NL8201114A - Electronic matrix display screen - uses closely-packed light guides to join small images to form larger without gaps or overlap - Google Patents

Abstract

The system has an array of, e.g. display screens (22), reproducing parts of a large image. The sub-images of the screens are blended together into the large image with no overlap and no gap using light guides (23,24). The light guides diverge from each screen to join neighbouring light guides and then travel parallel to meet a common plane (25) where the large image appears. The light guides may be solid optical fibres or hollow tubes coated on their insides with a reflecting material. The plane where the large picture is reproduced has a light scattering plate (25) acting as a screen. The size of the large picture may be chosen freely within limits so as to enlarge each sub-image.

Description

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The invention relates to a device for visually seamlessly joining -separate- and separated image planes into a homogeneous new image plane.

The electronic screens combined in matrix form, intended for large screen video display, show a visually annoying grid when viewed at shorter distances.

The screens used all exhibit an information-free zone around the field of view caused by the wall of the picture tube and the intermediate space between the picture tubes.

The object of the invention is to eliminate the above-mentioned drawbacks and to provide a simple, effective, compact device with which visually seamless neighboring self-illuminating image areas or displays can be combined seamlessly into a homogeneous image area.

Another object of the invention is to provide a device with which a self-luminous surface can be enlarged to be transferred to a second surface, whether or not uniform or parallel.

Another object of the invention is to provide a device with which an almost arbitrary spatial shape of the screen can be obtained (flat, curved, kinked, etc.).

Another object of the invention is to provide a device with which the emerging beam angle can be controlled or limited to a limited extent.

A further object of the invention is to provide a device which is lightweight and easy to apply externally or to be added.

The invention is further elucidated with reference to the drawing, in which an exemplary embodiment is shown.

Figure 1 shows a representation of the composition of the said device.

Figure 2 shows a longitudinal section of a light guide element.

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Figure 3 shows a cross section of a hollow light guide element.

Figure 4. shows a display of a screen module.

Figure 5. shows the joining of two image planes 5 and the radiation characteristic.

Figure 6. shows a principle of beam angle limitation.

Figure 7. shows an example construction in a partly cut-away view.

In figure 1, the elements 1 form the screens next to each other along length and width axis, respectively. 2 denotes the assembly of light guides, with which the brightness of the screen is transferred to the rectangular surface 3, the image-recording end of the light guides. The wedge-shaped portion of the light guide assembly provides, by magnification, an adapted transfer of the maximum achievable uniform crop of the image field of 1. to the surface 3.. The brightnesses on the neighboring images are hereby transferred and displayed without seam or overlap. Adjacent to the surface 3. a light-diffusing layer or plate 4. is applied in order to make all parts of the image visible to the observer's eye simultaneously and to scatter the light emerging from the light guide in all directions. The clear transparent plate indicated with 5. serves to protect the device placed behind it.

In figure 2. a longitudinal section of a light guide element is shown, as used in the assembly 2. 30 in position 6. in figure 1. The walls of the light guide extend from 9. in figure 2. widening wedge-shaped up to the bend or bend in the main direction at 10. From the kink 10. to the image-recording end of the light guide 11, the walls are parallel. The principle of light conduction is already known and for the hollow light conductor it is based on reflection at the o -41. - «ά <· £ · \ 8201114» 3.

A * - inner walls and for the solid light guide on internal total reflection or on reflection on a highly reflective material applied to the walls. The application of the highly reflective layers, such as by the known vacuum technique. The cross section of the light guide can be of any shape (round, square, diamond-shaped, hexagonal, etc.).

Figure 3 shows the cross section of a hollow light guide. The material for the wall 14. can be both plastic and metal and also functions as carrier 10 of the highly reflective layer 15 evaporated by known vacuum technology. The construction of the hollow light guide is preferably such that it can be manufactured from the stacking and connecting strip-shaped elements together.

The wedge-shaped part of the light guide, and with it the entire assembly of light guides, converges for all planes around the center line to one point, point 16 in figure 4. The planes 17 and 19 may be of any shape. When using picture tubes, will have a radius corresponding to that of the front surface of the picture tube. Plane 20 18. in figure 4 is the plane in which the kink points lie. The walls 20. and 21. form the side faces of the light guide module, the image transferring member. The top surface 21. is rectangular in shape and proportionally larger than the corresponding rectangular cut-out of the image plane on the display tube used, for example, and determined by the size and mounting method of the display tube or the display plane.

Figure 5 shows the merging of two images from two individual screens. The outer pixels 26. and 27. in Figure 5. and also 12. in Figure 2. of the maximally attainable rectangular section of the image are transferred, via the light guides 23 and 24., to the total screen at the location of 25., where they give full concatenation. The straight part of the light guides provides an equal and homogeneous radiation supply for all pixels at the location of the composite image 8201114.

% screen 25. Regardless of the shape of the radiation characteristic of the light diffusing screen 25., the eye of the observer will visually receive an equal impression on both sides of the transition of the image from pixel 26. and image-5. point 27. The brightness variation of the composite display is now a function of the radiation characteristic of the total screen and the angle difference, determined by the size of the screen and the position of the observer.

The light guide can also be used to limit the emerging beam angle, the diffusing screen 29 in Figure 6 being placed between the kink or bend 20ne 30 and the image receiving end face 31 when positioned. The dimensions of the light guides are determined by the required resolution and the contrast of the total screen and partly by the ratio of the diameter of the light guide and the distance to be bridged. The dimensions can vary within wide limits.

Figure 7 shows an example, in partly cut-away form, of a one-piece display screen, realized with the aid of said device using picture tubes 32 as the primary source of brightness and angle. Detail 34.shows the seamless connection of the image transfer members 35., 36., 37. and 38. The light diffusing layer 39. is in direct contact with the ends of the image transfer members and is protected from outside influences by the clear transparent cover plate 40.

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Claims (1)

5. A device for visually seamlessly merging separate and separated image planes into one homogeneous new image plane, characterized in that the brightness and the image information of neighboring self-illuminating individual image planes 5 is transferred uniformly but enlarged to a final self-illuminating screen, wherein the original individual image planes are merged seamlessly and without overlapping. 2. Device according to claim 1, characterized in that light conductors are used for the brightness and thus image transmission. Device according to claim 2, characterized in that the light guides can be both solid transparent and hollow. 4. Device as claimed in claim 3, characterized in that the light guide walls extend radially divergent up to a kink or bend and from there run parallel to the image emerging plane. 5. Device as claimed in claim 4, characterized in that a highly reflective layer is applied to the inner walls of the hollow light guide with a known vacuum technique. 6. Device as claimed in claim 5., characterized in that the hollow light guides are composed of strip-shaped elements which are stacked and joined together to form a total image transfer member. 7. Device as claimed in claim 6., characterized in that one image transfer member in each case corresponds to one primary image plane and the image transfer members are combined into one large whole. B. Device according to claim 7, characterized in that the combined image transfer members are provided with a light-diffusing layer or plate on the side of the parallel ends of the member. 9. Device as claimed in claim 8., characterized in that the spatial shape of the final image surface, the horizontal screen, can be arbitrary within limits. 8. Device as claimed in any of the foregoing claims, characterized in that the light-diffusing layer is placed between the kinking zone and the image-exiting end face of the image-transfer member. lp 8201114