SU681478A1 - Method of correcting astigmatism in cathode ray tubes - Google Patents

Description

(54) METHOD OF CORRECTION OF ASTIGMATISM IN ELECTRON-BEAM PIPE

This system 8 is oriented along the angle in such a way that the direction of one of the sweeps coincides with the direction of the sides of the electrodes of the cylindrical lens located perpendicular to the axis of the 7-tube.

The electron beam produced by the searchlight 1 passes through the region of the cylindrical lens (electrodes 2 and 3) and deviates from the tube axis under the action of a dynamic potential applied to its electrodes. Focused in, area; axisymmetric electrostatic lens, (electrodes 4, 5, 6), deflected from the tube axis by the magnetic field of a magnetic deflecting system 8 containing two pairs of horizontal and frame coils, and hits the screen (or target) 7. In the case when the third spatial harmonic of the deflecting current is zero, i.e. angular DENSITY, winding the turns of the deflecting coils distributed over cosine, the deflection of the beam in any direction by two pairs of coils (line and personnel) is similar to the deflection of one pair of coils, the axis of the magnetic field of which coincides with the direction of deflection of two pairs of coils. As a result of the astigmatism of the deviation, the beam on the screen is presented in the form of an ellipse, with (the bottom of whose main axes is directed toward the center of deflection.

As the ratio of the third spatial harmonic to the first (ij / i) is greater than zero, but less than 0.2, it is possible to fully compensate for the astigmatism of the deviation on the target by introducing dynamic sub-focusing with cylindrical and axisymmetric lenses. The upper limit of the specified range is determined by the fact that a further increase in the value of 1e / C is associated with an increase in the length of the deflecting system, leading to a noticeable increase in the dimensions of the tube, which is impractical.

The values of the optimal harmonic ratios obtained in the calculation are achieved by selecting a certain distribution of the angular density of the windings of the turns of the magnetic deflecting system, which differs from the xyzinusoidal one, at which ig / i is 0. So, in the case of using the magnetic deflecting system, the ij / i value corresponding to the transformation of the astigmatism ellipse at. the diagonal direction of the beam deflection into a circle, the first dynamic potential U, applied to the focusing electrode of an axisymmetric lens, translates the ellipse into a horizontal stroke, i.e. combines the surface of the meridional focus of 5 m with the screen plane. The second dynamic potential L supplied to the electrodes of the cylindrical lens reduces the horizontal edge to a point, i.e. combines the surface of the sagittal focus with the plane of the screen. Thus, at all points of the screen, the beam astigmatism will be completely corrected.

In modern transmitting and receiving television tubes, as well as oscillographic ones, the resolution at the edges of the screen (target) is on average 20-30% lower compared to its value in the center of the screen.

0 (targets) mainly due to image astigmatism.

The application of the proposed method of correcting astigmatism makes it possible to obtain a uniform resolution method 5 across the entire image field with a value equal to its value in the center, and thus significantly improve the image quality.

Claims (2)

1. A method for correcting astigmatism in a cathode ray tube with electron focusing and magnetic deflection containing a cylindrical lens by feeding to electrodes of a dynamic potential cylindrical lens, distinguished by the fact that, in order to improve the correction of astigmatism, an axisymmetric focusing electrode 0 lenses additionally supply dynamic potential, with dynamic potentials varying in quadratic law from the magnitude of the beam deflection in the directions of the sweeps. 5 2. Method POP1, characterized in that the ratio of the third spatial harmonic of the deflecting current to the first is chosen in the range greater than zero, but less than 0.2. 0 Sources of information taken into account in the examination 1. Bonstedt B.E., Markovich M.G. Focusing and deflection of beams in electron-beam devices, m., 1967, with. 97-99. 2. US patent 3887834, publ. 1975. ./tl 6 9