SU1195386A1 - Device for colour display of information - Google Patents

Abstract

A COLOR INFORMATION DISPLAY DEVICE containing a illuminator with a point source of light and mounted on the optical axis and optically coupled to the illuminator an input aperture, a negative cylindrical lens, and a three-color sectional light filter. a phase-optical light modulator, anamorphic objective lens, an output slit diaphragm and a line scanning system, characterized in that, in order to improve the photoelectric characteristics, the first and second rasters from flat mirrors are introduced into it, and the illuminator is made in the form of an ellipsoidal reflector, optical whose axis is offset parallel to the optical axis of the negative cylindrical lens, the point source of light is set at the first focus of an ellipsoidal reflector, and the first raster of flat mirrors is located between the foci of the ellipsoidal reflector and its mirrors are optically coupled to the mirrors of the second raster, which are located at the second focus of the ellipsoidal reflector and optically coupled to the entrance pupil of the negative cylindrical lens.

Description

The invention relates to a technique for recording and reproducing information using light modulating media by electrophotographic methods. The purpose of the invention is to increase the light and energy characteristics. Figure 1 shows the optical layout of the device; Figure 2 shows control electrodes. The device (Fig. I) contains a point source of light 1, located in the illuminator 2, the input aperture 3, a cylindrical negative lens 4, a three-color sectional light filter 5, a phase-optical light modulator 6 with control inputs 7, a light-modulating medium 8 and three parallel sections 9-11 of linear electrodes 12 (FIG. 2, anamorphic lens 13, output slit diaphragm 14, line scan system containing scanning mirror 15 with LED 16, control input 17, screen 18, illuminator condenser, made at an ellipsoidal reflector 19, between the foci of which there is a first mirror optical raster 20 of flat rotary mirrors 21, and a second mirror optical raster 22 of flat rotated mirrors 23 mounted in a row on a line m -m parallel to forming a cylindrical negative lens 4 intersecting the axis of this lens, is located in the second focus of the ellipsoidal reflector 19. Linear electrodes 12 are wired on a transparent dielectric plate 24 and connected to control inputs, and between them are electrodes 25, edinonnye with an earth bus. The electrodes 12 and 25 are made transparent and oriented perpendicularly forming a cylindrical negative lens 4, and the light-modulating medium 8 is deposited on the transparent conductive layer 26 of the transparent dielectric plate 27, which is connected to the earth bus. The optical-anamorphic lens 13 contains a projection cylindrical lens 28 and cylindrical compression lens 29. Forming projection lens 2 is parallel, and forming a cylindrical compression lens 29 are perpendicular to the control electrodes 12. 86 Light filter 5 contains three sections 30 - 32 for primary colors, optically conjugated with sections of linear electrodes 9. The device operates as follows. The point source 1 of light is placed in the first focus of the ellipsoidal reflector 19 and forms the illuminator 2 with it. The second focus of the reflector by flat mirrors 21 of the first mirror raster 20 is depicted on the gp-tv line as a number of real images of the point source 1. the source on the IJ1-tin line are installed flat mirrors 23 of the second mirror raster 22, which reflect the light beams falling on them into the entrance pupil of the cylindrical negative lens 4. Flat, mirrors 21 through the corresponding The constricting mirrors of the second raster 22 are conjugated by light beams to the entrance pupil of a negative cylindrical lens 4. Mirrors 23 of the second raster 22 fulfill the role of point secondary light sources and form a light flux with a small angle of divergence in the meridional plane. The number of pivot mirrors 23 and 21 depends on the size of the arc of the light source, the type of alignment on the axis of m-ti of the second raster on the axis of t-ti may be 7-9 for each raster. This ensures the alignment of the ellipsoidal reflector with the anamorphic lens 13 and increases the brightness of the image. A negative cylindrical lens 4 and a cylindrical compression lens 29 form a long-focus telescopic lens and project secondary light sources onto the screen 18 in a view, row. The sections 9-11 of the linear electrodes 12 and the electrodes 25 of the phase-optical modulator of the light 6 are filled on the dielectric plate 24 and illuminated through the sections 30 - 32 of the three-color sectional light filter 5 by the light fluxes of the main colors. The number of linear electrodes 12 in each section is equal to the number of resolution elements in the image line. Information signals are supplied to the control inputs 7 of the phase-optical light modulator 6, the line electrodes act on the light-modulating medium 8 and modulate the light flux passing through sections 9-11 in accordance with the luminance signals of the primary colors. The colored light fluxes on the screen 18 by cylindrical optics are reduced to a full-color line.

In the horizontal plane, the projection cylindrical lens 28, the input aperture 3 and the output slit aperture 14 form an optical information visualization system recorded on the light-modulating medium 8 applied to the transparent conductive layer 26 of the transparent dielectric plate 27 of the phase-optical light modulator 6. The projection lens 28 projects on the screen 8 sections of the light modulating medium 8 under the sections of the linear electrodes 9 1 are reduced by cylindrical optics to one side. The input and output apertures 3 and 1A convert the original light modulation (for example, phase) into intensity modulation in a row. As a result, the screen 18 receives a color image of the line, each element of which is modulated in brightness and color by the corresponding information signals.

The entire frame is obtained by scanning the lines by a scanner {mirror 15, the drive 16 of which receives synchronization signals via control input 17.

As a light-modulating medium, for example, electrically controlled PTSL-ceramics lead polycrystalline Dirconate-titanate doped with lanthanum or an electrically controlled deformable elastomeric layer 50-100 microns thick can be used. When using PZTL ceramics, the sections of linear electrodes of a phase-optical optical modulator of light are in electrical contact with its surface. The elastomeric layer is located at a distance of 20-30 microns from the linear electrons. The voltage control in both cases is 200-250 V.

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Claims (1)

(5 ¹ ”) A COLORED INFORMATION DEVICE comprising a illuminator with a point source of light and mounted on an optical axis and optically coupled to an illuminator with an input diaphragm, a negative cylindrical lens, a three-color section light filter, a phase-optical light modulator, an anamorphic lens, and an output lens a slit diaphragm and a row scanning system, characterized in that, in order to increase the light-energy characteristics, the first and second rasters from flat mirrors are introduced into it, and the illuminator is made in the form e of the ellipsoid reflector, the optical axis of which is offset parallel to the optical axis of the negative cylindrical lens, the point source of light is installed in the first focus of the ellipsoid reflector, and the first raster of flat mirrors is located between the foci of the ellipsoid reflector and its mirrors are optically connected to the mirrors of the second raster, which are located in the second focus is an ellipsoid reflector and is optically coupled to the entrance pupil of a negative cylindrical lens.