Dual vision device and associated process

The dual vision device addresses the discomfort of switching between direct and additional visual information by positioning display units above the eyes, ensuring clear images and compatibility with eyeglasses through adjustable display units and diopter settings.

FR3170023A1Pending Publication Date: 2026-06-19PLTECH

Patent Information

Authority / Receiving Office
FR · FR
Patent Type
Applications
Current Assignee / Owner
PLTECH
Filing Date
2024-12-13
Publication Date
2026-06-19

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Abstract

Dual vision device and associated method The present invention relates to a dual vision device (10) capable of generating, in addition to the direct vision of a user (18), a second vision, independent of the direct vision and located in the upper part of the user's field of vision (18), the device comprising a display assembly (14) carried by a support (12), the display assembly comprising two display units (32) capable of generating the second vision in the upper part of the user's field of vision,Each display unit (32) comprises an eyepiece (36) and a screen (38) chosen such that each display unit (32) forms an image clearly viewable by a separate eye of the user (18) under the following conditions: • the support (12) is inclined such that the image formed by each display unit (32) is viewable only in the upper part of the user's (18) field of vision when the user looks up, and • the distance between the user's (18) eyes and the entrance of the eyepieces (36) is greater than or equal to a predetermined distance, the predetermined distance being chosen to allow the insertion of eyeglasses between the user's eyes and the display unit. Figure for the abstract: Figure 2,
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Description

Title of the invention: Dual vision device and associated method

[0001] The present invention relates to a dual vision device capable of generating, in addition to a user's direct vision, a second vision independent of the direct vision. The invention also relates to a method for generating the second vision.

[0002] The emergence of augmented reality devices has highlighted the possibility for a user to access visual information in addition to that provided by direct vision, also known as natural vision. Such information can lead to increased productivity at the industrial level, for example by displaying plans or technical notes, but can also be useful for video sharing or entertainment purposes.

[0003] Devices that superimpose images onto the direct line of sight have the disadvantage of not being able to display a full image legibly, due in particular to ambient light. A full image is a rectangular image in which each pixel has a non-zero opacity.

[0004] Monocular devices with a screen are known, which are placed in front of one eye, thus allowing access to additional visual information with that eye and direct vision with the other eye. However, most users of monocular devices must close one eye and keep the other open to alternate between direct vision and additional visual information, which is uncomfortable, tiring, and requires an adaptation period when switching from one vision to the other.

[0005] There are also glasses equipped with screens that display video content. However, these are generally positioned close to the user's eyes, making the device incompatible with wearing eyeglasses, for example. Yet, in order to provide clear additional visual information to the widest possible range of users, it is useful for the device to be usable in conjunction with prescription glasses.

[0006] The aim of the invention is therefore to propose a dual vision device allowing a user to switch from direct vision to additional visual information simply and more comfortably, while ensuring that the dual vision device is suitable for a user wearing eyeglasses.

[0007] To this end, the invention relates to a dual vision device capable of generating, in addition to a user's direct vision, a second vision, independent of the direct vision, the second vision being located in the upper part of the field of vision of the user so that the user only has access to the second vision by looking up, and otherwise has access to their direct vision, the device comprising:

[0008] - a support for a display assembly,

[0009] - an adjustment unit suitable for fixing and adapting the support to the user's head so that the entire display supported by the mount is only visible in the upper part of the user's field of vision when the user looks up,

[0010] - the display assembly carried by the support, the display assembly comprising two display units designed to generate the second vision in the upper part of the user's field of vision, each display unit comprising an eyepiece and a screen which are chosen so that each display unit forms an image that can be clearly viewed by a separate eye of the user under the following conditions:

[0011] • the support is inclined such that the image formed by each display unit is visible only in the upper part of the user's field of vision when the user looks up, and

[0012] • the distance between the user's eyes and the eyepiece entrance is greater or equal to a predetermined distance, the predetermined distance being chosen to allow the insertion of glasses between the user's eyes and the display unit.

[0013] According to other advantageous aspects of the invention, the dual vision device comprises one or more of the following features, taken individually or in all technically possible combinations:

[0014] - the predetermined distance is between 20 millimeters and 28 millimeters, preferably between 22 millimeters and 25 millimeters;

[0015] - the screen of each display unit has a chosen size so that the image formed by the display unit is readable without the user having to move their eyes laterally to view the edges of the image;

[0016] - each eyepiece is formed from a set of lenses joined together, preferably to minus four lenses joined together, the surface of the lens at the entrance of the eyepiece being substantially flat;

[0017] - each display unit includes a frame into which the screen is inserted and the eyepiece, the frame having a parallelepiped shape with a conical base at the entrance of the eyepiece;

[0018] - each display unit includes a frame into which are inserted the screen and the eyepiece, the frame having a border, at the entrance of the eyepiece, the thickness of which is less than or equal to 2 millimeters, in particular less than or equal to 1.4 millimeters;

[0019] - each display unit includes a frame into which the screen is inserted and the eyepiece, the frame having a diopter adjustment mechanism allowing the user to adapt the focus of each display unit;

[0020] - the support includes a closing plate with two slots in which are received the display units, the display assembly including an interpupillary adjustment mechanism mounted on the closing plate and suitable for synchronizing the movement of the two display units, the interpupillary adjustment mechanism including a rocker arm on which are mounted two connecting rods and a locking wheel for the rotation of the rocker arm, each connecting rod being fixed to a separate display unit allowing the synchronous movement of each display unit when the locking wheel is in the unlocked position;

[0021] - the two display units also include, for each housing, two tabs on either side of the closing plate designed to cover the space created by the interpupillary adjustment in order to prevent the entry of light and dust.

[0022] The invention also relates to a method for generating a vision, independent of a user's direct vision, the second vision being located in the upper part of the user's field of vision so that the user only has access to the second vision by looking up, and has access to their direct vision otherwise, the method being implemented by a dual vision device as described above, the method comprising the following steps:

[0023] - the fixing and adaptation of the support of the double vision device to the head of the user so that the entire display supported by the mount is visible only in the upper part of the user's field of vision when the user looks up, and

[0024] - the user's visualization of the second vision provided by the device of double vision in the upper part of the user's field of vision when the user looks up, and of their direct vision otherwise.

[0025] The invention will become clearer upon reading the following description, given solely by way of non-limiting example, and made with reference to the drawings in which:

[0026] [Fig-1] [Fig.1] is a schematic representation of an example of a device double vision according to the invention,

[0027] [Fig.2] [Fig.2] is a schematic perspective representation from a user's point of view which provides an example of a dual-vision device,

[0028] [Fig. 3] [Fig. 3] is a side view of the user and the dual vision device of the [Fig.2],

[0029] [Fig.4] [Fig.4] is a bottom view of the user and the double device vision of [Fig.2],

[0030] [Fig. 5] [Fig. 5] is an exploded view of an example of a double device vision,

[0031] [Fig.6] [Fig.6] is an exploded view of an example of a display unit of a dual vision device

[0032] [Fig.7] [Fig.7] is a cross-sectional view of the display units and their attachment to a support for the device shown in [Fig.2], and

[0033] [Fig.8] [Fig.8] is a bottom view of the display units and their attachment to a support of the device shown in [Fig.2].

[0034] An example of a double vision device 10 is schematically illustrated in [Fig.1].

[0035] Such a device 10 includes a support 12 for a display assembly 14, the display assembly 14 itself, and an adjustment unit 16, suitable for adapting and fixing the support 12 to the head of a user 18.

[0036] The device 10 is adapted to generate a second vision, independent of the user's natural vision 18, intended to display additional visual information compared to direct vision. The second vision is adapted to be generated via the display assembly 14, in the upper part of the user's field of vision 18. The user thus has access to the second vision only by looking up, and has access to their direct vision otherwise.

[0037] For this purpose, as will be described later in the description, the adjustment unit 16 is in particular adapted to position the support 12 relative to the user's head so that the display assembly 14 is visible in the upper part of the user's field of vision 18 when the user raises their eyes.

[0038] A spherical frame of reference is defined, centered on a virtual point located between the focal points of the user's two eyes 18. The latitude and longitude of a point in space are defined with reference to the spherical frame of reference. Latitude is defined as zero at the horizon, positive above the user's head, and negative at the user's feet 18.

[0039] A user's field of vision is defined as the extent of space that the user can scan with their gaze while remaining stationary. The upper field of vision is defined as the portion of the field of vision that the user sees when looking upwards. More specifically, the upper field of vision is considered to be the set of points with a positive latitude greater than 10° included within the user's field of vision.

[0040] The support 12 carries the display assembly 14.

[0041] With reference to [Fig. 2], the support 12 extends mainly in length along a lateral direction X, in width along a transverse direction Y, and in thickness along an elevation direction Z. When the support 12 is positioned so that the assembly display is visible in the upper part of the user's field of vision 18, the lateral direction X is substantially parallel to the axis connecting the focal points of the user's eyes 18.

[0042] The support 12, for example, has a substantially polyhedral shape, some faces of which may be curved, as shown in [Fig. 4]. Alternatively, the support 12 has an arbitrary geometric shape extending mainly along the lateral direction X.

[0043] The support is, for example, made of a material comprising carbon, for example a carbon fiber reinforced composite material.

[0044] Preferably, as illustrated in the examples in Figures 2 to 5, the support 12 comprises an upper plate 20 and a closing plate 22 connected to each other by a wall 24. The support thus defines an internal volume in which, for example, an electronic card 28 is housed. The electronic card 28 defines a data reading system and advantageously has a video data reading connector. The data reading system is intended to control the display assembly 14 to display the received data. Alternatively, the electronic card 28 receives the video data wirelessly, for example, via an antenna.

[0045] The upper plate 20 extends in a plane generated by the lateral direction X and the transverse direction Y, orthogonal to the lateral direction X. The wall 24 extends along the elevation direction Z orthogonal to the plane of the upper plate 20.

[0046] Advantageously, the closing plate 22 has two housings 29 offset from each other along the lateral direction X, opening the internal volume to the outside of the support 12.

[0047] Preferably, the closing plate 22 has a thickness, taken along the elevation direction Z, less than or equal to 1.5 mm, preferably equal to 0.9 millimeters.

[0048] The display assembly 14 is suitable for displaying images visible to the user in the upper part of his field of vision, when the user looks up.

[0049] The display assembly 14 comprises two display units 32.

[0050] As illustrated in the examples in Figures 2 to 4, the two display units 32 are offset from each other along the lateral direction X. The display units 32 are aligned along the transverse direction Y and the elevation direction Z, that is to say that the display units 32 are flush with a plane orthogonal to the transverse direction Y and / or the display units 32 are flush with a plane orthogonal to the elevation direction Z.

[0051] Each display unit 32 comprises an eyepiece 36 and a screen 38 which are chosen so that each display unit 32 forms an image that can be clearly viewed by a separate eye of the user under the following conditions: • the support 12 is inclined such that the image formed by each display unit 32 is visible only in the upper part of the user's field of vision when the user looks up, and • the distance between the user's eyes and the eyepieces 36 entrance is greater than or equal to a predetermined distance, the predetermined distance being chosen to permit the insertion of glasses between the user's eyes and the display unit 32.

[0052] The two display units 32 are therefore intended to be placed in front of the eyes of the user 18 in order to reproduce a clear image at a distance greater than or equal to the predetermined distance.

[0053] The predetermined distance is a distance that leaves enough space between an input 33 of the display units 32 and the user's eyes 18 to insert glasses, making the dual-vision device 10 usable by a majority of users. For example, the predetermined distance is between 20 millimeters and 25 millimeters, in particular between 22 millimeters and 25 millimeters.

[0054] Fig. 5 presents an exploded view of an example of a dual vision device 10, in which the support 12 and the display assembly 14, which includes the two display units 32, are distinguished.

[0055] Preferably, the display units 32 extend at least partially beyond the support 12, in the example shown, of the closing plate 22.

[0056] In the examples in Figures 5 and 6, the eyepiece 36 is placed between the input 33 of the display unit 32 and the screen 38 in the transverse direction Y.

[0057] The eyepiece 36 is preferably formed from an assembly of lenses 39 joined together, for example, four lenses. Figure 6 illustrates an assembly of lenses 39 comprising four lenses, two of which are bonded together. The surface of the lens closest, along the transverse direction Y, to the entrance of the display unit 32 is preferably substantially flat, which reduces reflections potentially generated by an external light source. Alternatively, the eyepiece 36 comprises fewer than four or more than four lenses.

[0058] The screen 38 is adapted to display an image viewable by the user 18 through the eyepiece 36.

[0059] Advantageously, the screen 38 is optimized so that the image formed by the display unit 32 is as wide as possible while being readable without the user having to move their eyes to view the edges of the image, in particular the lateral edges in the direction of the lateral X.

[0060] For example, the screen 38 has a resolution that is at least high definition, that is to say, the screen 38 has a resolution, taken along the lateral direction X, greater than or equal to 1920 pixels. Such a resolution is dimensioned for to allow the user to view, in particular, characters that would be displayed clearly on screen 38.

[0061] As an alternative or complement, the screen 38 of each display unit 32 has a rectangular shape whose diagonal is less than or equal to 10 millimeters, preferably less than or equal to 8 millimeters.

[0062] Preferably, the screen 38 is an OLED screen (organic light-emitting diode in English, organic light-emitting diode in French).

[0063] In one example of implementation, as illustrated by [Fig.5], each display unit 32 comprises an armature 40 into which the eyepiece 36 and the screen 38 are inserted.

[0064] Preferably, the frame 40 has a parallelepiped shape with a conical base at the entrance of the eyepiece 36. This allows the border 37 around the front glass forming part of the eyepiece 36 to be limited.

[0065] As an optional addition or alternative, the border 37 has a thickness around the eyepiece entrance 36 of 2 millimeters or less, in particular 1.4 millimeters or less. The thickness of the border 37 is measured along the tangent direction to the contour of the eyepiece entrance 26. The small thickness of the border 37 around the eyepiece 36 prevents the formation of black bands around the image that the user 18 is intended to view through second vision by looking up.

[0066] In an example of an embodiment, shown in [Fig.6], the entrance of the eyepiece 36 is substantially contained in a plane generated by the lateral direction X and the elevation direction Z. The thickness of the edge 37 of the frame 40 is then measured along the lateral direction X and the elevation direction Z.

[0067] Preferably, as illustrated in [Fig. 5], the frame 40 comprises an upper tab 41, located within the internal volume of the support 12, and a lower portion 42 projecting from the end plate 22 on the outside of the support 12. The upper tab 41 and the lower portion 42 of a display unit 32 are fixed to each other on either side of a recess 29. The lower portion 42 advantageously has a lower tab 43, the dimensions of which in the lateral direction X and the transverse direction Y are greater than those of the recess 29, so as to cover the recess 29. The upper tab 41 and the lower tab 43 bear against the end plate 22 of the support 12 on either side. The upper tab 41 and the lower tab 43 are intended to provide a lightproof and dustproof seal for the support 12 at the level of the 29 housing units.To this end, the lower tongue 43 has a flared shape, that is to say that its section, taken along the lateral X and transverse Y directions, widens near the closing plate 22. Preferably, the dimensions along the lateral X direction and the transverse Y direction. the dimensions of the lower tongue 43 are substantially equal to the dimensions of the upper tongue 30.

[0068] In this example, the upper tab 41 has a substantially rectangular plate shape extending mainly along a plane parallel to the plane of the closing plate 22 and whose dimensions taken along the transverse direction Y and the lateral direction X are greater than the dimensions of the housing 29, taken along the transverse direction Y and the lateral direction X.

[0069] In this example, the upper tab 41 has a protruding surface 44, which extends along the elevation direction Z. The protruding surface 44 extends along the transverse direction Y, over the entire length of the housing 29, and extends along the lateral direction X over a length shorter than that of the housing 29. The protruding surface 44 thus cooperates with the housing 29, so as to create a sliding connection along the lateral direction X. The upper tab 41 is guided in translation relative to the closing plate 22 along the lateral direction X. Preferably, the dimensions along the lateral direction X and the transverse direction Y of the lower tab 43 are equal to the dimensions of the upper tab 30.

[0070] An opening 45 is provided in the upper tongue 41, the opening 45 being placed opposite the housing 29 according to the elevation direction Z.

[0071] An example of a lower part 42 of a display unit 32 is shown in [Fig. 6]. The lower part 42 receives, in particular, the screen 38 and the eyepiece 36 and includes the input 33 of the display unit 32.

[0072] The lower part 42 has a parallelepiped shape with a conical base at the entrance of the eyepiece 38. Advantageously, the entrance of the eyepiece 36 forms the entrance 33 of the display unit 32.

[0073] In the example of [Fig.6], the lower part 42 comprises a support wall 46 orthogonal to the elevation direction Z, side walls 47 orthogonal to the lateral direction X, and an intermediate wall 48 in which a frame 49 is provided.

[0074] Preferably, the frame 49 is made of a material that allows at least some of the visible radiation to pass through, for example, polymethyl methacrylate (or PMMA, marketed under the name Plexiglas). Alternatively, the frame 49 is a simple opening in the intermediate wall 48. The frame 49 is intended to allow radiation to pass from the screen 38 to the input 33 of the display unit 32.

[0075] In one embodiment, the lower part 42 further comprises a bottom wall 45, offset from the intermediate wall 48 along the transverse direction Y. The side walls 47 and the bottom wall 50 are connected to each other by the lower tongue 43 which projects from the upper end, taken along the elevation direction Z, of the side walls 47 and the bottom wall. 50. A space is formed between the bottom wall 50 and the intermediate wall 48. Protrusions 52 extend from the side walls 47, and are intended to be fixed to the upper tongue 41, by means of fixing.

[0076] In this example, the frame 40 also includes a housing 51 for receiving and fixing the eyepiece 36. The housing 51 is parallelepiped in shape and is received in the lower part 42. The housing 51 has two faces orthogonal to the transverse direction Y, the two faces being open so as to allow light to pass over the entire transverse length of the housing 51. The housing 51 has, at its transverse end furthest from the bottom wall 50, a conical shape, which gives the display unit 32 its conical shape.

[0077] In this example, the screen 38 is received in a heat sink 56 of the lower part 42, the heat sink 56 being positioned between the bottom wall 50 and the intermediate wall 48. The heat sink 56 is advantageously sized to fill the space formed between the bottom wall 50 and the intermediate wall 48. The heat sink 56 also has fastening means enabling it to be secured to the upper tab 4L

[0078] Preferably, the radiator 56 is made of a thermally conductive material, for example aluminium or copper, to dissipate the heat emitted by the screen 38.

[0079] In this example, the radiator 56 is a plate in which a receiving recess 58 is provided, into which the screen 38 is received. The receiving recess 58 extends in a plane orthogonal to the transverse direction Y. The radiator 56 is in contact, on the side opposite the receiving recess 58, with the bottom wall 50 via spacers 60. The spacers 60 create a gap between the bottom wall 50 and the radiator 56. The radiator also has a through opening 62, passing through the radiator in the transverse direction Y.

[0080] In this example, the screen 38 is attached to a wound strip 70 extending from a lateral edge of the screen 38. The strip 70 has a first portion 71 with windings along the vertical direction Z and a second portion 72 in which the windings are oriented along the lateral direction X. The strip 70 passes through the through-hole 62, extending into the space between the bottom wall 50 and the heat sink 56. The second portion 72 of the strip 70 passes through the opening 45 of the upper tab 41 and is located at least partially within the internal volume of the support 12. The strip 70 is intended, in particular, to provide the electrical connection between the electronic board 28 and the screen 38. The strip 70 may, for example, consist of a cable bundle to connect the screen 38 to the electronic board. 28.

[0081] An optical path is thus provided in each display unit 32 between the screen 38 and the input 33 of the display unit 32. The optical path passes through the frame 49 and the eyepiece 36 and allows the user 18 to view the image formed on the screen 38 with appropriate magnification allowing the entire image to be viewed without having to move the eyes.

[0082] Advantageously, the armature 40 also features a diopter adjustment mechanism 74 allowing the user to adjust the focus of each display unit 32.

[0083] The diopter adjustment mechanism 74 visible in [Fig.8] allows the position of the eyepiece 36 in the lower part 42 to be adjusted according to the transverse direction Y. Thus, the user 18 can focus on each display unit 32 adapted to each eye.

[0084] In the example shown, the diopter adjustment mechanism 74 allows the housing 51, which receives the eyepiece 36, to be moved transversely relative to the screen 38.

[0085] In this example, the diopter adjustment mechanism 74 comprises a diagonal groove 75, a lateral groove 76, and an adjustment pin 77 that cooperates with the diagonal groove 75 and the lateral groove 76. The diagonal groove 75 is a through groove not parallel to the lateral direction X and the transverse direction Y and is formed in the support wall 46. The lateral groove 76 is formed in a face of the housing 51 and is parallel to the lateral direction X. The adjustment pin 77 is inserted into the lateral groove 76 and into the diagonal groove 75, so as to pass through the support wall 46. The adjustment pin 77 is accessible to the user 18 from outside the display unit 32. The movement of the adjustment pin 77 in the diagonal groove 75 generates a force in the lateral direction X and the transverse direction Y.As the adjusting pin 77 is also inserted in the lateral groove 76, the adjusting pin 77 moves along the lateral direction X and the force along the transverse direction Y causes the housing 51 to move along the transverse direction Y.

[0086] Advantageously, the display assembly 14 includes an interpupillary adjustment mechanism 78 for moving the two display units 32 synchronously along the lateral direction X. The interpupillary adjustment mechanism 78 is designed to adjust the spacing, along the lateral direction X, between the two display units 32 to adapt to the interpupillary distance of the user 18, i.e., the distance between their eyes.

[0087] In the example shown, the interpupillary adjustment mechanism 78 is intended to ensure the symmetry of the display units 32 with respect to a plane of symmetry orthogonal to the lateral direction X.

[0088] Preferably, the interpupillary adjustment mechanism 78 also ensures parallelism between the display units 32, by ensuring that the display units 32 are flush on a plane orthogonal to the transverse direction Y and / or on a plane orthogonal to the Z elevation direction when the 32 display units are moved along the lateral X direction.

[0089] In an example of an embodiment shown in particular in [Fig.4], the inputs 33 of the display units 32 are thus included in the same plane, in particular when moving the display units 32 along the lateral direction X by means of the interpupillary adjustment mechanism 78.

[0090] The interpupillary adjustment mechanism 78 is mounted on the closing plate 22 of the support 12.

[0091] In particular, the interpupillary adjustment mechanism 78 is linked to the upper tab 41 of each display unit 32, thus enabling the tabs to cover the space induced by the interpupillary adjustment so as to prevent the entry of light and dust.

[0092] With reference to [Fig.7], the interpupillary adjustment mechanism 78 comprises a rudder 80, mounted movable in rotation about a rudder axis parallel to the elevation direction Z. The rudder 80 has two ends which are provided at an equidistance from the axis of rotation of the rudder 80.

[0093] The rocker arm 80 is rotationally linked, at each of its ends, to a connecting rod 82. Each connecting rod 82 is mounted to rotate freely relative to the upper tab 41 of one of the two display units 32.

[0094] The rotation of the rocker arm causes the connecting rods 82 linked to the upper parts 41 of the display units 16 to move. The movement of the connecting rods 82 generates a force at the insertion of the connecting rods 82 and the upper tabs 41, the force generated having at least one component along the lateral direction X. Since the upper parts 41 are movable in translation relative to the support 12 along the lateral direction X, the rotation of the rocker arm 80 implies a symmetrical displacement of the upper tabs 30, relative to the axis of rotation of the rocker arm 80.

[0095] In addition, the interpupillary adjustment mechanism 78 can be locked, so that an interpupillary adjustment suitable for the user is not inadvertently deregulated, for example by manipulating the double vision device 10.

[0096] As can be seen in [Fig. 8], the adjustment mechanism includes a locking screw 83 whose head forms a locking knurled 84, helically connected to a nut 86 of the adjustment mechanism. The nut 86 is disposed in a suitable recess in the rocker arm 80, visible in particular in [Fig. 7], and the locking screw 83 acts as a shaft for the rotation of the rocker arm 80 relative to the support 12.

[0097] The locking knob 84 is rotatable between an unlocked position, in which the rocker arm 80 is rotatable about the rocker arm axis relative to support 12, and a locked position in which the rocker arm is immobile in rotation relative to support 12.

[0098] In the locked position, the locking knob 84 rests on the closing plate 22 of the support 12, and the bolted connection between the locking screw 83 and the nut 86 generates a clamping force along the elevation direction Z which blocks the rotation of the rocker arm 86 around the rocker arm axis.

[0099] In the unlocked position, the locking wheel is not in contact with the closing plate 22 of the support 12, the bolted connection does not apply clamping force on the rocker arm 80 whose rotation around the rocker arm axis is free.

[0100] The locking wheel 84 allows the distance between the two display units 32 to be locked according to the lateral direction X, and thus to adapt to the interpupillary distance of the user.

[0101] The adjustment unit 16 is configured to fix and adapt the support 12 to the head of the user 18 in at least one operating position. In at least one operating position, the display assembly 14 is located in the upper part of the user 18's field of vision, at a latitude of at least 15°, as shown in [Fig. 3]. In at least one operating position of the support 12, the user can view images, including video content, via the display units 32 by looking up.

[0102] Figure 2 represents a dual vision device 10 in which the support 12 is positioned relative to a user in an operating position. The user has access to a second vision provided by the two display units 32, and the distance between the inputs 33 of the display units 32 and the user's eyes is large enough to accommodate, in particular, glasses.

[0103] The user shown in [Fig.2] can thus switch from direct vision to the second vision provided by the double vision device 10 only by raising his eyes, that is to say by orienting the direction of his optical axis to a latitude of 15°.

[0104] The adjustment unit 16 is articulated so as to be able to adjust the latitude of the support 12 with respect to the user and / or the distance of the inputs 33 of the display units 32 from the eyes of the user.

[0105] In one embodiment, the adjustment unit 16 comprises an attachment plate 90, intended to be positioned on the user's forehead, a support plate 92 fixed to the support 12, and a joint system 94 connecting the attachment plate 90 and the support plate 92. The joint system allows at least one degree of freedom of the support 12 in a profile plane orthogonal to the lateral direction X.

[0106] Preferably, the adjustment unit 16 has three degrees of freedom in the profile plane P, in particular by being articulated by three pivot joints in the lateral direction X, as shown in [Fig.3]. Alternatively, the adjustment unit 16 is articulated by two pivot joints along the lateral direction X.

[0107] The attachment plate 90 is provided with a fastening mechanism (not shown), allowing the attachment plate 90 to be secured to the head of the user 18. The fastening mechanism includes, for example, elastic bands or a helmet.

[0108] Alternatively, the attachment plate 90 has another shape, for example adapted to be positioned on a helmet.

[0109] Figure 3 shows the field of vision of the user wearing the dual vision device 10 in the operating position as a function of latitude. A direct vision zone 98 is distinguished, in which the user 18 sees naturally, and an obstructed vision zone 99 by the device 10. The height, measured along the elevation direction Z, of the support 12 and the display assembly 14 is advantageously less than 50 mm, preferably less than 30 mm, to ensure that the obstructed vision zone 99 remains small compared to the direct vision zone 98.

[0110] In addition, as illustrated in [Fig.4], the conical shape at the input of each display unit 32 reduces the size of the obstructed viewing areas 99.

[0111] An example of the operation of the double vision device 10 will now be described.

[0112] A user wishing to use the double vision device 10 positions the attachment plate 90 of the adjustment unit 16 on their forehead and uses the fastening system to secure the double vision device 10 to their head. The user then adjusts the support 12 of the vision device so as to position the display units 32 opposite their eyes in the operating position. The support 12 is then in the upper position of the user's field of vision, with the display units 32 at the predetermined distance from the user's eyes.

[0113] Consequently, the user provides a video data stream to the dual vision device 10 via the data reading system of the electronic card 28. The video data stream read by the electronic card is then transcribed onto the screens 38 of the display units 32.

[0114] User 18 then wishes to adjust the interpupillary distance to suit their vision. They therefore rotate the locking knob 84 to the unlocked position. The user then applies a force in the lateral direction X and moves the display units in the lateral direction X, symmetrically to the axis of the control arm. Once the interpupillary distance is correctly set, the user moves the locking knob 84 to the locked position.

[0115] By looking up at the adjustment units 32, the user views the video data stream displayed on the screens 38.

[0116] If the image is not clearly visible, the user uses the diopter adjustment mechanism 74 to adjust the focal length of the eyepiece 36 so that the image is visible. The user then closes one eye and grasps the adjustment pin 77 to move the eyepiece 36 and focus. Once the first display unit 32 is adjusted, the user adjusts the second display unit 32 in a similar manner.

[0117] Thus, the dual vision device 10 allows the user 18 to switch from a direct vision zone to a second vision zone, displaying the input video data stream, simply by looking in the upper part of his field of vision.

[0118] In addition, the interpupillary adjustment mechanism 78 and the diopter adjustment mechanism 74 make the double vision device 10 adaptable to a large number of users.

[0119] Finally, the distance between the display units 32 and the eyes of the user 18 is large enough for the user 18 to have access to second vision while wearing glasses.

[0120] A person skilled in the art will understand that the embodiments and variants described above can be combined to form new embodiments provided that they are technically compatible.

Claims

Demands

1. A dual vision device (10) adapted to generate, in addition to the direct vision of a user (18), a second vision, independent of the direct vision, the second vision being located in the upper part of the user's (18) field of vision so that the user (18) has access to the second vision only by raising their eyes, and has access to their direct vision otherwise, the device comprising: - a support (12) for a display assembly (14), - an adjustment unit (16) adapted to fix and adapt the support (12) to the head of the user (18) so that the display assembly (14) carried by the support (12) is viewable only in the upper part of the user's (18) field of vision when the user raises their eyes, - the display assembly (14) carried by the support (12),the display assembly (14) comprising two display units (32) adapted to generate the second vision in the upper part of the user's field of vision, each display unit (32) comprising an eyepiece (36) and a screen (38) which are chosen such that each display unit (32) forms an image clearly viewable by a separate eye of the user (18) under the following conditions: • the support (12) is inclined such that the image formed by each display unit (32) is viewable only in the upper part of the user's (18) field of vision when the user looks up, and • the distance between the user's (18) eyes and the entrance of the eyepieces (36) is greater than or equal to a predetermined distance, the predetermined distance being chosen to allow the insertion of glasses between the user's (18) eyes and the display unit (32).

2. A dual vision device (10) according to claim 1, wherein the predetermined distance is between 20 millimeters and 28 millimeters, preferably between 22 millimeters and 25 millimeters.

3. Dual vision device (10) according to claim 1 or 2, wherein the screen (38) of each display unit (32) has a size chosen so that the image formed by the display unit (32) is readable without the user having to move their eyes laterally to view the edges of the image.

4. A double vision device (10) according to any one of claims 1 to 3, wherein each eyepiece is formed of an assembly of lenses (39) joined together, preferably at least four lenses joined together, the surface of the lens at the entrance of the eyepiece (36) being substantially flat.

5. Dual vision device (10) according to any one of claims 1 to 4, wherein each display unit (32) comprises a frame (40) into which the screen (38) and the eyepiece (36) are inserted, the frame (40) having a parallelepiped shape with a conical base at the entrance of the eyepiece (36).

6. Dual vision device (10) according to any one of claims 1 to 5, wherein each display unit (32) comprises a frame (40) into which the screen (38) and the eyepiece (36) are inserted, the frame (40) having a border (37), at the entrance of the eyepiece (36), the thickness of which is less than or equal to 2 millimeters, in particular less than or equal to 1.4 millimeters.

7. Dual vision device (10) according to any one of claims 1 to 6, wherein each display unit (32) comprises a frame (40) into which the screen (38) and the eyepiece (36) are inserted, the frame (40) having a diopter adjustment mechanism (43) enabling the user to adjust the focus of each display unit (32).

8. A dual vision device (10) according to any one of claims 1 to 7, wherein the support comprises a closing plate (22) with two housings (29) in which the display units (32) are received, the display assembly (14) comprising an interpupillary adjustment mechanism (78) mounted on the closing plate (22) and adapted to synchronize the movement of the two display units (32), the interpupillary adjustment mechanism (78) comprising a rocker arm (80) on which two are mounted connecting rods (82) and a locking wheel (84) for the rotation of the rocker arm (80), each connecting rod (82) being attached to a separate display unit (32) allowing synchronous movement of each display unit (32) when the locking wheel (84) is in the unlocked position.

9. Dual vision device (10) according to claim 8, wherein the two display units (32) also include for each housing two tabs (41, 43) on either side of the closing plate (22) adapted to cover the space induced by the interpupillary adjustment so as to prevent the entry of light and dust.

10. A method for generating a second vision, independent of a user's direct vision (18), the second vision being located in the upper part of the user's field of vision (18) such that the user (18) has access to the second vision only by looking up, and has access to their direct vision otherwise, the method being implemented by a dual vision device (10) according to any one of claims 1 to 9, the method comprising the following steps: - the fixing and adaptation of the support (10) of the dual vision device (10) to the user's head so that the display assembly (14) carried by the support (12) is viewable only in the upper part of the user's field of vision when the user raises their eyes, and - the user's viewing of the second vision provided by the dual vision device (10) in the upper part of the user's field of vision when the user raises their eyes, and of their direct vision otherwise.