FR2891062A1 - Optical device for e.g. advertising display, has lenticular network comprising elementary devices each with optical system presenting identical optical characteristics and symmetry axis of rotation perpendicular to focal plane of lens - Google Patents

Abstract

The device has a lenticular network comprising elementary devices each with an elementary lens and a centered or assimilated optical system. An electronic screen e.g. plasma screen, has pixels each comprising sub-pixels of different colors. Each optical system has identical optical characteristics and possesses a symmetry axis of rotation perpendicular to focal plane of the lens. The pixels of interleaving image are not composed of sub-pixels of same primary image but of different primary images.

Description

Network screen of centered optical systems

  The present invention relates to a device associating a screen such as a liquid crystal screen or a plasma screen or a screen with colored light sources, such as, for example, light-emitting diodes (LEDs), with an optical lens assembly known as lenticular network, to allow the vision of still images or animated 3D without the need to wear specific glasses ^ the vision of still images or animated flat, with a better definition than that of the screen used.

  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 present invention has the advantage of allowing a very simple, rustic and inexpensive delivery of flat or embossed images.

  The proposed device is an optical device comprising: a screen 1 comprising luminous pixels, each of the pixels comprising sub-elements of different color, hereinafter referred to as sub-pixels, o a device called a lenticular network 2, comprising a plurality of so-called optical devices. elementary devices juxtaposed, said elementary devices each comprising a convergent elementary lens or an equivalent optical system called elementary lens 21, characterized by the fact that: o the pixels of the interlaced image are not composed of sub-pixels coming from the same image primary, but unlike different primary images, o and that said elementary lens 21 of the lenticular array 2 is a centered optical system or the like, it being specified that the term optical system centered or assimilated: o both an optical system having a substantially symmetrical axis of revolution ndicular to the focal plane of said elementary lens, o that an optical system having substantially identical optical characteristics.

  it being specified that it is understood above: o by interlaced image the image displayed by the screen 1 in the form of pixels, o and by primary image one of the images entering into the construction of said interlaced image to be proposed at the sight of a viewer's eye through said lenticular network.

  According to other features of the invention: the elementary lenses 21, 22 and following are organized in lines inclined with respect to an axis called Horizontal Axis, an angle whose absolute value of the 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 understood axes perpendicular to each other which are respectively: parallel to the lower edge and at the top edge of the rectangular interlaced image, or a crop of that image in portrait or landscape mode, for the so-called horizontal axis, - parallel to the left edge and right edge of the interlaced image rectangular, or a cutout of this image according to the portrait mode or according to the landscape mode, for the so-called vertical axis axis; each column of sub-pixels is composed of sub-pixels of identical color, and these sub-pixels are derived from primary images which succeed one another in the order of the primary images; subpixels from the same primary image are arranged in lines inclined with respect to said Horizontal Axis by an angle whose absolute value of the tangent is equal to the ratio between twice the height of a sub-pixel and a times its width; there is at least one horizontal line of elementary lenses facing a horizontal line of subpixels; subpixels originating from the same primary image are arranged in lines inclined with respect to said Horizontal Axis by an angle whose absolute value of the tangent is equal to the ratio between the height of a sub-pixel and four times its width; subpixels originating from the same primary image are arranged in lines inclined with respect to said Horizontal Axis by an angle whose absolute value of the tangent is equal to the ratio between a height of a sub-pixel and two times its width; subpixels from the same primary image are arranged in columns; and a column of sub-pixels out of two comes from a first primary image; and the sub-pixels of the other columns come from a second primary image; and the average height of an elementary lens of the lenticular array is substantially equal to half the height of a sub-pixel.

  the primary images all come from a single so-called original image, the resolution of which is greater than that of the screen 1, each primary image representing a different extraction of pixels from said single original image; subpixels from the same primary image are arranged such that each of said subpixels is located as close as possible to the middle of the line joining the two subpixels from the same primary image and belonging to the line lower or higher sub-pixels; the set of subpixels coming from a primary image represents the colored component of this color of the primary image considered; a sub-pixel originating from a primary image is fed only by extracting information from the color of the pixel of the primary image considered to be represented, which is that of the sub-pixel considered; the three sub-pixels coming from the same primary image forming the smallest possible triangle, called the elementary triangle, are of different colors; said elementary triangle is substantially equilateral; said elementary triangle is substantially isosceles; a square of 4 pixels formed by two columns 101 and 102 and two lines 201 and 202 of pixels 50 in a primary image 1000 corresponds to the three sub-pixels 300d 300 and 300i of an elementary triangle; for three of the pixels used, the corresponding sub-pixel 300 is fed only by the extraction of the information of the color of said pixel which is that of said sub-pixel 300; and one of the four pixels of a primary image 1000 is not used; a square of 4 pixels 50, 51, 52 and 53 adjacent horizontally in a primary image 1000 corresponds to 9 subpixels located on three horizontal lines; one of these 4 pixels (50) is represented by a sub-pixel 300 fed by the extraction of the information of the color of said pixel 50 which is that of said sub-pixel 300; one of these 4 pixels (52) is represented by two subpixels 300f and 300k which are each fed by the extraction of the color information of the considered pixels, which are those of said subpixels 300f and 300k; and two of these 4 pixels (51 and 53) are each represented by three sub-pixels forming a triangle (300e 300a and 300j for the pixel 51 and 300g 300b and 3001 for the pixel 53), these subpixels being each powered by the extracting information from the three colors of the pixel in question; said sub-pixels of the screen 1 are organized in honeycombs; the lenticular network 2 is constituted by the superposition of two lenticular networks 210 and 220 with cylindrical lenses, these two networks having a substantially common focal plane after having been 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 by FIGS. 1 to 8 FIG. subpixels of an interlaced image according to the invention. The dashed rectangles represent the subpixels simultaneously seen by a viewer's eye, and also represent the envelope of the focusing zones of the elementary lenses of the lenticular network 2.

  2, a plane of distribution of the pixels of an interlaced image not respecting the invention, because the interlaced image is here associated with a cylindrical lenticular network whose lenses have a longitudinal axis of symmetry inclined to the horizontal. The envelope of the focusing areas of these lenses are represented by inclined parallelograms whose outlines are in dashed lines.

  3, a plane of distribution of the pixels of an interlaced image, in a second embodiment of the invention, where the lenses as the sub-pixels located opposite, are arranged according to an organization which is the as close as possible to a honeycomb, each hexagon being composed of triangles called elemental triangles whose shape is as close as possible to equilateral triangles.

  4, a perspective view of a lenticular array portion according to the invention, corresponding to the plane of distribution of the pixels of FIG. 3, said lenticular array consisting of the superposition of two lenticular networks with cylindrical lenses 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.

  5a to 5d, the plane of distribution of the pixels of an interlaced image, in a third embodiment of the invention in which the interlaced image combines sub-pixels from 4 primary images.

  Figure 6a and 6b, the pixel distribution plane of an interlaced image, in a fourth embodiment of the invention wherein the interlaced image combines sub-pixels from only 2 primary images.

  FIG. 7: a synoptic representation of the distribution in the interlaced image of the sub-pixels coming from a primary image; the left part represents a source image 1000, which comprises pixels 50, 51, 52, 53 and following, arranged in lines 201, 202, 203 and following, and in columns 101, 102, 103 and following; and the right part represents the corresponding sub-pixels in an interlaced image 5 - the sub-pixels of the line 1 are noted, from left to right, 300d, 300e, 300f, 300g and 300h. The sub-pixels of line 2 are noted, from left to right, 300, 300a, 300b and 300c. The sub-pixels of line 3 are noted, from left to right, 300i, 300j, 300k, 3001 and 300m.

  Colored subpixels are represented by circles for a first color, squares for a second color, and triangles for a third color. This color representation convention is also used for Figure 8.

  Figure 8: a variant of a device according to the invention according to which the screen 1 is composed of sub-pixels such as LEDs, and provided with a lenticular network 3 with optical systems centered 31, 32, 33 and following.

  FIG. 1 shows a plane of distribution of the pixels of an interlaced image according to a first embodiment of the invention in which the elementary lenses are organized in lines inclined with respect to an axis called Horizontal Axis, of an angle whose absolute value of the tangent is equal to the height of a sub-pixel divided by the width of a sub-pixel.

  Above and hereinafter, horizontal axis and vertical axis are understood to mean mutually perpendicular axes which are respectively: parallel to the lower edge and to the upper edge of the rectangular interlaced image, or a section of this image according to portrait mode or landscape mode, for the so-called Horizontal Axis axis, o parallel to the left edge and right edge of the rectangular interlaced image, or a crop of this image in portrait or landscape mode , for the axis called Vertical Axis.

  In this arrangement, as in all those described below, there is at least one horizontal line of elementary lenses opposite a horizontal line of sub-pixels. This is not essential, but it makes it possible to have a larger number of elementary lenses, and thus to improve the resolution perceived by the spectator.

  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. This notation can be found in Figures 2, 3 and 5.

  Each line of sub-pixels is successively composed of sub-pixels red green and blue, and these sub-pixels are derived from primary images that succeed one another in the order of the primary images. It would be possible to have two adjacent pixels from the same primary image, but it would not be advantageous for the number of primary images that one seeks to maximize while maintaining the resolution perceived by the viewer.

  Each column of sub-pixels is composed of sub-pixels of the same color red or green or blue, and these sub-pixels are derived from primary images that succeed one another in the order of the primary images.

  The lenses 21, 22 and following (the position of which is symbolized in FIGS. 1 to 3 by bold dashed rectangles) are all located opposite the pixels whose value n is identical.

  The expression opposite should be understood taking into account the parallax. In fact, the orthogonal projection on the plane of the interlaced image of the optical centers of the elemental lenses does not coincide perfectly with the centers of the subpixels because the spectator is not located at infinity and the distance between two Elemental lenses that are said to be opposite two sub-pixels are slightly smaller than the distance between these two sub-pixels.

  When the viewer moves parallel to the plane of the screen, he always sees pixels coming 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.

  Other devices have been proposed for associating screens comprising subpixels of different colors to lenticular arrays, but the elementary lenses proposed are cylindrical lenses which have the characteristic of focusing on a line segment and not on a point. All therefore have the defect, for certain positions of the viewer, to focus simultaneously on several sub-pixels from different primary images.

  The device of the invention is thus the first to provide an effective response to the problem of allowing a viewer to see different primary images perfectly clear, and to see different primary images with both eyes.

  FIG. 3 shows that the invention can also be implemented in a different way, by not respecting the rule that each column of subpixels is composed of sub-pixels coming from primary images which succeed one another in the order of the primary images .

  The sub-pixels coming from the same primary image are here arranged in lines inclined on the horizontal of an angle whose absolute value of the tangent is equal to the ratio between the height of a sub-pixel and four times its width. .

  This arrangement is one of the preferred arrangements for displaying 9 primary images, which corresponds, for example, to an advertising display device.

  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 pupil aperture of each lens, and thus to improve the sharpness of the perceived image.

  It also has the advantage of improving the white synthesis, which is obtained by the addition of three colored sub-pixels R, V and B, this synthesis being all the more effective that the three pixels are substantially equidistant and form therefore a triangle whose shape is as close as possible to an equilateral triangle. This triangle is hereinafter called elementary triangle.

  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 4, which is constituted by the superposition of two cylindrical lenticular lens networks 210 and 220.

  The assembly between two cylindrical lenses forms an optical system having optical characteristics very similar 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.

  The advantages that can be found in using such cylindrical lens lenticular system assemblies is to reduce the vertical parallax with respect to the horizontal parallax, and also to be able to realize lenticular networks of large dimensions at a lower cost.

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

  When the sub-pixels come from primary images whose pixels are arranged in orthogonal checkerboard, the arrangement in equilateral triangles is not always possible. Otherwise, it is advantageous to arrange the sub-pixels according to an elementary triangle which is substantially isosceles.

  FIGS. 5a to 5d show a particularly advantageous implementation of the invention when the number of primary images is 4. The four figures represent the same interlaced image portion, according to the same subpixel notation as for the Figures 1 to 3, but the elementary lenses of the lenticular array are here represented by their hexagonal circumference.

  These 4 figures allow to see how the horizontal variation of the parallax allows the spectator to see successively the 4 primary images 40.

  What is remarkable in this arrangement is the almost perfect arrangement of honeycomb lenses.

  The apparent resolution for the viewer is very close to the native resolution of the screen 1 since the distance between two inclined lines of elementary lenses is only slightly greater than the width of a complete pixel. The device therefore displays 4 primary images with minimal loss of resolution.

  This arrangement is one of the preferred arrangements for the display of 4 primary images, which corresponds for example to a device serving as a terminal for a single person, such as an individual video conference terminal or a game console.

  Figures 6a and 6b show a particularly advantageous implementation of the invention when the number of primary images is 2, which is sufficient to achieve a stereoscopic pair. The two figures represent the same portion of interlaced image, according to the same notation of the sub-pixels as for FIGS. 5a to 5d, and the elementary lenses of the lenticular network are here also represented by their hexagonal periphery.

  These 2 figures allow to see how the horizontal variation of the parallax allows the spectator to see successively the 2 primary images.

  The average height of an elementary lens of the lenticular array is substantially equal to half the height of a sub-pixel, and the apparent resolution for the viewer is significantly greater than the native resolution of the screen 1. The distance between two lines of elementary lenses is indeed very much less than the width of a complete pixel. The device therefore displays 2 primary images instead of one while substantially improving the perceived resolution.

  In reality, for both Figures 5a to 5d and Figures 6a and 6b, the perceived resolution is significantly higher than that shown above when the viewer uses his two eyes and not one. In this case, unlike what he would see in the absence of lenticular network, the viewer sees two sets of pixels simultaneously.

  The arrangement of FIGS. 6a and 6b is particularly recommended for displaying flat images while benefiting from such an increase in the resolution. All that is required for this purpose is that the primary images all come from a unique original image whose resolution is greater than that of the screen 1, each primary image representing a different extraction of pixels from said unique original image.

  In the case of the implementation of this method, in particular with the arrangement shown in Figures 5a to 5d, it may be advantageous to provide the device with a means of varying the distance between the lenticular array 2 and the screen 1, so as to displace the focal length of said lenticular array when using the screen for displaying 2D images. The device according to the invention then allows both the display of 2D images without loss of resolution or with improvement of the resolution, and the display of 3D images.

  Figure 7 shows different ways of matching the pixels of a primary image to subpixels in the interlaced image.

  For each of the pixels of the primary image 1000 shown in the interlaced image 5, it is desirable for the set of subpixels of a color to represent the color component of this color of the primary image 1000. other words, this can be expressed by the fact that all the sub-pixels of the interlaced image that come from a primary image that have the same color completely represent the layer of the same color of the primary image considered.

  This can be obtained quite easily by software, but it is also possible to obtain this result by an electronic control of the screen 1: the sub-pixel 300 is powered only by the extraction of information from the color of the pixel to be represented, which is that of said sub-pixel 300.

  In the case where the image diffused by the screen 1 according to the invention comprises square pixels, one can match as illustrated in FIG. 1 a square of 4 pixels formed by two columns 101 and 102 and two lines 201 and 202 pixels 50 in the primary image 1000 to the three sub-pixels of an elementary triangle in the interlaced image. The method to be used is in this case that for 3 pixels used, the corresponding sub-pixel 300 is fed only by the extraction of the information of the color of said pixel which is that of said sub-pixel 300; and that one of the 4 considered pixels of the primary image 1000 is not used.

  A particularly advantageous variant is that a sub-pixel 300 is defined by a combination of the values obtained by the two methods described above, ie: by the method that the set of sub-pixels of a color represents the colored component of this color of the primary image 1000 considered, ^ by the method that a sub-pixel 300 is powered only by the extraction of information from the color of the pixel to be represented which is that of said sub-pixel 300.

  Once the screen 1 according to the invention is equipped with an improved digital control electronics, its design can be improved to increase the resolution perceived by the viewer with the following arrangement which is also illustrated by FIG. A square of 4 horizontally adjacent pixels 50, 51, 52 and 53 in the primary image 1000 corresponds to 9 subpixels on three horizontal lines; one of these 4 pixels (50) is represented by a sub-pixel 300 fed by the extraction of the color information of said pixel 50 which is that of said sub-pixel 300; one of these 4 pixels (52) is represented by two subpixels 300f and 300k which are each fed by the extraction of the information of the colors of the pixels considered, which are those of said subpixels 300f and 300k, and two of these 4 pixels (51 and 53) are each represented by three sub-pixels forming a triangle (300e 300a and 300j for the pixel 51 and 300g 300b and 3001 for the pixel 53), these sub-pixels being each powered by the extracting information from the three colors of the pixel in question.

  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.

  Similarly, the screen 1 is ideally an electronic screen such as a liquid crystal display or a plasma screen or a screen with colored light sources such as light emitting diodes (LEDs), but the device also works with any screen whose pixels have subpixels of different colors.

  The main applications of the present invention are: the advertising display, the advertising signs, the promotion at the point of sale, the composition of virtual showcases; all applications of television, video and film, 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-rays, NMR, scanner, ultrasound, endoscopy, microsurgery, etc.), computer systems piloting equipment and flight simulators, personal films, education, mission planning, reconnaissance, damage assessment, terrain analysis, cartography, geography, seismic research, teleconference; - lighting, works of art, decorative objects and gadgets.

Claims (14)

claims   An optical device comprising: 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, a screen 1 comprising luminous pixels, each of the pixels having sub-elements of different color hereinafter referred to as sub-pixels, the pixels of the interlaced image not being composed of sub-pixels coming from the same primary image, but contrary to images different primaries, characterized in that said elementary lens 21 of the lenticular array 2 is a centered optical system or the like, it being specified that the term "centric optical system" or the like is understood to mean: o both an optical system having an axis of symmetry of revolution substantially perpendicular to the focal plane of ladit e an elementary lens, o that an optical system having substantially identical optical characteristics being specified that is understood above: o by interlaced image the image displayed by the screen 1 in the form of pixels, o and by primary image one of the images entering the construction of said interlaced image to be proposed to the view of a millet of the viewer through said lenticular network.   2. An optical device according to claim 1 characterized in that the elementary lenses 21, 22 and following are organized in lines inclined relative to an axis called Horizontal axis, an angle whose absolute value of the tangent is equal to the height of a sub-pixel divided by the width of a sub-pixel, it being specified that is meant above and hereinafter by Horizontal Axis and Vertical Axis axes perpendicular to each other which are respectively: o parallel at the lower edge and at the top edge of the rectangular interlaced image, or a cutout of this image according to the portrait or landscape mode, for the axis called Horizontal Axis, o parallel to the left edge and the right edge of the rectangular interlaced image, or of a cut of this image according to the portrait mode or according to the landscape mode, for the so-called Vertical Axis axis.   3. Optical device according to claim 1, characterized in that each sub-pixel column is composed of sub-pixels of identical color, and these sub-pixels are derived from primary images which succeed one another in the order of the primary images. .   4. Optical device according to claim 1, characterized in that the sub-pixels originating from the same primary image are arranged in lines inclined with respect to said Horizontal Axis by an angle whose absolute value of the tangent is equal to the ratio between twice the height of a sub-pixel and once its width 5. Optical device according to claim 1 characterized in that there is at least one horizontal line of elementary lenses opposite a horizontal line of sub-pixels.   6. An optical device according to claim 1, characterized in that the sub-pixels originating from the same primary image are arranged in lines inclined with respect to said Horizontal Axis by an angle whose absolute value of the tangent is equal to the ratio between the height of a sub-pixel and four times its width.   Optical device according to claim 1, characterized in that the sub-pixels originating from the same primary image are arranged in lines inclined with respect to said Horizontal Axis by an angle whose absolute value of the tangent is equal to the ratio between once the height of a sub-pixel and twice its width.   8. The optical device as claimed in claim 1, wherein the sub-pixels originating from the same primary image are arranged in columns, where one column of sub-pixels out of two comes from a first primary image and the sub-pixels of the other columns come from a second primary image o and that the average height of an elementary lens of the lenticular array is substantially equal to half the height of a sub-pixel.   12. An optical device according to claim 1 characterized in that the primary images all come from a single so-called original image whose resolution is greater than that of the screen 1, each primary image representing a different extraction of pixels from said unique original image.   13. An optical device according to claim 1 characterized in that the sub-pixels from the same primary image are arranged so that each of said sub-pixels is located as close as possible to the middle of the line joining the two sub-pixels. -pixels from the same primary image that belong to the lower or higher subpixel line.   11 optical device according to claim 1 characterized in that the set of sub-pixels from a primary image represents the colored component of this color of the primary image considered.   Optical device according to Claim 1, characterized in that a sub-pixel originating from a primary image is fed only by extracting the information of the color of the pixel of the primary image considered to be represented, which is that of the sub-pixel considered.   13 optical device according to claim 1 characterized in that the three sub-pixels from the same primary image forming the smallest possible triangle, said elemental triangle are of different colors.   14. An optical device according to claim 12 characterized in that said elementary triangle is substantially equilateral.   15. Optical device according to claim 12 characterized in that said elementary triangle is substantially isosceles.   16. The optical device as claimed in claim 12, wherein: a square of 4 pixels formed by two columns 101 and 102 and two lines 201 and 202 of pixels 50 in a primary image 1000 corresponds to the three sub-pixels 300d 300 and 300i of an elementary triangle, o that for three of the pixels used, the corresponding sub-pixel 300 is fed only by the extraction of the information of the color of said pixel which is that of said sub-pixel 300 o and that one of the four pixels of a primary image 1000 is not used.   17. An optical device according to claim 12 characterized in that a square of 4 pixels 50, 51, 52 and 53 horizontally adjacent in a primary image 1000 corresponds to 9 sub-pixels located on three horizontal lines o that one of these 4 pixels (50) is represented by a sub-pixel 300 fed by the extraction of the information of the color of said pixel 50 which is that of said sub-pixel 300 o that one of these 4 pixels (52) is represented by two sub-pixels 300f and 300k which are each fed by the extraction of the color information of the considered pixels, which are those of said sub-pixels 300f and 300k, where two of these 4 pixels (51 and 53) are each represented by three sub-pixels forming a triangle (300e 300a and 300j for the pixel 51 and 300g 300b and 3001 for the pixel 53), these sub-pixels being each fed by the extraction of the information of the three colors of the pixel 18. Optical device according to claim 1, characterized in that said sub-pixels of the screen 1 are organized as close as possible to a honeycomb arrangement.   19. An optical device according to claim 1 characterized in that the lenticular network 2 is constituted by the superposition of two lenticular networks 210 and 220 cylindrical lenses, these two networks having a substantially common focal plane after being superimposed.