FR2891059A1 - Optical device for e.g. advertising sign, has electronic screen with pixels each comprising sub-pixels, where pixels of interleaving image are not composed of sub-pixels of same primary image but of different primary image - Google Patents

Abstract

The device has a lenticular network comprising elementary optical devices each with an elementary lens. An electronic screen e.g. plasma screen, has light pixels each comprising sub-pixels of different colors. The pixels of an interleaving image are not composed of sub-pixels of same primary image but of different primary image. The sub-pixels aligned horizontally on the screen present a surface with dimension greater than width of a pupil of the lens.

Description

3D screen with a network of optical centered systems

  The present invention relates to an electronic image diffusion device associating an electronic screen such as a liquid crystal screen or a plasma screen with one or more lenticular networks, to allow the viewing of still or moving flat or 3D images. without the need to wear specific glasses.

  Optical devices known as lenticular arrays, which are often constituted by a plate of transparent material of which one face is plane and the other comprises a large number of cylindrical or spherical lenses, can be used to emit different images according to the directions. They are used in particular for the production of relief images or for the restitution of animations.

  In these known systems, the image which is affixed opposite the lenticular network is hereinafter referred to as interlaced image because it comprises pixels (pixel comes from picture element and signifies an elementary part of an image) coming from several different images, these images hereinafter referred to as primary images being viewed successively by the eye of the spectator when the latter moves horizontally in a plane parallel to the interlaced image.

  The interlaced image can be produced by two methods known hereinafter as the calculation method and the projection method.

  / The calculation method In this method, the interlaced image is calculated from the primary images. It is then printed on paper or on the back of the lenticular network itself, or produced by an electronic screen, or even projected on a screen frosted by a projector located at the rear of said lenticular network.

  This method can be considered as known since 1903, since, at this date, F. Ives has already used a plate with vertical slits as parallax barrier to see an interlaced image with alternating vertical streaks from right-eye images and left-eye images (US Patent 725,567, April 1902).

  ^ To increase the viewing angle and possible viewing positions, Kanolt and H. Ives used more slit streaks.

  In 1908, Lippmann proposed using spherical lens arrays instead of slots. (LIPPMANN, G. 1908. Reversible tests giving the sensation of relief, Journal of Physics 7, 4 (Nov.), 821-825) These networks are frequently called "fly's-eye" or integral networks, because they provide both a horizontal parallax and a vertical parallax.

  A large number of documents have long described lenticular arrays associated with devices displaying interlaced images by electronic means, and many improvements have been proposed in this family of products. Particular mention may be made of: EP 0 791 847 A (KONINKLIJKE PHILIPS ELECTRONICS N.V.-Aug. 27, 1997) which uses exclusively cylindrical lenses (unlike the present application) and proposes to tilt these lenses relative to the vertical.

  É FR2782438 (Pierre Allio - February 18, 2000) which proposes to modify the interlace calculation by permuting the sub-pixels R, V and B. ^ The patent WO 98/20392 (GUIGAN) published on May 14, 1998, describes how to use spherical lens arrays not to provide both horizontal parallax and vertical parallax, but to increase the number of images in horizontal parallax. This patent has been the subject of two improvements: new types of lenses having performances similar to those of spherical lenses have been discovered, and lenticular systems with optical systems known as double cylindrical lenses have been described in the patent application. FR02 / 0013, and are illustrated in Figure 7 which shows a lenticular array consisting of two lenticular networks 210 and 220 with cylindrical lenses, each set formed by the intersection of a cylindrical lens of the array 210 and a cylindrical lens of network 220 constituting an optical system whose optical characteristics are similar to those of a centered optical system.

  / lenticular networks with so-called annular optical systems have been described in the patent application FR04 / 0659.

  The main advantage of this way of organizing the lenses according to WO 98/20392 and its subsequent improvements is the considerable increase in the number of images successively seen by the viewer during his horizontal movement.

  It has a constant characteristic that the set of pixels or subsets of pixels corresponding to an elementary lens has a larger dimension greater than the largest dimension of the pupil of the elementary lens considered, it being specified that one considers as pixels corresponding to an elementary lens the pixels present on the screen, adjacent to each other, originating from different primary images, and visible through the same elementary lens of the lenticular network.

  / The projection method In this method, the interlaced image is obtained by projection on the lenticular network 3 of said primary images from projectors located at different locations.

  The present invention relates to the calculation method. It has the advantage of allowing a very simple, rustic and inexpensive realization of diffusion of relief images.

  The invention consists mainly of implementing the arrangement of the lenses of the patent WO 98/20392 (GUIGAN) by combining it with a particular interleaving method.

  The device proposed is an optical device comprising: an electronic screen 1 comprising luminous pixels, each of the pixels comprising sub-elements of different color, hereinafter referred to as subpixels, a device called a lenticular network 2, comprising a plurality of optical devices said elementary devices juxtaposed, said elementary devices each comprising a convergent elementary lens or an equivalent optical system called elementary lens 21, said elementary lens 21 of the lenticular array 2 being a centered optical system or the like, it being specified that by system optical centered or similar: o both an optical system having an axis of symmetry of revolution substantially perpendicular to the focal plane of said elementary lens, o that an optical system having optical characteristics close, that is to say, allowing it to focus to say focal point of parallel light rays: either on a small disk, or on a small rectangle attached by its short sides to two half-disks of a diameter equal to the said small side of the rectangle, or on a small parallelogram, or on a small surface of any shape, the small word here meaning that the considered surface is equal to a fraction of the surface of the pupil of the elementary lens considered.

  characterized in that the pixels of the interlaced image are not composed of subpixels from the same primary image, but unlike different primary images.

  According to other characteristics of the invention: the surface of the set of sub-pixels aligned horizontally on the electronic screen and corresponding to different views, said elementary strip, has a larger dimension greater than the width of the pupil of the elementary lens 21 located vis-a-vis.

  the elementary lenses 21, 22 and following are organized in lines inclined with respect to an axis called Horizontal Axis, an angle whose tangent is equal to the height of a sub-pixel divided by the width of a sub-pixel. pixel, being specified that is meant here and hereafter by Horizontal Axis 30 and Vertical Axis perpendicular axes between them which are respectively: parallel to the lower edge and the upper edge of the rectangular interlaced image 6, or of a cutout of this image according to the portrait mode or in the landscape mode, for the so-called horizontal axis axis parallel to the left edge and the right edge of the rectangular interlaced image 6, or a cutout of this image according to the portrait mode or landscape mode, for the axis called Vertical axis; each line of sub-pixels is successively composed of sub-pixels corresponding to the primary colors retained, for example, red, green and blue, and these sub-pixels are derived from primary images that succeed one another in the order of the primary images. each column of subpixels is composed of subpixels of identical color, and these subpixels are derived from primary images which follow one another in the order of the primary images; the lenticular network is divided into portions of the lenticular network, each having an additional plate 3 for aligning said portions in the plane of the screen.

  Said lenticular network portion comprises locating means 41 and 42 for arranging said lenticular array portions in a template to ensure accurate positioning of said portions.

  said lenticular network portion comprises assembly means between said lenticular network portions. 10

  Subpixels from the same primary image are arranged in lines whose absolute value of the tangent is equal to the ratio between twice the height of a sub-pixel and once its width.

  The lenticular array 2 is constituted by the superimposition of two cylindrical lenticular lens arrays, both of which have a common focal plane after being superimposed.

  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 in FIGS. 1 to 7 FIG. pixels of an interlaced image according to the invention. The dashed rectangles represent the sub-pixels seen simultaneously by a spectator's eye, and also represent the focusing areas of the elementary lenses of the lenticular network.

  FIG. 2, a plane of distribution of the pixels of an interlaced image in accordance with the invention, but which is associated with a cylindrical lenticular network whose lenses have a longitudinal axis of symmetry inclined to the horizontal, this figure not being in conformity to the invention and to note the disadvantages that the invention allows to bypass; the focusing areas of these lenses are represented by inclined parallelograms whose outlines are in dashed lines.

  3 is a perspective view of a lenticular array portion of FIG. 4, seen from the lens side.

  4, a perspective view of a lenticular array portion according to the invention, seen from the opposite side to the lenses FIG. 5, a perspective view of a plurality of lenticular array portions according to the invention, assembled together, seen from the lens side.

  Figure 6, a plane of distribution of the pixels of an interlaced image, in a second embodiment of the invention.

  FIG. 7, a perspective view of a lenticular array portion according to the invention, corresponding to the plane of distribution of the pixels of FIG. 6, said lenticular array consisting of the superposition of two cylindrical lenticular lens networks 210 and 220, the lenticular network 210 consisting of the elementary lenses 2101, 2102 and following, and the lenticular array 220 consisting of the elementary lenses 2201, 2202 and following.

  FIG. 1 shows a plane of distribution of the pixels of an interlaced image 40 according to a first embodiment of the invention.

  The sub-pixels that are here red, green and blue, as is most often the case for liquid crystal or plasma screens, are respectively denoted Rn, Vn and Bn, notation in which n represents the serial number of the primary image from which the sub-pixels considered.

  Each sub-pixel line is successively composed of sub-pixels red green and blue, but these sub-pixels are derived from primary images that follow each other in the order of the primary images. Each column of sub-pixels is composed of sub-pixels. identical pixels of color 50 red or green or blue, and these sub-pixels are derived from primary images which succeed one another in the order of the primary images.

  The lenses 21, 22 and following (shown in Figures 1 to 3 by bold dashed rectangles), are all located vis-à-vis pixels whose value n is identical.

  Thus, when the viewer moves parallel to the plane of the screen, he always sees pixels from the same primary image.

  Figure 2 shows what would happen if, instead of using a lenticular spherical lens network, a lens array with horizontally inclined cylindrical lenses was used: the lenses would focus not only on primary images having the same value of n, but also on other lenses. This would result in a lack of sharpness and a lack of perception since the viewer would simultaneously see a primary image and portions of pixels from other primary images.

  FIG. 3 shows a portion of a lenticular network comprising elementary spherical lenses 21, 22 and following aligned according to the arrangement of FIG. 1.

  This portion of the lenticular network, visible from the back of FIG. 4, comprises an additional molded plate 3 having the same surface area as said lenticular network portion, but laterally shifted so that when these network portions are assembled to form a large lenticular network, the portions align easily in the plane of the screen.

  FIG. 4 shows two optional lugs 41 and 42 coming from molding on the back of the plate 3, which are used to be able to arrange all the lenticular network portions in a template comprising the corresponding holes, before gluing these portions to each other. These lugs are intended to ensure precise positioning of said portions. They can be removed after assembly by mechanical means such as sanding. These pins can also be replaced by holes or notches which are then plugged (e) s.

  Figure 5 shows the construction of a large array using the lenticular array portions. Bonding can be performed between on the one hand the front faces of said additional plates 3a, 3b and following, and on the other hand the rear faces of the network portions 2a, 2b and following.

  Figure 6 shows that the invention can also be implemented in a different way, by not respecting the rule that each column of subpixels must be composed of sub-pixels from primary images which succeed one another in the order of the images primary.

  This implementation has the advantage that the lenses have a layout that is similar to that known by the name honeycomb, and therefore each have a surface that is closest to the circle. This arrangement makes it possible to reduce, for a determined number of lenses, the maximum aperture of each lens, and thus to improve the sharpness of the perceived image.

  This implementation may also seem a priori less favorable because a vertical movement of the viewer leads to faster changes of primary images seen by him. In some cases, however, this can be considered as an advantage since, in a movie theater, a slight height adjustment of the chairs allows all viewers to be in a position to comfortably enjoy the performance of the device .

  But in cases where this drawback is real, it is recommended to implement the present invention using a lenticular network similar to that of Figure 7, which is constituted by the superposition of two lenticular cylindrical lens networks 210 and 220.

  The assembly between two cylindrical lenses forms an optical system having optical characteristics close to those of a centered optical system, because it makes it possible to focus on a single plane parallel light rays either on a small parallelogram or on a small rectangle or on a small square, according to the characteristics of each of the two networks, and according to the value of the angle between the longitudinal axes of the cylindrical lenses of each of the two networks.

  An important condition for such networks to work is that they have a common focal plane after being superimposed.

  In the present description and in the claims that follow, the term lenticular array is used to describe sets of lenses of different types. It goes without saying that this expression must be understood in the broad sense, and that lenticular networks with optical systems centered, with double cylindrical or annular lenses can be replaced by opaque plates having holes or circular transparent zones, or whimsical shapes in place and place of optical systems described.

  - The main applications of the present invention are: advertising display, advertising signs, promotion at the point of sale, the composition of virtual showcases; all the applications of television, video and cinema, and in particular the following: sports broadcasts, films and serials, television news and reports, video games, advertising, amusement park attractions, computer-aided design workstation terminals, product design and architecture, scientific visualization, medical imaging (3D X-ray, NMR, scanner, ultrasound, endoscopy, microsurgery, etc.), - driving control systems and driving simulators, - personal films, - lighting fixtures, works of art, decorative objects and gadgets, - planning missions, reconnaissance, 35 damage assessment, terrain analysis, mapping, geography, seismic research, -education, - teleconferencing, - devices allowing car drivers to apprehend 40 the distance they must keep between their vehicle and the vehicle ahead, according to their speed.

Claims (10)

claims   An optical device comprising: an electronic screen 1 comprising luminous pixels, each of the pixels comprising differently-colored sub-elements hereinafter referred to as sub-pixels, o a device called a lenticular network 2, comprising a plurality of optical devices. said elementary devices juxtaposed, said elementary devices each comprising a convergent elementary lens or an equivalent optical system called elementary lens 21, said elementary lens 21 of the lenticular array 2 being a centered optical system or the like, it being specified that the term optical system centered or similar: o both an optical system having an axis of symmetry of revolution substantially perpendicular to the focal plane of said elementary lens, o an optical system having optical characteristics close to, that is to say, allowing it to focus at the focal length of the light rays parallel in parallel: ^ either on a small disk, ^ or on a small rectangle attached by its short sides to two half-disks of a diameter equal to the small side of the rectangle E or on a small parallelogram, E or on a small surface of any form, the small word meaning here that the considered surface is equal to a fraction of the pupil surface of the elementary lens considered.   characterized in that the pixels of the interlaced image are not composed of subpixels from the same primary image, but unlike different primary images.   2. projection system according to claim 1 characterized in that the surface of the set of sub-pixels aligned horizontally on the electronic screen and corresponding to different views, said elemental strip, has a larger dimension greater than the width of the pupil of the elementary lens 21 located vis-a-vis.   3. projection system according to claim 1 characterized in that the elemental lenses 21, 22 and following are organized in lines inclined relative to an axis called Horizontal axis, an angle whose tangent is equal to the height of a sub-pixel divided by the width of a sub-pixel, it being specified that above and hereinafter Horizontal Axis and Vertical Axis are used axes perpendicular to each other 45 which are respectively: parallel to the lower edge and at the upper edge of the rectangular interlaced image 6, or of a cut-out of this image according to the portrait mode or according to the landscape mode, for the axis called Horizontal Axis, - parallel to the left edge and to the right edge of the image interlaced 6 rectangular, or a cutout of this image according to the portrait mode or landscape mode, for the so-called axis Vertical axis.   4. projection system according to claim 1 characterized in that each line of sub-pixels is composed successively of 55 subpixels corresponding to the primary colors retained as for example red, green and blue, and these sub-pixels are derived from primary images that follow each other in the order of the primary images.   5. Projection system according to claim 1 characterized in that each column of sub-pixels is composed of sub-pixels of the same color, and these sub-pixels are derived from primary images which succeed one another in the order of the images. primary.   6. projection system according to claim 1 characterized in that the lenticular array is divided into portions of lenticular array, each having an additional plate 3 for aligning said portions in the plane of the screen.   7. projection system according to claim 6 characterized in that said lenticular network portion comprises locating means 41 and 42 for arranging said lenticular network portions in a template to ensure accurate positioning of said portions.   8. Projection system according to claim 6 characterized in that said lenticular network portion comprises connecting means between said lenticular network portions.   9. projection system according to claim 1 characterized in that the sub-pixels from the same primary image are arranged in lines whose absolute value of the tangent is equal to the ratio between twice the height of a sub- pixel and once its width 10. projection system according to claim 1 characterized in that the lenticular network 2 is constituted by the superposition of two lenticular cylindrical lens networks, these two networks having a common focal plane after being superimposed.