is shown in FIG. 4 for the vertical deflection. Two output stages 11, 12 with individual coils 13, 14 for the vertical deflection are shown, which are operated with a control voltage Ust (sawtooth) via resistors 15, 17, 19, 21 and diodes 16, connected in anti-parallel. 18 and 20, 22 can be controlled. The resistors 15, 17, 19, 21 are dimensioned in such a way that di <in FIG. 5 show the curves of the control voltages Ust and Usa , d. That is, the deflection current (and thus also the deflection field) is of different magnitude in each of the two individual coils 13, 14 during one trace half.

6 shows a modification of the circuit nacl F i g. 4. With the potentiometer 24 the anastigmatism setting is done at the lower one, with the potentiome ter 25 at the top of the picture. The vertical deflection amplitude can be adjusted with the potentiometer 23.

For this purpose 3 sheets of drawings

Claims (3)

Patent claims: 1. Device for anastigmatic deflection of the electron beams of a television picture tube with two mutually perpendicular deflection directions, in which the toroidal deflection coil pairs fed by the deflection current, each consisting of two individual coils, are designed so that without correction in the diagonals of the picture anastigmatism and in both Deflection directions astigmatism is present, and with an additional correction of the deflection field in the sense of eliminating the astigmatism, which is ineffective if the electron beam is in one of the diagonals as a result of the deflection by the deflection coils, characterized in that a separate correction for each deflection direction with a correction current (hon) derived from the associated deflection current in this direction, the correction current (I _corr ) being fed into the two individual coils (10) of the deflection coil pair in such a way that the deflection current during its first half of the delay time is in the first en individual coil is reduced and correspondingly increased in the second individual coil and it is increased during its second half of the trace time in the first individual coil and correspondingly reduced in the second (FIG. 3). 2. Device for anastigmatic deflection of the electron beams with a television picture tube two mutually perpendicular deflection directions, in which the toroidal deflection coil pairs, each consisting of two individual coils, fed by the deflection current, are designed in such a way that without correction in the diagonals of the image anatigmatism and in It is known that television sets require means to deflect one or more electron beams. The deflection is done by magnetic fields, which are generated by deflection coils and the beam or the electron beams in two to each other deflect vertical directions. Distraction errors occur because of the image area of the screen does not represent a spherical surface with respect to the center of deflection and because of the non-momogenic Deflection field different electrons of the electron beam are deflected to different degrees. A round one As a result, the electron beam generates, for example, a light spot on the screen that is elliptical. Based on the imaging errors known from optics, one then speaks of an astigmatic Failure or simply from astigmatism. To create a round light spot anywhere on the screen, an anastigmatic deflection coil device is required. In the case of color television using a shadow mask tube, the deflection errors occur except for the individual ones Electron beams themselves also noticeable when the three electron beams work together. You can imagine the electron beams as a single electron beam. Express the distraction errors get into trouble adjusting convergence and color purity. The appearance of astigmatism is noticeable by the fact that the color points excited by the electron beams (color triples) lie on an ellipse instead of a circle. There is also a desire here to have the deflection coil device ÄfiäSugfriäiiSCii AusüSZüicgcn. 40 45 50 55 the two deflection directions astigmatism is present, and with an additional correction of the deflection field in the sense of eliminating the astigmatism, which is ineffective when the electron beam is due to the deflection by the deflection coils in one of the diagonals, characterized in that one for each deflection direction own correction, which is only dependent on the control voltage for the associated deflection current of this direction, is provided that each individual coil (13, 14) of a deflection coil pair is assigned an output stage (11, 12) for power supply, and that the sawtooth control voltage (Us,) is assigned to the output stages via a pair of anti-parallel connected diodes (16, 18; 20, 22), with which adjustable resistors (15, 17; 19, 21) are connected in series, the resistors are set so that during the first half During the delay time, a smaller deflection current flows in the first single coil than in the second single coil and in the second In half of the delay time in the second individual coil, a smaller deflection current flows than in the first individual coil (Fig. 4 and 6). 3. Device according to claim 2, characterized in that the input-side electrodes of two diodes (18, 22; 16, 20) polarized in the same direction, each via a first or second potentiometer (24, 25) are connected to one another and the control voltage from the tap of a third potentiometer (23) is common to the taps of the first and second potentiometer (24, 25) is supplied (Fig. 6).