KR950008841B1 - Deflection distortion correction device - Google Patents

Abstract

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Description

Deflection Distortion Compensator

1 is a schematic diagram of a deflection system of a video display device comprising a deflection yoke in accordance with the present invention;

2A and 2B are front and side views, respectively, of a magnetic field correction device according to an aspect of the present invention.

3 is a perspective view of a portion of the deflection yoke cut in accordance with an aspect of the present invention.

4 is a side cross-sectional view of a video display device according to the present invention.

5 is a front view of another embodiment of the field correction device shown in FIGS. 2A and 2B.

* Explanation of symbols for the main parts of the drawings

12: tuner 13: video detector

14 Sync Signal Separator 15 Chromaticity and Luminance Signal Processor

16: horizontal deflection circuit 17: vertical deflection circuit

27: adjuster

The present invention relates to the correction of raster distortion of cathode ray tubes used in video display devices.

Video display devices such as television receivers and computer monitors have a cathode ray tube for displaying video information on a fluorescent display screen. The plurality of electron beams are deflected horizontally and vertically to the electromagnetic field generated by the deflection yoke to form a raster on the display screen. The difference in the deflection distance between the edges and the edges of the display screen is warped inwards or generates pincushioned rasters unless corrected. In color video displays, physical separation of the electron beam in the electron gun assembly of the cathode ray tube causes misconvergence or other beam landing errors on the display screen.

The horizontal and vertical deflection windings of the deflection yoke are designed to provide substantial convergence and raster distortion correction by the specific distribution of each coil of the deflection winding. The winding distribution determines the overall harmonic content of the deflection magnetic field, i.e. non-uniformity, or determines a local variation in the non-uniformity of the magnetic field along the longitudinal direction of the deflection yoke.

Certain beam landing errors or raster distortions are more sensitive to correction than elsewhere in the yoke longitudinal feature region, and windings that produce local changes in non-uniform magnetic fields are particularly effective at correcting these errors or distortions. .

For example, a deflection yoke that provides self-convergence of three in-line electron beams of a colored cathode ray tube is a horizontal deflection magnetic field and a full barrel type with full pincushion magnetic field non-uniformity. Generates a vertically deflected magnetic field with magnetic field nonuniformity. Local changes in magnetic field non-uniformity are intended to correct for specific errors or distortions while maintaining the overall non-uniformity required for self-convergence.

Mechanical windings limit the amount of possible local variation, but in practice, possible winding distribution changes result in undesirable mutual interference in error or distortion. This prevents full correction of all errors and distortions, thereby requiring an undesirable compromise on the amount of correction provided.

The present invention is intended to provide an alternative to the compromise conditions described above, and allows full correction of certain raster distortion errors without degrading or degrading other beam landing conditions or beam convergence conditions.

According to the present invention, the deflection yoke for deflecting the electron beam in the cathode ray tube includes vertical and horizontal deflection windings for generating vertical and horizontal deflection magnetic fields. A magnetically permeable member constituting the closed circuit is disposed adjacent to the electron beam exit end of the yoke and modifies at least one magnetic field of the horizontal and vertical deflection magnetic fields to correct the deflection distortion introduced by the deflection magnetic field.

Referring to FIG. 1, there is schematically shown a video display device operating with a television receiver, a computer monitor, and the like. During video deflection, the device responds to the broadcast signal received through the antenna 10 and operates in response to the red, green, and blue (RGB) video signals supplied through the input terminal 11. The broadcast signal is applied to a tuner and an intermediate frequency (IF) circuit 12 to which an output is applied to the video detector 13. The output of the video detector 13 is a composite video signal that is applied to the synchronization signal Syne / separator 14 and the chromaticity and luminance signal processor 15. The synchronous separator 14 generates horizontal and vertical sync pulses applied to the horizontal and vertical deflection circuits 16 and 17, respectively. The horizontal deflection circuit 16 generates a horizontal deflection current in the horizontal deflection winding 20, while the vertical deflection circuit 17 generates a vertical deflection current in the vertical deflection winding 21. The horizontal and vertical deflection windings 20, 21 constitute deflection yokes located at the neck of the cathode ray tube 22.

The chromaticity and luminance signal processing circuit 15 receives individual red, green, and blue video signals from the computer via the terminal 11 in addition to the composite video signal from the video detector 13. The sync pulse is applied to the sync separator 14 in relation to the green video signal as shown in FIG. The output of the chromaticity and luminance signal processing circuit 15 is composed of red, green, and blue driving signals applied to the electron gun assembly 23 of the cathode ray tube 22 via the conductive wires RD, GD, and BD, respectively. The electron gun assembly 23 generates three electron beams aligned in the horizontal direction.

The power for the video display device is supplied by the AC line from the AC power source 24, which is connected to the rectifier circuit 25 and the filter capacitor 26 to form a fine-tuned DC voltage source. The unregulated DC voltage is supplied to the voltage regulator 27, which is of conventional design such as a switch-mode type regulator or an SCR regulator that generates a regulated DC voltage level + V ₁ . The + V ₁ power supply powers the horizontal deflection circuit 16.

The output of the regulator 27 is applied to the terminal 30 of the primary winding 31 of the power transformer 32. The winding 31 is connected to the horizontal deflection circuit 16. The secondary windings 33 and 34 and the high voltage winding 35 are excited by the excitation of the primary winding 31. The winding 33 generates a rectified and filtered voltage to generate a + V ₂ voltage that is used to be supplied to various circuits of the video display device, for example the vertical deflection circuit 17. Winding 34 generates a voltage to terminal 36 that is used, for example, as a feedback voltage for regulator 27. The high voltage winding 35 generates a high voltage level of the cathode ray tube 22 or a high voltage level applied to the filter terminal 37.

The deflection yoke 19 is of a self-convergence type that issues an astigmatism deflection magnetic field required to achieve the convergence of a three-line electron beam. The analysis using the cubic error theory shows that the vertical deflection field exhibits nonuniformity in the total negative polarity representing the barrel type magnetic field and the horizontal deflection exhibits nonuniformity in the total positive transverse direction representing the pincushion type magnetic field. It is explained that the actual beam convergence is obtained by the magnetic field.

While maintaining some overall nonuniformity, local changes in magnetic field nonuniformity are efficient at correcting any raster distortions and beam landing errors. For example, the E-W pincushion raster distortion resulting from the difference between the tube faceplate and the beam scanning radius can be corrected by modifying the vertical deflection magnetic field to exhibit pincushion nonuniformity near the electron beam exit end of the yoke. This local change in magnetic field nonuniformity can be achieved by varying the winding distribution of the deflection coil. Most of the correction of distortions and errors may result in yokes with coil winding distributions that are difficult or impossible to wind using known winding equipment and techniques while maintaining some overall magnetic field non-uniformity. Physical limits to modify the coil winding distribution cause interference between the error and distortion states, causing one form of error or distortion to be corrected while the other worsens. Correction compromises often result in deflection yokes that require additional distortion or error correction, for example in the circuitry of the video display device.

The correction compromise is required when the horizontal deflection coil is modified to correct the N-S pincushion distortion. This results in deterioration of the beam convergence at a central point called the A-zone between the center and the corner of the cathode ray tube display screen.

3 shows the deflection yoke 19 in more detail. The yoke 19 comprises a vertical deflection winding 21 wound annularly on the permeable core 39. The horizontal deflection winding 20 is tensioned and separated from the vertical winding 21 by an insulator 41. 4 shows the direction of the yoke 19 and the windings 20, 21 mounted on the cathode ray tube 22.

According to one aspect of the invention, the magnetically permeable device shown in FIGS. 2A and 2B shows a deflection near the electron beam exit end to provide practical NS pincushion distortion correction without reducing A-zone convergence. It is located on yoke 19. The device comprises a thin annular ring made of a high permeability material such as manganese or magnesium ferrite, located between the vertical deflection windings 21 of the insulator 41 of the deflection yoke 19 as shown in FIGS. 40). The ring 40 is glued using glue or similar adhesive to the portion of the insulator 41 surrounding the end winding of the horizontal deflection winding 20.

The ring 40 is operated by shunting a portion of the magnetic flux generated by the vertical deflection winding 21 to the ring 40 and changes the magnetic field intensity distribution along the electron beam deflection path. The change in magnetic field strength is greater in the area closer to the area farther from the ring. Therefore, the electron beam passing near the ring is more affected than the electron beam near the ring center. The ring 40 also changes the yaw magnetic field nonuniformity near the ring. Since the ring is thin, the area in the longitudinal or Z-axis direction where the ring acts effectively is small. Therefore, the electron beam passing through the ring region at an inclined angle travels a greater distance from the effective region and is therefore more affected by the ring than the electron beam passing through the ring region substantially perpendicular to the plane of the ring. . Since the deflected electron beam passes through the ring region at an inclined angle, as compared with the undeflected electron beam, the influence of the ring increases as the deflection angle increases. Since the beam crosses the plane of the ring at an increased angle of inclination, the effect of the ring increases as the deflection angle of the cathode ray tube increases. Therefore, it is possible to control the amount of N-S pincushion distortion correction by changing the longitudinal position of the ring with respect to the electron gun assembly of the cathode ray tube and the diameter and thickness of the ring.

5 shows another embodiment of the magnetic field correction device of FIG. A plurality of wire loops form a ring 42. As an example, a ring of 16 turns of 26 wires (0.405 mm diameter) provides some N-S pincushion distortion correction. The ring 42 is mounted to the insulator 41 in a manner as described for the ring 40, for example by an adhesive or some clamping device.

Claims (10)

A deflection device comprising a deflection yoke for deflecting an electron beam of a cathode ray tube in a video display device, the deflection yoke comprising: a horizontal deflection winding and a vertical deflection winding; and forming a horizontal and vertical deflection magnetic field to deflect the electron beam in a raster pattern. Means for generating a deflection current in the windings, and to correct the raster pattern distortion, to modify the magnetic field pattern for the magnetic flux generated by the deflection current flowing through at least one of the horizontal deflection winding and the vertical deflection winding; And a permeable member (40,42) adjacent the electron beam exit end of the deflection yoke in a longitudinal position to form a substantially closed path surrounding the electron beam. 2. Deflection apparatus according to claim 1, wherein the transparent member comprises a ferrite ring (40). The deflection apparatus according to claim 1, wherein the permeable member includes a plurality of concentric wire loops forming a coil. 2. Deflection apparatus according to claim 1, wherein the permeable member shunts a part of the magnetic flux generated by the vertical deflection winding (21). The deflection apparatus according to claim 1, wherein the permeable member primarily corrects the vertical deflection magnetic field. The deflection apparatus of claim 1, wherein the deflection distortion comprises an N-S pincushion distortion. In a deflection yoke for deflecting an electron beam of a cathode acid tube in a video display device, a horizontal deflection winding and a vertical deflection winding which respectively form a horizontal deflection magnetic field and a vertical deflection magnetic field by flowing currents, to correct deflection raster pattern distortion. A thin annular shape adjacent to the electron beam exit end of the deflection yoke in a vertical position to modify the magnetic field pattern for the magnetic flux generated by the current of at least one of the horizontal deflection winding and the vertical deflection winding, surrounding the electron beam. And a member, wherein the modification of the magnetic flux by the thin annular member is limited to occur in the plane of the annular member. In a deflection yoke for deflecting an electron beam of a cathode ray tube in a video display device, when a voltage is applied, a horizontal deflection winding and a vertical deflection winding respectively forming a horizontal deflection magnetic field and a vertical deflection magnetic field, and to correct the deflection distortion, the horizontal deflection yoke. And a permeable member that modifies at least one of the deflection windings and the vertical deflection windings, and which forms a substantially closed path adjacent the electron beam exit end of the deflection yoke and surrounding the electron beam, wherein the horizontal deflection winding comprises: And a tension winding having flux return end turns located at the electron beam exit end of the deflection yoke. Deflection current in the windings generating a horizontal deflection magnetic field and a vertical deflection magnetic field to deflect the electron beam in a raster pattern, a deflection yoke integrating a cathode ray tube generating an electron beam, a horizontal deflection winding and a vertical deflection winding; And means for correcting the NS pincushion distortion on the display screen of the cathode ray tube, wherein the correcting means has a permeable member disposed in a longitudinal position at an electron beam exit end of the deflection yoke and surrounding the electron beam. And correcting the NS pincushion distortion by reducing the strength of the vertical deflection magnetic field formed by the vertical deflection winding in an adjacent region of the permeable member. Means for generating an electron beam for dimming a display screen, a cathode ray tube integrating the display screen, a deflection yoke for forming a horizontal deflection magnetic field and a vertical deflection magnetic field for deflecting the electron beam, and a current flowing therein; and the electron beam Means for correcting at least one of the horizontal deflection magnetic field and the vertical deflection magnetic field generated by the deflection yoke, in order to correct raster pattern distortion associated with the deflection of A permeable member disposed in a plane perpendicular to the longitudinal axis of the deflection yoke that surrounds the electron beam without magnetization and is perpendicular to the longitudinal axis of the deflection yoke, wherein the influence of any one deflecting magnetic field on the electron beam The permeable member positioned away from the electron beam to reduce And shunt a part of the magnetic flux generated by the current in the deflection yoke occurring in the plane of the shunt.

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