DE1018096B - Device for projecting color television images - Google Patents

Description

Applicant:

Societe Generale d'Electronique, Monaco-Condamine (Monaco)

Representative: Dipl.-Ing. W. Meissner, Berlin-Grunewald, Herbertstr. 22

and Dipl.-Ing. H. Tischer, Munich 2, patent attorneys

Claimed priority: France of July 4, 1953

The invention has a device for projecting

of color television pictures on a large screen of color television pictures

to the subject.

There are known color television methods, bed which

the shadow effect of a grid in front of the screen a cathode ray tube is used to produce with the help of cathode ray generator systems, their Rays intersect in the lattice plane, exciting different colored lines. Here, however Strips made of different fluorescent (or leucinting) colors.

It is also known to use cellular

Corrugations on the screen of the cathode ray tube glass plate in front, a homogeneous white fluorescent screen and a lens that displays the fluorescent screen on the projection screen, three-zone filter in front of it, on the projection screen to receive colored television projection images. These However, the arrangement uses a fluorescent material screen in the tube.

In contrast, the device according to the invention belongs to the type in which a reflective and Deformable metal foil is used to localize the light emitted by an external source to modulate; it is therefore a. Light modulation system, d. H. around a color and whiteness intensity modulator a constant external source.

The device for projecting color television images with one in a schlieren optical System arranged light control screen, whose reflection properties point by point through the; Cathode ray are changed, is characterized by the fact that before a deformed by the cathode ray -

An optical grid made up of cylinders 35

lenses is arranged so that the behind each cylinder

lenticular strips of film in; the basic colors.

associated sub-elementary strip em is divided, which receive its white light and at the same time in front of the from one or more cathode rays to the projection lens with a zone color filter the respective. Primary color signal corresponding to 40 cylindrical lenses is arranged in parallel zones. Beam intensity via a parallel to the cylinder The invention relates to a simultaneous system with three

Lenticular conductors with existing color control - simultaneously acting electron beams and a point grid acted upon that the Schlieren optics follow system with a single electron beam; two separate, perpendicular to the cylindrical lenses each of these two systems uses only one light-oriented Has rod grids and the gaps of the 45 and color modulation film of a special structure, on the first grid if the film is not deformed.

the bars of the second grid by a direct dung with no restriction of the protection The lens arranged on the lenticular screen and the film include drawings illustrating the invention be mapped that the level of modulation- the arrangement and operation of the invention film on the project 50 easier to understand through a projection lens; in the drawings shows tion screen is displayed, and that finally Fig. 1 is a modulation tube with three electron

Gaps in the first optical grating through to the cannons,

Cylindrical lenses parallel strips of light in the Fig. 2 is an enlarged view of a portion of the

different basic colors are illuminated or instead of the modulation organ according to FIG. 1,

709 757/9 '?

Michel Auphan, Neuilly-sur-Seine (France), has been named as the inventor

Fig. 3 is an elevation of the optical device below the prerequisite that the modulation film assumes a vertical position and is such that the grooves provided on their support are horizontal,

Fig. 4 is a corresponding plan view of the optical Facility,

5 shows a diagrammatic representation of the same optical device as in FIGS. 3 and 4, specifically with the same, additional symbols,

FIGS. 6 and 7 show two possible modifications of the transparent corrugated support structure according to FIG. 2.

With the simultaneous arrangement of three electron guns 1, bombard them with electrons across a grid 2 consisting of parallel threads a reflective and deformable modulation film 3, which has the structure defined above and which is arranged at a short distance from the transparent insulating support 4, caused by the strip r. The colored light - in blue z. B. in the case of the strip b _i - is then reflected by the reflective modulation film 3 in the space corresponding to the images mentioned, ie in the space of the strip b for the example under consideration; the strips V ₁ and T ₁ are also reflected by the strips ν and r of the modulating film. For each of the individually considered strips, e.g. B. for the strip b _v , the reflected colored light, xo as it was just said, goes through the diopter 5 and the lens 13 again and reaches a grating G ₂ , the rods of which are parallel to those of the grating G ₁ , i.e. perpendicular to Direction of the light streaks. This grid G ₂ takes one position; a, which corresponds to the image of the grating G ₁ in the system of reflective film 3, diopter 5, lens 13, and the various components (or elements) are arranged in such a way that the image of a rod of the grating G ₁ exactly in the two bars of

which z. B. can be made of glass. This carrier 20 grid G ₂ separating space is created. It follows has regular corrugations 5. The electrons - from the fact that in the absence of the electron bombardment gun 1 - no light can be arranged through the grid G ₂ trically to the tube axis in the same plane or concentrated on the film 3. The Mo- passes through. If, on the other hand, the film 3 is due to the dulating film 3, it is generally flat (see FIG. 2). Electron bombardment locally deformed, so you are resting on rafters 6 at a constant distance 25 the strips corresponding to the light deviated from. the insulating carrier 4. The grid 2 is, from which and go between the bars of the grid G ₂ hln electron source viewed from, stretched in front of the film; its threads or wires 7 are parallel to
arranged the rafters. Distance and strength of the

Wires are chosen in a known manner so that the sub-elementary strips b can only be reached by the electron gun which is reproducing.

Blue effects, while the stripes ν and r can only be reached by the “green” or “red” electron gun.

The · glass 4, which carries the film 3, forms on the the side opposite the film corrugations 5, which are formed by adjacent convex cylinder parts 8 develop. The generatrices of these cylinders run

parallel to the threads of the grid 2. The distance 40 The width of the grid G ₂ is almost twice as wide

this corrugation is exactly three times that of the film carrier. The focal length of the corrugations forming the cylindrical diopter is the same as the glass diopter.

Those in combination with the one described above modulated surface used optical

Device is shown in Fig. 3 to 5 schematically. Crossed after the last mentioned figures

the light emerging from a source 9, a condenser 10, then a prism 11, which breaks it apart. 50, which rests against the insulating support 4, which carries the film 3. The strips of the three basic colors b _lt v _v T ₁ will be.

is therefore projected onto an optical grating G ₁ , which, when perfected according to FIG. 7, is the

Rods perpendicular to those of the wires of the grid 7, foil 3, on a very thin glass plate 15; The prism 11 splits the light into strips ^ _1, can see what is arrival of a glass plate 16, the v _v r _v to the direction of the bars is perpendicular fluted 55 on both sides. In this case that occurs

by. This grating modulates the light of each strip as a function of the local deformation of the Modulation foil 3.

After this modulation, the light can be captured by a second objective 14, which projects it onto a screen E indicated by arrows in FIGS. In a variant that is not shown but is easy to understand, the prism 11 is replaced by a zonan filter consisting of three filter strips, which is arranged in front of the projection lens 14 as in the known projection arrangement mentioned at the beginning. The modulation foil thus receives in this. Trap white light.

like the image of the grating G ₁ which would be obtained through the lens 13 if the film 3 were to be replaced by a flat mirror. In this way, the light is obtained which, after reflection on the strip of the modulation film, would occasionally emanate from it through an adjacent groove through which it entered. In the variant of the screen shown in FIG 4 a provided,

Grids G ₁ and G ₂ are. The grating G ₁ is located approximately at the focal point of an objective 13 which is arranged in the immediate vicinity of the insulating support 4. In this way, z. B. the stripe ^ ₁ in each of the diopters 5, an image which forms on the stripe (Fig. 2), corresponding to the diopter considered there, exactly as it was indicated similarly to FIGS. 1 and 2; the focal length of the cylindrical diopter 5 is equal to the thickness of the glass of the insulating support 4, the outer surface of which forms this diopter.

Likewise, the corresponding direction to the stripe, ^ ₁ in each of the diopters 5 produces an image which on the stripe (Fig. 2), corresponding to the observed: diopter, exactly arises; The same applies to the strip r _v whose images on light always pass through the groove through which it entered. The grid G ₁ can then be larger without changing the grid G ₂ , and one thus obtains one better light output.

In a suitable modification of the invention, not shown, the two optical bar grids G ₁ , G _{2 can be} replaced by a single bar grating with mirrored bars. The colored light stripes from the light source are then reflected by a first reflection from the rods onto the film and, if there is no deformation, reflected back onto the rods. The rods are thus mapped onto themselves, while when a deformation occurs, light falls through the rods and gains access to the projection surface.

Instead of working with a film that is flat when at rest, a film can also be used which is wavy in the idle state and becomes flat when modulated. The cathode ray then receives a negative television signal.

According to the present invention, the color projection system called "dot sequence" and not shown in the drawing is formed by all of the components shown in FIGS. The tube of Fig. 1 is replaced by a tube with a single electron gun. This tube has a deflection coil in order to change the orientation of the electron beam at its point of impact with the grid 2 without changing this point of impact. This coil is then driven by a sawtooth current of. matching amplitude synchronously in the rhythm of the sequence d: he excited colored points. It is clear that the arrangement of glass corrugations relating to the invention is applicable in all cases where one uses colored adjacent stripes or bands for the reproduction of the colors, whatever the order of the stripes like. So z. B. the order red, green, blue, blue, green, red etc. can be applied. In this case one will use a corrugation for six strips instead of three, and the optical grating G ¹ ₁ will be illuminated by six color stripes in the same arrangement. In a variant, six strips of color filters are placed in the same arrangement in front of the projection lens. This modification relates in particular to the system known as the "Lorentz system", in which the color control grid stretched out in front of the modulation film consists of two rows of interconnected wires and the wires in one row are aligned with those in the other row alternate:; a variable potential difference between the two rows is used in order to steer a single electron beam one after the other onto the individual strips, corresponding to each color.

Claims (12)

Claims: 45 . 1. A device for projecting color television pictures with buckets in a schlieren optical system arranged light control screen whose reflection properties are pointwise changed by the cathode-ray, characterized by $ _0, that before a deformable by the cathode ray: reflection sheet (3) is an optical grid (5) from cylinder lens »(8) is arranged that the strip lying behind each cylinder lens, the film (3) in the. Sub-elementary strips (b, v, r) assigned to primary colors are divided, which are acted upon by one or more cathode rays (1) with the beam intensity corresponding to the respective primary color signal via a color control grid (2) consisting of conductors running parallel to the cylindrical lenses, d! the Schlieren optics have two separate rod grids oriented perpendicular to the cylinder lenses and the gaps in the first grating (G ₁ ), if the film is not deformed, exactly on the rods of the second grating (G ₂ ) through a lens (13 ) and the film (3) are imaged so that the plane of the modulation film is imaged on the projection screen through a projection objective (14), and that finally the gaps; of the first optical grating (G ₁ ) can be illuminated by strips of light in the different primary colors parallel to the cylinder lenses or, instead, white light is received and at the same time in front of the projection lens. Zone color filter is arranged with zones parallel to the cylinder lenses. 2. Device according to claim 1, characterized in that the number of wires of the. Color control grid, is equal to the number of corrugations of the insulating support. 3. Device according to claims 1 and 2, characterized in that the modulation film is acted upon by at least three electron guns, the wires of the color control grid are arranged such that the electron beams of said guns, which between two consecutive wires of the grid pass through, one on said sheet Cover group of parallel adjacent strips, the number of which is equal to the number the cannon is. 4. Device according to claim 1, characterized in that that each corrugation of the insulating support on the said modulation film has a number of said adjoining stripes equal to the number of primary colors used. 5. Device according to claim 1, characterized in that that the tube contains only one electron gun, with a coil being provided, which the angle of incidence of the electron beam in his. Point of impact on the color control grid, without changing the point of impact ;, changed, the coil being driven by a sawtooth-shaped current is excited, the amplitude of which is synchronized with the rhythm of the succession of colored dots is. 6. Device according to claim i, characterized in that the color control grid in front of Modulation foil contains two sets of electrically connected wires, the wires of the alternate one set with those of the other and means are provided to move between the two Sentences to apply a changeable potential difference and thereby the electron bundle one after the other to the said adjoining stripes, corresponding to each of the three basic colors. 7. Device according to claim 1, characterized in that that the light from an external source (9) through a prism (11) in at least three at the same time projected primary colors is decomposed. 8. Device according to claim 1, characterized in that that the modulation foil on rafters (6) running parallel to the cylindrical lenses is attached. 9. Device according to claim 1, characterized in that cylindrical lenses are provided on the side of a glass plate (4 d) facing the carrier of the film and adjoin the carrier (4), which is now flat on both sides. 10. Device according to claim 1, characterized in that the modulation film on one first ,, very thin glass plate that is attached to a second, fluted on both sides. Glass plate is attached. 11. The device according to claim 1, characterized in that each lying behind the corrugation, © strips of the film (3) instead of three in six sub-elementary strips! (r, v, b; b, v, r) under- and the optical diverging grating (G) divides the light into six in the same order Color bundle separates. 12. Device according to claim 1, characterized in that that instead of a film that is flat at rest, a film is provided which is in the Idle state is wavy and even with modulation so that the cathode ray then receives a negative television signal. Considered publications:
German Patent Nos. 822 846, 736 575; U.S. Patent Nos. 2,479,820, 2,446,791; German patent application F 4664 VIII a / 21 a ¹ . 1 sheet of drawings © 709757/97 10.57