FR3110003A1 - Screen for displaying a projected image with a structured coating. - Google Patents

Abstract

Screen for displaying a projected image comprising a structured coating Screen (5) comprising a support (10) and a reflective coating (20) carried by the support, the coating having a face (25) on which an image can be projected, structured by at least one 3D pattern (30) comprising several concentric annular portions (P0, P2, P4, P6) of axis X and of the same sign of radial slope, called “MSPR annular portions”, the X axis being normal to the face of the support facing the coating, each annular portion MSPR of rank i extending around the axis X between radially inner ri and outer ri + 1 ends and having a height hi (r) expressed according to l 'equation r being the radial distance to the X axis, hmb (r), called "height of the base pattern", being defined at least over all the intervals [ri; ri + 1] over which the MSPR annular portions s' extend, the highest of the MSPR annular portions having a height less than or equal to 15 μm. Figure for the abstract: Fig. 1

Description

Screen for displaying a projected image with a structured coating.

The present invention relates to a screen for displaying projected images, in particular by means of a cinematographic projection system. In particular, it relates to a screen intended for the projection of images with a view to a 3D visual effect.

In order to provide a 3D visual effect, movie theater projection systems are typically configured to simultaneously project two images onto a screen, one intended for the right eye and the other for the left eye of an observer.

The screen is adapted to reflect the corresponding images from the projection system either towards the right eye or towards the left eye of the observer.

A first flaw of conventional screens is the decrease in stereo contrast with increasing viewing angle, due to screen-induced depolarization which increases with viewing angle. By "stereo contrast" is conventionally meant the ratio between the luminance of the image intended for one eye and the luminance of the image intended for the other eye through a polarizing filter. A second flaw of known screens is the rapid decrease in screen luminance with viewing angle. Thus, an observer looking at the screen with a viewing angle between 20 ° and 30 ° can receive up to 50% less luminance than an observer looking at the screen from the front, ie with a viewing angle of 0 °.

WO 2009/097371 A1 describes the general shape of a 3D pattern for structuring a coating of a screen, in order to distribute the light energy in a predetermined area while at the same time maintaining the incident polarization state as well as possible and preventing the light rays projected on the screen are not reflected more than once on the screen surface. The general shape described in WO 2009/097931 A1 further limits the formation of diffraction patterns and reduces the speckle effect of the reflected light.

The area covered on a motion picture screen by one pixel of the projected image is usually about several square millimeters. This implies that, on the one hand, many 3D patterns structuring the metallized coating each extend over a substantially identical surface area, and on the other hand, that they above all each have a height of at least 100 μm.

In order to manufacture such a structured coating, a conventionally implemented technique consists in embossing the flat surface of the coating by means of an imprint having negative shapes on the surface of the 3D patterns to be formed in the coating.

The negative shapes of the 3D patterns are generally engraved by means of photo-plotters, the maximum engraving depth of which is 15 μm at most.

The production of 3D patterns with a height greater than 100 μm on the surface of a screen therefore proves to be complex and expensive in practice.

There is therefore a need to overcome this drawback.

The invention aims to meet this need and it achieves it by means of a screen for displaying a projected image, the screen comprising a support and a reflective coating carried by the support, the coating having one face, on which the image is projected, structured by at least one 3D pattern comprising several concentric annular portions of axis X and of the same sign of radial slope, called "MSPR annular portions", the axis X being normal to the face of the support in look of the coating,
each annular portion MSPR of rank i extending around the axis X between radially inner ends r _i and outer r _{i + 1} and having a height h _i (r), measured along the X axis, which is expressed according to the equation

r being the radial distance to the X axis,
h _mb (r), called "height of the base pattern", being defined at least over all the intervals [r _i ; r _{i + 1} ] over which the MSPR annular portions extend,
the highest of the MSPR annular portions having a height less than or equal to 15 μm.

The screen according to the invention is simple to manufacture. The 3D pattern is low in height and can be easily fabricated, for example by embossing using an imprint engraved with a conventional photo-plotter. In addition, the MSPR annular portions ensure a suitable distribution of the light energy of the radiation reflected by the 3D pattern. As will appear in more detail later, from a mathematical point of view, the MSPR annular portions can appear to be obtained by successively folding the graph of the function h _mb (r) along different lines of height y _i = h _mb (r _i ) and y _{i + 1} = h _mb (r _{i + 1} ) which are spaced apart by no more than 15 µm. Thus, the 3D pattern of the screen according to the invention can provide substantially the same visual effect to an observer of the screen as the basic pattern defined over the set of intervals [r _i ; r _{i + 1} ] by the higher total height function h _mb (r).

The height h _i (r) of each MSPR annular portion is measured along the X axis, relative to the textured face of the coating. A negative height corresponds to a depth, that is to say that the annular portion MSPR is then a hollow relief formed in the coating. An MSPR annular portion of positive height is a relief projecting from the structured face.

A "radial" distance r is measured along a radial axis that is perpendicular to the X axis, starting from the intersection of the radial axis with the X axis.

Among all the annular portions, the "rank" of an annular portion increases away from the X axis.

The "height" of an annular portion is measured by reference to a portion of the structured face remote from the 3D pattern.

The term “sign of radial slope” of an annular portion is understood to mean the sign of the variation in the height h _i (r) of the annular portion with a variation in the radial distance r. In other words, mathematically, the sign of radial slope of an annular portion is the sign of the derivative of the height h _i (r) with respect to the radial distance r, i.e. the sign of the function dh _i / dr.

The sign of the radial slope of an annular portion is constant over the radial extent of the latter.

3D PATTERN

The 3D pattern preferably has axial X-axis symmetry. Thus, the light energy of the radiation reflected by the 3D pattern is spatially uniformly distributed.

Preferably, the 3D pattern has a shape invariant by rotation around the axis X. In other words, each radial portion MSPR is preferably such that h _i (r, θ ₁ ) = h _i (r, θ ₂ ), which let θ ₁ and θ ₂ each vary between 0 ° and 360 °, θ ₁ and θ ₂ being different from each other and being the angles around the X axis along which two respective radial axes extend .

As a variant, when observed along the X axis, the MSPR annular portions may have radially inner and radially outer contours each having the shape of an ellipse, the major axis of each ellipse being contained in the face of the coating opposite the support. . A 3D pattern having such MSPR annular portions is particularly suitable for reflecting incident radiation inclined relative to a normal to the face of the screen intended for the projection of the image.

Preferably, two successive MSPR annular portions are connected by an intermediate annular portion having a radial slope of sign opposite to the signs of slope of the two MSPR annular portions. The reversal of slope sign between the MSPR annular portions and the intermediate portion has the effect of locally reversing the angle of reflection of the incident radiation. The intermediate annular portion, ensuring continuity between the MSPR annular portions, helps maintain the state of polarization of the reflected light. In addition, it limits multiple reflections from the screen surface, without significantly altering the spatial distribution of the light energy of the reflected radiation.

Preferably, the intermediate annular portion of row j extends radially between the radially outer r _j and radially inner _{ends r j + 1} of the MSPR annular portions arranged radially inside and radially outside respectively of the intermediate annular portion .

Preferably, the MSPR annular portions can each have a face opposite the support which is concave and the annular portion which connects them can have a face opposite the support which is convex, and vice versa. In this way, strong variations in the height of the 3D pattern are reduced or even eliminated, which reduces or even prevents multiple reflections of the light incident on the screen support.

The height g _j (r) of the intermediate annular portion of rank j can be the equation g _j (r) = h _mb (r _j ) -h _mb (r). The intermediate portion is thus symmetrical with respect to the line y = h _mb (r _j ) of the portion of the base pattern of height h _mb (r) over the interval [r _j ; r _{j + 1} ].

The 3D pattern can include a plurality of intermediate portions. Preferably, each of the MSPR annular portions is connected to its single adjacent MSPR portion or to each of its adjacent MSPR annular portions by an intermediate annular portion having a radial slope of opposite sign. In particular, the intermediate annular portions and MSPR can be arranged radially in alternation with respect to one another.

The 3D pattern can consist of MSPR annular portions and intermediate annular portions.

The 3D pattern may include n MSPR annular portions, n being greater than or equal to 2, at least n-1 of the MSPR annular portions being of the same maximum height. Thus, the height of each of said n-1 annular portions MSPR is obtained by a division by congruence of the height h _mb of the base pattern, the reason for the congruence being the maximum height of each of said portions.

In one embodiment, all the MSPR annular portions are of the same height. Alternatively, n-1 of the MSPR annular portions are of the same height, the other MSPR annular portion having a lower maximum height than the n-1 annular portions.

The height h _mb of the basic pattern can grow monotonically over all the intervals [r _i ; r _{i + 1} ] over which the MSPR annular portions extend, or even over the interval [0; r _max ], r _max being the radius of the 3D pattern.

The height h _mb of the basic pattern is preferably continuous over each of the intervals [r _i ; r _{i + 1} ] over which the MSPR annular portions extend, or even over the interval [0; r _max ], r _max being the radius of the 3D pattern.

In particular, the height of the basic pattern is preferably governed by the following general equation

where r is the radial distance to the X axis, the 3D pattern extending over the interval [0; r _max ], r _max being the radius of the 3D pattern and being less than the constant a.

The radius of the pattern r _max can be equal to a.sin (Ω _max ). Ω _max is the maximum scattering half-angle of the radiation and can be between 10 ° and 80 °.

The radius r _max of a 3D pattern can be between 10 µm and 1 mm.

PLURALITY OF 3D PATTERNS

Preferably, the face of the coating is structured by a plurality of 3D patterns as described above.

Advantageously, when the screen is installed in a cinema projection room, the incident radiation can thus be reflected uniformly throughout the room.

The 3D patterns can be distributed randomly on the structured face, in order to limit or average the interference between the light rays that they reflect. Preferably, the centers and radii of the 3D patterns are preferably distributed randomly on the structured face of the coating.

The plurality of 3D patterns can be formed of 3D patterns whose radii r _max are between 10 μm and 1 mm.

A portion of the plurality of 3D patterns may be formed from 3D patterns having a radius r _max greater than 250 μm and may cover more than 30%, or even more than 40%, or even more than 50% of the area of the structured face. . Said portion may comprise patterns having a radius greater than 500 μm.

Another portion of the plurality of 3D patterns can be formed of patterns whose radii are less than 200 μm, or even less than 100 μm.

The plurality of 3D patterns can cover more than 95% the area of the structured face of the coating.

Furthermore, the 3D patterns can have the highest annular portions of different heights. For example, one of the 3D patterns whose radius is greater than 250 µm may have an uppermost annular portion with a height between 5 µm and 10 µm, and one of the 3D patterns whose radius is between 10 µm and 100 µm may have an uppermost annular portion with a height of between 1 µm and 5 µm.

As a variant, the 3D patterns can have an identical maximum height. In this case, a 3D pattern with a large radius may have a greater number of annular portions, in particular MSPR, than a 3D pattern with a smaller radius.

SCREEN

Furthermore, the invention also relates to an image projection system comprising a screen according to the invention and at least one projector for projecting an image onto the structured coating.

The projector can be configured to project two different polarized wave images onto the structured coating, to provide a visual impression of a 3D display of the projected image to an observer of the screen.

The invention finally relates to a method of manufacturing a screen according to the invention, the method comprising:
a) the definition of at least one 3D pattern from a base pattern of _{predetermined height h mb} , the 3D pattern comprising several concentric annular portions of axis X and of the same sign of radial slope, called "MSPR annular portions ", Each annular portion MSPR of rank i extending around the axis X between radially inner ends r _i and outer r _{i + 1} and having a height h _i (r), measured along the X axis, which is expressed according to the equation

r being the radial distance to the X axis, and
b) the formation of a structured reflective coating on a support, the structuring of the coating being carried out by means of the 3D pattern such that the X axis is normal to the face of the support facing the coating.

The structuring of the coating is for example carried out by embossing.

The invention may be better understood from reading the detailed description and by means of the accompanying drawing which accompanies it in which:

Figure 1 is a cross-sectional view of part of an example of a screen according to the invention,

Figure 2 is a front view of the screen shown in Figure 1,

FIG. 3 is a graph representing the evolution of the height of a basic pattern,

FIG. 4 is a graph showing the evolution of the height of the annular portions of the example of the screen illustrated in FIG. 1,

FIG. 5 is a sectional view illustrating the implementation of an example of manufacturing a screen according to the invention,

FIG. 6 is a front view of another example of a screen according to the invention,

FIG. 7 is a graph showing the evolution of the height of a basic pattern of another example according to the invention, and

FIG. 8 is a graph showing the evolution of the height of the annular portions defined from the basic pattern illustrated in FIG. 7.

In the drawing, the proportions of the various elements that compose it have not necessarily been shown to scale, for the sake of clarity.

Figures 1 and 2 schematically show part of a screen 5 according to the invention. The screen comprises a support 10 having a face 15 covered with a metallized coating 20, for example aluminum.

The face 25 of the coating opposite the support is partly structured by means of a 3D pattern 30. It has an unstructured portion 35 by the 3D pattern remote from the latter, which is preferably flat, and a structured portion 40 by the 3D pattern. which is complementary to it.

The 3D pattern has an invariant shape in rotation around an X axis perpendicular to the face 15 of the support. Thus, the height h (r) of the face opposite the support in the area of the coating structured by the 3D pattern, determined by reference to the unstructured portion 35, is dependent only on the radial distance to the r axis. It is independent of the angle θ between the radial axis and a Y reference axis.

The 3D pattern comprises a plurality of concentric annular portions P ₀ to P ₆ of axis X, arranged successively radially one after the other and contiguous with one another. The number of annular portions in the example is given by way of illustration, it may vary as a function of the radius of the pattern and as a function of the height of the annular portions, as will appear below, and be lower or higher than in the example shown.

Each annular portion of rank i extends radially between radially interior positions r _i and radially exterior positions r _{i + 1} , with i varying between 0 and 5 in the example illustrated. For example, the annular portion of rank 0 extends between the axis X (radial position r ₀ ) and the radial position r ₁ .

Each annular portion is characterized by a sign of the radial slope ∆ _i (r) which is constant between the radially interior positions r _i and exterior r _{i + 1} . In other words, the height of the annular portion h _i (r), which is the height h (r) of the face opposite the support in the part of the coating structured by the annular portion, varies continuously monotonously between the radially interior positions r _i and radially outer r _{i + 1} .

In the example illustrated, the annular portions P ₀ , P ₂ , P ₄ and P ₆ have the same positive sign of radial slope ∆ ₀ to ∆ ₆ , their height continuously increasing with an increase in the radial distance over the intervals over which they are respectively defined. They are called MSPR annular portions, acronym for “Same Radial Slope Sign”.

The MSPR annular portions are interconnected in pairs by intermediate annular portions P ₁ , P ₃ and P ₅ , which have a negative sign of the radial slope ∆ _1, ∆ ₃ and ∆ ₅ respectively opposite to the sign of the MSPR annular portions .

Thus, the MSPR annular portions P ₀ , P ₂ , P ₄ and P ₆ exhibit a monotonic increase in height as they move away radially from the X axis while the intermediate portions P ₁ , P ₃ and P ₅ exhibit a decrease. of height.

Furthermore, the height of the 3D pattern changes continuously as it moves away radially from the X axis. In particular, the height of an annular portion MSPR of rank i at its radially outer end r _{i + 1} is equal to the height of the intermediate annular portion of rank i + 1 which is contiguous to it at the same position r _{i + 1} . In other words, the height of the 3D pattern changes without discontinuity between two contiguous annular portions. Such a conformation of the 3D pattern is optional. It is preferred in order to limit the development of multiple reflections on the surface of the screen.

In addition, as illustrated, the faces of the MSPR annular portions opposite the support can all be convex or concave and the faces of the intermediate annular portions opposite the support can all be concave or convex respectively. The alternation of convex and concave portions helps to limit multiple reflections.

In the example illustrated, the faces of the MSPR annular portions are concave when the face 25 is viewed from the front while the faces of the intermediate annular portions are convex.

One of the essential aspects of the invention is that the height h _i of each of the MSPR portions is determined from the height h _mb of a basic pattern.

FIG. 3 is a graph illustrating the evolution of the height of the basic pattern h _mb as a function of the radial distance r from the X axis.

In the example illustrated, the height of the basic pattern h _mb is governed by the function governed by the following general form equation

where a is a positive number related to the radius of the screen pattern by the relation

Ω _max is the maximum half-angle of diffusion and is for example between 10 ° and 80 °.

However, other equations governing the height of the base pattern can be considered.

In order to form the MSPR annular portions and the intermediate annular portions, the basic pattern is "folded" along different lines of height y _i = h _mb (r _{i + 1} ). The distance between the consecutive lines y _i is preferably constant as illustrated in FIG. 2. It is less than or equal to 15 μm. In a variant, such a difference can vary, provided that it is less than or equal to 15 μm.

Thus, mathematically, the height h _i of an annular portion MSPR of rank i is defined as being the height of the base function between the radially inner ends r _i and radially outer r _{i + 1} of the portion of the annular portion MSPR , from which is subtracted the value of the height of the base function for the radially outer position r _{i + 1} , namely:

For example, the height h ₂ of the annular portion MSPR P ₂ is equal over the interval [r ₂ ; r ₃ ] to h ₂ (r) = h _mb (r) - h _mb (r ₃ ).

The difference between the _{consecutive lines of height y i} = h _mb (r _{i + 1} ) being constant, the different annular portions are obtained by a division by congruence of the height h _mb of the base pattern, modulating said difference.

In the example illustrated, the "folding" of the base function has the effect that the change in the height of each intermediate annular portion of rank j appears, over the definition interval [r _j ; r _{j + 1} ] of this portion, as being symmetrical of the height of the base pattern with respect to the line of equation y _j = h (r _j ).

Thus, mathematically, the height g _j of an intermediate annular portion of rank j is defined according to the equation

As illustrated in FIG. 4, the maximum height of the 3D pattern thus generated is the height of the largest annular portion MSPR, which is less than or equal to 15 μm. In the example illustrated, the distance between the annular portions y _{i + 1} -y _i being constant, all the annular portions have the same maximum height.

Alternatively, only the heights of the MSPR functions are defined as above from the base function as h _i (r) = h _mb (r) -h _mb (r _{i + 1} ). The heights of the intermediate annular portions can each be governed by an equation independent of the function of the base height.

From the evolution of the heights of the different annular portions, an imprint 50 can be made, for example by photoengraving the negative 55 of the 3D pattern. As illustrated in Figure 5, the imprint 50 can then be applied against the support 10 covered with the coating 20. The 3D pattern 30 is then formed in the coating by embossing.

One pixel of the projected image can cover a size of several mm ² on the screen. The diameter 2r _max of the 3D pattern can therefore be is approximately 1 mm.

A 3D pattern of the prior art whose height is defined by the function h _mb has a maximum depth | h _mb (0) | of about 120 µm for such a diameter. Such a 3D pattern is difficult to produce in practice.

On the contrary, the pattern according to the invention, having a height less than or equal to 15 μm, is easy to produce.

Preferably, as illustrated in FIG. 6, the face 25 of the coating is structured by a plurality of 3D patterns each being as defined above. The 3D patterns are especially different in that they can have different radii from each other.

In particular, the centers and radii of the 3D patterns can be distributed randomly on the face of the coating. In the example illustrated, the 3D patterns cover in total more than 95% of the area of the structured face of the coating. The 3D patterns with a diameter of 2r _max greater than 500 µm cover more than 30% of the surface area of the coating.

The radius of the smallest 3D patterns is equal to 5 µm. Furthermore, all the 3D patterns have the same maximum height which is for example around 5 μm. As can be observed in FIG. 6, the 3D patterns of large radius thus have a higher number of annular portions than the annular portions of smaller radius.

The shape of the 3D pattern can be adapted to take account of an inclination of the incident radiation at an angle α with respect to an axis normal to the face of the support covered by the coating, as illustrated by means of Figures 7 and 8 .

For example, the basic pattern of the example illustrated in FIG. 7, of height h ′ _mb , can be obtained by an angle rotation α of the basic pattern of height h _mb as already represented in FIG. 1 ( and recalled in FIG. 7 in long broken lines), around an axis contained in the face 25 of the coating.

The height of the 3D pattern can then be generated by forming the MSPR annular portions and the intermediate annular portions by folding back the base pattern of height h ' _mb along different lines of height y _i = h' _mb (r _{i + 1} ) as described above, and illustrated in Figure 8.

Thus, the coating can be structured by means of 3D patterns as illustrated in FIG. 1 and 3D patterns adapted to take into account the inclination of the incident radiation as illustrated in FIGS. 7 and 8. For example, the central portion of the coating, intended to reflect a substantially normal radiation can be structured mainly by 3D patterns such as according to Figure 1 and the peripheral portions of the coating which surround the central portion and which may be caused to reflect an inclined incident radiation, may in part be structured by means of 3D patterns having a height h '(r) as illustrated in figure 8.

The invention is of course not limited to the embodiments and examples presented in order to illustrate the invention.

Claims (14)

Screen (5) for displaying a projected image, the screen comprising a support (10) and a reflective coating (20) carried by the support,
the coating having a face (25), on which the image is projected, structured by at least one 3D pattern (30) comprising several _{concentric annular portions (P 0} , P ₂ , P ₄ , P ₆ ) of axis X and with the same sign of radial slope, called “MSPR annular portions”, the X axis being normal to the face of the support facing the coating,
each annular portion MSPR of rank i extending around the axis X between radially inner ends r _i and outer r _{i + 1} and having a height h _i (r), measured along the X axis, which is expressed according to the equation

r being the radial distance to the X axis,
h _mb (r), called "height of the base pattern", being defined at least over all the intervals [r _i ; r _{i + 1} ] over which the MSPR annular portions extend,
the highest of the MSPR annular portions having a height less than or equal to 15 μm. Screen according to Claim 1, two successive MSPR annular portions being connected by an intermediate annular portion (P ₁ , P ₃ , P ₅ ) having a radial slope of opposite sign. Screen according to claim 2, the intermediate annular portion of row j extending radially between the radially outer r _j and radially inner r _{j + 1} ends of the MSPR annular portions disposed radially inside and radially outside respectively of the intermediate annular portion. Screen according to Claim 3, the height g _j (r) of the intermediate annular portion of row j being the equation g _j (r) = h _mb (r _j ) -h _mb (r). Screen according to any one of claims 2 to 4, each MSPR annular portion being connected to its single adjacent MSPR portion or to each of its adjacent MSPR annular portions by an intermediate annular portion having a radial slope of opposite sign. Screen according to any one of the preceding claims, the 3D pattern comprising n MSPR annular portions, n being greater than or equal to 2, at least n-1 of the MSPR annular portions being of the same maximum height. Screen according to any one of the preceding claims, the face (25) of the coating being structured by a plurality of 3D patterns, the 3D patterns being distributed randomly on the structured face. Screen according to the preceding claim, the plurality of 3D patterns being formed of 3D patterns whose radii r _max are between 5 µm and 1 mm. Screen according to any one of Claims 7 and 8, a fraction of the plurality of 3D patterns being formed of 3D patterns having a radius r _max greater than 250 µm, and covering more than 30%, or even more than 40%, or even more 50% of the area of the structured face. Screen according to any one of claims 7 to 9, the centers and radii of the 3D patterns being distributed randomly on the structured face (25) of the coating. Screen according to any one of the preceding claims, the height of the basic pattern h _mb being governed by the following equation of general shape

where r is the radial distance to the X axis, the pattern extending over the interval [0; r _max ], r _max being the radius of the 3D pattern and being less than the constant a. Screen according to any one of the preceding claims, 3D pattern having a shape invariant by rotation around the X axis Screen according to any one of claims 1 to 11, wherein when observed along the X axis, the MSPR annular portions have radially inner and radially outer contours each having the shape of an ellipse, the axis of each ellipse being contained in the face (25) of the coating opposite the support. A method of manufacturing a screen according to any one of the preceding claims, the method comprising:
a) the definition of at least one 3D pattern from a base pattern of _{predetermined height h mb} , the 3D pattern comprising several concentric annular portions of axis X and of the same sign of radial slope, called "MSPR annular portions ", Each annular portion MSPR of rank i extending around the axis X between radially inner ends r _i and outer r _{i + 1} and having a height h _i (r), measured along the X axis, which is expressed according to the equation

r being the radial distance to the X axis, and
b) the formation of a structured reflective coating on a support, the structuring of the coating being carried out by means of the 3D pattern such that the X axis is normal to the face of the support facing the coating.