DE4415782A1 - Simultaneous image sending-receiving screen construction method for e.g. video conferencing - Google Patents

Abstract

The method involves using pixels represented by the ends of three glass fibres (1) assigned to different primary colours. The fibres are joined together at a node immediately behind a transparent baseplate. The fibres are optically screened from one another by a totally reflecting coating (2) vapour-deposited and overlaid with a totally absorbent coating (3). The radiant end (8) of each fibre is expanded and flattened for fixing to the baseplate. The other end (5) is concave and coated with the appropriately coloured fluorescent layer (4), and may have a porous portion (6) to increase the output of light.

Description

The invention relates in particular to a method for constructing a screen flat, flexible, high light intensity and building a picture at the same time, so how a picture can receive. Furthermore, the screen is only used to a small extent disturbed by external light sources and has no edge distortions, too no shadow mask needed anymore.

Such an invention is of great interest, because one is able with simple Chen means building flat and flexible screens with a high light enable intensity for computer, home and industrial applications. By the invention is able to build up screen areas that are not just bodies shapes can be adapted, but can also change constantly. Further this invention is stable against mechanical stress. The invention he it is possible to build up an image on the screen at the same time and similar a camera to receive an image of the room in front of the screen. So you are in able z. B. Video conferencing on screen phones with only one device per part perform what is not possible with today's procedures.

Methods have already been described which allow screens with high light build up intensity, but these should not be made flat, as they are at least a Braun tube, which is almost vertically behind a shadow mask and need a screen coated with a fluorescent coating. Furthermore are LCD screens known and described, which can be made very flat NEN, but only emit a relatively low light intensity. Both are mechanical Stresses are sensitive to and can not be in their surfaces constantly changing shape. Methods are also known for the glass fibers for over Use images to carry out the function of a screen.

The invention is based on rigid and flexible screens on the task build, which are both able to emit high light intensities, as well as be be designed particularly flat. The invention is also intended to make it possible for images to be able to build screens that send and send image information at the same time to be able to receive. The invention is also based on the object of screens to enable the mechanical stresses to be insensitive to and without optical edge distortion. Furthermore, the invention enables the build both small and very large screen systems, the same ver driving can be used.

According to the invention, individual glass fibers are put together to form rows and row layers ( FIG. 1, A) 1). Each individual fiber is used to display a pixel on the screen. To create a flat screen, the glass fibers are glued or fused next to each other into rows. Another is glued or melted onto this first glass fiber line or glass fiber layer. This is repeated until the desired number of layers and layer width has been reached. The ends are cut to a uniform length by sawing. If the glass fibers are glued together, the layer thickness can be used to determine the distance between the fibers. In this way, different light spot widths can be generated on one screen. A light-transmissive base plate ( FIG. 1, A) 2, B) 2, D) 2)) is glued or melted onto this glass fiber surface for stabilization and for changing the optical properties. A base plate that is non-reflective and slightly diffuse should be used to avoid light reflections. Here, a rigid plate z. B. a glass plate can be used or a flexible plate z. B. made of plastic, can be used. This enables the construction of a flexible screen. The principle of the screen uses the light conductivity of the glass fiber, so that a screen light point can be irradiated at one end per glass fiber and the light point on the base plate is visible at the other end. Each individual, the glass fibers merged into rows and row surfaces is by a light source z. B. laser ( Fig. 1, B) 3) or Braun tube ( Fig. 1, B) 3), as in a conventional screen with shadow mask, the pixels, addressed or scanned. Where, in relation to the screen area, the radiation ( Fig. 1, B) 4) takes place in one end of the glass fiber is not important due to the flexibility of the glass fiber. So the screen can be adapted to any technical need. All systems, such as PAL, SECAM, etc. can be used to display the images line by line. However, it is not necessary to select a line-by-line display of individual pixels.

If only monochrome screens are set up, only one glass fiber system ( FIG. 1, A)), that is one glass fiber per pixel, is required. For a color screen, at least three separate glass fiber systems must be used, one fiber for each of the colors blue, red and green, which together form a point of light. These can be organized into groups of three directly on the base plate. These groups of three are so nested that the individual colors ben, which are passed through the fibers, have the maximum distance from each other ( Fig. 1, D) 6). Since a color is a mixture of three primary colors, the glass fiber strands for the three primary colors can also converge to form a glass fiber strand in a glass fiber node ( Fig. 1, B) to E) 5) ( Fig. 1, B), C)), which is then applied as a single strand on the base plate ( Fig. 1, C)), as described above. Both methods enable color screens to be designed flat, like monochrome screens. With the installation of a further fiber optic line, as a supplement to each group of three or single fiber optic line, it is possible at the same time to build up an image on the screen and to receive an image of the room in front of the screen. This is routed separately from the imaging glass fibers to an opto-chip or other light-sensitive reception system. Overall, it is not necessary for each glass fiber that forms a pixel to be assigned a glass fiber that is used to receive a pixel or image. So it is not only possible for. B. videophones but also to build touch screens.

The individual glass fibers are optically shielded from one another ( FIGS. 2, A) to D) 2 and 3). To improve the optical properties, they can be vapor-coated with a layer of completely reflective material ( FIGS. 2, A) to D) 2). A further completely absorbent layer ( FIGS. 2, A) to D) 3) can be applied to this layer, depending on the application in different layer thicknesses. Such a layer can e.g. B. be the adhesive layer that fulfills such a double function. Both layers must be flexible in themselves so that they do not restrict the flexibility of the glass fiber and increase the breaking strength of the glass fiber. One end (emitting end) of the individual glass fibers is widened and flattened planar ( FIG. 2, D) 8). This flattened side is, as described above, attached to the base plate ( Fig. 1, A) to E) 2 without D)). Depending on the intended use, the individual glass fibers can have different cross sections. Round and hexagonal cross sections proved to be very versatile, but square, diamond-shaped, triangular or polygonal cross sections can also be selected. The hexagonal cross-sections are particularly suitable for the construction of screens whose individual light points no longer have a border with the neighboring light point. This results in extremely smooth color transitions, better than is possible with a shadow mask of a conventional screen. Furthermore, the hexagonal cross section can be divided into three diamonds of the same size. A triple glass fiber group can thus be built up from three glass fibers with a diamond-shaped cross section. These can be brought together as a single fiber and run together as a glass fiber with a hexagonal cross-section to the screen base plate.

The other end (radiating end) ( Fig. 1, E) 7)) has different designs depending on the intended use ( Fig. 2). These depend on the type of source from which the light or electron radiation comes. In addition to the planar opening, the beam end of the glass fiber can be concavely indented to improve the optical properties ( FIGS. 2, A) to C) 5)).

If Braun tubes (electron radiation) ( Fig. 1, B) 3) are used to generate the light spot on the screen, the glass fiber radiation ends can be designed as follows. The end is indented concave ( Fig. 2, A) and B)). Another possibility is the design of a partially open hollow sphere ( Fig. 2, C)). The concave end or the hollow spherical surface is coated with a fluorescent coating which can be activated with electrons, corresponding to one of the three basic colors red, green or blue ( FIG. 2, A) 4). Furthermore, the end can be made of porous glass material ( Fig. 2, B) 6) to increase the light output, in continuation of the glass fiber, which is coated with a fluorescent coating, corresponding to one of the three basic colors red, green or blue. Furthermore, a polymolecular layer that completely reflects light but is permeable to electrons can be applied to the cross-sectional area that is perpendicular to the fiber axis, towards the electron source.

If Braun tubes are used to build up a color screen, a three-glass fiber system must be used as described above. Fiber optic ends must be used for Braun tubes. Either one or three Braun tubes can be used. When using a Braun tube, it scans the glass fibers of all colors. When using three separate Braun tubes, each tube scans only one type of glass fiber that corresponds to one color. The glass fibers can be led separately to the screen and depict a pure color point there. However, they can also be brought together beforehand in a glass fiber point, the mixed color, as described above, being formed at the junction point ( FIGS. 1, B) to E) 5). This mixed color is only led through a glass fiber strand ( Fig. 1, C)) to the screen and forms a mixed color pixel there, as described above. This type of construction can always be used if the three primary colors are generated from three different sources. This applies both to systems with Braun tubes or systems with lasers.

If polychromatic light sources or monochromatic lasers are used, the beam ends of the glass fibers can be designed as follows. The end is indented concave or designed as a partially open hollow ball ( Fig. 2, C). Up to half of the hollow sphere is struck with a light-reflecting layer ( FIG. 2, C) 7). This hollow sphere is also designed so that an incident light beam, in the direction of the longitudinal axis of the glass fiber, is reflected into the glass fiber by the reflective layer of the hollow sphere. In this way, the light output can be maximized.

A polychromatic is used to display the mixed color point on the screen Only one fiber optic strand group is required. This will the polychromatic light beam in its spectral colors with a prism lens system. The separated primary colors are now with another lens system again directed the individual glass fibers, with the intensity of the individual Spectral color was weakened as necessary to create the mixed color is. It is also possible to use the three spectral colors red, green and blue on a triple lens to direct the fiber system and thus produce the mixed color as described above is.  

For the construction of a television screen, computer screen, etc. everyone can Standard systems are used. The system can be applied to all existing ones Adjust standards.

Claims (15)

1.Procedure for the construction of a screen surface, in particular for the purpose of building rigid, as well as flexible and thus spontaneously deformable screens, which are both able to emit high light intensities and can be made particularly flat and are not sensitive to mechanical stresses, as well as being able to send and receive an image at the same time, as well as being without optical edge distortions, characterized in that glass fibers which represent a single pixel are line-by-line and then these glass fiber lines are melted or glued one above the other, so that a screen area of different sizes is composed of individual pixels is built up. 2. Device according to claim 1, characterized in that the glass fiber surface according to claim 1 on an optically transparent rigid or flexible base plate, is applied by sticking or melting. 3. Apparatus according to claim 1, characterized in that the individual glass fiber, to improve the optical properties, with an optically reflective Layer is surrounded. 4. The device according to claim 1 and characterized in that the individual glass fiber, to improve the optical properties, above which reflect optically the layer is surrounded by an optically dense layer, which in different Layer thicknesses is applied. 5. The device according to claim 1, characterized in that the individual glass fiber, is flattened planar at the end and widened in cross section at which it adjoins the Base plate is attached according to claim 2. 6. Apparatus according to claim 1 and 2, characterized in that the individual Glass fiber, at the end that leads to the light source, to one at different angles is expanded concavely to an open hollow ball, further that the hollow ball the edge areas of the opening that are inside with a reflective Layer is occupied. 7. The device according to claim 1, characterized in that the individual glass fiber, at the end facing a Braun tube with a fluorescent filament layer is coated according to the primary colors. 8. Apparatus according to claim 1 and 7, characterized in that the individual Glass fiber, at the end of which is directed towards a Braun tube made of porous Glass material is made with a fluorescent coating, according to the reason colors, is coated. 9. The device according to claim 1 and 2, characterized in that several one individual optically shielded glass fibers are brought together so that they become one light-conducting fibers are passed on to the optically transparent base plate becomes. 10. The device according to claim 1, 2 and 9, characterized in that three glass fibers are brought together so closely that they have a point of light on a ground plate result, so that from irradiated light of the spectral colors red, green, blue one Mixed color can result. 11. The device according to claim 1, 2, 9 and 10, characterized in that in egg nem glass fiber system, separated from this, glass fibers are available for emp be used and used to capture a pixel or image Process pixel or an image further.   12. The apparatus of claim 1 and 2, characterized in that the individual Cross section of glass fibers used for the construction of the screen are square. 13. The apparatus of claim 1 and 2, characterized in that the individual Cross section of glass fibers used for the construction of the screen are diamond-shaped. 14. The apparatus according to claim 1 and 2, characterized in that the individual Cross section of glass fibers used for the construction of the screen are hexagonal. 15. The apparatus according to claim 1 and 2, characterized in that the individual Cross section of glass fibers used for the construction of the screen are polygonal.