FR3019911A1 - LENTICULAR NETWORK DEVICE WITH DISCONTINUOUS LENSES - Google Patents

Abstract

The principle of the present invention consists in associating a coded image similar to those made to be read with a cylindrical lens lenticular network, composed of elementary coded images which are strips of juxtaposed images, with a lenticular network composed of discontinuous lenses. . Such lenticular networks make it possible, on the one hand, to reduce the effect of parasitic reflections, but also to enable the manufacture of lenticular networks of very high quality by varnish printing, a technology that is much more economical than the other known methods, while at the same time offering the viewer of 3D images that do not vary when moving vertically relative to the screen, or moving images that do not vary as it moves horizontally relative to the screen.

Description

FIELD OF THE INVENTION The invention is a lenticular array device associating a lenticular array with an encoded image. Such types of devices allow to see a scene with a relief print, and / or animations that occur when the viewer moves with respect to the optical device. They are widely known, often under the inappropriate name of holograms. Problem posed Lenticular arrays are most often composed of cylindrical or spherical lenses. The first ones allow to see an animation by a vertical movement of the spectator or a 3D image by a horizontal movement of the spectator. The axes of the cylindrical lenses are respectively arranged vertically or horizontally, respectively. The latter produce both effects simultaneously, which is not always in line with the desired objective, but they have the advantage of neutralizing parasitic reflections and being easier to manufacture by varnish printing.

The objective is to cumulate the advantages of the two types of lenticular networks which have just been described. Previous Art Document PCT / FR-1997-01976 (Franck Guigan) of 05/11/1997 which describes lenticular spherical lens networks, PCT / FR-2009-50883 (Franck Guigan & Al.) Of 13 / 05/2009 which describes a method of manufacturing optical lenses by varnish printing, and PCT / FR-2011-00315 (Pierre Guigan) 27/05 / 2011which describes another method of manufacturing optical lenses by varnish printing. The invention will be well understood, and other objects, advantages and characteristics thereof will appear more clearly on reading the description which follows, which is illustrated by the figures which are all views of mechanical transmissions according to the invention. Figure 1 is a perspective view of a lenticular array device according to the invention. It is composed of a coded image 1 constituted by the juxtaposition of rectangular elementary coded images 11, 12 and 13. On each of the elementary coded images, there is a primary rectangular image respectively 111 and 121 and 131, the largest of which is parallel to the largest side of the elementary coded image 11 considered. Above this coded image 1 is a lenticular network 2 constituted by the juxtaposition of elementary optical devices 21, 22 and following which are here spherical lenses with hexagonal pupil assembled in a honeycomb, a spherical lens 21 being located in a plane parallel to that of the coded image and substantially opposite a portion of a coded elementary image which it allows to see a part that depends on the position of the viewer. FIG. 2 is a view from above of the optical device of FIG. 1. FIGS. 3 and 4 are perspective views of lenticular array variants, the basic optical devices 21, 22 and following of which are cylindrical lenses of rectangular pupil, of which the ends are rounded. DESCRIPTION OF THE INVENTION The invention is an optical device comprising: a. an encoded image 1 constituted by the juxtaposition of rectangular elementary coded images 11, 12 and following, an elementary coded image 11, comprising at least two so-called primary rectangular images 111 and 112 whose largest side is parallel to the largest side of the Elementary coded picture 11 considered, b. a lenticular network 2 constituted by the juxtaposition of elementary optical devices 21, 22 and following, an elementary optical device 21 being situated in a plane parallel to that of an elementary coded image 11 and substantially facing a part of it. an elementary coded image, said coded image 1 being located at a distance from said lenticular array 2 substantially equal to the focal length of said elementary optical devices 22 and following characterized by the fact that an elementary optical device 21 comprises a plurality of convergent lenses 211, 212 and following.

According to other features of the invention: - said coded image is projected through said lenticular array 2 on the surface of said coded image 1 said convergent elementary lenses 211, 212 and following are spherical lenses. said convergent elementary lenses 211, 212 and following are cylindrical lenses whose ends are portions of spherical lenses. the pupil of said elementary convergent lenses 211, 212 and following is substantially a rectangle. the pupil of said elementary convergent lenses 211, 212 and following is substantially a hexagon. the pupil of said elementary convergent lenses 211, 212 and following is substantially a regular hexagon. said convergent elementary lenses 211, 212 and following are constituted by a transparent varnish. said elementary convergent lenses 211, 212 and following are separated by opaque lines. the invention is a method of manufacturing optical devices whose lenses are obtained by printing transparent varnish. DETAILED DESCRIPTION OF THE INVENTION The principle of the present invention consists in associating an encoded image made to be read with a lenticular network with cylindrical lenses, composed of elementary coded images which are strips of juxtaposed images, with a compound lenticular network. discontinuous lenses. The first advantage is to reduce the unpleasant effect of parasitic reflections. Indeed, a spherical lens lenticular network reflects a light source located in the viewer's environment in the form of a light bar that occupies the entire width of the screen when the cylindrical lenses are vertical axis, or all its height when they are horizontal. This makes cylindrical lens arrays unsuitable for three-dimensional image projection by several associated projectors. The second advantage is to allow the manufacture of these lenticular networks by varnish printing. Indeed, when trying to produce lenticular networks with this technique, it often happens that the varnish moves along a lens before being solidified, and that the curvature of the lens becomes irregular. The separation of lenses in subassemblies which one controls more easily the periphery makes it possible to remedy this disadvantage. The encoded image image can be printed on any medium, or projected onto it.

When projected from behind, it can be projected by a single projector, while in the opposite case, it is the so-called primary images, those that are intended to be seen by the viewer, which are all projected on the screen. plane of the image through the lenses of the lenticular network, by as many projectors that we want to have different images. Advantageously, the convergent elementary lenses 211, 212 and following are spherical lenses, but they can also be cylindrical lenses. Their ends are then advantageously spherical lens portions. In the latter case, the pupil of said convergent elementary lenses 211, 212 and following is advantageously substantially a rectangle, while it is a regular hexagon for spherical lenses, since such hexagons easily assemble into honeycombs to occupy the entire surface of the device fi is also possible to use lenses whose pupil is substantially an irregular hexagon. Such lenses then have a shape which is for example a cylinder portion for the main part, and a sphere portion at each end. The convergent elementary lenses 211, 212 and following can be manufactured by transparent varnish printing, for example according to the technologies described in documents PCT / FR-1997-01976 and PCT / FR-2009-50883 already mentioned. The devices according to the invention are then particularly economical to produce. Advantageously, the convergent elementary lenses 211, 212 and following are separated by opaque lines, which improves the contrast perceived by the viewer. Applications The invention mainly concerns all known applications of lenticular networks. .70 £ 0E1.000091.9 £ 1.922961

Claims (10)

REVENDICATIONS1. An optical device comprising: a. an encoded image (1) constituted by the juxtaposition of rectangular elementary coded images (11, 12 and following), an elementary coded image (11), comprising at least two so-called primary rectangular images (111 and 112) whose largest side is parallel to the largest side of the elementary coded picture (11) considered, b. a lenticular network (2) constituted by the juxtaposition of elementary optical devices (21, 22 and following), an elementary optical device (21) being situated in a plane parallel to that of a coded elementary image 11 and substantially facing a part of an elementary coded picture, said coded picture (1) being located at a distance from said lenticular array (2) substantially equal to the focal length of said elementary optical devices (21 22 et seq.) characterized by the fact that an elementary optical device 21 comprises a plurality of convergent lenses (211, 212 and following). Optical device according to claim 1, characterized in that said coded image is projected through said lenticular array (2) onto the surface of said coded image (1) 3. Optical device according to claim 1, characterized in that said convergent elementary lenses (211, 212 and following) are spherical lenses. 4. Optical device according to claim 1, characterized in that said convergent elementary lenses (211, 212 and following) are cylindrical lenses whose ends are spherical lens portions. 5. Optical device according to claim 1, characterized in that the pupil of said elementary lenses convergent 211, 212 and following is substantially a rectangle. 6. An optical device according to claim 1, characterized in that the pupil of said elementary lenses convergent 211, 212 and following is substantially an exaggeration. 7. Optical device according to claim 1, characterized in that the pupil of said elementary lenses convergent 211, 212 and following is substantially a regular hexagon. 8. Optical device according to claim 1, characterized in that said elementary convergent lenses (211, 212 and following) are constituted by a transparent varnish. 9. The optical device according to claim 6, characterized in that said convergent elementary lenses (211, 212 and following) are separated by opaque lines. 10. A method of manufacturing optical devices according to claim 1 characterized in that the lenses are obtained by printing transparent varnish.