SU999125A1 - Optronic system with electrostatic focusing - Google Patents

Description

The invention relates to electronic engineering, in particular, to structures of electron-optical systems (EOS) of electron-beam tubes (CRT),

An EOS is known, comprising a cathode, a modulator, an anode, first and second focusing electrodes.

Such a design allows for an increase in the uniformity of resolution over the field of the screen by forming the distribution of luminance in the spot, however, the resolution itself remains low.

The closest technical solution to the present invention is an EO.C with electrostatic focusing, containing a cathode, a modulator, a focusing lens, consisting of three electrodes, the first and third of which are electrically interconnected, cutting the aperture, an additional electrode focusing electrode and the anode such EOS to prevent secondary electrons knocked out from the edges of the cutting diaphragm from entering the area of the main forcing lens; the potential of the additional electrode should be lower than the potential of the cutting lens. aperture, i.e. The hyphenic j electrode is simultaneously anti-dinatronic. Such a requirement is limited. It does not affect the range of effects of the potential of the additional electrode on the aperture of the electron beam in the region of the main focus of the lens, and therefore on the angle of convergence of the electron beam at the screen, which does not allow reducing the aberration of the electron beam, the aberration of deviations, and limits the further increase in resolution across the entire screen field. .

The purpose of the invention is to improve the image quality by increasing the contrast across the screen field at small points of the beam and increasing the dependence of the contrast value on the sub-focusing voltage.

Claims (2)

This goal is achieved by the fact that an electrostatic focusing EOS containing a cathode, a modulator, a focusing lens consisting of three electrodes, the first and third of which are electrically interconnected, the cutting diaphragm, the additional electrode, the focusing electrode and the anode, are equipped with four additional apertures, of which the first and second along the beam are placed between the third electrode of the focusing lens and the cutting diaphragm, the third between the cutting diaphragm and the additional electrode, even the mouth is between the auxiliary and focusing electrodes, while the first aperture has a self-contained output, a second electrically connected with the first electrode of the focusing lens, a third and a fourth are electrically interconnected, the second electrode of the focusing lens is electrically connected to the auxiliary and focusing electrodes, cutting out the diaphragm is electrically connected to the first electrode of the focusing lens, and the distance between the third diaphragm and the additional electrode, between the additional The electrode and the fourth diaphragm and between the fourth diaphragm and the focusing electrode are at least 2/3 of the diaphragm orifices diameter. The drawing shows the EOS EOS circuit consisting of cathode 1, modulator 2 and the first electrode 3 of the focusing lens with holes 4 and 5, the second electrode 6 with a hole 7, the third electrode 8 with a hole 9 electrically connected to the first electrode 3, the first additional diaphragm 10 with a hole 11, have a self-contained terminal, the second additional diaphragm 12 with a hole 13 and cutting out afragmy 14 with a hole 15 which are under the potentials of the electrode 3, a third additional aperture 16 with a hole 17, the additional electrode composed of two plates 18 and 19 with apertures 20 and. 21 electrically connected to a focusing electrode of a fourth additional diaphragm 22 with a hole 23, which is under the potential of a third additional diaphragm 16, a focusing electrode 24 with a hole 25 and an anode 26. The drawing also shows the first crossover .27, electron beam 28, passing part 29 of the electron beam, the second crossover 30, the last part 31 of the electron beam falling on the screen, electron spot 32 on the screen 33. The EOS works as follows. An immersion lens formed by electrodes 1-3 forms an electron beam 28 and a crossover 27. The electron beam 28 is accelerated by an electrode 3, sub-focused by a lens, developed by three electrodes 3, b and 8 with apertures 5, 7 and 9 and limited by aperture. The PCR portion 29 of the electron beam 28, by means of a single lens formed by the third electrode 8 of the focusing lens with aperture 9, the first and second additional diaphragms 10 and 12 with apertures 11 and 13, forms the second crossover 30 and is limited in current and aperture by the aperture 15 low voltage cutting aperture 14, which is under the potential of the first electrode 3 of the focusing lens. The passed part 31 of the electron beam 28, which directly forms the beam current, with the help of lenses formed by a cutting diaphragm 14 with a hole 15 and a third additional diaphragm 16 with a hole 17, as well as the specified diaphragm1 "16 and an additional electrode formed by plates 18 and 19 with holes 20 and 21, an additional electrode and a fourth additional diaphragm 22 with a hole 23, a diaphragm. 22 and a focusing electrode 24 with a hole 25, enters the main focusing lens formed by the focusing electrode 24 and the anode 26, and forms an electron spot 32 on the screen 33. By changing the potential at the first aperture -10, you can choose the minimum size of the second crossover 30. The change in beam current is compensated to a known limit by changing the current of the cathode by increasing or decreasing the voltage on modulator 2. When the voltage on the modulator 2 is constant, a change in potential on the additional diaphragm 10 allows L is varied the slope of the modulation characteristics of the beam current. A change in potential at the third 16 and fourth 22 additional diaphragms makes it possible to reduce the aperture of the transmitted part 31 of the electron beam 28 in the region of the main focusing lens, reduce the aberration of the electron beam, and reduce the convergence angle of the electron beam at the screen. CRT. The optimal design of the focusing lens was determined experimentally with the distance between the third aperture 16 and the auxiliary electrode (plates 18 and 19), the auxiliary electrode and the fourth aperture 22, the fourth aperture 22 and the focusing electrode 24 of at least 2/3 of the hole diameter in them. At a distance of less than 2/3 of the bore diameter, the effect of the additional diaphragms is insignificant. The potential of the third additional diaphragm 16 must be less than the potential of the cutting diaphragm 14 in order not to miss the secondary electrons knocked out of the opening 15 of the cutting diaphragm 14. An increase in the dependence of the angle of convergence at the screen on the voltage of the additional diaphragms 16. And 22 leads to an increase in the dependence of the magnitude Contrasting across the field of the screen from the focus voltage. The ability to adjust the size of the second crossover by varying the potential at the first additional diaphragm 10 without changing the aperture of the past part 31 of the electric beam 28 allows a significant increase in contrast in small parts across the entire screen field. The lenses formed by diaphragm 16 and plate 18, plate 19 and the diaphragm 22, diaphragm 22 and electrode 24 can be adjusted so that the voltage on the diaphragms 16 and 22 is the same with the voltage on the cutting diaphragm 14 and electrically to connect. In this case, the number of supply voltages decreases, and the additional diaphragm 16 serves as the background voltage. 1 Thus, the proposed EOS scheme makes it possible to increase the contrast in small parts over the entire screen field with an increase in the dependence of contrast on the focusing voltage. The use of such an EOS will make it possible to improve the image quality across the e-wound field in receiving CRTs with a low beam current with both monolithic and fiberglass screens. An Electro-Electrostatic Focusing Electro-Optical System Containing a Cathode, a Modulator, a Focusing Lens Consisting of Three 27 5 7 o ft.., 0 2f iVb lr "2Sfg 10 1229 k IS Id 19 electrodes, the first and third of which are electrically interconnected, cutting a diaphragm, an additional electrode, a focusing electrode and an anode, which is different in order to improve image quality due to the contrast across the field screen, it is equipped with four additional :, diaphragms, of which the first and second along the beam are placed between the third electrode of the sub-focus lens and the cutting diaphragm, one-third between the cutting diaphragm and the additional electrode, one-fourth between With the additional and focusing electrodes, the first additional diaphragm has a self-pin, the second is electrically connected to the first electrode of the focusing lens, the third and fourth are electrically interconnected, the second electrode of the focusing lens is electrically connected to the additional and focusing electrodes, the trimming diaphragm is electrically connected to the first the electrode of the focusing lens, and the distance between the third axis and the auxiliary electrode, between the additional electrode and the the solid diaphragm and between the fourth diaphragm and the focusing electrode are at least 2/3 of the diameter of the aperture holes. . Sources of information taken into account in the examination 1.Patent of France 2109513, cl. H 01 J 29/00, published 1972. 2.ABiopcKoe certificate of the USSR 762057, cl. H 01 J 29/00, 1978 (prototype).