RU2172009C2 - Holographic device for formation of minimum one light beam of preset spectral composition and picture projector containing such a device - Google Patents

Abstract

FIELD: holographic device designed for projection of pictures represented on a matrix liquid crystal screen. SUBSTANCE: the device has a plane mirror formed by alternating transparent and reflecting strips with rectilinear and mutually parallel boundaries, the first and second identical reflection holograms each producing minimum one diffracted beam of the preset spectral composition, light source for illumination of the above holograms at an angle of incidence close to the normal one by means of the mentioned mirror; the above holograms are positioned symmetrically relative to the plane of the mentioned mirror so as to be illuminated by means of the transparent and reflecting strips, respectively of the mirror, and so that the beams diffracted by the first and second holograms would be reflected and passed through by the reflecting and transparent strips respectively, mirror, so as to be combined into a continuous light beam of the above mentioned spectral composition. EFFECT: enhanced efficiency of use of the light energy emitted by a lengthy source, compactness, prevented use of raster of filters, enhanced luminous efficiency. 15 cl, 3 dwg

Description

 The invention relates to a holographic device for generating at least one light beam of a given spectral composition and, in particular, to such a device for projecting images displayed on a matrix liquid crystal screen.

 Such a device containing a white light source, a three-dimensional phase hologram illuminated by the above source and registered in such a way that it decomposes the light into a continuous spectrum from red to blue, is known from the article entitled "Compact Spatio-Chromatic Single-LCD Projection Architecture" Loiseaux et al. (Publication of the S7-4 ASIA DISPLAY 95 conference, held in Hamamatsu, Japan, in 1995). As a result, the dispersed beam illuminates the raster of cylindrical microlenses at a variable angle of incidence, depending on the wavelength. In the focal plane of each microlens, an incident light spectrum is constructed, spatially distributed over three columns of cells opposite the microlens. The hologram dispersion, focus and pitch of the microlens raster are selected so that the color composition of the light illuminating each of the three columns of cells opposite each microlens corresponds to the red, green, and blue regions of the spectrum, respectively. The named cells are liquid crystal cells that form part of the matrix screen on such cells. Each element of the image formed by this screen is formed by three cells, or a pixel. They allow or do not allow light coming from the hologram to the lens, which projects an enlarged image of the image displayed on the screen onto an opaque or translucent observation surface. Such a device makes it possible to increase the fraction of useful light emitted by the source and illuminating the liquid crystal cells of the screen, and therefore, the brightness of the image projected onto the observation surface compared to the brightness achieved in conventional projectors containing color filter arrays placed close to the liquid crystal screen.

 The device described in the aforementioned publication can only be used with liquid crystal screens in which the cells forming the image pixel for the red, green and blue components are aligned along a line perpendicular to the orientation direction of the cylindrical microlenses in the raster. Thus, such a device cannot be used when the cells of such a triplet are located, for example, at the vertices of a triangle, as is often the case.

The closest in technical essence is known from the international patent application WO 92/09915 a lighting device for a three-color screen on liquid crystals. For the projection of the image displayed on this screen, such a device contains three ensembles of prisms and holograms, and the holograms are illuminated at an incidence angle of 45 ^o , at which their angular selectivity is high; each ensemble is associated with one of the monochrome components of the image. In addition, the named device contains a system of mirrors for illuminating the liquid crystal screen with radiation coming from three ensembles. The light processed by these three ensembles comes from one source, which should ensure the formation of a beam of rays of small divergence. Therefore, this source must be point-like, which determines its short service life and limited power. In addition, light passing through three ensembles also passes through numerous media interfaces and, therefore, suffers losses caused by spurious reflections from holograms and from the surfaces of prisms. Finally, the described system is cumbersome and, therefore, its inclusion in the projector, intended for wide consumption, is difficult.

 The present invention is the implementation of a holographic device (the formation of at least one light beam of a given spectral composition, which is intended, in particular, for use in projectors tri-color images with a matrix screen consisting of liquid crystal cells, and free from the disadvantages of the above analogues. To achieve this , such a device should ensure the efficient use of light energy of a real, non-point, white light source and minimize nels reflection loss or dispersion having a small size, which facilitates its incorporation into the image projector.

 The present invention is also the implementation of such a device that would be compatible with a liquid crystal matrix screen, in which the cells corresponding to the pixel of the displayed image are not arranged in a line, but are installed, for example, at the vertices of the triangle.

These objectives of the invention, as well as some others, which will be clear from the following description, are solved by the fact that, in a holographic device for forming at least one light beam of a given spectral composition, containing a mirror and holograms, the mirror (7) is made flat and formed adjacent alternately transparent (6 _i) and reflecting (5 _i) portions of the hologram are at least a first (4) and second (4 ') are designed as identical reflection holograms, each of which generates at least one diffracted sheaves to the above spectral composition, the device also contains a light source (1) for illuminating the named holograms (4.4 '), by means of the named mirror (7), at an incidence angle close to normal, the named holograms (4.4') are located symmetrically with respect to planes of said mirror (7) so as to be illuminated by transparent (6 _i ) and reflecting (5 _i ) sections of mirror (7), respectively, and so that beams diffracted by the first (4) and second (4 ') holograms are reflected and passed respectively reflecting (5 _i) and Transp GOVERNMENTAL (6 _i) areas, respectively, of mirror (7), to join together in a continuous light beam of the aforementioned spectral composition.

The problems are also solved by the fact that the said alternating sections of the mirror (7) are in the form of strips (5 _i , 6 _i ) with rectilinear boundaries parallel to the edge of the dihedral angle bounded by the planes of the holograms (4.4 ').

 The tasks are also solved by the fact that the aforementioned transparent and reflective sections of the mirror (7) are staggered.

 The problems are also solved by the fact that the mirror (7) is inclined to the axis of the beam of light emitted by the source (1) at an angle β such that the light beam of the above spectral composition that leaves the device is significantly inclined to the axis of the beam emitted by the source (1).

 The problems are also solved by the fact that it contains a lens (2) for the collimation of light coming from the source (1).

The problems are also solved by the fact that part of the beam emitted by the source (1), transmitted or reflected by the mirror (7), is diffracted by a hologram (4.4 '), which it illuminates at an angle θ such that it is reflected or transmitted, respectively, by the section (5 _i , 6 _i ) mirrors (7) adjacent to the one that missed or reflected the named part of the beam from the source, respectively.

 The problems are also solved by the fact that each of the holograms (4.4 ') forms at least two diffracted beams having each given spectral composition, and the diffraction angles of two beams are such that the traces of the central rays of these diffracted beams in the mirror plane (7) lie on axis of the same mirror section.

The problems are also solved by the fact that each of the holograms (4.4 '), in addition, forms a third diffracted beam having a given spectral composition; the diffraction angle θ _{1 of} this third beam is such that the trace of its central ray in the plane of the mirror (7) lies on the axis of the portion of this mirror closest to the region of the same function and containing traces of the central rays of two other diffracted beams.

,

,
где L₀ - максимальное расстояние от зеркала (7) до любой одной из голограмм, i - номер рассматриваемого участка (5_i, 6_i), возрастающий от полос 5₀ и 6₀, расположенных на расстоянии L₀ от голограмм, θ - угол дифракции, измеренный в проекции на плоскость, перпендикулярную зеркалу (7), β - угол падения пучка, идущего от источника (1), на это зеркало.The problems are also solved by the fact that the reflecting (5 _i ) and transparent (6 _i ) sections of the mirror (7) have widths l (5 _i ) and l (6 _i ) such that:

,

,
where L ₀ is the maximum distance from the mirror (7) to any one of the holograms, i is the number of the considered section (5 _i , 6 _i ), increasing from the bands 5 ₀ and 6 ₀ located at a distance L ₀ from the holograms, θ is the angle diffraction measured in a projection onto a plane perpendicular to the mirror (7), β is the angle of incidence of the beam coming from the source (1) onto this mirror.

The problems are also solved by the fact that the reflecting (5 _i ) and transparent (6 _i ) sections of the mirror (7) have the widths l (5 _i ) and l (6 _i ) intermediate between the values obtained from the formulas of paragraph 7 for the angles θ and θ ₁ respectively.

The problems are also solved by the fact that the projector of images displayed on a matrix screen (12) with liquid crystal cells (15 _R , 15 _V , 15 _B ) placed close to the raster (13) of optical microlenses installed to focus each of them at least one beam light (16 _R , 16 _V , 16 _B ) of a given spectral composition on the corresponding cell (15 _R , 15 _V , 15 _B ) of the screen (12), contains a holographic device according to any one of items 1 to 8 for lighting lenses (14 _ij ) raster (13) with at least one light beam of a given spectral composition.

The problems are also solved by the fact that in the image projector the matrix screen (12) consists of groups of cells located in a line (15 _R , 15 _V , 15 _B ), each group corresponding to an image element displayed on the screen (12).

The problems are also solved by the fact that in the image projector the matrix screen (12) consists of and; groups of cells (15 _R , 15 _V , 15 _B ) located not on one straight line, and each group corresponds to an image element displayed on the screen.

The tasks are also solved by the fact that in the image projector the cells (15 _R , 15 _V , 15 _B ) of each group are located in the "Δ" configuration.
The tasks are also solved by the fact that in the image projector, a holographic device generates three beams of light: red, green and blue, respectively.

 The device according to the invention finds use in a projector of images displayed on a liquid crystal matrix screen placed close to the raster of optical microlenses installed to focus each of them at least one light beam of a given spectral composition on the corresponding screen cell; this projector includes a holographic device according to the invention for illuminating a raster of lenses with at least one light beam of a given spectral composition.

Other characteristics and advantages of the present invention will be described in the description with reference to the drawings, which represent the following:
- FIG. 1 is a graph representing the dependence of the angular selectivity of a reflective hologram on the angle of incidence of a beam of rays illuminating the hologram; it is used to explain the operation of the device according to this invention,
- figure 2 - diagram of a device according to the invention in axial section,
- figure 3 is a diagram of an image projector equipped with a device according to the invention.

From the attached FIG. 1 it is clear that the angular selectivity Δθ i.e. the angular deviation from the Bragg drop corresponding to the drop in the efficiency of the reflective hologram to the level of 50% of its maximum value is a function, on the one hand, of the optimal angle of incidence i illuminating the hologram of the beam and, on the other hand, of the thickness of the layer in which the above hologram is recorded. From this graph it follows that the angle Δθ is maximum when the beam falls along the normal (i = 0 ^o ) to the plane of the hologram. For a hologram with a thickness of 10 μm, Δθ is therefore about 12 ^o . This practically means that the efficiency of the hologram remains high when the angle of incidence of the beam illuminating the hologram does not deviate from the normal by an angle exceeding 12 ^o . It is clear that such a tolerance is especially favorable when the beam illuminating the hologram is emitted by a real, non-point source, and therefore has a significant divergence, which is the most common case.

Note also that, as follows from FIG. 1, when the beam illuminating the hologram falls significantly different from normal, the angle Δθ decreases significantly. So, for example, when the angle of incidence i = 45 ^o corresponding to the angle of incidence used in the device described in the above patent application WO 92/09915, the angular selectivity is characterized by an angle Δθ of the order of 2 ^o for a hologram with a thickness of 10 μm. At this angle of incidence, the formation of a regenerating beam requires the use of a substantially less extended and, therefore, less powerful source than with normal incidence. Measurement of the spectral selectivity of the hologram as a function of the angle of incidence of the beam also shows that it almost does not change when the angle of incidence from i = 45 ^o to normal incidence. We use the noted features in the device according to the invention, which we will now describe in connection with the consideration of FIG. 2.

This drawing schematically shows a light source 1, which may not be point, the radiation of this source, collimated by lens 2, the axis 3 of the collimated beam, which illuminates the reflective hologram 4 after passing between sections 5 ₁ , 5 ₂ , etc. in the form of strips, reflecting on both sides and enclosed each between the transmitting sections 6 ₁ , 6 ₂ , etc. in the form of strips of a flat mirror formed by a transparent substrate on which the above reflective strips are fixed. Reflective strips can also be localized between two supporting transparent plates, the outer sides of which can undergo anti-reflection treatment. The boundaries dividing the strips 5 _i and 6 _i are rectilinear and perpendicular to the plane of FIG. 2.

According to the invention, the surface of the hologram 4 is perpendicular to the axis 3 of the beam emitted by the source 1. The hologram 4 is registered in such a way that a part of the light flux from the source, here in the form of partial beams that pass through the transparent sections 6, generates partial diffracted beams inclined at a diffraction angle θ normal to the surface of the hologram; this angle θ is chosen in such a way that each partial diffracted beam hits the surface of the reflecting strip 5 _{i of the} mirror 7 adjacent to the transparent strip 6 _i through which the partial beam incident on the hologram, which generated this diffracted partial beam, passes.

Partial diffracted beams parallel to the direction of axis 8 of the central partial beam (see Fig. 2) are then sent in stripes 5 _i ; mirrors 7 in direction 9, to an output device (not shown here), for example, to a liquid crystal matrix screen, as will be seen from further consideration.

Thus, the device according to the invention has the following advantages. On the one hand, it makes the best use of the light energy emitted by a non-point source 1, due to the normal incidence of the beam 3 on the hologram, but for the reasons indicated in connection with the analysis of FIG. 1. On the other hand, the zero-order beam reflected by the hologram 4 in the direction normal to it returns back to source 1, through the transparent sections 6 _{i of the} banded mirror 7, without spurious reflections of this beam in the device, capable of polluting the useful beam 9.

 In addition, it has significantly smaller dimensions than a conventional device devoid of a banded mirror 7. Indeed, in this latter, if you want to maintain the advantages of low angular selectivity of holograms illuminated at a normal angle of incidence, the diffracted beam 8 can only be used when it is sufficient is removed from the axis 3 of the incident beam, so that it is possible to place an output device, such as, for example, a matrix screen on liquid crystals, in the path of the beam 8. Then the distance separating the source 1 and the hologram 4 should be large. Thanks to the streaky mirror of the device according to the invention, the diffracted beam is sent in the direction of the axis 9, which is strongly inclined to the axis 3. Then this beam can illuminate the matrix screen on liquid crystals, located quite close to the mirror; the distance between source 1 and the hologram can be reduced; these two factors make it possible to realize a very compact device, compatible, for example, with a projector intended for wide consumption, as will be seen later on.

It is clear that the hologram 4 of the device shown in FIG. 2, it allows only discrete partial beams diffracted by hologram 4 to be formed and directed in the direction of axis 9. In many cases of use, and especially in the case concerning the projection of images from a matrix screen on liquid crystals, it is necessary to have a continuous diffracted beam. For this, according to the invention, a second hologram 4 'is installed in the device, identical to hologram 4; two holograms are placed in planes symmetrical with respect to the plane of the banded mirror 7, while the edge of the dihedral angle bounded by the planes of these holograms is parallel to the boundaries separating the transparent and reflecting portions of the mirror. Thus, as shown in FIG. 2, part 3 of the collimated light flux from a source that does not illuminate hologram 4 is reflected from bands 5 _i to hologram 4 'in direction 10. Hologram 4' sends diffracted partial beams back to 11; these partial beams pass through the transparent strips 6 _{i of the} mirror 7 in order to fill the gaps between the partial beams reflected in the direction 9 parallel to the direction 11. It is clear, therefore, that the diffracted light beam exiting the device is continuous and has a predetermined spectral composition everywhere.

In FIG. 2, the mirror 7 is inclined at 45 ^° to the axis 3 of the beam emitted by the source 1, in which case the holograms 4 and 4 'are located in mutually perpendicular planes. However, it is clear that the inclination β of the mirror 7 to the axis 3 can be different from 45 ^o , provided that the conditions for the normal incidence of the beams emitted by the source 1 on the holograms 4 and 4 'are satisfied.

The projector shown in FIG. 3 includes a substantially liquid crystal matrix screen 12 placed adjacent to the raster 13 of microlenses 14 _ij intended to focus the red, green, and blue light beams 16 _R , 16 _V , 16 _B , respectively, on the respective cells of the screen 12. Three liquid crystal cells, such as 15 _R , 15 _V , 15 _B , grouped in the Δ configuration, together make up a color image element (pixel); these cells selectively control the passage of beams of light 16 _R , 16 _V , 16 _B, respectively, to the lens 17 projecting the light transmitted by the screen 12 onto an opaque or translucent surface (not shown), where an enlarged image is observed, observed by users of the projector.

This projector is equipped with a device for generating three beams of red, blue and green radiation according to the invention, including a light source 1, holograms 4 and 4 'and a mirror 7 of the device shown in FIG. 2. In FIG. 3 schematically shows a change in the width of the strips 5 _i and 6 _i , of the mirror 7, which progressively decreases in the direction of the sections that are least distant from the holograms 4 and 4 ', which corresponds to the equations below.

,

,
где L₀ - это максимальное расстояние от зеркала до любой одной из голограмм, i - номер рассматриваемой полосы, возрастающий от полос 5₀ и 6₀, расположенных на расстоянии L₀ от голограмм, θ - угол дифракции, измеренный в проекции на плоскость чертежа, β - угол падения пучка 1 на зеркало 7, равный наклону этого зеркала к оси этого пучка.From FIG. 2 it follows that the distance measured along the beam diffracted by any one of the holograms 4, 4 ′ between its point of emission from the hologram and its point of reflection or passage through the mirror 7 varies in the section of the diffracted beam by the plane of the drawing. It follows that the width of the bands 5 _i and 6 _i cannot be constant, taking into account the constancy of the diffraction angle θ. It is shown that the widths l (5 _i ) and l (6 _i ) of the bands 5 _i and 6 ⁱ are given by the following expressions :

,

,
where L ₀ is the maximum distance from the mirror to any one of the holograms, i is the number of the strip in question, increasing from the bands 5 ₀ and 6 ₀ located at a distance L ₀ from the holograms, θ is the diffraction angle measured in projection onto the drawing plane, β is the angle of incidence of the beam 1 on the mirror 7, equal to the inclination of this mirror to the axis of this beam.

 We describe the operation of the device. The device allows the formation of several beams, light of various spectral compositions, for example, beams of red, green and blue, useful in the case of using the invention, which will be mentioned in connection with FIG. 3. For this, the source 1 can emit white light and holograms 4, 4 'can be recorded so as to form three diffracted beams, for example red, green and blue light; these beams are diffracted in directions that coincide in the projection onto the plane of the drawing, but which differ in projection onto a plane perpendicular to the plane of the drawing (mirror plane 7, for example). It is clear that the partial beams of three colors are reflected or transmitted by the same bands of the mirror 7. The three beams with coplanar axes thus formed at the output of the device can correctly illuminate the liquid crystal cells of the matrix screen, in which the image pixel is formed by three linearly arranged cells that control the passage of radiation red, green or blue, respectively, to the surface onto which the image formed on the liquid crystal is projected with magnification m screen.

 However, this arrangement of the beams is unacceptable when the above cells are not arranged in a ruler, but, for example, at the vertices of a triangle, according to a configuration called "Δ". The device according to the present invention is applicable for illuminating a screen in which cells are arranged in this configuration, as will be explained in connection with the consideration of FIG. 3, which shows the optical part of the projector of color images displayed on a liquid crystal screen: the projector is improved by turning on the device according to the invention.

From the circuit shown in FIG. 3 for cells 15 _R , 15 _V , 15 _B , for example, it follows that the microlens 14 _{11 of the} raster 13 focuses the light beams 16 _R , 16 _V , 16 _B on the cells 15 _R , 15 _V , 15 _B, respectively, while the axis of the beams 16 _R and 16 _V are located in the same plane intersecting the same strip 5 ₂ , while the beam 16 _B extends from the strip 5 _{1 of} the same function, closest to the strip 5 ₂ . It is obvious that the transparent strips 6 _i are used in the same way as the reflective strips 5 _i , as shown in the drawing in connection with the microlens 14 _{14 of the} raster 13. This result was achieved simply by setting the corresponding diffraction angle θ ₁ (see Fig. 2) radiation of blue color on holograms 4.4 ', different from the diffraction angles of the red and green beams and chosen so that the 16 _B beam, for example, would be reflected from the band 5 ₁ while the 16 _R , 16 _V beams would be reflected from the band 5 ₂ . It is clear that in this way the same microlens, for example 14 ₁₁ , focuses the beams of red, green and blue light on three cells 15 _R , 15 _V , 15 _B , located in the Δ configuration, as shown in FIG. 3. This is an important advantage of the device according to the invention over the device described in the publication of the ASIA DISPLAY 95 conference mentioned above, which can only be used with matrix screens in which cells corresponding to one image element are arranged in a line. This arrangement, however, is compatible, as shown above, with another method of implementing the device according to the invention.

It follows from the above formulas that the width l (5 _i ) or l (6 _i ) of the bands of mirror 7 is a function of the diffraction angle. When using at least two values of this angle, as in this case, when the cells are located in the Δ configuration, the calculations give two width values for each mirror strip. For it, a value is selected that is intermediate between the two calculated values, providing a minimum degradation of the device parameters.

 From the foregoing, it follows that the device according to the invention has the desired advantages, namely: the efficient use of light energy emitted by an extended, that is, not a point source; compactness, ensuring its compatibility with projectors designed specifically for widespread consumption, with the exception of spurious radiation caused by beams of zero diffraction order of the holograms used, by reflecting this light directly to the source. In addition, the device according to the invention, which eliminates the use of a raster of filters, usually used for spectral selection of radiation passing through the cells of the matrix screen, has high luminous efficiency, which ensures the formation of a bright and saturated color image using a projector equipped with this device.

 The invention is not limited to the described and depicted implementation methods, which were given only as examples. Thus, for example, a banded mirror can be replaced by a mirror consisting of sections, respectively transparent and reflective, arranged in a checkerboard pattern, but in a section preserving the arrangement shown in FIG. 2. The banded mirror portions and partial beams described above then become discontinuous in a direction perpendicular to the plane of FIG. 2 without changing their properties and calculating their sizes in projection onto the plane of the drawing.

 It would also be useful, for example, to use the possible high spectral selectivity of the holograms of the device according to the invention and the small angular selectivity of these holograms in order to collect and process the light signal coming from a remote and moving source, such as a laser reflector mounted on a satellite.

Claims (15)

1. A holographic device for generating at least one light beam of a given spectral composition, comprising a mirror and holograms, characterized in that the mirror (7) is made flat and formed by adjacent, alternately transparent (6 _i ) and reflecting (5 _i ) sections, holograms, which are at least the first (4) and second (4 ') made in the form of identical reflective holograms, each of which generates at least one diffracted beam of the above spectral composition, the device also contains a light source (1) for illuminating the aforementioned holograms (4.4 '), by means of the named mirror (7), at an incidence angle close to normal, the named holograms (4.4') are located symmetrically relative to the plane of the named mirror (7) so as to be illuminated by means of transparent ( 6 _i ) and reflecting (5 _i ) sections, respectively, of the mirror (7) and so that beams diffracted by the first (4) and second (4 ') holograms are reflected and transmitted, respectively, reflecting (5 _i ) and transparent (6 _i ) sections, respectively, of the mirror (7), to combine into a continuous beam of light in the above spectral composition. 2. The holographic device according to claim 1, characterized in that the said alternating sections of the mirror (7) are in the form of strips (5 _i , 6 _i ) with rectilinear boundaries parallel to the edge of the dihedral angle bounded by the planes of the holograms (4.4 ').  3. The holographic device according to claim 1, characterized in that the said transparent and reflective sections of the mirror (7) are staggered.  4. A holographic device according to any one of claims 1 to 3, characterized in that the mirror (7) is inclined to the axis of the light beam emitted by the source (1) at an angle β such that the light beam of the above spectral composition that exits the device is significantly inclined to the axis of the beam emitted by the source (1).  5. A holographic device according to any one of claims 1 to 4, characterized in that it contains a lens (2) for the collimation of light coming from the source (1). 6. A holographic device according to any one of claims 1 to 5, characterized in that a part of the beam emitted by the source (1) transmitted or reflected by the mirror (7) is diffracted by a hologram (4.4 '), which it illuminates at an angle θ such that it is reflected or transmitted, respectively, by the portion (5 _i , 6 _i ) of the mirror (7) adjacent to that which missed or reflected, respectively, the named part of the beam from the source.  7. The holographic device according to claim 6, characterized in that each of the holograms (4.4 ') forms at least two diffracted beams having each given spectral composition, and the diffraction angles of the two beams are such that the traces of the central rays of these diffracted beams in mirror planes (7) lie on the axis of the same mirror section. 8. The holographic device according to claim 7, characterized in that each of the holograms (4.4 '), in addition, forms a third diffracted beam having a given spectral composition; the diffraction angle θ _{1 of} this third beam is such that the trace of its central ray in the plane of the mirror (7) lies on the axis of the portion of this mirror closest to the region of the same function and containing traces of the central rays of two other diffracted beams. 9. The holographic device according to claim 7, characterized in that the reflecting (5 _i ) and transparent (6 _i ) sections of the mirror (7) have widths 1 (5 _i ) and 1 (6 _i ) such that

where L _o is the maximum distance from the mirror (7) to any one of the holograms;
i is the number of the considered section (5 _i 6 _i ), increasing from the bands 5 ₀ and 6 ₀ located at a distance L _o from the holograms;
θ is the diffraction angle measured in projection onto a plane perpendicular to the mirror (7);
β is the angle of incidence of the beam coming from the source (1) onto this mirror. 10. The holographic device according to claim 8, characterized in that the reflecting (5 _i ) and transparent (6 _i ) sections of the mirror (7) have widths 1 (5 _i ) and 1 (6 _i ) intermediate between the values obtained from the formulas Claim 7 for angles θ and θ _1, respectively. 11. The projector of images displayed on a matrix screen (12) with liquid crystal cells (15 _R , 15 _V , 15 _B ), placed close to the raster (13) of optical microlenses, installed to focus each of them at least one light beam (16 _R , 16 _V , 16 _B ) of a given spectral composition on the corresponding cell (15 _R , 15 _V , 15 _V ) of the screen (12), characterized in that it contains a holographic device according to any one of claims 1 to 8 for lighting lenses (14 _ij ) raster (13) with at least one light beam of a given spectral composition. 12. The image projector according to claim 11, characterized in that the matrix screen (12) consists of groups of cells arranged in a line (15 _R , 15 _V , 15 _B ), each group corresponding to an image element displayed on the screen (12). 13. The image projector according to claim 11, characterized in that the matrix screen (12) consists of groups of cells (15 _R , 15 _V , 15 _B ) located not on one straight line, each group corresponding to an image element displayed on the screen. 14. The image projector according to claim 11, characterized in that the cells (15 _R , 15 _V , 15 _B ) of each group are located in the configuration "Δ".  15. The image projector according to any one of paragraphs.11 to 14, characterized in that the holographic device generates three beams of light: red, green and blue, respectively.

Images