EP1417531A1 - Method for 3d adaptation - Google Patents

Abstract

The invention concerns a device for forming mutually interactive video images which appear to be in non-material levitation, occupying a spatial portion distinctly offset from their original source. Said device represented in the drawing accompanying the abstract comprises two zoned lenses (2) whereof the concentric turns are alternately substituted once every two times with a flat surface. One lens (4) is used to magnify the source images in (10), antiglare and anti-radiation coatings follow the contours of the turns of one of the two lenses (3), and the flat surface the other (3). Two liquid crystal cyclic modulators with alternate frequency of 25 times per second in the form of liquid crystal lines, and/or concentric circles top the lenses (3). The inventive device is designed for integrating three-dimensional effects, not exclusively, in video games, for air control, in ophthalmology, electronic household appliances, advertisement, as well as computer-assisted design systems.

Description

 MONOLITHIC RELIEF ADAPTATION PROCESS

The present invention relates to a device for the formation of immaterial images in levitation, visually spatially very clearly offset from original source sources, but also fully interactive with another normal or immaterial video image from the "same source.

The device presented here is of the type comprising two stepped fresnel lenses, the turns of which are replaced alternately every second time by a flat surface. A third incremental fresnel lens, the full concentric coils of which are installed at a variable distance from the first two. Anti-reflection and anti-radiation coatings suitable for the present invention conform to the turns of one of the two lenses with fresnel steps having only one turn out of two, and the flat surface of the other.

Two elements in the form of plates of the type comprising a cyclic modulator by alternating frequency mode with liquid crystal with lines becoming opaque or translucent according to a speed which is more or less than 25 times per second determined by an electronic clock quartz itself synchronized with the images of the video source for example. The device presented here, in accordance with the present invention is held by supports or flanges; all constituting a compact, light, thin and multi-adaptable adapter monolyte. This adapter monolyte making it possible to form at least two separate images, independent of each other, but fully interactive with one another according preferably to identical software for controlling the two source images. • ^• -one of these two images, from the same video source is visible to an observer according to a perfectly stabilized wavefront, and identifiable within a spatial territory clearly offset from the material structure of the adapter monolyte.

The present invention may be presented according to the embodiments set out below. This list is not exhaustive.

A device for the training of doctors possibly oriented towards surgery, an air control unit to validate various and multiple altitudes in order to prevent collisions between planes, a device for video games, a system for CAD, CAD. state of the prior art bringing out all the problems posed:

Nowadays, technologies which allow to generate relief effects without the need to wear special glasses, mainly use common fresnel lenses. also called ladders already existing and widely introduced in various industry sectors. Existing relief machines include one or more of these lenses; either combined with each other to form objectives, or also recombined with parabolic type mirrors this, in multiple ways depending on the concept encountered.

Some of these machines also sometimes use liquid crystal concepts so as to cyclically obstruct once in two video images corresponding to different points of view for observers. This of course requires a certain computing power for an image processor due to the large number of images to be displayed at each cycle. These are called stereoscopic effect machines.

These display devices are used in particular in simulators, for events. Other devices consist in providing users with special glasses to the glasses of which thin layers of liquid crystals are attached which become alternately transparent at high speed, and opaque for each eye, the left and the right, of course synchronism with the image projections; glasses are always a nuisance for users.

These machines, some of which are very efficient, traditionally occupy far too much space to be easily integrated into the many sectors of the industry.

Heavy and bulky, their technical principles require complex montages to generate one or more relief images from one or more sources. These so-called machines are even more important if there are several sources.

In addition, these relief images seem to belong to bright halos surrounding the generator screens with little lag. Integration into many existing products manufactured by our consumer company often seems difficult, the size of these machines being too large.

But, despite this description which has just been given briefly, we know in this context many other achievements of which here is a list ...

US Patent 132,839 uses a spatial modulator disposed between an image forming system and the user. It includes a very very expensive refractive optics device for obtain a wide field of vision image with a cathode ray tube or similar. Finally, this principle takes up a lot of space. And its implementation is very complex.

The French patent N ° 2776 882 (publication number) generally uses the same principles as the American patent US132839 which has just been quoted above: That is to say that this French patent includes an image source, a spherical mirror, a fully semi-reflective blade, a liquid crystal shutter placed at the focal point of the mirror, and a single normal fresnel lens. The shutter is controlled in synchronism with the formation of right eye images, and also left eye. A camera covers all of this technology to detect the head movements of the observer (s). This beautiful achievement takes up space, is expensive and quite complex to implement. French patent N ^° 2768 822 (publication number), uses the classic principles for the projection of 2 relief images in two or three dimensions: Either: A screen made up of a fresnel lens, a mixer in the form of 'a one-way mirror, several sources of images, of objectives constituted by fresnel lenses, And, by varying the position of all these elements, one acts on the magnification of the images. Another good achievement that still takes too much volume, and therefore, too heavy and bulky.

The US patent N ^° 4671 625 is very simple in its design, since it uses only two fresnel lenses, and a source of images. But the depth of the device is still very important. Within this same patent, Figures 3,, and 5 _> explains a system whose volume appears even greater. The fresnel lenses used are common since they do not give any explanation about them, concerning their own structures with maximum precision.

American patent US Pat. ^No. 4,261,657 is very simple since it uses only a single fresnel lens, an object, and a single lighting means. The fresnel lens is classic.

The US patent US Pat. ^No. 5,790,322 demonstrates an excellent device for car meters by sometimes using single, attached fresnel lenses forming what are called double condensers. This patent mainly plays the role of enlarger.

American patent US 5782 ^ 7, is largely part of the category of machines with imposing relief, heavy and complex to implement. FIG. 1 highlights the use of two parabolic mirrors 8 and 10, 'of a projector at 12, of a video monitor at 2, The projector 12 outside the machine forms an image on the screen 14, l 'relief image being generated by the monitor 2 screen, because this relief image first bounces on the two mirrors which are parabolic: 8; and 10. Figure 2 concerns a slightly different assembly. All the other figures using fairly large devices comprising in a large majority of combinations with conventional fresnel lenses, one-way windows, mirrors, and monitors allowing multiple video sources to obtain relief images on one or more plans.

US Patent ^No. 4,391,495 is primarily constructed to serve as an enlarger of video images. It includes two pairs of fresnel lenses forming a double condenser, (classic lenses). Figures 1 and 2 highlight combinations with parabolic mirrors and semiconductor glass, to generate relief images. The solutions are very good but still take up too much space. The American PCT patent N ° W089 / 09423 transformed into a patent

European, is a great classic of the relief image using under a certain volume of the classic fresnel lenses, panes which are semi reflective, and parabolic mirrors.

The Japanese patent in the name of SONY filed in the United States US ^No. 438 316 confirms according to all of the figures: 1, 2, 3, 4,5,6,7, once again large dimensions, and quite difficult integrations within consumer products.

The French Patent Publication ^No.: 2741 961 allows the formation and projection of images by reducing and reproducing images in full relief. The image obtained can be photographed, recorded in the form of slides or cinematographic film. or be trained on a photosensitive plate of a video camera.

It can also be recorded on magnetic tape or transmitted by a television network. This excellent and very complex system unfortunately still takes too much volume to be fairly easily introduced into the products of the Consumer Company. The following set of patents is a global continuity of all the patents already explained above. Since none offers solutions truly capable of significantly reducing their achievements _{* in} order to integrate them into as many products as possible from our consumer society; what the present invention proposes to achieve, however. On the other hand, it is very easy to observe that: Since the advent of the first invention patents Or: for the oldest: 1963, others, little known, are still much earlier, therefore, no really serious integration and therefore large scale has come to take some market share in known configurations such as for example: relief television, or simple machines to advertise. There are indeed a few relief units that are exhibited during an exhibition, or even an exhibition, but no case is rescenced today confirming large-scale integrations of machines to generate relief effects. List of other patents for inventions known to generate relief effects in various ways, often effective, but too complex and bulky.

EITHER: US N ^° 5257 130, US N ^° 4571 041, FR N ^° 2472 197, FR N ^° 2582 494, Japan filed US N ° 160790, FR N ^° 2657 969, FR N ^° 2702 871, US N ^° 5438 357 , Angland N ^° 1076 466, FR N ^° 2065 533, US W098.10584, FR N ^° 2522 832 FR N ^° 2542 103, FR N ° 2557 983, US N ^° 3261 977, GB / N ^° 675 549, DE N ^° A 261 2566, DE N ^* A 301 3959, US N ^° A 4120563, US N ^° 462 3223, GB N ^° A 215 5651, US N ° 3418 426, FR N ^° 1346 696, FR N "1379018, FR N ^° 2737 581 .. A person skilled in the art will easily understand that the list of patents previously explained confirms a very general tendency to emphasize the essential points of the ideas which all converge in an identical direction. EITHER: The bulk, the weight, the complexity , prices, difficult integrations in general in the products of our consumer society.

Therefore, one of the very first objectives of the present invention is to simplify the basic structures of the systems for forming relief images by making the latter totally floating and spatially, and immaterially very clearly offset from their original sources. The second objective of the present invention therefore its strong point par excellence is the ease of integration according to many potential embodiments already set out on page (l) of this description. Another objective of the present invention will be αe r_nur- interactive at least two images completely independent of each other, managed by a common software, one of the two images being spatially offset from its original source, the other image completely normal on his video screen.

Furthermore, the spatial shift of the floating images is very easily observable for an observer who will look closely at the portion of the space occupied.

Consequently, the present invention overcomes a constant prejudice according to the state of the current art in that it combines according to a first embodiment:

References: Drawing N ° l, drawing for the abstract drawing N ^° 2, two fresnel lenses with steps, (3). Specially built for the needs of the present invention, and whose concentric turns are alternately replaced every second by a flat surface (14) the turns (15) of the two stepped lenses (3) 'face each other, the flat parts also facing each other. These two so-called stepped lenses (3) therefore being symmetrically opposite.

A third step lens (4), the complete concentric turns of which are positioned on the source side (10), at a distance which can be variable with respect to the lenses (3) opposite on a symmetrical plane. The serration, or turns very visible on, the drawing for the abstract is oriented towards the side of the two stepped lenses mounted in opposition (3). the positioning of this lens (4) has the essential function of enlarging the primary source images into (10) preferably originating from a video monitor; before said images are, by the optical path of light rays, received by the mounting in opposition of the two lenses (3). Advantageously, the present invention includes anti-reflection and anti-radiation coatings whose advantages and precise description will be explained a little further within this description.

These coatings in (5) and (6), suitable for the present invention have the essential functions of 'attenuating in very high proportions the undesirable parasitic radiations and reflections.

In (6) this special coating, adapted for the present invention, follows the shapes of the serration turns ((15), and the flat parts (14) of the lenses (3) located on the lens side (4). 5), the special coating covers the flat part on the observer side at (9) of the cyclic modulator assembly with liquid crystal zones in 2).

Advantageously, this anti-radiation and anti-reflection coating in (5) and (6) is preferably installed according to the locations already explained for physical reasons related to the optical path of the light rays coming from the source side of images in (10).

In the context of the present invention, this anti-radiation and anti-reflection coating will relate to all of all of the embodiments explained in the present description.

This coating could just as easily be installed in a different way, and could just as well cover only one or more of the flat parts or having striations of the lenses (3) (4) or other types of lenses relating to all embodiments of this description.

Just as this anti-radiation and anti-reflection coating could just as well be partially or completely integrated within the same material constituting the lenses with steps (3-) (O, or all other types of lenses according to all modes of realization of this description.

As well, this anti-radiation and anti-reflection coating could just as easily be partially or totally integrated in multiple ways according to the different embodiments included in the present description concerning the present invention.

That said, still concerning the first embodiment, and also concerning the other embodiments included within the present description in the context of the present invention, two plates of the type comprising a cyclic modulator by alternating frequency mode, and liquid crystal lines changing state; thus going from opaque to translucent, or vice versa depending on the programming speed of an electronic quartz clock, cover the two lenses (3). The precise operation of this cyclic liquid crystal modulator will be explained a little later in this description.

However, the essential function of these cyclic liquid crystal modulators is to obstruct or make opaque the parts (14) and (15) of the stepped lenses (3). These cyclic liquid crystal modulators (in (2) include, as can be clearly seen in, for example, drawing (1), alternately dark and light translucent zones. As we can quite easily see, the division of clear translucent areas and dark opaque in (7) and (8) alternately corresponds to the width of the turns (15) and the flat parts (14).

Of course, if the programming of the two cyclic liquid crystal modulators commands the opaque zones 0 ^{p to} change state to become translucent, on the one hand, and that at the same time, this same programming commands the translucent zones to change state to become opaque on the other hand; It will always be alternating; That is to say that these zones (7) and (8) must never all be at the same time opaque or translucent; and even whatever all kinds of proportions or organizations that could be any and, or organized in multiple ways other than alternately in accordance with the present invention.

However, and for reasons related to future developments concerning the present description of the present invention, it could be advantageous to organize the synchronization of these cyclic liquid crystal modulators in other ways.

__ The main purpose of these two modulators () being to let the light pass or not. The shutter frequency of the two modulators (2) is

25 (twenty five) times per second. This frequency could be either lower or higher.

That is to say that 25 times per second, the zones (7) and (8) will change state, they will either be opaque so that the light does not pass, or else translucent so that the light passes ...

And alternated linearly as follows; .. Opaque, translucent, opaque, translucent Or: Translucent, opaque, translucent, opaque.

The electronic control of these zones (7) and (8) is ensured by a common device which is very easily found on the market. If only a single transparent carrier clock and liquid crystal display is controlled by a similar _system.

The present shutter device (2) spτ> has understood better on reading the detailed below.

The drawing (1), and the drawing for the abstract represent cyclic modulators with liquid crystals (in 2) seen in section.

The drawings (36) and (3) show an enlarged view of the same cyclic modulators (2) in a schematic aerial view.

We immediately see the significant correspondence between the sectional views and the aerial views. 1>'Except that the aerial view of the drawing (3) shows the organization of the cyclic modulator (2) according to lines or bands alternately in a parallel manner;

While the drawing (36) shows the organization of the cyclic modulator (2) according to lines or bands alternately in a concentric manner.

The drawing (36) illustrates liquid crystal lines or bands which actually correspond to the zones (7) and (8) of the stepped lenses (3). The opaque parts of the drawing (36) cover in this specific case as an example of operation the flat parts (14) of the stepped lenses (3). While the grooved and concentric white parts of the drawing (36) cover the turns of the stepped lenses (3).

The schematic representation of the drawing (36) could have been reversed: The opaque parts or zones would be white translucent, and the white translucent parts would be opaque.

That said, during a synchronization sequence at a frequency of 25 times per second, alternatively, 25 times per second, the opaque concentric circles will become translucent, and the translucent circles will become opaque.

This same drawing (36) shows the organization of the modulators (2) and (FIG. 31) alternately styling the opaque and (8) translucent zones in an electronic state which could be the reverse as previously already explained within the present description. As it is easy to see, Figure (32) is the aerial view of the section (31). The drawing (36) explains, according to the figure (31), an example of obstruction with only one stepped lens (3); while the drawing (3) explains an example of obstruction with the two stepped lenses (3) which we can clearly see, their turns being symmetrically opposite; figure (5). Figure (6) being the aerial view of the section (5).

Drawings (3) and (36) demonstrate two different possibilities for organizing the. zones (7) and (8): be parallel, or also be concentric. For reasons of convenience specific to the ^" present invention, the cyclic stopping device (s) (2) is physically produced according to a substantially flat plate as far as possible. This plate containing the liquid crystals could be of identical or neighboring technology. transparent pendulum technologies or alarm clock already on the market.

The cyclic liquid crystal stoppers falling within the scope of the present invention (2), alternate 25 times per second in more or less areas (7) and (8). This can be more than 25 times per second, or less than 25 times per second. In such a way that the human eye cannot be aware of the changes of states. This frequency is also often used by screen display technologies in communication. The drawing (9) therefore falls within the framework for the conformity of the invention, since it presents in the form of a monitor (17) two superimposed images: Either: a video tree (19) and a video apple (20 )

These two video images (19) and (20) are alternated in (49) 25 times per second. For an observer (23), placed in front of the monitor (17) alone,

This said observer, given the alternating speed of 25 times per second will see two images at a time and nothing else. Now, and still according to the drawing (9), the monolytic adapter (11) comprising according to the drawing for the abstract: (Two stepped lenses (3), one lens (4), two modulators (2) and the filtration device

(5), and (6); Therefore, this monolytic adapter (11) is placed in front of the monitor (17). The adapter (18) being only the practical support for suitably supporting the monolytic adapter (11).

As noted in the drawing (9), the assembly (11) and (18) therefore constitutes a monolytic adapter, light, compact, thin, and multi-adaptable. The size of this set (11), (18) will vary according to multiple potential adaptations already existing on the world consumer market, some examples of which are already cited on the first page of this description. Now, and concerning the formation of two separate images, and shifted in the eyes of the observer (23), the present device will be better understood on reading the detailed description of this operating mode. .

Here is therefore a step-by-step explanation of the device: First, the alternating electronic control of the two cyclic modulators (2) is linked and therefore synchronized with the alternating appearance of the two images (20), the apple and (19), the tree.

When all the zones (7) are opaque, according to the drawing for the abstract and the drawing (1) for the example, the trajectory of the light rays (50) pass through two stepped lenses (3), and flat parts of the two cyclic modulators (2) as well as through anti-reflection coatings (5) and (6).

By deciding for example convention that the tree (19) is the source video image which corresponds to this programming instant, only the trajectory of the light rays constituting the tree will pass through the elements (5) , (6), (14), (8). The observer (23) will see the video image of the tree (19) reconstructed on the surface of the screen of the adapter monolyte (II, 18). The next instant, the programming establishes a reverse state: the zones (7) which were opaque become translucent, and the zones (8) which were translucent become opaque.

By always deciding by example convention that the apple (20) is the video image which corresponds to this instant; programming, the path of the light rays constituting the apple (20) will pass through elements (15), (5), (6), and (7) which is now translucent; since at this time, the zones (8) are opaque.

The observer (23) will thus see the image of the apple (20) but at the front of the screen of the monolyte adapter (11, 18) according to a state which is now immaterial for the following reasons:

The trajectory of the light rays which according to always by convention of example correspond to the video source apple (20). These light rays pass mainly through the turns (15) of the stepped lenses (3). These so-called turns having the particularity of having a focal length adapted as a consequence of the desired visual effects, since the focusing of the trajectory of the light rays will be concentrated in front of the adapter monolyte (11, 18), thus reconstituting the immaterial image of the apple in (16) in front of the observer (23).

As a consequence, the synchronization ies two video source images: apple (20) and tree (19) being as previously explained - 25 times per second, that is to say: Once the apple (20) then a once the tree (19), then once the apple (20), then once the tree (19), The observer will see the two images simultaneously at the same time: The tree (19) on the screen of the adapter monolyte (11, 18) and the apple (20) transformed into (16) according to the focusing of the path of the light rays at a point of convergence located at the front of the screen of the adapter monolyte (11, 18) this distance separating the screen from the adapter monolyte (11,18) from the immaterial apple (16) can vary because of the focal length of the lenses (3) This choice of focal length will be determined according to the various types of destinations, adaptations, integrations of the adapter monolytes. *

Given that the present invention is constituted by a whole set of components whose logic of their presence comes within the framework of the said invention, and that on the other hand, the said present invention is declined in several embodiments , it is now necessary in the context of this description to explain the particularities of certain components, and of certain effects caused by the various embodiments of the present invention.

Advantageously, the construction of the present invention as well as its various embodiments include an anti-radiation and anti-reflection filtration device whose presence is explained by the fact that a very strong attenuation of parasitic reflections and unwanted radiation will be observed. .

This present anti-reflection and anti-radiation device has above all a function of separation of the images with respect to the various trajectories of the light rays which would interfere in supper- -position or behind the images generated by the video source.

According to the drawings (N ^° 7) and (N ^° 8), the graphs figures (7) and (8) highlight two essential parameters of filtration.

FIG ^(# 7) gives a length ^r waves in millimeters of the antiglare layer. In (21), there is a packed curve of the said anti-reflection layer. In (22), the conductive layer which is ^' transparent is calculated to conduct a maximum of light without the reflections in (21) figure (7) coming to interfere with the conductive layer and the desired passage of light.

The drawing (7) gives a precise image of the behavior of light in the context of this anti-reflection and anti-radiation device, since the monolytic adapter is found in (11) (18) which will be declined within this description in other embodiments .; Or: the monolytic adapters (108, 129, 130, 131).

The drawing ( ^No. 7) shows the behavior at (25) of the radiations contained by the filtration part included 'within the adapter (11). In (24), The blocking of the filtering light waves which are not desirable: Either: The reflection waves. The observer (23) sees an immaterial image (16) absolutely clear. Taking as reference: The drawing for the abstract, also drawing N ^° l, for the correct understanding of this coating, (5) and (6) The layer (6) consists of anti-radiation particles provided against the electrostaticity, as well as against electromagnetic-radiation by eliminating: 99% of reflections, this layer blocks just as well: up to 99-99% electrical emissions ELV, and VLF, This protective layer always marries in (6 ), the tooth-teeth of the stepped lens in (3), of which one tooth (streak) in two opposes the serration of the other lens placed in front of it. In (5), the filtration layer covering the flat part of the stepped lens in (3) on the observer side in (9); this so-called filtration neck is an optical coating reducing up to 99-99%> the re-reflection and glare.

The improvement of the resolution of the image is located in very important proportions; contributing for an observer (23) to observe a frank and clear detachment of the immaterial images which are focused in front of the adapter monolyte (11), or (108), or, (129), or (130), σu, (131) .

In addition, the ocular constraints are surprisingly attenuated. This filtration layer in (5) comprises a layer of metal, and also highly conductive metal oxide for the transmission of high and low light.

Preferably, a conductive coating with grounding cord will be integrated into the filtration layer (5) to block up to 99-99% of the electromagnetic radiation.

Advantageously, a thin anti-reflective film but also at the same time electrically conductive will block up to 99-99% the radiation of the electric field at extra low frequency., Very low frequency; while eliminating the .static field; the index difference being: 1.46 to 1.56.

The qualities of photocopy reflections being at most: 0.25%, per side; that is to say on each side of the filtration assembly in (5).

The resistivity of the surfaces is: 350 ohms per m2. Protection at UV level (rays) is 95% •

The protection at the level of the rays: U.V. A. is 77% • The protection at the level of the rays: U.V.B. is 100%.

In the context of the present invention, this device filtration in (5), and (6), constitutes an essential element of integration to ensure the technical sharing of light fluxes, according to their trajectories so that as already partially explained in this description, the observer (23) cannot visually confuse and therefore mix, the images and the different forms of undesirable light parasites.

It goes without saying that the present invention; as well as all its different embodiments explained in the present description could function very well without the installation, and therefore the integration of this filtration device in (5) and (6).

But this would be to deprive the present invention of an element integral with it.

This filtration device acting and working in finality as a separator of good and bad trajectories of light rays from a video source on a preferential basis.

Advantageously, the present invention as well as its various embodiments can be easily provided preferably over the filtration layer in (5) with a one-way mirror, with a mesh fabric allowing sufficient light to pass through, or still paper, or other transparent material, these examples being given in a nonlimiting manner.

The one-way mirror will have a magic function, since an observer for example (23) will see himself in a mirror while noting the appearance for example: of apple (lo) drawing N ^° 9.. A mesh fabric with sufficient light to pass through will create a surprising surprise; Since the observer (23) will see in a totally detached manner a floating image of the apple (16); but, because of the fabric, the observer (23) will distinguish the image of the tree (19) without the latter being clear. - A transparent paper, for example, will have the effect of creating a high incidence of eye reference for an observer (23) Since a cleverly pleated transparent paper will cause a background slightly charged with reflections whose source is external to the monoly- - the adapter; this skillfully pleated paper will be: for the observer (23) visually clearly behind the immaterial apple (16).

In the context of the present invention, apart from the description, these three examples given without implied limitation do not appear on any of the drawings accompanying this description. By the mere presence of the filtration device (5) and (6), The immaterial images and support: for example: the apple (16) drawing (9); very clearly shift from their original source (11) for an observer (23). Therefore: for one or more observers (23), the ima-

-gees in lift such as for example: the apple (16) ^' become an immaterial reality.

Thanks to this filtration device in (5) and (6), the defects of parralaxes, the abbrations, and other undesired parasites are attenuated in very high proportions.

By observing for convenience, the drawing for the abstract we can easily see the path traveled by the light rays in (50), and the filtration layer in (6) covering the turns (15) and the flat parts ( 14) of the step lens (3) installed closest to the lens (4)

This filtration layer (6) constitutes in a certain way the first filtration element which will prepare the source image by attenuating the reflections and the radiations of said source image.

The image will therefore be cleaned of its primary parasites. In (5), the filter layer covering the ^~ flat part of the lens (3) on the observer side (9) has the function as previously explained of reducing glare and reflection by up to 99-99% •

It is therefore preferably the two combined layers (5) and (6) which allow the quality of vision sought in the context of the present invention. Of course, these two filtration layers could be combined in multiple ways other than previously explained; Similarly, a single filtration layer or (5) or (6) could be installed in multiple ways. Just as more than two layers of filtration (5) or (6), or differently could be installed in multiple ways; everything is possible.

However, and for logical reasons corresponding to the proper functioning of the present invention, the locations of the two filtration devices will be installed according to all of the precisions given in this description. In the context of the present invention and its various embodiments which will be explained a little further within this description, the stepped lens (N ^° 4) visible on the drawings accompanying this description: Drawings: (for the abstract), drawing (2), then drawing (4), and (5), then, (12), and (17) and (18) is installed in the monolytic adapters: (11), (108), (129); •

'Concerning the stepped lens (No. 4), the functions of this so-called lens, its logical presence in the context of the present invention, will be better understood on reading the detailed description below.

This stepped lens No. (4) has all its turns as can be seen in the drawings: (for the abstract), (12), (4), (5), (17), and (18 ). Its main function is only to enlarge the video images for example before the trajectory of the light rays of these said video images reach the assembly constituting the two stepped lenses (3).

This quality of enlargement of lens N ^° (4) is mainly due to its particular focal length which is the subject of optical details within a table forming part of the present description.

This step lens (4) is preferably installed at a distance which can be variable with respect to the groups constituting the other two step lenses (3) -

The distance which can be variable between the lens (4) and the group of two lenses (3) in opposition is variable according to the magnification of the source images which it is desired to obtain.

However, it is the incidence of the focal length of the lens (4), and of its other optical characteristics; which, combined with the lenses (3) mounted in opposition which will cause for an observer (23) a wide angle vision of a video image, for example, the apple (16), of the drawing (9). For an observer (23) looking for example at the screen of the adapter (11) of the drawing (9) on the side, the latter will see the apple (16) flattened on the screen (11) of the adapter (11 ) It is only by advancing step by step to position itself in front of the screen of the adapter (11) that the observer (23) will gradually see the image of the apple (16) literally take off from the screen of the adapter (11) and then stabilize at a certain distance from the screen of the adapter (11) according to the chosen optical characteristics of the step lenses (3) and (4).

The presence of the lens (4) within the adapters (11), (108) and (129) constitutes for the present invention a very important element. since it authorizes for an observer (23) an angle of view of the immaterial imaged images; for example the apple (16), therefore, an angle of view greatly exceeding 100 degrees.

Given an angle of vision exceeding 100 degrees, there can naturally be more than one observer; This is the purpose of the presence of this lens (4) within the monolytic adapters (11), (108), and (129).

There is shown in the drawing ( ^No. 2) a sectional view of the adapter (11). for convenience. All the other adapters: (108), (129), (130), and (131) are constructed according to the same idea in order to preserve the essential qualities of the various embodiments of these adapters forming an integral part of the present invention: : thinness, compactness, adaptability, weight This sectional drawing of the monolytic adapter (11) is characterized by the fact that it comprises two opposing lenses (3), a recessed lens (4) whose position may vary from the group of two lenses (3), this device also comprising two cyclic liquid crystal modulators with alternating zones at (2); .. this modulator (11) comprising, also at (5) a device for filtering anti-parasite and anti-reflection light. The filtration part (6) not shown in this drawing. Figure (3) of this drawing (2) shows the sandwich assembly of the monolytic adapter (11). Figure (4) of this drawing (11) shows the sandwich section of the adapter (11). “According to the drawing ( ^No. 6), a cava- -lière perspective has been represented as a floating of immaterial information according to a stabilized wave front. This overview of the drawing (6) is intended to demonstrate the effectiveness of the various embodiments of the present invention This overview, according to the invention comprises in (11) the monolytic adapter for the example; in (18), the adapter support (11), in (5M, an electronic digit reproducing by light-emitting diode mode the number (8) (EIGHT), in (55), and this assembly therefore constituting the material source of the image of (8) .When positioning a frosted glass at (56) as close as possible to the screen of the adapter (11), this position can nevertheless vary, an observer (23) will see a blurred image of the number (8) in (53) according to the frosted glass (56) .When positioning this same frosted glass in <58), the observer (23) will see the image of (8) in (53) may be even more blurred. While when you position the frosted glass at (57) at a variable distance that must be adjusted if possible and preferably manually, by very slightly searching for the image of (8), you will easily obtain an image net of what (8) that the observer (23) can observe.

While it will be impossible to perform this sharpness control operation by positioning the frosted glass at (56) and (58). The frosted glass (at 56) being too close, and the frosted glass at (58) being too far.

It is only by slightly seeking the (8) in a clear way with the frosted glass (57) that one will obtain a satisfactory result for the observer (23).

This drawing (6) is given only by way of nonlimiting example. The position for the example of the frosted glass (57) collects the sharp image of (8) (53) at a distance from the screen of the adapter (11) which can vary according to the different focal lengths chosen for the mounting of the adapter (11), that goes without saying.

According to this example, the observer (23) will have at least proof of the exact spatial position occupied by the stabilized wave front constituting (8).

The observer (23) could just as easily repeat the operation in relation to the drawing (6) but with, for example, the apple (16) of the drawing (9). The observer (23) will see in the absolute the image of this figure

(8) very clearly offset from the screen of the monolyte (11); This image of (8), or for example the apple (16) of drawing (9) could easily be interactive with another image backwards or forwards according to the design of the present invention. One of the optical impressions of the observer (23) will be that he will see floating images as coming from nowhere; This is also largely due to the presence of the two optical filtration devices in (5) and (6) integrated within the monolytic adapter (11). For information, this image of (8) in (53) pasted on the frosted glass in (57) according to a stabilized wave front; this said image floating in space and thereby occupying a spatial portion which can be easily determined as the drawing (6) the demonstrates, if now we remove the frosted glass in (57), the observer (23) will see the same image of (8) but all alone without any material support. The distance between this sharp image and (8) pa. ¹ report to the screen of the adapter monolyte (11) is also time consuming. As short as it is. So there is space and time ..

Up to now, within the present description, the present invention has been explained according to its base constituted by the adapter monolyte, or monolytic adapter (which is the same thing) (11). However, and according to a different embodiment, the monolytic adapter (11) can easily be declined into a different assembly that can be seen in the drawings (4) and (5). These drawings (4) and (5) highlight the cyclic liquid crystal modulator (2), precisely specifying two shutter states as previously explained in the present description. The drawing (4) shows the following shutter state from the left as for the direction of reading: Either: Opaque translu-

-cide, opaque, translucent The drawing (5) always according to the same direction of reading, ie: left to go to the right: Either: Translucent, then opaque, then, translucent From the outset, we note an analogous arrangement with respect to the monolytych adapter (11) corresponding to the drawings: (for the abstract), then the drawing (1), (2), (3) i Except that a single cyclic liquid crystal modulator (2 ) is installed according to the drawings (4), and (5).

In addition, this modulator (11) is installed in the middle of the two stepped lenses (3) which are always mounted in opposition.

This results in identical operation with respect to the mono- -lite adapter (11) except that the trajectory of the light rays emanating from the source side (at 10) will be more likely to overflow on the sides of the flat areas (14) and, or areas turns in (15), of the two stepped lenses (3) during the alternation of source images 25 times per second. This particular assembly corresponding to the drawings (4) and (5) is an economical assembly of the present invention.

The space occupied by the cyclic modulator (2) in the middle of the two lenses (3) constituting a thickness, Therefore, the space found between the two lenses (3) will be greater than the space cons- -stated in the middle lenses (3) of the monolytic adapter (11).

Consequently, depending on the desired results, it will be necessary to choose lenses with preferably a length other focal length without the latter being limiting.

Otherwise, we immediately find the same concept of adaptability, thinness, compactness specific to the monolytic adapter (11).

The present invention, according to its monolytic adapter (11) and its variant explained with drawings (4), and (5), proposes to give, and to explain some applications which fall within the framework of different adaptations or, and constructions existing and, or partially - only existing on the current markets of the consumption and other marginal markets, and, or specialized. These examples are given for information and are not limiting.

Thus, taking the drawing first as a reference: (9), the observer (23) sees two different images. Or: the immaterial image of the apple (16) clearly offset from the screen of the monolytic adapter in (11). On the screen of the monolytic adapter (11), the observer (23) sees the image of the tree at (19).

Of course, the interactivity of these two images (16) and (19) is now possible thanks to the internal functioning of the adapter (11) already explained. One could now envisage using this present device inherent in the present invention the mounting of a video game for non-limiting and indicative example.

According to the drawing (No. 10) in figure <(9), the apple (16) is replaced by the plane (62); the observer (23) is now the actor of the interactive images of the airplane (62) and dutank (61); thanks to its joystick (60). The figure (10) of this drawing (N ^° 10) shows a particular application in CA0 mode, it could also be a mode: DA0, or even: PAO.

In the case of the figure (10) of the drawing (10), the observer (23) works thanks to his computer keyboard visible on the drawing, a piece in (64) stabilized immaterially in front of the monitor screen video (17), itself fitted with its monolytic adapter in position (11). The part (63) can be either a normal video image, or a 3D video image, or both. The operator can, within the framework of his work, cause the part (64) to go back and forth.

According to a very particular embodiment, the present invention proposes to assemble several video monitors each equipped with a monolytic adapter (11). whose cyclic liquid crystal modulators are of course synchronized with the appearance of the video images according to a frequency cycle of 25 images per second., .. as previously explained in the chapter liquid cyclic modulator.

These video monitors, or other video sources equipped according to the drawing (11) of their monolytic adapter in (11), are preferably installed horizontally, but that could be otherwise.

This device according to drawing (11) is characterized by the fact that it is an air traffic control system that can simultaneously control: speed, altitude, direction of aircraft. But it could be other different elements: for example boats; except that altitude control would be useless for boats.

The drawing device (11) comprises, for example, four video monitors and each with their adapter (11). There could be more than four, or just one.

The four monitors and adapters are preferably installed horizontally as close as possible to each other for very understandable reasons of compactness. Each monitor (17) - is connected to a conventional radar device (for the example). Each monitor can correspond by example convention to two aircraft. The radar calculation unit will transfer, for example, two aircraft echoes which correspond to two different altitudes; for example: 3000 and 2000 meters.

Assuming that these two altitudes correspond to two planes flying at two maximum heights supported by an air traffic control, the other three monitors (17) wearing their mono- -lytic adapters in (11) will support the altitudes of aircraft thereby flying at lower altitudes.

It is built in (65) visual altitude control lines materialized by lines that can be video; Thus, and advantageously, an observer operator (23) will be able to instantly control visually in real 3D the altitude .. of the planes under his responsibility, in (66) In (65) we observe the aircraft altitude reference lines. Consequently, the invention demonstrates an ability to control air traffic no longer on a flat traffic radar screen, but in 3D. In (67), the frame of the altitude control lines is shown. It is assumed that for this example, all the information is naturally connected in the form of rodondance. The immaterial sphere effect in (59) will be explained later in this description. This drawing (11) shows an embodiment device specific to the present invention. And according to this embodiment given as an indication and not limiting, it could be very easily declined a set taking into account for example given as an indication and not limiting therefore, taking into account a control both aerial, boats are located- - surface and submarine. Showing both a multiple control situation for an operator observer (23).

That said, and concerning the drawing (11), advantageously, the observer (23) will be able to better avoid potential aerial collisions than if he were placed in front of a traditional radar screen and with a flat surface. The materialization of the aircraft still according to the drawing (11), the aircraft in (66), therefore, this materialization in 3D can also be of two different types; or more ....

Either: the operator in (23) will see miniaturized planes in (66) whose image of each one will approach at least the real image of the real aircraft, this, being due to the particularity of the particular radar signals specific to practically each type of planes., Or, 1 operator in (23) will only see light spots. All this is only a matter of choice for the construction of such an assembly.

The idea of the drawing (11) coming within the framework of a particular adaptation of the present invention is based on the principle that all forms, and all existing technologies concerning the modes of computer and electronic combinations are integrated into the present device; since these technologies already exist for various other applications. The drawing N ^° (11) gives a particular form of application of the present invention, based on the union of at least two monolytic adapters (11). These adapters (11) according to the drawing N ^° (ll) are for the needs of this embodiment of air traffic control installed side by side, but they could be installed in many different ways.

Up to now, within the present description, the present invention has highlighted: Thanks to its monolytic adapter (11) and its derivatives according to the drawings (4) and (5) the interactivity of two images: one immaterial in front of the screen of the adapter (11), and the other image recessed.

According to drawing N ^° (12), this monolyte adapter N ^° (129) proposes to highlight in an equally interactive manner as for the adapter (11), two images floating spatially in front of his screen. The adapter comprises, like the variants of the invention according to drawings (4) and (5), only one cyclic liquid crystal modulator. But this time, the cyclic modulator (2) is installed above the two stepped lenses in (3) -So, on the observer side in (9). The operation of the cyclic modulator (2) is strictly the same as the two modulators installed within the adapter (11).

This embodiment of the present invention according to this drawing (12) proposes to generate therefore, two floating immaterial images spatially stabilized in front of the screen of the adapter (129), and naturally interactive with one another according to the present invention.

This particular embodiment therefore comprises two lenses with steps. One: is identical to the N ^° (3) already known within this description. Except that its turns (15) and its flat parts (in (j) are oriented on the observer side in (9). The other lens N ^° (3) is installed, according to the drawing (12) under the other step lens , the turns of the latter at '(15) being oriented opposite the flat parts (14) of the lens (3) installed on the observer side (at 9) -

This display device for the monolytic adapter (129) operates in the following manner: Firstly, and according to the dice -No # (12), the cyclic modulator (2) is linearly in the following state of left to right: Opaque, then translucent, then opaque, then translucent And so on .... Using the convention of examples at the source of images in (10), the apple and the tree, 25 times a second each in turn as previously already explained, according to the descriptive part relating to the cyclic liquid crystal modulator; therefore, according to this example convention, the apple (16) is assigned to this phase of cyclic shuttering. It follows that the trajectory of the light rays of the apple attributed to the turns (15) of the lens (3) installed on the source side at (10) will be obstructed by the zones of liquid crystals programmed in opaque mode according to this drawing (12). In the next phase, the exact opposite will happen: The opaque areas will become translucent, and the translucent areas will become opaque; Previously, only the image of the tree appeared to the observer. immaterially of course. This time, only, the image of the apple appears to the observer. That said, by speeding up the process according to the functioning of the cyclic modulator, that is to say: 25 times per second, the observer will ultimately see the tree and the apple at the same time, float immaterial: either one next to the other, or one offset relative to the other or in any other way according to the types of focal length chosen for the * lenses (3) installed in this monolytic adapter (129). The drawing (13) highlights the adapter (131) which corresponds

responds to another embodiment of the present invention.

To do this, we install in the monolytic adapter (131) Only one cyclic modulator (2), and only one stepped lens in (128). Except that this step lens (128) is not positive with reference to its optical construction, but this step lens (128) is negative with reference to its optical construction.

This means that an observer for example (23), grabbing manually this negative lens (128) all alone, and looking through the concentric turns part, after having chosen the corresponding side, said observer (23) by pointing the said lens

(128) towards any objects, will see the images of these objects as if he were looking through a window; except that the optical characteristics of focal length among others of said lens (128) will cause the images viewed by the observer (23) to have different sizes compared to reality.

That said, the operation of this monolytic adapter (131) is as follows: According to the cyclic shutter (2) of the drawing (13), we attribute for example convention, the tree (127) of the drawing (14 ), and the apple (20) of the same drawing (14), in the following way: the trajectory of the light rays of the shaft (127) for the turns (15) of the negative lens (128). And the trajectory of the light rays from the apple (20) of the drawing (14) to the flat parts (14) of the negative lens (128). It is important to specify first of all that this adapter (131) does not include an image enlarger lens (4). During an operating phase generated by the source in

(10), and the cyclic modulator in (2), an observer will see simultaneously: the image of the tree (127) visually withdrawn from the monitor (17) therefore, as if the tree (127). of the drawing (14) was installed behind the monitor (17 of the drawing (14); and the apple (20) of the drawing (14) in a normal video image format.

The monolytic adapter (130) of the drawing (15) represents another embodiment of the present invention; since it combines a single cyclic modulator (2) installed in the middle of two stepped lenses: one in (3), and the other negative in (128). The negative lens (128) is installed on the source side at (10), its turns (15) oriented on the observer side at (9). The lens (3) of this drawing (15) also has its turns oriented towards the observer at (9) For example convention, we attribute the trajectory of the light rays of the tree (127) of the drawing (16) to the turns (15) of the negative lens (128) and the turns of the lens (3) of the drawing (15) to the apple (16) of the drawing (16). Thus, and according to the operating mode of the cyclic shutter (2) of the drawing (15), the observer (23) of the drawing (16) will simultaneously see the image of the tree (127) of the drawing (16) set back from the monitor (17) of this same drawing, due to the optical characteristics of the negative lens (128); and the image of the apple (16) of the drawing (16) in front of the adapter (130) of the drawing (16) according to an intangible buoyancy already previously explained in the present description. This monolytic adapter (130) does not include an image enlarger lens (4).

According to an embodiment stripped of the present invention, the drawings ((17), and (18) show the monolytic adapter (108) which, generally being able to '' enter within the framework of an integration, and therefore of an extremely easy marketing with regard to the numerous examples specified in the following drawings: (20, 21, 22, 23, 24, 25, 26, 27, 28, 29) .

The monolytic adapter (108) does not include a cyclic liquid crystal modulator (2). Only installed: anti-reflection and anti-radiation filtration in (5), and (6). As well as two stepped lenses (37), provided with their whorls (15) without dSj £ interposed flat areas .; we also visualize concerning this adapter (108), a lens (4) for enlarging images. the focal lengths and other optical characteristics of these two stepped lenses at (37) are such that for an observer (23) of the drawing (18), there is materialized a kind of very visible immaterial sphere whose use will be largely integrated as a surprising visual effect for the various applications which will be explained according to the drawings ranging from: (20), to (29).

This present adapter monolyte will only generate, due to its construction, a single immaterial image spatially stabilized in front of its screen. Except that this immaterial image will float inside the immaterial sphere (59) of the drawing (18). In conclusion, this is a particular embodiment concerning this adapter (108). link of the present invention within the present description.

According to the drawing (19), the integration of the monolytic adapter (108) causes for an observer (23), a surprising visual effect; since the observer (23) sees the immaterial apple (16) floating along its stabilized wave front inside the immaterial sphere (59) of this drawing (19) -

This present particular embodiment inherent in the present invention is characterized by the integrations and applications explained according to the detailed reading below: The drawing N ° (20) integrates the monolytic adapter (108) provided with a multi-position articulated arm. The patient to be observed and, or operated on (43) is seen covered by a matte black material preferably comprising (132) an orifice allowing only the eye (133) of the patient (43) to be seen. The observer (23) will manipulate the monolytic adapter (108) included in his adapter box (18) so as to place the present monolytic adapter (108) above the patient's eye ⁽ 133). The function of the lamp (110) is to illuminate the patient's eye (43); This figure (13) of the drawing (20) highlights a possibility of ophthalmological study for doctors possibly oriented towards surgery.

As soon as the eye (133) of the patient (43) according to the figure (13) of this drawing (20) is sufficiently lit, the observer will note: the existence of the immaterial eye (39) according to a forehead stabilized waves; this eye (39) occupying a spatial portion in front of the mono- -lyt adapter (108) perfectly observable according to the qualities of this embodiment (108) in the context of the present invention.

The multi-position articulated arm (40) will allow various manipulations for the observer (23). Figure (11) of the drawing (20) shows the patient before being covered by the matte dark matter. The drawing (12) shows the patient (43) covered by the matte dark matter.

Preferably, the patient (43) must be covered with this matt black material so that the trajectory of the light rays coming from his eye (133) lit by the lamp (110) is the only element taken into account. by the mounting and the optical characteristics of the adapter monolyte (108).

Therefore, it will be easy for the observer (23) or others if they were present to carefully observe the patient's intangible eye (39) (43), even to operate this eye (43) at the help of scalpel, or interactive electronic scalpel as shown in drawing (38) of drawing (21). This drawing (21) presents as an indicative and non-limiting example an immaterial operating sequence.

This sequence according to the drawing (21) comprises the following elements by way of indicative and therefore nonlimiting examples:

An observer (23) who could just as easily be an eye doctor, an electronic scalpel (38) interactive with respect to the multipoint infrared emitting plates (42) and the multipoint infrared receiving plates (45). Thus, at the intersection of each multi-point infrared line generated by the transmitters (42), the interactive tip of the electronic scalpel (38 will cause a programmed reaction by the computer software and hardware designed for this device. All electronic links are provided by the interface (41). Naturally, the specialized IT for this device also manages: infrared transmitters and receivers with interactive lines, monitor images (17) and electronic scalpel (38).

The operation of the electronic scalpel is as follows: At each intersection of at least two infrared lines generated by the transmitters (42) installed at an angle of 45 ^° , if the interactive electronic scampel (its tip) comes into contact with this intersection -tion, then, according to the installed programming, there will be an interaction in direct relation with the image of the immaterial eye (39). occupying a spatial portion identifiable by the oservator (23).

The infrared lines of the transmitters (42) being at the same height as the intangible eye.

The drawing (22) is a very particular embodiment of the present invention. This assembly of the drawing (22) comprises: as an indicative and nonlimiting example: Four monitors in (17), Four monolytic adapters (108), a distributor of video cables (121), a display device already known and marketed in (122 ).

This present application and integration of the adapter (108) on reading the detailed description below:

First of all, the display apparatus (122) makes it possible to project on video screens, or on screens i installed against walls, or other systems, images, or real objects placed FOLLOWING the screen ( 123) of the display device (122).

Consequently, and preferably according to a detail which is not represented on the screen (123) of the apparatus (122), therefore, the screen (123) of the device (122) will preferably be dark and matte. As the technical characteristic of the device (122) is to receive any objects and / or images on its screen (123) for then project them on any video monitors, and or computer or conventional screens installed against walls; then it will be easy to install in front of each monitor (17) of the drawing (22) accompanying the present description of the present invention; therefore: a monolytic adapter (108).

When installing for example a glass (117) and a key (118) these (two objects being real;), on the screen (123) of the display device (122), the observers (23) will see thanks to the adapter (108) the immaterial images of the glass (117), and of the key (118) occupying a spatial portion in front of the monolytic adapters which cover the monitors (17). This operation which has just been described can also be carried out using a conventional overhead projector. In this case, only, any images installed on a dark background can be seen by observers (23), but not objects; since this is the particularity of the device (122) known and already marketed. This device comprising according to the drawing (22) a very special mirror in (124).

According to drawing N ^° (23), the adapter monolyte or monolytic adapter (108) is installed according to drawing N ^° (23) and the figure (14) in the upper part of the panel (STOP). The monolytic adapter (108) being integrated inside this panel (STOP) (72), the information (STOP) serving as a source in electroluminescent mode in this case, said information (STOP) will appear for the observer (23) immaterially in (71) inside the immaterial sphere in (59). This present adaptation of figure (14) of the drawing (23) is explained by way of indicative and non-limiting example. Since this present adaptation of FIG. (14) comprising the monolytic adapter (108) can just as easily be integrated into all kinds of systems presenting security and / or advertising information. Especially since thanks to the integration of the monolytic adapter (108), the viewing angle for one or more observers (23) exceeds 100 ^° . According to the same drawing (23), Figure (15) also shows a new mode of integration of the adapter (108). In (68) the adapter (108) is installed in a wall revealing only its external surface The source being made up: Either of an object: a lighted toy car or self-lit by a light source, or the video image of the car (70) installed inside the wall. This could be any other object than the car; this example of figure (15) of the drawing (23) and of the car (70) is given for information only and not limiting. Always according to indicative and non-limiting title, the figure

(15) of the drawing (23) shows the integration of the monolytic adapter (108) in the ground in front of the observer (23). this assembly is strictly identical

-tick as integration into the wall; except it's in the ground. f Advantageously, these two wall and floor assemblies of the adapter (108) in this figure (15) of the drawing (23) prove that the present invention is capable of delivering all kinds of indicative information within all kinds of fields. .

According to the drawing (24), the adapter monolyte (108) is integrated into a wall in front of the observer (23). This monolytic adapter is covered with a one-way mirror: (73). The observer (23) normally sees himself in this one-way mirror (73), but at the same time, the non-tangible perfume bottle (74) along a visible stabilized forehead, occupies a portion of the space in front of the two-way mirror (73) and in front of the observer (23). This example of integration into a wall of the monolytic adapter (108) covered by the two-way mirror (73) is given as an indicative and non-limiting example.

According to the Drawing (25), the figure (17) shows the integration of the adapter monolyte (108) in the lid of a pan (at 99) •

Still as an indicative and non-limiting example, we note the intangible foods in (100) inside the immaterial sphere (59) characterizing the adapter (108). ,

According always to the drawing (25), the figures: (16, 18, 19) are also given by way of indicative examples and therefore non-limiting: Also, and according to the figure (16), the adapter monolyte (108 ) is installed in front of the entrance to a box containing: in (98) therefore, the mono- -lyte adapter, in (96) the source of the time in light-emitting diodes ,; in (59), there is the presence of the immaterial sphere (and in (97), the immaterial time according to its stabilized front occupying a spatial portion located in front of the monolytic adapter (108). According to the figure ( 18), the adapter monolyte (108) is installed in front of a box containing a real apple (104) lit by the light source (105). In (59) we will notice the immaterial sphere (And in

(16) the intangible apple included in the immaterial sphere (59). According to the figure (19) of the drawing (25), the assembly is identical with respect to the drawing (18)., Except that the apple is replaced by a photo (102,) immaterial contained in the immaterial sphere (59)

According to the drawing (26) and Figures 20, 21, 22, 23) showing the integration of the monolytic adapter (108) according to the specific integrations given in titre of indicative and non-limiting examples, it will be noted according to drawing of figure (21) of drawing (23) the immaterial appearance according to its stabilized wave front of the immaterial leg (82) inside the immaterial sphere (59). In (77) the adapter monolyte (108) is integrated inside the oven door of a cooking appliance. In (109) according to this figure (21, one will notice the figures of intangible information in source by light-emitting diodes; thanks to a small adapter (108) installed in front of this source of the cooker cooking appliance. According to the drawing (26) and its figure (20), the adapter monolyte

(108) is integrated in front of a night light for children in (78).

In (81) according to this figure (20), we notice the immaterial man (81) contained in the immaterial sphere (59).

According to figure (23) of the drawing (26), the adapter monolyte (108) is installed on the surface of a table; in (76). The helicopter (79) is located inside the intangible sphere (59).

According to figure (22) of the drawing (26), the adapter monolyte (108) is installed in a scale in (75) - Thus, during a weighing, the immaterial information (80) in the form of figures in this case there. will appear inside the immaterial sphere (59).

According to the drawing (27), the figures which represent the integration of the monolytic adapter (108) give examples which are only indicative and not limiting. EITHER: Figures 24,25,26.

Figure (24) shows the installation of the monolyte adapter in a wall as for Figure (15) of the drawing (23), except that the immaterial lamp (88) replaces the immaterial car (70) of the drawing (23). In (87), the figure (24) of the drawing (27), therefore shows this application of the adapter monolyte (108).

Figures (25) and (26) show an integration of the adapter monolyte (108) according to the same system as Figure (21) of the drawing (26). The drawing (in figure (25) represents a dishwasher. The drawing in figure (26) represents a washing machine.

According to the drawing (28), the figures (27, 28, 29, 30) represent try the integration of the monolytic adapter (108) into the optical signals according to FIG. (28); then, in a landline phone, figure 27), then, in a mobile phone, figure 30), then, in a CD laser radio handset figure 29. These examples according to the drawing (28) and its figures: 27,28, 29.30 are given as examples of indicative and therefore nonlimiting examples.

Figure (28) of the drawing (28) therefore represents the integration of the monolytic adapter in the light signals of a vehicle.

In this case, it is the headlights, but it could be the flashing lights, or the position lights, or the reversing lights, or the fog lights or others .... In (90), we notice the intangible lighthouse contained in the immaterial sphere (59).

At (89), the integrated adapter (108). According to figure (27), the male or female correspondent is included in the immaterial sphere (59). The adapter monolyte (108) being installed at (95) in a non-mobile handset phone. According to Figure (30) of the drawing (28), the adapter monolyte (108) is integrated at (93).

According to Figure (29) the adapter monolyte (108) is integrated at 91) '; according to an animation of immaterial leeds synchronized or not with music, in (92).

According to the drawing (29) included in the description of the present invention, and relating to the adaptation of the monoly--tic adapter (108),; this example of the drawing (29) is given only as an indication and therefore not limiting. This drawing (29) highlights the installation of a large monolytic adapter (108), in a wall (112), plants in their tray in (114), an optical path in (27), a woman immaterial in (115), a plasma screen in (113), a traditional mirror in (28);

The operation of this integration of the monolytic adapter (108) within this drawing (29) is as follows:

The plasma screen (113) delivers the video image of the woman (115). Then, the path of the optical path of the light rays of the plasma video image (113), this optical path (27) collides with the mirror (28) installed at an angle of 45 ^° or close to it. Then, the optical path in (27) crosses the monolytic adapter (108) which, by its main optical characteristics already explained transforms the video image coming from the plasma source (113) into an immaterial image of the woman (115) in a stabilized wave ront and also identifiable in a spatial portion observed by the observer (23)

The applications of this assembly of the drawing (29) integrating the adapter monolyte (108) can be numerous; And, by way of indicative and non-limiting examples: Intangible fashion shows, the duplex conversation with people being in reality elsewhere, the speech of a man seen by an assembly and the professor teaching a course to his students. ...

According to all the examples given as indicative and nonlimiting within the drawings: (20), (21), (22), (23, (24), (25), (26), (27), (28) , (29); and their figures: 11, 12, 13, 14. 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30; L 'monolytic adapter (108) cited in all of the above drawings and figures, can therefore be constructed in all kinds of sizes according to the adaptations and integrations encountered in all their forms, whatever their nature.

On the other hand, according to all the examples given in indicative and therefore nonlimiting, and, according to the figures of (ll) eleven to (30) thirty, and the drawings of (20) twenty to (26) twenty six, c 'is the monolytic adapter (108), which is integrated according to the various adaptations cited. As a result, and advantageously, the other types of adapt

-teurs cited and explained within the present description in the context of the present invention; therefore, the other monolytic adapters; IS:

The monolytic adapter: the (11), then the (129), then the (130), then the (131) can replace each in turn or together in a combined way in multiple ways the monolytic adapter (108) ; just as the adapter (108) can also be combined with the other monolytic adapters (11, 129, 130, 131, in multiple ways this, within all the drawings and figures cited within this page.

So that the explanations concerning all the adapters which fall within the framework of the present invention, on the one hand, and its main embodiments on the other hand are well understood, here is a summary table of the monolytic adapters:

The present invention is therefore described with reference to the following monolyte adapters or monolytic adapters according to the - drawings embellishing the present description:

1) Drawing for the abstract .... Monolytic adapter (11)

2) Drawing N ^° 1 .... Monolytic adapter (11)

3) Drawing N ^° 2 .... Monolytic adapter (11) 4 i Drawing N ° 3 .. Monolytic adapter H)

5 l Drawing N ^* 4 .. Monolytic adapter H)

6 Drawing N ° 5 .. Monolytic adapter 11)

7 Drawing N ° 6 .. Monolytic adapter U)

8 ι Drawing N ° 7 .. Monolytic adapter 11) or: 108, 129, 130, 131.

9 Drawing N ° 9. Monolytic adapter H)

10 Drawing N ° 10. Monolytic adapter H)

11 Drawing N ° 11. Monolytic adapter 11)

12] Drawing N ° 12. Monolytic adapter 129)

13) Drawing N ° 13. 13D monolytic adapter

14) Drawing N ° 14. 13D monolytic adapter

15) Drawing N ° 15. Monolytic adapter 130)

16) Drawing N ° 16. Monolytic adapter 130)

17) Drawing N ° 17. Monolytic adapter 108)

18) Drawing N ° 18. Monolytic adapter 108)

19 Drawing N ° 19. Monolytic adapter 108)

20 Drawings N ^° from 20 to 35. Monolytic adapters 108)

To conclude this table, here is the correspondence of the different monolytic adapters with their characteristics specific to each in the context of the various embodiments of the present invention, a) Monolytic adapter (11). Either: A video or slightly burst image, and a picture ^p immaterial. The two images are interactive with each other. 'sb) Monolytic adapter (108). Or: A single image floating immaterially according to a stabilized wave front. c) Monolytic adapter (129) • - Either: Two immaterial interactive images between them. d) Monolytic adapter (130). Either: A negative image and an immaterial image, interactive with each other. c) Monolytic adapter (131). Either: A negative image, and a normal video image. interactive between ità Adapters: (11), (108), (129), (130), (131), are constructed with materials of which here below is a description of three indicative and nonlimiting examples: This description for stepped lenses Either: UVT acrilic, polycarbinate, rigid vinyl, UVF acryl.c, Polyurethane IR 6, Polyurethane IR 5, Polyurethane IR 1.2, Polyurethane IR 4.7, Polyurethane IR3, Polycarbonate, PPMA three subjects refractive indices:

ACRYLIC ^• VINYL RIGID POLYCARBONATE 1.49 1.54 1-586 For these same materials, here are three indicative and non-limiting examples of the maximum service temperature: (degrees centigrade). ACRYLIC VINYL RIGID POLYCARBONATE

80 70 120

In the context of the present invention, the monolytic adapter (108) which is one of the main embodiments, will find its place within a concept bringing together the skills to deliver two interactive images between itself while by offering the possibility of presenting itself in a folding mode.

This concept explained with three indicative and non-limiting examples concerns the drawings: (30, 31, 32, 33, 34, 35.) -

This concept will be better understood on detailed reading of several embodiments below given by way of indicative and nonlimiting examples.

The drawing N ^° (30) shows a front view of a monitor (17) whose screen (32) firstly displays the normal video image of the tree (19), and at the same time, l normal video image of the apple (29) itself presented visually on a background preferably as dark as possible.

This image generated by the monitor screen (17) is connected to a game unit for example, and, or to a software of C.A.0, or D.A.0, or P.A.0, for example. And, by convention of examples, these two images the tree, (19), and the apple (29) of the drawing (30) are interactive between them; That is to say that the hardware and the software of use allow for example, to bring back and forth of the apple in the tree, and, or, at the same time, branches and, or leaves of the tree (19), can very well appear in place of the apple (29); all forms of combinations being possible as during a sequence of C.A.0: (Computer-aided design.)

Nowadays, existing computer software authorizes multiple combinations of constructions and assemblies of all kinds of things in multiple fields. It is no longer a secret for anyone.

That said, the drawing (31) shows a section of this concept including the adapter monolyte (108). According to this drawing (31), we observe in (26) the location of the semi-reflecting glass at an angle of 45 ° relative to the screen (32) of the monitor (17).

In (59) the observer (23) will note the existence of the immaterial sphere (59) proper and particular to the characteristics of the lens (lθδ) explained in the drawings: (17, 18, 19), accompanying this description.

The trajectory of the light rays (27) coming from the screen source of the monitor (17), this trajectory of the light rays (27) conveying the image of the apple (29) on the dark background of the drawing (30). ) whose light rays the vehicle, by incidence of the mirror (28) through the adapter monolyte (108), then, by incidence always, comes into contact with the semi-reflecting glass (26), to then stabilize spatially in ( 16) drawing (31) in a portion of the space observable by the observer (23).

The mirror (28) of the drawing (31) is installed at 45 ^° in the support (134).

Naturally, for the observer (23) of the drawing (31) the image of the tree (19) of the drawing (30) normally appears; since the semi-reflecting glass (26) of the drawing (31) lets in the light of the video images of the monitor (17). This is, moreover, one of the well-known characteristics of semi-reflecting glass.

For clarification: the drawing (30) represents two images from the front: that of the tree (19), and that of the apple (29). That said, in front of the observer (23), these are the same images . Except that that of the apple (29), conveyed as just explained, appears in the eyes of the observer (23) of the drawing (31) stabilized immaterially in (16), of the drawing (31) -

The drawing (31) represents in (135) the articulated parts allowing the assembly appearing in the drawing (31) to fold.

This assembly of the drawing (31) comprising: the semi-reflective glass (26), the support (134), the monolytic adapter (108), the mirror (28), is independent of the monitor (17); and can therefore easily be adapted to another monitor, or screens of all types.

The drawing (32) shows a perspective view of the drawing (31). It contains exactly the same elements; Therefore, the observer (23) of the drawing (32) visualizes the apple (16) floating immatéricllemnt before him, according to a portion of the identifiable space The tree (19) of the drawing (32) is seen by D ' drawing observer (23) (32) naturally through the one-way window (26).

Assuming that the observer (23) of the drawing (32) is in front of this set of the drawing (32) with a game software, he will then have the possibility thanks to his joystick (60) to cause actions as if he really played with the fact that the two images apple (29), and tree (19) in the context of this drawing (32) are completely interactive and therefore controlled by the same software; This said software can be built, and / or existing for any other applications other than a game software cited simply for illustrative and non-limiting example.

The drawing (33) shows a situation which takes up the drawing (32) in perspective, but with three adapter monolytes (108) instead of one, and also, three images on a dark background instead of one like this. was the case with the apple. The operation of this assembly of the drawing (33) is identical to the operation of the drawing comprising the assembly (included in the drawing (32); except that three images: The pair of glasses (35), the car (126) ,, and the apple (29) have their video images on a black or dark background ^' which, by the trajectory of the light rays of their own images in (27); passing through the monolytic adapter (108), via, the mirror ((28) and via the semi-reflecting glass (26), appear to the observer (23) according to the drawing (33), in immaterial mode with stabilized wave front in (70) for the car, in (34) ), for the pair of glasses, and in (16) for the apple. According to this drawing (33), in (23), the observer therefore sees the normal image of the tree (19), and three images which can easily be interactive with one another according to the types of software used; These three intangible images can just as easily be interactive in many ways with the tree in (19); d e same that the observer (23) thanks to his joystick (60) can easily intervene in an interactive way according to, or the types of software used.

The drawing (33) comprises three monolytic adapters (108), but it could quite naturally include only one or more, or, more than three as is the case within the drawing (33). As for the explanations of the drawing (32) all forms of software combinations and combinations of images are possible. The drawings (34) and (35) show the same device as the drawings (30, 31, 32, 33) Except that the two images integrated -ractive of the apple (29) of the drawing (34) and of the pair of glasses (35) of the drawing (34) are both on a preferably dark background; It follows, according to the drawing (35) that the observer (23) sees two immaterial images thanks to two monolytic adapters (108) of different sizes relative to each other.

The observer (23) of the drawing (35) sees the pair of glasses (34) of the drawing (35) floating immaterially according to a stabilized front, and occupying a portion of space behind the semi-reflecting glass and in front of the screen of the monolyte adapter (108) installed in front of the monitor screen (17). In (33) optionally, the presence of anti-reflective foam will be observed.

The observer (23) will be able, despite this not being mentioned on the drawing (35) to play and manipulate his joystick (60) at will in an interactive manner and to play with his images according to the types of software used . The drawings (34, and 35) represent a configuration with two images; there could be more than two interactions between them.

All the drawings (30, 31, 32, 33, 34, 35) explain integrations of the adapter monolyte (108) according to several situations of images systematically interactive with one another; All of these images could just as well not be interactive at all and, or only be partially.

As in all of the drawings (30, 31, 32, 33, 34, 35), only the monolytic adapter (108) is used. Therefore, and according to a set of explanations not illustrated within this description, all the other monolytic adapters either: (11), (129), (130), (131), could be the subject of integration alone or combined with one another in multiple ways with also the adapter (108), within the drawings explaining various situations, namely: the drawings: (from 30 to 35).

Just as all the monolytic adapters (11), (108), (129), (130), (131), could be combined together or alone, and, or in multiple ways within identical applications, and, or, bordering on the situations that can be viewed and already explained in the drawings: (10, II, 14, 16, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29,); These multiple combinations are not illustrated within this description. The monolytic adapter (11) constituting the basis of the present invention, the monolytic adapters: (108), (129) (130) and (131) constituting the other embodiments of the present invention; each embodiment can and includes adaptations and also destinations explained in the present description.

That said, the adapters (11, 108, 129, 130, 131), can also be partially disassembled and combined totally and, or partially with each other in multiple ways according to, and for destinations and, or adaptations are not illustrated in the drawings accompanying this description as there are so many solutions and there are so many adaptations and destinations. All the monolytic adapters explained within the present description in the context of the present invention allow for one or more observers visions without special glasses or other systems and, or devices which may be used.

A tt of indicative and nonlimiting examples, here below is a table summarizing the stepped lenses, also called fresnel lenses used for the needs of the present invention and its various embodiments according to the monolytic adapters.

-that (11) ^" , ^" 108), (129), (130), (131).

Knowing that the stepped lens (3) installed in various ways according to the monolytic adapters; and therefore comprising, as explained in the present description, an arrangement of one out of two turns; half the time, the location of the turn having been replaced by a flat part. That this so-called stepped lens (3) appears in the table below according to indications delivered to titer indi- -cati s and not limiting.

These stepped lenses can be of different sizes and different thicknesses depending on the adaptations and applications Taking for example a conventional 17 inch computer screen, the stepped lenses used in the context of the present invention are of this size , but can be just as much larger, or smaller.

According to a representation not illustrated in the drawings accompanying this description, the stepped lenses used and commented on may be installed in the various monolytic adapters not necessarily in a planar manner or approaching it in general;

To do this, the so-called stepped lenses used and commented on can be installed in convex or concave ways. Table of optical characteristics of stepped lenses used in the context of the present invention and according to its various embodiments; all given as an indicative and therefore non-limiting title:

Distance Number of Plan Points clarity distance

Focal spiers / jmw conjugates conjugates visual object

123 0.508 38I.OO

126.2 0.508 402.00

172.2 0.508 387.20

182.5 0.508 365.00

762.0 0.508 infinite 762.00 889.00

1200.0 0.112 infinite 1200.00 1701.80

1000.0 0.112 infinite 1000.00 1295.4

780.0 0.112 infinite 780.00 1066.80

698.7 0.508 infinite 698.70 889.00

762.0 0.508 infinite -762.00 440.00

110.2 0.508 infinite 110.20 163.80

50.8 0.229 infinite 50.80 76.20

206.0 0.508 infinite -206.00 302.00

• 186.0 0.508 infinite -186.00 269.00

According to a representation not illustrated within the drawings which accompany the description of the present invention, taking as reference the drawing N ° (1) as an example, the empty space existing between the two stepped lenses (3) may contain a liquid neutral in which metallic particles circulate, and conductive of electric current. This liquid may as well not be neutral. On the other hand, the metallic particles may very well not be, provided that they are electrically conductive, if they are other.

That said, this liquid containing electrically conductive particles also contains phosphorescent particles.

As soon as an electric voltage is applied in this liquid, in an alternating manner, and, by way of nonlimiting examples indicative of 5 (five) times per second, the electrically conductive particles will entrain with they by panicking the phosphorescent particles (which they too could be conductive in electricity,), thus ionizing the phosphorescent particles, and, consequently, changing 5 (five) times per second the focal length of, or of the lens (3). Advantageously, and, for convenience, this frequency of 5 times per second can be less or more depending on the requirements which are envisaged. For a use allowing an observer to better realize the incidence of this assembly, by convention of indicative and nonlimiting example, the observer has the possibility of choosing himself the frequency.

That said, the observer initiates powering up of the device; the liquid charged with its electrically conductive particles and its phosphorescent particles in sufficient number, modify the focal length (its length) of) or stepped lenses (3); it could be just as any other scale fresnel lenses, but also any other material for other destinations and other adaptations whatever they may be.

The observer will thus be able to observe, depending on the voltage and the amperage applied to the said liquid installed between the two lenses

(3) of the drawing (1) for the example, focal changes (the length) which, as a consequence will generate intangible spurts with stabilized fronts changing and different from each other according to, therefore the electric voltage and the amperage applied. The phosphorescent particles can be replaced by other particles other than phosphorescent.

REFERENCES

REFERENCES OF THE DRAWINGS ACCOMPANYING THIS DESCRIPTION:

Design for the abstract. . Basic drawing of the invention.

1) Drawing N ^° 1. Basis of the invention, and alternating frequencies.

2) Drawing N ^° 2. Montage of the slim and compact invention.

3) Drawing N ^° 3. Aerial view of the cyclic zone modulator.

4) Drawing ^No. 4 .. Cyclic modulator (2) installed in the middle.

5) Drawing ^No. 5 .. Cyclic modulator (2) installed in the middle.

6) Drawing N ^° 6 .. Demonstration of stabilized wave front.

7) Drawing ^No. 7 .. Anti-reflective, anti-radiation filtration.

8) Drawing ^No. 8 .. Anti-reflection, anti-radiation filtration.

9) Drawing N ^° 9 .. Assembly Monolytic adapter (11) in 2 images

10) Drawing N ° 10 .. Video game applications, and C.A.O.

11) Drawing N ° 11 .. Application in air traffic control mode.

12) Drawing N ^° 12 .. Cyclyc modulator for 2 floating images.

13) Drawing N ^° 13 .. Cyclic modulator for negative images and normal video images.

14) Drawing N ^° 14 .. Video monitor demonstration with negative image and normal video image.

15) Drawing N ^° 15 .. Cyclic modulator for negative images and floating images.

16) Drawing ^No. 16 .. Video monitor demonstration with negative image and floating image.

17) Drawing N ^° 17 .. Cyclic modulator in section N ° (lθ8).

18) Drawing N ^° 18 .. Cyclic sectional modulator, immaterial sphere.

19) Drawing N ^° 19 .. Video monitor with monolytic adapter (108) 0 l Drawing N ^° 20 .. Drawing for ophthalmology. 1 i Drawing N ^° 21 .. Drawing for Ophthalmology. 2 ι Drawing N ^° 22 .. Drawing for multivision of floating objects. 3 Drawing ^No. 23 .. Applications of the adapter monolyte (108). 4 Drawing ^No. 24 .. Applications of the adapter monolyte (108). 5 Drawing No. 25 .. Applications of the adapter monolyte (108). 6) Drawing ^No. 26 .. Applications of the monolyte-adapter (108). 7) Drawing ^No. 27 .. Applications of the adapter monolyte (108). 8) Drawing No. 28 .. Applications of the adapter monolyte (108). 9) Drawing N ° 29 .. Applications of the adapter monolyte (108). ) Drawing N ° 30 Monitor screen, and images for viewing 2 plants.

) Drawing N ° 31 Folding montage for images in two plants.

) Drawing N ° 32 Perspective view montage images in 2 plants.

) Drawing N ° 33 Perspective montage for 1 normal video image, and 3 immaterial images.

) Drawing N ° 34 Video monitor with screen 2 images black background.

) Drawing N ° 35 Montage with adapter (108) for two interactive immaterial images. ) Drawing N ° 36 Aerial view of a cyclic modulator (2) covering a stepped lens alternately comprising: a concentric turn, then a flat part, and so on ... The cyclic modulator of drawing (36) is also alternated in the same way, that is to say in a concentric way; and not online like the drawing (3).

1. Lateral support of the monolyte.

2. Cyclic liquid crystal modulator according to a flip flop state synchronized with video images 25 times / S-

3. Lenses with a so-called fresnel rung, in a special version, that is: one out of two turns.

4. Ladder lens with all its streaks; used here as an image enlarger and prefocus.

5. Light filter.

6. Direct coating on the turns of a light screen filter. 7. Opaque zone: the light does not pass, unless the electronics program this zone in translucent mode.

8. Translucent zone: light passes, unless the electronics program this zone in opaque mode.

9. Observer side of the monolyte. 10. Image source side of the monolyte.

11. Monolyte: basic set of the invention corresponding to the drawing of the abstract. A normal video image + a burst image.

12. Connection - to electronic interface for managing flip flop masks (one or the other state, but never both). 13. Monolyte in section.

14. Flat part of the fresnel rung lens. '15- Spiers of the step fresnel lens.

16. Intangible image of the apple.

17. Video monitor. 18. Adapt.

19. Video image of the tree: Every other time: 25 frames per second.

20. Video image of the apple: half the time: 25 frames per second.

21. Graphic of the anti-reflective layer: (Figure 5) •

22. Graph of the transparent conductive layer: (Figure 6) 23. Observer.

24. Reflection.

25. Cancellation.

26. Semi-reflective glass.

27. Optical trajectory. 28. Mirror.

29. Video image of the apple on a black background.

30. Direction of lateral movement of the monolyte.

31. Device housing. 32. Monitor screen.

33. Anti-reflective foam.

34. Pair of intangible glasses.

35. Video image of the pair of glasses, on a black background. 36. Video line separating the two images: glasses and apple.

37. Ladder lens, called fresnel lens, full turns.

38. Electronic scalpel with interactive tip.

39. Intangible image of the eye.

40. Multi-position articulated arm. 41. Interface between the interactive electronic scalpel and the software controlling the video monitor.

42. Emitters: multi-point infrared radiation plates.

43. Patient to be observed, and, or operated on.

44. Dark, matt cover around the eye. . Receivers: multi-point receiver plate.

46. Dotted lines confirming the separation of the flat areas from the teeth: streaks, turns of the lenses with fresnel rung.

47. Video image of the apple on a black background.

48. Video image of the eye on a black background. 9. Alternating images.

50. Direct trajectory of light rays.

51. Path deviated from light rays.

52. blockage of light rays by opaque areas, of liquid crystal. 53. Image of the (8) intangible.

54. (8): hardware digit in electroluminescent mode.

55- Digit of (8) Electroluminescent constituting the material source. 56. Frosted glass closest to the adapter, collecting a blurred image. 57. Frosted glass in good position collecting the clear, spatially offset image of the (8) intangible whose source is: (55) •

58. Frosted glass furthest from the adapter, and therefore from the source (55) collecting a fuzzy image.

59. Intangible sphere. 60. Game remote control joystick.

61. Video image of the tank.

62. Intangible image of the aircraft.

63. Normal or 3D video image of the mechanical assembly. 64. Intangible image of the mechanical part to be worked and, or observed, or others by the CAD operator

65. Aircraft altitude reference lines.

66. Intangible aircraft.

5 67. Altitude and direction control unit.

68. Monolyte Adapter integrated into a wall.

69. Monolyte Adapter integrated into the soil.

70. Small intangible car.

71. The word (S.T.O.P.) intangible.

10 72. Stop sign with its Monolyte Adapter integrated inside.

73. One-way mirror installed in front of a Adapter monolyte installed in the wall.

74. Bottle of intangible perfume.

75. Monolyte Adapter integrated in scale mode. 15. 76. Monolyte Adapter integrated into a table.

77. Monolyte Adapter integrated in the door of a range oven.

78. Monolyte Adapter integrated in mode: Night light for children.

79. Intangible helicopter.

80. Intangible figures. ^ 0 81. Intangible snowman.

82. Intangible leg.

83. Monolyte Adapter integrated in the door of a washing machine.

84. Monolyte Adapter integrated in the door of a dishwasher.

85. Intangible linen. 5 86. Intangible tableware.

87. Integrated Monolyte Adapter in lighting mode.

88. Intangible lamp.

89. Monolyte Adapter integrated in car headlight.

90. Intangible lighthouse .. '0 91. Monolyte Adapter integrated into a radio in the leed part synchronized with music or lyrics.

92. Animation of intangible leed.

93. Monolyte Adapter integrated in a mobile phone.

94. Correspondent, immaterial man or woman. 5 95. Monolyte Adapter integrated in a handset telephone.

96. Source in light emitting diodes.

97. Intangible light emitting diodes. 98. Monolyte Adapter integrated in mode (immaterial time).

99. Monolyte Adapter integrated in the lid of a pan.

100. Intangible foods.

101. Monolyte Adapter integrated in a photo frame. 102. Intangible photo.

103. Monolyte Adapter constructed in any intangible object mode.

104. Source image of the apple; it could also be a real apple.

105. Source lighting mode.

106. Monolyte Adapter built and integrated in video game mode. 107. Monolyte Adapter integrated and built in interactive C.A.O mode.

108. Simple monolyte.

109. Intangible information figures in light-emitting diodes.

110. Lamp for lighting the patient's eye (a man in this case) /.

111. Space found between the material digit and the (8) sharp image collected by the frosted glass N 57-

112. Wall.

113- Plasma screen

114. Plants in their containers.

115. Intangible woman. 116. Virtual door. ^r:

117. Real stem glass.

118. Real key.

119. Intangible stem glass.

120. Intangible key. 121. Video cable distributor.

122. Display device.

123. Screen of the display device.

124. Upper mirror.

125. Monolyte adapter device constructed with 3 fixed or mobile elements allowing the immaterial floating of 3 images simultaneously.

126. Image of the car in video mode on a black background.

127. Image of the tree (1 /) seen far away, behind the video monitor (17).

128. Negative lens. 129. Monolyte two spurts of images.

I 0. Monolyte, a negative image + a gushing image. 131. Monolyte, a negative image, + a normal video image in +. 132. Dark matter preferably and, or matt black.

133. The patient's eye.

134. Support.

135. Articulated parts.

Claims

1. Device for the formation of at least two interactive images between them, one of the two images appearing to be in immaterial levitation according to an identifiable wave front and capable of being stabilized, one of the two images visually and spatially offset from its original source, characterized in that it comprises - according to the drawing (l) and the drawing for the abstract: Two stepped lenses (3) whose turns (15) are alternately replaced every second , therefore, by a flat part (14), these two lenses (3) being installed, their turns (15) and their flat parts (14) in opposition, therefore, facing each other; these two lenses (3) being covered in (5) and in (6) with anti-reflection and anti-radiation filtration; this said device also comprising a step lens (4) installed on the source side of the images in (10), its whorls being complete, this lens (4) having the essential function of enlarging the images coming from the source side in (10), the present device also comprising in (2) two cyclic modulators (2 ) whose zones (7) and (8) installed linearly - according to drawing (1) and (abbreviated) have their widths at least equal to the width of the turns (15) and the flat parts (14) of the two lenses - -the steps (3) as shown on the drawing (1) and (the abstract) these zones (7) and (8) becoming alternately opaque or translucent thanks to the liquid crystal technology, and according to a frequency of at least minus 25 times per second more or less, this frequency being synchronized with the appearance of two images (drawing N ° 9), n tree

(19), and an apple (20) becoming immaterial in (16); the apple and the tree appearing in turn each in turn once in two 25 (twenty five) times per second more or less synchronized with the two cyclic liquid crystal modulators in (2), the image of the tree remaining more or less on the surface of the screen of the monolithic adapter (ll) of the drawing (9), the image of the immaterial floating apple - in (l6) in front 1 observer (23), the two images of the apple (16) and the tree (19) being interactive thanks to a suitable computer unit, therefore appropriate.

2. Device according to claim N ^° l) characterized in that the zones (7) and (8) have their widths at least equal to the width of the turns (15) and of the flat parts (l4) of the two stepped lenses (3), but that these widths could be greater DU smaller, the correspondence of the widths of the liquid crystal zones (7) and (8) with respect to the widths of the turns (15) and of the flat parts (14), which must nevertheless be sufficiently precise so that the trajectory of the light rays (drawing ^No. l) and (drawing for the abstract) (50) (51), do not overflow, and do not interfere on the sides thus causing unwanted parasites of light, the trajectory of the light rays coming from the source side in (10) d 'images will pass or will not pass through the turns (15) and flat parts (l4) according to the shutter cycle of the zones (7) and (8) of the two liquid crystal modulators (2) including the zones (7) and (8) work symmetrically, at the same time and in concert, at a frequency of 25 times per second more or less, this frequency synchronized with the appearance of two images on the source side in (10), and, for convention d example, according to the synchronization, the trajectory of the light rays of the shaft (19) will pass through the flat parts s (l4) stepped lenses (3), the image of the tree appearing approximately on the surface of the screen of the monolytic adapter (11), the next instant, the trajectory of the light rays of the apple (20) will pass through the turns (15) of the two stepped lenses (3) appearing in an intangible mode (in 16) thanks to the incidence of the focal length of the turns (15) and their angles (according to the technical table of stepped lenses) existing within this description); The image of the apple (16) and the tree (19) appear alternately on the monitor screen (17) (49) each in turn, and this, 25 (twenty five) times per second; according to for example a video film synchronized electronically and, or by computer with the two cyclic modulators (2) installed, one covering the flat part, observer side (9), the other cyclic modulator (2) covering the flat part of the stepped lens (3) placed on the image source side (in 10), and the fact that the apple and the tree appear 25 times per second, it is natural that 1 Observer (23) will see only two images at the same time time, one of the tree roughly on the surface of the monitor screen (17) of the drawing (9), the other image of the immaterial apple (16) floating in front of the observer (23), the tree and the apple being or not being interactive according to a computer program which, by the design of the present invention is the same for the two images apple (16) tree (19) the set of objects , tree, apple. car, telescope. planes, etc ... taken as examples of interactive images or not within this description -tif is indicative and not limiting; moreover, according to the cycle of 25 times per second of the two cyclic modulators (2) synchronized with the appearance of the apple and tree images originating from the source (in 10), the trajectory of the light rays (50) (51 ): for the tree, it is the trajectory (50), and for the apple, the trajectory (51), the opaque zones every second ((7) and (8) block the trajectory of the rays luminous thanks to the cyclic filling of liquid crystals of the two modulators (2); figures (3) and (4) of the drawing (2) show the assembly of the different parts thus constituting the monolytic adapter (11) explained in the drawing (l), and in the drawing for the abstract; the drawing (3) according to its figures (5) and (6) shows an aerial view of an adapter monolyte (11) capping a step lens ( 3) the figure () particularly shows an exploded view in section; the drawing (36) shows an aerial view of another mode of arrangement of the liquid crystal zones (7) and (8) installed in a con centric, while the figure (6) of the drawing (3) shows a mode of arrangement of the liquid crystal zones (7) and (8) of a modulator (3) installed in a linear fashion; preferably, the invention will opt for the example of FIG. (32) of the drawing (36) for its various embodiments.

3. Device according to claim ( ^No. 1) and claim No. (2), characterized in that the present invention advantageously comprises anti-reflection and anti-radiation coatings in (5) and (6), in ( 6), the coating follows the shapes of the turns (15) and the flat parts (14) of the lens (3) located on the image source side in (10), this re-coating covers in (5) the flat part of the lens (3) installed on the observer side at (9); These coatings could just as well cover only one, or several flat parts or turns (15) or flat parts (14) of the lenses (3) and (4) constituting the adapter monolyte (11), or all the other monolytic adapters constituting the various embodiments of the present invention; all forms of combinations being possible; but, preferably, this anti-reflection and anti-radiation coating is installed according to the locations (5) and (6) for physical reasons related to the trajectory of the light rays from the source side of the images (lθ); Just as this anti-reflection and anti-radiation coating could just as easily be totally and / or partially integrated, embedded, and or mixed with the material constituting the stepped lenses. installed within the monolytic adapters (11), (108), (129), (130), and (131) constituting the present invention, and its various embodiments; these anti-reflection and anti-radiation coatings, suitable for the present invention, contribute to attenuating in a very large proportion, of the order of 99-99%, the reflection and the dazzle according to the explanations contained within of this description -tif embellished with the drawings (7) and (8) according to their figures (7) (8) of the drawing (8) and the figure of the drawing (7) comprising in section the adapter mono- -lyte (11) and its monitor (17); eye strain is also considerably reduced; preferably, a conductive coating with grounding cord will be integrated into the filtration layer (5) to block up to 99-99% of electromagnetic radiation; the filtration layer (5) on the observer side can advantageously be covered with three indicative and therefore nonlimiting examples of a two-way mirror, of a fine mesh fabric, and, or transparent and / or semi-transparent paper.

4. Device according to any one of claims from (1) to (3), characterized in that according to the monolytic adapter (11) visua- -lisé, and explained in the drawings: (for the abstract), (1), (2), (3), (7), (8), (9), (36), this so-called monolytic adapter (11) characterizes the essential basis of the present invention by highlighting, the multi - adaptation of the invention, its compactness, its thinness, its lightness, while allowing the formation of at least two interactive images between them; which, consequently, according to the drawing (10) figure (9) allows an observer (23) to manipulate a joystick for controlling video games (joystick 60) fully interactive for the 2 images constituting the scene example for the indicative and nonlimiting example, either: the intangible plane (62), and the tanck (61), the observer (23) having the possibility according to the computer program of games to cause precise reactions of the aircraft (62) relative to the tanck (6l), the monolytic adapter (ll) being installed in front of the monitor screen (17); just as, according to this same drawing (lθ), figure (10) highlights a CAD program, (computer-assisted design; the observer (23) is free to work on his mechanical part (64 ) immaterial, with its computer keyboard connected to figure (10) of this drawing (10) as viewed by a cord; the mechanical part (63) appearing on the monitor screen (17) of figure (10) being, as for the previous example (figure (9), interactive with the mechanical part (6), which authorizes the observer (23) to provoke back and forth of the mechanical part (64 ) while working according to his professional guidelines and also, the computing power of his computer; this example of CAD could just as well be an example of PAO, or DAO, with examples of indicative and nonlimiting examples; in all in the cases, the monolytic adapter (11) will always be installed in front of a video monitor screen, or the like; The drawing (11) highlights an example of construction with indicative and non-limiting title, combining, 4 video monitors, there could be less or more, installed horizontally, one if possible next to the other in (17), these video monitors (17) according to this drawing (ll) could be installed in multiple other ways; each video monitor wearing a monolytic adapter (11), g each enumerating two immaterial images, which, on the drawing (11) materialize aircraft ((66); in (65), the observer (23) being able to simultaneously view and control the altitude markers in (65), the miniature presence of the aircraft (66) as well as visually their respective positions in a portion spatial located above the four monolytic adapters (11) which cover the monitors (17); according to this drawing (11), this reproduction of a piece of airspace in miniature can also find independently, and, or at the same time its application for at the same time: an air control, an underwater control , and a surface control of the sea, and, or the land; everything will only be a question of adaptation and organization; each aircraft (66) of the drawing (11) in miniature, being the fruit of a coded radar signal, and corresponding to a computer database which will calculate and take the decision according to said database. computer images of aircraft corresponding to those flying in reality under the control of, or radars; this device according to this drawing (11) makes it possible to avoid in most cases the risk of collision. This device of the drawing (11) can just as easily be produced with the adapter (129) of the drawing (12); this design device (ll) could just as easily be used for multiple other applications.

5. Device according to any one of the preceding claims, characterized in that the present invention according to its monolytic adapter (11) is available in several other embodiments; whose drawings (4) and (5) show the same organization and arrangement of the stepped lenses (3), the lens (4), and also the anti-reflection and anti-radiation filtration device in (5 ) and (6) according to these drawings (4) and (5); these two said drawings (4) and (5) each comprising only one cyclic modulator with liquid crystals in (2); the latter being installed in the middle of the two lenses - the rungs (3); these two drawings (5) and (4) having only differences as the arrangement of the zones (7) and (8) of the liquid crystal cyclic modulators (2), the alternation of the opaque and translucent zones being offset so as to well explain that, according to a cycle of 25 times per second, these zones (7) and (8) change state passing alternately from opaque to translucent, then from translucent to opaque, and so on .... The zones (7) and (8) being preferably organized in a concentric manner according to the drawing (36), figure (32); the drawing (12) highlights another embodiment of the present invention according to the monolytic adapter (11) this monolytic adapter (129) according to the drawing (12) always includes the lens (4), anti-reflective and anti-radiation filtration in (5) and (6) always occupying the same places, a single modulator c clicks (2) covers the flat part of the lens (3) installed on the observer side (9), against, the position of the two lenses (3) in steps, the turns (15) of the lens (3) on the source side (10 oriented opposite the flat parts (14) of the lens (3) on the observer side (9) the lens (3) on the observer side having its turns (15), and flat parts (14) turned resolutely on the observer side (9); which will cause, during a video sequence synchronized at the speed of 25 times per second, gushing, therefore, floating immaterial net of two images in front of the screen of the adapter (129); these two images, being offset one by comparison rt to the other because of the different focal lengths of the two lenses (3). The drawing (13) highlights a step lens (128) whose characteristic is to be negative according to the technical table present in this description; thus, for an observer (23), the image of the tree 127) according to the drawing (14) will be seen clearly set back from the monitor (17); according to the drawing (15), two stepped lenses both having their turns (15) and their flat parts (l4) oriented side observer (9), and having their turns (15) offset one with respect to the other as viewed in the drawing (15), the lens (128) of this drawing (15) has a negative focal length, the lens (3) has a focal point; so that for an observer (23) according to the drawing (l6), the latter (23) will see the image of the tree (127) behind the monitor (17), and the image of the apple, immaterial (16) in front of the monolytic adapter (130) which characterizes this situation. ^' 6. Device according to claims (1), (2), (3), (4), characterized in that the drawing (17) shows a sectional view of an embodiment stripped of the base of the present invention characterized by the drawing for the abstract, the drawing (1), and therefore, the monolytic adapter (11); the adapter (108) of the drawing (17) in this simplified form does not include a cyclic modulator (2), the two stepped lenses (37) have their turns (15) in full, the lens (4) retains its place , and the anti-reflection and anti-radiation coatings in (5), and (6) are installed in the same way as on the monolytic adapters (11), (129), (131), (130), all qualities of thinness, compactness, adaptability are preserved; the focal length of the lenses (37) highlight for the observer (23) of the drawing (18) an immaterial sphere (59) with a surprising effect, the applications of which are commented on within the drawings (20, 21, 22, 23, 24, 25, 26, 27, 28, 29); the drawing (19) shows the monolytic adapter (108), installed in front of the monitor (17) which delivers only one image (47) of the immaterial apple (16) in front of the observer (23); the apple (16) of this drawing (19) appearing to the eyes of the observer (23) included in the immaterial sphere (59). 7. Device according to any one of claims from (1) to (6), characterized in that the adapter (108) of the drawings (17), (18), (19), is an embodiment stripped of the present invention which is demonstrated according to the monolytic adapter (11); this so-called monolytic adapter (108) generates, due to its construction, only one immaterial image spatially stabilized in front of the screen of the adapter (108); This monolytic adapter (108) gives av-.rι- -agely birth to a certain number of applications contained within the present description, and to titre of indicative and nonlimiting examples of which here is the list: The drawing (20) integrates the monolytic a-adapter (108) for studying the patient's eye (133) of figure (13), figures (11), and (12) show the preparation of the patient (43), advantageously, the observer (23) manipulates the articulated arm (4θ) of the adapter (108) to adjust his vision with respect to the immaterial eye (39) contained in the immaterial sphere (59) the eye (133) is illuminated by a lighting means: the lamp (llθ);

The drawing (21) shows the extrapolation of the drawing (20) in the form of an ophthalmological operation simulation using the interactive tip scalpel (38), and the transmitters (42) and receivers (45). the drawing (22) distributes through the direct display device (122) sold commercially, 4 images for indicative and non-limiting examples; identical (117), and (118), in front of ¹ each monitor (17), each capped with the adapter (108) these 4 images being included immaterially within the spheres (59). Figure (14) of the drawing (23) shows the integration of an adapter (108) in a panel for road safety (72); Figure (15) of the drawing (23) shows two integrations of the adapter (108): one in a wall, and the other in the ground in front of one observer (23). The drawing (24) shows the integration of the adapter (108) in a wall topped with a one-way mirror

(73). The drawing (25) first shows according to its figure (16) a mono- adapter lyte (108) for the immaterial time (97) in the form of dio-of the electroluminescent. The figure (17), an adapter (108) for the lid of a pan (99). The figure (18) shows an adapter (108) for a transport of ob and, the apple (16). Figure (19) shows the adapter (108) for a photo frame. The drawing (26) shows the integration of the adapter (108) in the figure (20) for child pilot (78). Figure (21) shows the integration of one adapter (108) for the oven of a stove (77) - Figure (22) shows the integration of the adapter in a scale (75). Figure (23) shows the integration of the a-adapter (108) in a table (76). The drawing (27) shows the integration of the adapter (108) in a wall figure (24) for a luminaire (87); the figure (25) and (26) shows the integration of the adapter (108) in a dishwasher in (84) figure (25, and the door of a washing machine (83). In (109), we find the information displays equipped with an adapter ( The drawing (28) shows, figure (27) the integration of the adapter (108) in a telephone handset (95) and the figure (30) in a mobile telephone (93); the figure (28) receives the adapter (108) for automotive optical signaling (90); Figure (29) incorporates the adapter (108) for ONE CD radio handset. to animate intangible luminescent leeds. The drawing (29) highlights the integration of an adapter (108) combined with a mirror (28) which before returning it to the adapter (108), receives the image of the plasma screen (113) • 8. Device according to any one of claims from (1) to (7) characterized in that the adapter (108) finds its part within a concept. Drawings: (30,31,32,33,34 , 35) bringing together the skills to deliver two interactive images to each other while offering the possibility of being possibly folding, The drawing (30) shows a video image comprising an apple (29) on a dark background, a tree (19 );the drawing

(31) receives a semi-reflecting window (26) which allows the observer (23) to see the image of the tree (19) normally, this window (26) at the same time returning the image from the apple (29) to the observer (23) in intangible mode (16) of the apple; the trajectory of the light rays of the apple (29) is returned by the mirror (28) to then pass through one adapter (108); the points (135) are articulated to allow the assembly to bend; the angle of the window (6) is 45 ^° relative to the monitor screen (17); it can be more or less; the drawing

(32) shows a view of the drawing (31) in the form of a cavity perspective; the drawing (33) shows the same mounting principle of the adapter (108) as the drawings (31) and (32) , but by highlighting three images on a dark background instead of one, and three adapter (108) instead of one; the images are: the pair of glasses (34), the apple (16) and the car (70) these three immaterial images are on the monitor screen (17): the pair of glasses (35), the apple (29 ), and the car (126) The drawing (43) shows two images on a dark background of the monitor (17): Either: the pair of glasses (35), and the apple (29); these two images of the drawing (34) are found in the drawing (35) in (16) for the apple, and in (34) for the pair of glasses; in this assembly of the drawing (35), two adapters (108) are installed: one horizontal as in the drawings (31,32,33) and the other adapter (108) integrated into the adapter chassis block (18); this said assembly of the drawing (35) allowing the observer (23) • to visualize, at a glance two intangible images between them thanks to a suitable computer program. this device can also include more than one adapter (108) installed horizontally and thus enabling more than one image to be delivered, such as the apple (16); exactly as shown in the drawing (33) in perspective perspective; 9. Device according to any one of claims from (1) to (8) charac--tèrisé in that according to a representation not embedded in the drawings accompanying this description, the space between the stepped lenses (3) may contain a neutral liquid in which metallic and electrically conductive particles circulate; this liquid might as well not be neutral; electrically conductive particles may just as well not be; this liquid can also contain phosphorescent particles; as soon as an electrical voltage is applied according to for example - a frequency of 5 times per second, the metallic particles entrain with them by searing the phosphorescent particles and, consequently consequently changing the focal length of the lenses. - pins (3). 10. Device according to any one of claims from (1) to (9) characterized in that the organization of the liquid crystal lines of the cyclic modulator (2) can be organized according to the drawing (3) in a longitudinal manner ( Figure 6), and, or, concentrically according to the drawing (36) Figure (32), or in these two ways combined together, or in any other way.