FR2967790A1 - Optical multi-stereoscopic imaging method for audio-visual applications, involves providing holographic screens with holographic optical element, where Lambertian scattering surface is located in hologram plane in one function of element - Google Patents

Abstract

The method involves associating multiple image sources (18, 19) with light sources (20). Holographic screens (16) are provided with a holographic optical element (HOE) that exhibits two functions, where Lambertian scattering surface is located in a plane of the hologram in a function of the HOE and a slit or a network of slits of a real image are located in front of a hologram image in another function of the HOE. The functions are restituted from the hologram image. The slit or the network of slits represent obstacles as an object (17) recorded during production of the hologram.

Description

The present invention relates to an optical multisteoscopic imaging method using a hologram acting as a screen and having a simultaneous multiplicity of N images, visible without special glasses or other prostheses, each visible without loss of resolution regardless of the number N of images, visible in single lobe or in several lobes. The technical field relates to imaging systems using a holographic screen, without special glasses or other prostheses, offering a polyscopic potential from static or animated video-type images, the hologram having the combination of two specific functions (holography of combined functions). According to the state of the art, methods of this type are known but which presents the difficulty of associating a polyscopic potential with a result without loss of resolution for each of the N images. The technical problems to be solved are the following: - Multiply the points of view without reducing the resolution; it is a question of multiplying the number of images on the screen, to multiply the number of points of view available to the vision of the public, without reducing the resolution of each of the images. - Manage polyscopy in a fully modular way; the problem being to manufacture multi-stereoscopic video systems with the right adequate number of projected pairs, depending on the application and polyscope requirement required; This makes it possible to adjust the cost of the system with regard to the actual level of polyscopy targeted. - To obtain from the process a highly polyscopic potential. In theory, the principle of the present invention does not limit the amount of couples projected on the holographic screen. The limit would come from the optical architecture which in practice could not physically incorporate too many video projection sources. - Manage an anti-pseudoscopic system without loss of resolution. A pseudoscopic prevention means is necessary to avoid the effects of inverted relief during the movements of the observers in front of the screen. The various methods of multi-stereoscopic video incorporate means treating the problems of inverted relief, but this is done to the detriment of the overall image resolution. Thus, often the question is evaded and anti-pseudoscopic means are not implemented. - Have a unique polyscopic vision of the sequence of images or a polyscopic vision in several lobes (choice of vision in single lobe or multi-lobes). This choice between these two method methods is related to the application and the required angular field width. - Achieve a regular sequence of images for an observer moving, laterally or receding, in front of the screen. - Avoid the effects of moiré or moire, present in some processes. These effects are unpleasant and disrupt the attraction or benefit of a raised vision. The method according to the invention overcomes these disadvantages. The present invention allows relief (stereoscopic) vision without special glasses or other prostheses. This multi-stereoscopic process is flexible in use, comfortable and easy to see, and it has a highly polyscopic potential without loss of resolution. This polyscopic potential lies in the fact that a plurality of images can be formed simultaneously and thus a plurality of stereoscopic pairs. This multiplicity of images (polyscopy) does not lead to loss of resolution. The resolution of each image is added to the others.

The method exploits the principle of a complex holographic screen that distributes all images selectively to the eyes of an audience, and designed so that each observer can have a binocular perception in relief. The holographic screen consists of a single-content hologram based on a combination of 2 specific functions (holography of the combined functions): - A Lambertian surface function at the screen plane - A selective angular distribution function of the fields of Diffusion (for each image) The hologram produces as many distinct images of this content as there are distinct rendering beams, each having the same angle (a) of incidence to the hologram and each thus presenting an offset lateral to another. The restitution of the hologram is thus plural, each rendering beam generates a real slit image or slot network whose spatial location is shifted by a slit width with respect to that of another real slit image or slot network, originating from a neighboring rendering beam. There is no pseudoscopic perception at the junction of 2 series or series of images (at the junction of 2 lobes), for the observers placed in contact with or near the surface containing the images of slits, by means of a distance (u) between 2 slots of the fixed network such that it is equal to the width of the number of slots identical to the number of image sources contained in the system. As a result, the vision is fully orthoscopic, there is no inverted relief effects during public movements.

The regularity of sequences of images is managed according to the dimensions of the screen (inter-pupillary distance of the observer relative to the screen base) and the useful area of evolution of the observers (position in decline of the observer with respect to its lateral position), by means of the holographic screen integrating a function of spatial distribution of the images according to a geometry, parameterized during the production of the screen, which is optimized according to the dimensions of the screen and expected behavior of observers according to the application. The method thus has comfort of observation, it allows a lobe organization and contains an anti-pseudoscopic means; finally, it ensures a fluidity of vision in a video situation (provided by the polyscopy), as well as a regularity of sequences of images. In conclusion and according to the invention, these technical problems are solved by means of a multi-stereoscopic optical imaging method by means of a hologram acting as a screen, having a simultaneous multiplicity of N images, static or animated. , visible without special glasses or other prostheses, each visible without loss of resolution regardless of the number N of images, visible in single lobe or in multiple lobes, the method allowing a polyscopic potential and containing an anti-pseudoscopic means, characterized in what the process comprises among others, a multiplicity of N image sources each associated with a light source, and that the holographic screen consists of a holographic optical element (HOE) incorporating two functions, the first being a lambertian diffusing surface located on the plane of the hologram, the second being that of a slot, in real image, or of a network of slots, in a single image; it, for each way of restitution, located at the front of the hologram towards an observant public; these two functions being each an image of the hologram to the restitution. The invention is described with reference to the accompanying drawings showing, by way of non-limiting examples, the preferred embodiments of the process. Figures 1 and 2 show the basic principle.

A screen consists of a hologram (1). It is a holographic optical element (HOE) of transmission, amplitude or phase, which incorporates 2 functions. The first function is that of a Lambertian scattering surface located on the plane of the hologram (1).

This function is an image of the hologram (1) at restitution. The second function is that of a network (2) of real slots located at the front of the hologram (1) towards an observer audience. Each slot consists of 2 obstacles, actual images of the hologram, and so elaborate, represents an optical slot function.

The network (2) of slots thus represents a set of obstacles as an object recorded during the realization of the hologram (1). This function is an image of the hologram (1) at restitution. The 2 functions are connected.

The lambertian surface diffuses only in the directions of the slits (6) and not in those of the obstacles (7). The rendering beam (3) from a point source of light (4) is transmitted through an image source (5). This image source (5) is an amplitude object.

This image source (5) consists of a slide or an optical valve imaging device such as an LCD panel among others, as non-limiting examples. According to a variant based on a reflection principle, the image source (5) consists of a micro-mirror system by way of non-limiting example.

The image source (5) provides spatial amplitude modulation of the hologram (1) during its rendering. The enlarged image of the image source (5) is formed on the screen plane by the fact that the Lambertian scattering surface, image of the hologram (1), is spatially modulated by this same image source (5).

The image of the source (5) is formed directly to the screen without the need for a lens and this by the punctuality of the source (4). In practice, the punctuality of the source (4) is identical to or slightly smaller than the dimensions of a pixel of the image source (5). The plane of the hologram (1) is parallel to that containing the image source (5) to maintain the shape homothety in the geometry of the projected image. Figure 1 shows the principle in profile view. Figure 2 shows the principle in top view. The width of a slot (6) or an obstacle (7) is equal to or slightly less than the average interpupillary distance of the observers. A slot (6) or an obstacle (7) are each images of the hologram (1). The light source (4) is in practice a monochromatic source such as a laser or a spectral lamp provided with an interference filter as non-limiting examples. In the case of a non-monochromatic light source (4), the image of the Lambertian surface would only suffer negligible aberrations due to its location in the precise plane of the hologram (1).

On the other hand, the image of a slot (6) or of an obstacle (7) would undergo strong physical and geometrical aberrations. Indeed, there would be as many images of a slot (6) or an obstacle (7) as there are restitution waves of different length, and the dimensions of each of these images as well as their spatial location would be different, depending on the wavelength rendering them. Figures 3 and 4 show the multi-stereoscopic principle allowing a multiplicity of distinct images. Figure 3 shows the principle in top view. Figure 4 shows the principle in profile view. The hologram (8) has a unique content. The rendering beam from a point light source (11) is transmitted through an image source (9) in the optical axis of the hologram (8). The hologram (8) has an optical axis perpendicular to its plane; this optical axis passes through the hologram at its center. The projected image is formed on the plane of the hologram (8) by the spatial amplitude modulation of a Lambertian scattering surface, an image of the hologram in the plane of the latter. A slot (13) consisting of a space limited by two obstacles, real images of the hologram, is located on the same optical axis, and represents an optical slot function. Another rendering beam from a point light source (12) is transmitted through an image source (10) constituting another channel, with an offset with respect to the other beam. This offset is represented by the distance (d). A slot (14) consisting of a space limited by 2 obstacles, real images of the hologram, is located on the same optical axis, and represents an optical slot function. The geometrical conditions of restitution by the beam coming from the light source (11) are faithful to those of the reference beam at the recording. In the case of the restitution beam from the light source (12), only the angle of incidence (a) is maintained with respect to the geometric conditions of the reference beam at the recording, which allows the vision of the hologram (8). The distances between the point sources (11,12) and the center of the hologram (8) are identical for the principle of equalizing processing of restitution. The shift does not cause any disturbance in the restitution of the Lambertian scattering surface because it lies exactly on the plane of the hologram (8). On the other hand, the image of the 2 obstacles forming the slot is shifted.

The slot image is localized according to the variations in offset of the rendering beam corresponding to the function of this slot. The distance (d) is adjusted to place the actual image of the slot (13) in continuity with that of the slot (14).

There are thus as many distinct images of the content of the hologram (8) as there are separate rendering beams. The hologram thus incorporates two functions, the first being that of a Lambertian scattering surface, the second being that of a slot, in real image, for each playback channel.

The two functions are connected by means that the Lambertian surface restored by the beam coming from the light source (11) diffuses only in the directions of the slot (13) just like the Lambertian surface restored by the beam coming from the source of light (12) diffuses only in the directions of the slot (14). The axes of the rendering beams are each contained in vertical planes. The beams are directed from the bottom to the top. This geometry allows the evacuation of non-diffracted beams at the emergence of the hologram (8) above the observers' heads. The process also works in the reverse case of top-down directional restitution. It is the practice of the device that determines the meaning. Thus the zone of vision is not tainted by the undiffracted beams. The horizontal angle of vision is thus not limited by the undiffracted restitution beams. The vertical high limitation of the viewing zone is a function of: the distance between the two slot gratings (13, 14) in real image and the hologram (8) the angle of incidence (a) of the beams from point sources (11,12) - the opening of beams from point sources (11,12) FIG. 5 represents by way of example a version including 5 projections and thus 5 gratings of slots. The device of FIG. 5 for the implementation of the method is shown in a view from above. The optical architecture around the hologram (15) thus consists of 5 channels. The slot networks, each in real image, are shown in offset only for the sake of clarity.

The images of the network of slots are all contained in the same plane, within the limit of the spatial distortion aberration of the location of the image of each network. Each slot image is continuous with that of another slot.

The 5 image projections constitute 4 stereoscopic pairs (1,2) (2,3) (3,4) (4,5). This set of couples represents a series or series of images. The network presented as an example includes 3 slots. This series or sequence of images is thus reproduced (or visible) 3 times, as many times as there are slots in the same network, and thus available in the example to the vision in 3 distinct localities. The distance (u) between 2 network slots is calculated such that it contains, in continuity, the width of 4 slots corresponding to the other 4 slot networks, added to the so-called neutralized width having the function of an obstacle and approximately corresponding to the width of a slot (ie a width of 5 slots in total).

The distance (u) between 2 network slots is thus fixed such that it is equal to the width of a number of slots identical to the number of image sources in the device. This width or neutralized zone ensures the sequence on another cascade of slots in continuity.

This width or neutralized zone thus closes a series of images and partitions the neighboring series. This break between two cascades of slots in continuity is necessary to the stereoscopic vision to avoid the inversion right eye / left eye in the vision of a couple of images corresponding to the junction between 2 series of images. An inversion right eye / left eye in the vision of a couple of images would lead to a pseudoscopic perception of it. The means of this break between 2 sets of images does not cause loss of overall image resolution. The means of this break between 2 series of images is valid only for the observers placed in contact with or in the vicinity of the surface containing the images of the network of slots. Distances (d1, d2, d3, d4) are adjustable by mechanical means to adjust the continuity of each slot image to its next. The distances between the different point sources and the center of the hologram are identical for the principle of egalitarian processing of restitution. This principle is necessary to maintain a constant width on the image of the slots.

This processing of the restitution also intervenes on the coincidence or almost coincidence of the surfaces containing the image of the gratings of slots, in the limit of the aberration in spatial distortion of the location of each image of network. In order to fix an identical magnification of all the images in the plane of the hologram (15), it is necessary to introduce mechanical adjustment means on the retreating location of each image source with respect to the center of the hologram. FIG. 6 presents a variant presenting a multiplicity of distinct images less limited by the congestion of the image sources.

In FIG. 5, the limitation of the multiplicity comes from the fact, for the transmissive image sources, of the minimum dimensions of the component pixel. For practical reasons of manufacture, the pixel in use represents a few microns and determines, depending on the resolution of the image source, the dimensions thereof.

This congestion base represents a constraint that increases with the number of channels that the system contains. In the case of a holographic screen in modest format, this constraint constitutes a disturbance in the geometric conditions of restitution for the tracks located too far from the optical axis. A gap of restitution too large, with respect to the optical axis, causes an aberration on the image of the network of slots which then would not be more negligible and which would thus disturb the cascading storage of slots in continuity. The aberration in this case is a distortion on the image of the slots and also on their location. The slot tilts as a function of the spacing of the rendering beam with respect to the optical axis. Thus, by adjusting the distances (d1, d2, d3, d4), the adjustment is adjusted by juxtaposing slit images only for a fixed slit length. Outside this height, there is an overlapping of slots or a non-continuity of slots.

For the distortion in the localization of the image of the slits, it is a vertical leak of the network of slits which is amplified when the beam of reproduction of the hologram (8,15) deviates from its optical axis . In addition, the dimensions of a pixel on the image source (9, 10) must not be less than the punctuality of the source (11, 12) of rendering light.

In the opposite case, the image on the hologram (8, 15) of a pixel would overlap with that of one or more other pixels depending on the importance of the dimensional overshoot of the source (11, 12) punctually on the dimensions of the pixels.

The resolution of the projected image is then reduced. In practice, the dimensions of a pixel on the image source (9, 10) must not be too small and thus condition congestion as a consequence of this same source of images.

Thus, the congestion of the image source represents a limit. The optical architecture shown in FIG. 6 allows a multiplicity of distinct images, easier to implement, while treating the constraint of the punctuality of the rendering sources with respect to the dimensions of the pixels in the presence.

The device for implementing the method of Figure 6 is shown in plan view. The hologram (16) has a unique content. An objective is the origin of each rendering beam. The nodal point of emergence of the objectives represents the top of the beams of restitution.

Each goal represents the source of a path. The objective (17) has the most limited numerical aperture possible in order to maintain a pseudo-punctuality to the rendering beam which is derived from it. The image source (18) is illuminated by means of a condenser (19) or a series of condensers by a source (20) of light.

This source (20) must be relatively punctual so that its image on the pupil of the lens coincides with the format thereof. The condenser (19) represents an objective forming the image of the light source (20) on the pupil of the objective (17). The pupil being narrow, the projection on this one must be made with precision. Thus the condenser (19) is provided with mechanical adjustments in X and Y on the plane containing it to spatially optimize the projection on the pupil. Another solution consists in providing the light source (20) with complete XYZ mechanical adjustments in order to target the optimum energy distribution on the pupil of the objective (17).

The distance between the hologram (16) and each lens being fixed to determine the width of the slots and, the width of all the slots being the same, the objective is in practice fixed, without mechanical adjustments for its adjustment. All objectives are set to freeze the rendering geometry of the hologram (16).

The adjustment of the projection parameters of the image to the plane of the hologram (16) is effected by the mechanical adjustment of the components upstream of the objective (17): the image source (18), the condenser (19), and the light source (20). - The sharpness of the projected image of a channel on the hologram (16) is obtained by moving the image source back and forth along the optical axis of the same channel. - The coincidence of the projected image of a channel with those of the other channels is achieved by a mechanical adjustment on the X and Y image source on the plan containing it. This coincidence can be achieved by an electronic adjustment on the pixel addressing by shifting rows or columns. This solution, however, slightly reduces the resolution of image sources.

The objective (17) has the most limited numerical aperture possible. The pupil associated with it provides this function. There are as many images of slits as there are points contained in the plane of the pupil, each point representing a point source. The image of the slots is thus enlarged.

This magnification is a function of the following parameters: - the ratio of the distance of the image of the gratings from the slits to the plane of the hologram (16) to that of the same plane from the hologram to the objective (17) - l numerical aperture of the objective (17) To neutralize the effect of this magnification on the width of the image of each slot, a reduction of the width of the slits is made during the realization of the hologram (16) by in relation to the case of the hologram (15). The enlarged image of a slot remains a slot. In the direction of the height, the magnification has no or very little effect in the case of the channels situated too far from the optical axis of the hologram (16) due to the inclination generated on the slot function. In the width direction, the spatial distribution of energy on the slit function is no longer regular in the case of a circular pupil associated with each objective. There is more apparent energy at the center of the slits in the situation where the observer's eyes are also moving vertically. A pseudo-homogeneous distribution of energy on the slit function is possible by means of a pupil constituted by an opening having a slit-like shape whose edges or cutting edges consist of knives adjustable in inclination. The inclination is then different from one channel to another depending on its position with respect to the optical axis of the hologram (16). A tilt adjustment of knives on each pupil makes it possible to adjust the energy distribution on each slot function.

FIG. 7 shows the device for carrying out the method in the form of a piece of furniture having a transmission hologram (16) and having a plurality of channels. The device of Figure 7 is shown in profile view.

The hologram (16) has an optical axis perpendicular to its plane; this optical axis passes through the hologram at its center. Each channel consists of an image source associated with a point source of light. The cabinet incorporates 5 ways as an example in Figure 7.

The hologram (16) is attached to the top of the cabinet which incorporates the entire device. In all of FIGS. 1 to 7, the screen incorporates, according to a variant, a method, polarizing by way of nonlimiting example, intended to block the zero-order beam at the emergence of the hologram (1), the vision of the content of this hologram taking place in orders 1 or -1.

Figure 8 shows an optical architecture in the case of a reflection hologram. The hologram (21) is a holographic optical element (HOE) of volume thus operating according to the Bragg diffraction regime. There is thus no longer the constraint of zero-order beams emerging in the direction of the public in the case of transmission HOEs operating according to the diffraction regime of the networks. Alternatively, undifferentiated light on the hologram (16) is absorbed by one or more surfaces (not shown) at the rear of this hologram. It is no longer necessary to employ monochromatic light sources to avoid producing aberrations on the function of the slots. The Bragg principle, upon reading the hologram, allows selection of a limited portion of the spectrum of the rendering light source. In this case, there are no more aberrations on each of the images of the hologram, within the limit of the resulting spectral width of the chromatic selection of Bragg. For the solution of a hologram with 3 chromatic selections, in use, red, green, blue, there are 2 cases: - the hologram is recorded using a single wavelength and the function of the 3 chromatic selections is achieved by swelling and / or shrinking of the interference pattern. In this case, there are 3 separate images of each color for each slot. the hologram is in true colors and recorded using 3 distinct wavelengths: red, green, blue. There is thus summation of 3 different interference figures. At restitution, the images of each slot color (s) coincide.

The physical aberrations on the image of the slots are thus absent, within the limit of compatibility of the geometric conditions of the reference wavefront of the recording, those of the restitution wavefront. Each optical architecture shown in Figures 1 to 7 is based on the use of a transmission hologram (1,8,15,16) has a variant 10 based on a reflection hologram. Figure 8 shows the variant in the form of a cabinet having a hologram (21) of reflection and having a plurality of channels. The device for carrying out the method of FIG. 8 is shown in profile view. The hologram (21) has an optical axis perpendicular to its plane; this optical axis passes through the hologram at its center. Each channel consists of an image source associated with a point source of light. The cabinet incorporates 5 channels as an example in Figure 8. The hologram (21) is attached to the top of the cabinet that incorporates the entire device. In all of FIGS. 1 to 8, each hologram is either of analog type in use or of synthetic type according to other variants. In the common case of an analog hologram, it is an interference record. A wavefront resulting from a Lambertian surface and a set of obstacles arranged in a network of slots is recorded, the convergence of this wavefront determining, inter alia, the opening of the angular field of vision. The dimensional limit of the optical equipment intervening on the convergence of this wavefront leads to restricting the opening performance of this angular field. In the case of a synthetic hologram, the wavefront is mathematically defined. The interest lies in the fact of being able to freely intervene on the main parameters of the wavefront, and in particular to allow a wide opening of the angular field of view of the hologram. In all of FIGS. 1 to 8, the screen made up of a hologram optionally also incorporates an anti-reflection treated window or an anti-reflective device based on the principle of a circular polarization, by way of non-limiting examples. In all of FIGS. 1 to 8, the method has a polyscopic potential by means of a distance from the image sources with respect to the hologram, this retraction determining the space available for accommodating the image projectors; the greater this decline and the greater the polyscopic potential.

The image projector is defined as the device incorporating the image source, the light source, and possibly the optical equipment for projection by means of a lens. In all of FIGS. 1 to 8, it is possible to manage the polyscopy in a completely modular way by means of an optional juxtaposition of the number N of the hologram restitution channels that the user wishes, N being an even number or odd since all these paths refer spatially to each other and not to a reference outside them. In all of Figures 1 to 8, the image sources are of the "transmissive" type.

For each optical architecture constituting the invention as presented, there is a variant exploiting sources of the "reflective" type. These variants are not shown in the drawings. In all FIGS. 1 to 8, the images are formed on the screen by means that each image source (5, 9, 10, 18) acts as an amplitude object and that each of these sources provides a spatial modulation. in amplitude of the hologram (1, 8, 15, 16, 21) at restitution. In conclusion, the method according to the invention and all its variants is particularly intended for the audiovisual field and imaging in general for applications where a multi-stereoscopic vision is desired or required. 20 25 30 35

Claims (26)

CLAIMS1) Optical multi-stereoscopic imaging method by means of a hologram acting as a screen, having a simultaneous multiplicity of N images, static or animated, visible without special glasses or other prostheses, each visible without loss of resolution whatsoever the number N of images, visible in a single lobe or in several lobes, the method allowing a polyscopic potential and containing an anti-pseudoscopic means, characterized in that the method comprises inter alia, a multiplicity of N image sources (9 , 10, 18) each associated with a light source (11, 12, 20), and that the holographic screen (8, 15, 16, 21) consists of a holographic optical element (HOE) incorporating two functions, the first being that of a Lambertian diffusing surface situated on the plane of the hologram, the second being that of a slit, in real image, or of a network of slits, in real image, for each way of restitut ion, located at the front of the hologram towards an observer audience; these two functions being each an image of the hologram to the restitution. 2) The optical method according to claim 1, characterized in that the slit or slit network represents a set of obstacles as a registered object when making the hologram (8 ', 15, 16, 21). ). 3) Optical method according to claims 1 and 2, characterized in that the two functions are connected by means that the Lambertian surface diffuses only 25 in the directions of the slot or slots and not in those of the obstacles, for each way of restitution . 4) Optical method according to claims 1 and 3, characterized in that the images are formed on the screen by means that each image source (5, 9, 10, 30 18) acts as an object of amplitude and that each of these sources provides spatial amplitude modulation of the hologram (8, 15, 16, 21) at restitution. 5) Optical method according to claims 1, 3 and 4, characterized in that the hologram (8, 15, 16, 21) has a unique content and produces as many distinct images of this content by means of has as many separate rendering beams, each having the same angle (a) of incidence to the hologram and each thus having a lateral shift with respect to another. 6) Optical method according to claims 1, 3, 4 and 5, characterized in that the restitution of the hologram (8, 15, 16, 21) is plural, and each restitution beam generates a real image slot or slot network whose spatial location is shifted by a slit width with respect to that of another actual slit or grating image originating from a beam of. restitution neighbor. 7) An optical method according to claims 1, 3, 4, 5 and 6, characterized in that it presents to the vision a single series or series of images filling the entire angular field of vision, or in a single lobe, and this by means of a holographic screen (8, 15, 16, 21) producing the function of a real image of a single slot. 8) An optical method according to claims 1, 3, 4, 5 and 6, characterized in that it presents to the vision the same series or sequence of images reproduced at various localities of the total angular field of view, or in several lobes , and this by means of a holographic screen (8, 15, 16, 21) producing the function of a real image of a network of slots, the number of slots on the same network corresponding to the number of presentations of the suite images in the field of view. 9) The optical method according to claims 1, 3, 4, 5, 6, 7 and 8, characterized in that there is absence of pseudoscopic perception at the junction of 2 series or series of images (either at the junction of 2 lobes), for observers placed in contact with or near the surface containing the slit images, by means of a distance (u) between 2 slits of the fixed network such that it is equal to the width of the number of slits identical to the number of image sources contained in the device. 10) Optical method according to claims 1, 3, 4 and 5, characterized in that each retrieval beam of the hologram (8, 15, 16, 21) originates from a point source of light or the nodal point of emergence of an objective. 11) Optical method according to claims 1, 5, 6, 7, 8 and 10, characterized in that there is in the case of the hologram (8, 15, 16, 21) the maintenance of a constant width on the slot image and also a coincidence or almost the surfaces containing the image of the gratings of slots, within the limit of the spatial distortion aberration of the location of the image of each network, and that by means of that the distances between the different point sources or the emergence point of the lenses and the center of the hologram are identical for the principle of equal treatment of restitution. Optical method according to claims 1, 5, 6, 7, 8, 10 and 11, characterized in that the juxtaposition adjustment of the slit images in the case of the hologram (15, 16, 21) is performed by mechanical methods of setting distances (d1, d2, d3, d4). 13) Optical method according to claims 1, 4, 5 and 10, characterized in that, in the case of the hologram (8, 15, 21) each image source is projected directly on the screen by a point source of light and this by means that the dimensions of the point source of light are less than or equal to those of each pixel constituting the image sources. 14) Optical method according to claims 1, 4, 5 and 10, characterized in that, in the case of the hologram (16, 21), each image source is projected onto the screen by a light source ( 20) by means of a lens (17) associated with a pupil. 15) Optical method according to claims 1, 2, 3, 4, 5, 6, 10 and 14 characterized in that in the case of a hologram (16), to reduce the magnified image of the slots by the non-punctuality of the restitution beam coming from the nodal point of emergence of each objective (17), presenting as many real images of slots as there are points with the plane of each pupil, a reduction of the width of the slots is operated at the realization of the hologram (16) relative to that of the hologram (15). Optical method according to claims 1, 3, 4, 10, 14 and 15, characterized in that, in the case of the hologram (16), the pupil of each objective (17) consists of an opening having a slit shape whose edges or edges consist of adjustable knives in inclination so that this knife tilt adjustment on each pupil allows to adjust the energy distribution on each slit function. 17) Optical method according to claims 1, 3 and 4, characterized in that the transmission hologram (8, 15, 16) radiates no undiffracted wave by means of a method incorporated in the screen and intended to block the zero-order beams at the emergence of this hologram. 18) Optical method according to claims 1, 3 and 4, characterized in that each optical architecture based on the use of a transmission hologram (8, 15, 16) has a variant based on the use of a hologram reflection (21). 19) Optical method according to claims 1, 3 and 18, characterized in that the reflection hologram (21), operating according to the Bragg diffraction regime, provides a trichromatic function by means of this hologram is recorded at the using a single wavelength and that the function of the 3 chromatic selections is performed by swelling and / or shrinkage of the interference pattern, which produces 3 separate images of each color for each slot. 20) Optical method according to claims 1, 3 and 18, characterized in that the reflection hologram (21), operating according to the Bragg diffraction regime, provides a trichromatic function by means that this hologram is in true colors and recorded using 3 distinct wavelengths: red, green, blue; which thus constitutes the summation of 3 different interference figures during the recording. 21) Optical method according to claim 1, characterized in that the angular field opening is determined without constraint to the realization of the hologram (8, 15, 16, 21) by means that it is of synthetic type of which the wavefront at the restitution is defined mathematically, which allows to intervene freely on the main parameters of this same wavefront, contrary to the technique of the analog hologram for which the dimensional limit of the optical equipment intervening in the realization of this leads to restrict the opening performance of this angular field. 22) Optical method according to claim 1, characterized in that the screen consisting of a hologram (8, 15, 16, 21) optionally incorporates an anti-reflection treated window or an anti-reflective device based on the principle of a circular polarization, by way of non-limiting examples. 23) Optical method according to claims 1, 3, 4, 5, 6 and 10, characterized in that it has a polyscopic potential by means of a distance from the image sources relative to the hologram, this determining decline the space available to house the image projectors; the greater this decline and the greater the polyscopic potential. 24) Optical method according to claims 1, 3, 4, 5, 6, 7 and 8, characterized in that it is possible to manage the polyscopy in a completely modular way by means of an at will juxtaposition of the number N of channels restitution of the hologram that the user desires, N being an even or odd number since all of these channels refer spatially to each other and not to a reference external to them. 25) Optical method according to claims 1, 4, 5, 6, 13 and 14, characterized in that the optical architecture constituting the present invention is made from image sources of "transmissive" type or "reflective" type ". 26) Optical method according to claims 1, 4, 5, 6, 7, 8, 9, 13, 14 and 24, characterized in that the regular sequence of images is managed according to the dimensions of the screen (distance inter-pupillary of the observer with respect to the screen base) and of the useful area of evolution of the observers (position in retreat of the observer relative to its lateral position), by means that the holographic screen integrates a function of spatial distribution of the images according to a geometry, parameterized during the manufacture of the screen, which is optimized according to the dimensions of the screen and the expected behavior of the observers according to the application. 30