FR3016974A1 - VISUALIZATION SYSTEM - Google Patents

Abstract

The present invention consists of a display system based on a base and comprising: a transmission means capable of emitting at least one image, such as a screen or a video projector, a mirror held on the base by holding means and adapted to reflect said images transmitted by the transmitting means, - control means able to control the diffusion of the images transmitted by the transmitting means, the system being characterized in that the transmitting means is a transflective screen and or in that it furthermore comprises at least one means for limiting the viewing angle that can be arranged between the emission surface of the image transmission means and the mirror, the plane of the mirror and the plane of the transmitting surface of the transmitting means forming an angle so that the light of the reflected images is directed into the field of view of at least one user and / or at least one image sensor.

Description

TECHNICAL FIELD OF THE INVENTION The present invention relates to the field of display terminals. More particularly, the invention relates to a visualization system related to optical theaters. BACKGROUND OF THE INVENTION In a manner known per se, there are visualization systems that can be interactive, generally comprising at least one peripheral device for interactions between the terminals and the users, and a three-dimensional display device. Systems with these features most commonly used are optical theaters. Optical theaters are based on the combination of an image transmission system and a mirror, most often semi-reflective, to generate a depth effect. The optical theater consists of a screen or a video projector generally placed in the base of the optical theater, this base being placed on the ground and the emission surface of the screen or the video projector being in a horizontal plane. A semi-reflective mirror is placed at 45 ° above the screen or the projector, so that the light coming from the screen or the projector and then reflected by the mirror runs parallel to a horizontal plane, the image reflected then being in the field of vision of a user. A variant is to place the screen or the projector not in the base of the theater but above the mirror, in a cap provided for this purpose. These optical theaters are sometimes equipped with interaction means, for example a touch screen, allowing a user to control the content transmitted by the screen or the projector. However, these systems of the prior art have several drawbacks reducing the quality of the user's experience and therefore of the visualization.

The first disadvantage is the difficulty encountered in reducing the size of the theater structure, especially the headdress when the screen is included in the latter. The reduction in the thickness of the screens today goes in the direction of a thinning of the cap, but this to the detriment of the available light power. In addition, the electronics and the power supply are often deported, adding problems of implementation. A second drawback concerns mainly optical theaters whose screens are included in the cap. In order to mask the emission surface of the screen, it is necessary to force the user to look down. In other words, the problem occurs when the height of the user's eyes is below the theater's horizon: the transmitting surface of the screen then becomes visible, which of course must be avoided. Given the first and second drawback, many systems of the prior art propose to remove the cap by systematically placing the screen in the base. But a disadvantage similar to the second disadvantage appears: if the user observes the interior of the display system too high, the screen then appears to the user. A third disadvantage relates to ambient brightness, defined as the average light intensity of an environment, by definition omnidirectional. Just like for a conventional screen, it is necessary to see the projected image that its light is emitted with a luminous intensity higher than that of the ambient light. It is for this reason that the ambient lighting must be very controlled in the presence of optical theaters, especially when they do not have a cap and are therefore more exposed to ambient light. A fourth drawback concerns the brightness coming from the background. Indeed, the viewer visualizes the projected image on a semireflective glass. In order for the user to perceive most of the light coming from the reflected image, it is necessary that not only the ambient lighting be low, but also that very little light, compared with the brightness of the reflected image, come from the background of the theater, the mirror being between the spectator and the background. One solution is to completely hide the background by replacing it with a neutral element, but the disadvantage is the loss of the notion of depth induced by the vision of an environment behind the projection. GENERAL DESCRIPTION OF THE INVENTION The object of the present invention is therefore to propose a display system making it possible to overcome one or more of the disadvantages of the prior art.

The invention proposes a visualization system optimizing the visibility conditions for any user or image sensor placed in front of the system and able to record the reflected image. To this end, the invention relates to a display system based on a base and comprising: a transmission means capable of transmitting at least one image, such as a screen or a video projector; a mirror held on the base by holding means and able to reflect said images transmitted by the transmitting means; control means capable of controlling the diffusion of the images transmitted by the transmitting means; the system being characterized in that the transmitting means is a transflective screen and / or in that it further comprises at least one means for limiting the viewing angle that can be arranged between the transmitting surface of the image transmitting means and the mirror, the plane of the mirror and the plane of the transmitting surface of the transmitting means forming an angle so that the light of the reflected images is directed into the field of view of at least one user and / or at least one image sensor.

According to another feature, the display system is characterized in that the means for limiting the viewing angle is a privacy filter. According to another particularity, the display system is characterized in that the transmission means is a high brightness screen. According to another feature, the display system is characterized in that the mirror is a semi-reflective mirror. According to another feature, the display system is characterized in that the transmitting means is placed in the base of the system, the mirror being positioned above the transmission means so that the light of the reflected images are directed in the field of view of the user and / or at least one image sensor. According to another feature, the display system is characterized in that the transmitting means is disposed above the mirror.

According to another feature, the display system is characterized in that the system comprises a cap capable of covering the system. According to another feature, the display system is characterized in that the means for limiting the viewing angle reduces the viewing angle of said transmission means by a value between 10 ° and 40 ° around the median axis perpendicular to the emission surface of the emission means, preferably between 15 ° and 30 °. According to another feature, the display system is characterized in that it comprises a transparent screen capable of producing a mask of the images transmitted by the transmission means, the transparent screen being secured to the base via holding means, and arranged between the background of the system and the mirror, so that the plane of reflection of the emission surface of the emission means relative to the mirror is at most close to the plane of the surface of the transparent screen, and so that the reflected images and the mask are superimposed in the field of view of the user and / or at least one image sensor. According to another particularity, the display system is characterized in that the transparent screen is a passive screen.

According to another particularity, the display system is characterized in that the transparent screen is an emissive screen. According to another feature, the display system is characterized in that the control means are adapted to be accessible to a user to be manipulated by the user so as to interact with the image transmission device. The invention, with its features and advantages, will emerge more clearly on reading the description given with reference to the accompanying drawings in which: FIG. 1a shows a display system of the prior art with a screen in the base; Figure lb shows a prior art display system with a screen in a cap; Figures 2a and 2b show a display system according to the invention with a privacy filter; Fig. 3a shows a system according to the invention illustrating the light of the transmitted background and the light of the reflected image; FIG. 3b represents a display system according to the invention provided with a transparent screen. DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE INVENTION Referring to FIGS. 1 to 3, the invention will now be described.

In one embodiment, the display system comprises a base (1) resting on the ground. The system comprises a transmission means (2) capable of transmitting at least one image and / or at least one video. For example and in a nonlimiting manner, this transmission means (2) is a plasma type screen, LCD, or OLED. In one embodiment, the display system comprises a mirror (3) able to reflect the images and / or videos, transmitted (40) by the transmission means (2), in the field of view of a user or of a system comprising at least one image sensor. In one embodiment, so that the mirror reflects the entirety of the transmitted images (40) by the transmission means (2), said mirror (3) is larger than the transmission means. The field of vision is defined as a cone whose base is directed towards the visualization system. Preferably, the mirror (3) is semireflecting so as to allow the light of the background (60) from the bottom of the display system to be transmitted. For example and without limitation, this mirror transmits 60% and reflects 40% of the light it receives. This light of the transmitted background (61) is thus captured by the user and / or at least one image sensor at the same time as the light of the reflected images (41), which brings a notion of depth induced by viewing the environment from the background. The mirror (3) and the transmitting means (2) are oriented relative to each other so that light from the reflected image (41) is directed into the field of view of the least one user using the display system, and / or at least one image sensor placed in front of the display system. In one embodiment, when the transmission means is comprised in the base of the display system (1), the mirror (3) is held by holding means above the transmission means (2) so as to forming an angle ((3) with a plane parallel to the plane of the emission surface of the transmitting means (2), so that light from the reflected image (41) is directed to the eyes of the This angle ((3) is 45 ° in order to avoid any deformation of the reflected image (41). In one embodiment, the transmission surface of the image transmission means (2) is in a horizontal plane, and light from the reflected image (41) is directed parallel to a horizontal plane towards the user's eyes and / or the image sensors. Embodiment assumes that a user's eyes and / or image sensors are at the same height as the mirror (3) d In an alternative embodiment, the display system is inclined so that the transmitting surface of the transmitting means (2) is inclined. Thus, the light from the reflected image (41) does not run parallel to a horizontal plane. Thus, the images produced and reflected (41) by a display system whose mirror (3) is placed at a height different from the eyes of a user or at least one image sensor, will be viewed and / or recorded optimally. In an alternative embodiment, the transmitting means (2) is disposed above the mirror (3) so as to form an angle ((3 ') with a plane parallel to the plane of the transmitting surface of the medium d emission (2), so that the light from the reflected image (41) is directed towards the user's eyes and / or the image sensors, preferably this angle is 45 ° so as to The transmitting means (2) is for example covered with a cap (5) capable of covering the display system and making it possible to hide the transmission means (2) from the users and / In one embodiment, the display system comprises control means, for example computer means included in the base of the display system, able to control the broadcast of the images and / or videos transmitted. (40) by the transmitting means (2) In one embodiment, these means of control includes an interaction device adapted to be manipulated by a user of the display system, so that the user can at least partially control the broadcast of images and / or videos (40) from the transmission means (2). ). For example and in a nonlimiting manner, the interaction device comprises a touch screen allowing the display of tactile objects, such as for example and without limitation a wind rose or a circle of orientation, in order to vary the orientation of an image representing an object, a work of art, so that it can be observed from all angles.

In one embodiment, in order to facilitate the masking of the transmission means (2) of the display system, a means of limiting the viewing angle, for example and in a nonlimiting manner a confidentiality filter, is added and disposed between the surface of the transmitting means (2) and the mirror (3). This means of limiting the viewing angle makes it possible to reduce the viewing angle (a) of said transmission means. In one embodiment, the viewing angle is defined by the solid angle formed around the median axis of the transmission means (2), this median axis being perpendicular to the emission surface of the transmitting means (2). In an alternative embodiment, the viewing angle is defined by a truncated pyramid whose large base is directed into the field of view of the user and / or image sensors. Thus, beyond a certain angle depending on the characteristics of the means for limiting the viewing angle, the light emitted (40) by the transmission means (2) is drastically reduced, strongly encouraging the user to maintain his field of view in this predetermined angular window. For example and without limitation, this angle (a) is between 10 ° and 40 °, preferably between 15 ° and 30 °. In this way, the view of the user is little removed from the center of the display system, which allows him to view only the reflected image (41) by the mirror and not the images (40) directly transmitted by the transmission medium (2). Those skilled in the art also understand that for an optimal viewing experience, it is necessary that the solid viewing angle (a) of the visualization system is included in the user's field of vision and / or sensors. images. This solution of adding a means of limiting the viewing angle makes it possible to integrate the transmission means (2) in the base (1) without the user being tempted to look at the viewing system from above. , thereby preventing it from detecting said transmitting means (2). Thus, the structure of the cap (5) can then be reduced or even eliminated. In another embodiment, the transmission means (2) is a high brightness screen, the luminous intensity of the transmitted images is almost always greater than the ambient brightness. In a manner known in itself, the intensity of the light emitted by the screens most used by those skilled in the art is between 500 and 800 candelas. The high brightness screens emit light at a luminous intensity higher than 800 candelas, for example between 800 and 1000 candelas, or even well above 1000 candelas. However, these high brightness displays, which in addition require advanced and efficient cooling systems, consume a lot of energy. In an alternative embodiment, the transmission means (2) is a so-called translational screen. Transflective screens are hybrid displays that are both emissive and reflective. In addition to a backlight conferring their emissivity property, the transflective screens have mirrors allowing them to exploit the surrounding light in reflection. Thus, the light balance of these screens is such that the final brightness sent by the screen (2) is almost always higher than the incident light, from the environment. These screens are well known to those skilled in the art and are often used in places often exposed to powerful light sources, such as sunlight. The use of a transflective screen in the display system of the invention therefore makes it possible to worry less about the surrounding luminosity. In an alternative embodiment, it is possible to use a hybrid screen with high brightness, provided with mirrors allowing them to exploit the surrounding light in reflection. The visualization system then comprises a transflective screen with high brightness. Advantageously, it is possible to arrange between the emission surface of the screen (2) and the mirror a means of limiting the viewing angle, for example a privacy filter. Such an embodiment makes it possible to improve the brightness of the screen (2) while encouraging the user to direct his gaze so as to observe only the reflected image (41) by the semi-reflecting mirror (3). ) without perceiving the transmission means (2), thus optimizing the visibility conditions of the display system. In one embodiment, the display system comprises a transparent screen (7), for example integral with the base via holding means, and disposed at the bottom of the display system, that is to say that the half mirror reflector (3) is placed between the user and the transparent screen (7), so that the reflection plane (20), relative to the mirror (3), of the emission surface of the transmitting means is as close as possible to the plane of the transmitting surface of the transparent screen (7). This type of screen is known to those skilled in the art and allows the production of an image while viewing the background. In one embodiment, this screen (7) is passive and associated with a light source. This light source can be artificial, or natural. In the latter case, light from the background acts as a light source. In an alternative embodiment, this screen (7) is emissive and has its own light source. In one embodiment, this transparent screen (7) will be programmed to produce a mask (70) of non-black areas of the image and / or transmitted video (40) by the transmitting means (2). In one embodiment, the mask is a black replica of non-black areas of the image and / or transmitted video (40). In an alternative embodiment, this replica (70) is grayscale or color. The mask (70) and the reflected images (41) are superimposed in the field of view of the user and / or image sensors disposed in front of the display system, so that the image and / or the reflected video (41) has a background, the background being black, gray or colored, without being hidden behind the background. Thus, this replica (70) of the non-black areas of the image and / or the transmitted video (40) forms a dynamic mask which will be stalled, from the point of view of the user and / or the image sensors. exactly on the reflected images (41) by the semi-reflecting mirror (3). Thus, the final luminosity perceived by the user and / or at least one image sensor comes mainly from the reflected image (41), and the notion of depth induced by the vision of the light transmitted from the background is preserved, since the transparent screen (7) makes it possible to visualize, beyond the black replica, the environment located behind the semireflective mirror (3). Of course, this transparent screen (7) can be used in combination with the transflective screen (2) and / or the means of limiting the viewing angle, so as to maximize the visualization experience provided by the visualization system. The combined use of these various technical means offers synergistic technical effects contributing to solving the technical problem of optimizing the visibility conditions for any user or image sensor placed in front of the system and able to record the reflected image. . But the skilled person will keep in mind that he can use the different technical means of the invention independently of each other, depending on the environment in which the display system is located.

The present application describes various technical features and advantages with reference to the figures and / or various embodiments. Those skilled in the art will appreciate that the technical features of a given embodiment may in fact be combined with features of another embodiment unless the reverse is explicitly mentioned or it is evident that these features are incompatible. In addition, the technical features described in a given embodiment can be isolated from the other features of this mode unless the opposite is explicitly mentioned. It should be obvious to those skilled in the art that the present invention allows embodiments in many other specific forms without departing from the scope defined by the scope of the appended claims, and the invention should not be limited. to the details given above.

Claims (12)

REVENDICATIONS1. Display system resting on a base (1) and comprising: - transmission means (2) capable of emitting at least one image (40), such as a screen or a video projector, - a mirror (3) held on the base (1) by holding means and able to reflect said transmitted images (40) by the transmission means (2), - control means able to control the broadcast of the images transmitted by the transmission means, the system characterized in that the transmitting means (2) is a transflective screen and / or in that it further comprises at least one means for limiting the viewing angle (a) adapted to be disposed between the surface transmitting the image transmitting means (2) and the mirror (3), the plane of the mirror and the plane of the transmitting surface of the transmitting means (2) forming an angle ((3) of so that the light of the reflected images is directed into the field of view of at least one user and / or at least one image sensor. 2. Viewing system according to the preceding claim, characterized in that the means for limiting the viewing angle is a privacy filter. 3. Viewing system according to any one of the preceding claims, characterized in that the transmitting means (2) is a high brightness screen. 4. Viewing system according to any one of the preceding claims, characterized in that the mirror (3) is a semi-reflective mirror. 5. Viewing system according to any one of the preceding claims, characterized in that the transmitting means (2) is placed in the base (1) of the system, the mirror (3) being positioned above the transmitting means (2) so that the light from the reflected images (41) is directed into the field of view of the user and / or at least one image sensor. 6. Display system according to any one of claims 1 to 4, characterized in that the transmitting means (2) is disposed above the mirror (3). 7. Display system according to any one of the preceding claims, characterized in that the system comprises a cap (5) adapted to cover the system. 8. Viewing system according to any one of the preceding claims, characterized in that the means of limiting the viewing angle reduces the viewing angle (a) of said transmitting means by a value of between 10 ° and 40 ° around the median axis perpendicular to the emission surface of the emission means (2), preferably between 15 ° and 30 °. 9. Viewing system according to any one of the preceding claims, characterized in that it comprises a transparent screen (7) capable of producing a mask (70) images emitted by the transmitting means (2), the transparent screen (7) being secured to the base via holding means, and arranged such that the mirror (3) is between said transparent screen (7) and the user and / or the image sensors, so that the plane of reflection (20) of the emission surface of the emission means (2) relative to the mirror (3) is at most close to the plane of the surface of the transparent screen (7), and so that the reflected images (41) and the mask (70) are superimposed in the field of view of the user and / or at least one image sensor. 10. Viewing system according to the preceding claim, characterized in that the transparent screen (7) is a passive screen. 11. Display system according to claim 9, characterized in that the transparent screen (7) is an emissive screen. 12. Viewing system according to any one of the preceding claims, characterized in that the control means are adapted to be accessible to a user to be manipulated by the user so as to interact with the image transmission device (2).