DE102017223273B4 - Projection device comprising a hologram, and method - Google Patents

Abstract

Projection device (22), in particular for a vehicle, wherein the projection device (22) has an image generation device (30) for generating at least two image representations, namely a first image representation for representing a two-dimensional image representation and a second image representation for representing a three-dimensional image representation, wherein the projection device (22) has a hologram (40) for deflecting the light rays (28, 70) of the at least two image representations and wherein the hologram (40) of the projection device (22) has a first optical function for deflecting the first image representation and wherein the hologram (40) has a second optical function for deflecting the second image representation independently of the deflection of the first image representation, and wherein the second optical function of the hologram (40) is designed as a holographic micro-lens array for deflecting the second image representation to display the three-dimensional image representation.

Description

State of the art

The invention relates to a projection device comprising a hologram.

From the EN 10 2011 075 884 A1 A display device, in particular a head-up display, is known, with a light-emitting image source, with optical elements that form a beam path for beams. The optical elements comprise a holographic optical element with a predetermined optical imaging function and a reflector.

From the DE 20 2014 003 241 U1 A projection device is known which has an image generation device for generating at least two image representations. This also enables a representation of flat and three-dimensional images. The projection device has a hologram for deflecting the light rays from at least two image representations, wherein the hologram has at least two optical functions for deflecting the at least two image representations independently of one another.

Disclosure of the invention

A projection device is proposed, in particular for a motor vehicle, wherein the projection device has an image generation device for generating at least two image representations, in particular a first image representation for representing a two-dimensional image representation and a second image representation for representing a three-dimensional image representation. Furthermore, the projection device has a hologram for deflecting the light rays of the at least two image representations, wherein the hologram of the projection device has at least two optical functions for deflecting the at least two image representations independently of one another.

A vehicle, for example a motor vehicle, can have a projection device. The projection device can be designed, for example, as a head-up display, whereby information is displayed in a field of vision of an occupant of the vehicle, in particular of an observer, preferably in the direction of travel of the vehicle behind the windshield. The projection device can in particular have a hologram, wherein a hologram is an element with holographic optical properties.

The advantage of the present invention is that the two independently redirected or deflected image representations are directed to a viewer. This advantageously allows a viewer to see two independent image representations on a virtual screen in front of the vehicle. Advantageously, a two-dimensional representation and a three-dimensional representation can be shown either one after the other or simultaneously, whereby the two-dimensional representation and the three-dimensional representation can be deflected accordingly, in particular by means of a production device using a hologram. The use of a hologram can in particular save installation space. A viewer can advantageously perceive the information shown reliably. This can preferably reduce or minimize fatigue and/or irritation of the viewer.

A further advantage is that short switching times and/or multiple repetition rates can be enabled. Furthermore, multiple optical functions can be enabled. Furthermore, effort, such as costs, can be saved by using a hologram.

The hologram has a first optical function for deflecting the first image representation and a second optical function for deflecting the second image representation independently of the deflection of the first image representation. In this way, in particular the at least two image representations can be deflected independently of one another, whereby, for example, two image representations can be displayed independently of one another, in particular a two-dimensional image representation and/or a three-dimensional image representation. By using a corresponding hologram, installation space can advantageously be saved, since the optical functions can be incorporated on a hologram.

In an advantageous embodiment, the first optical function of the hologram is designed as a scattering function for deflecting and/or scattering the first image representation to display the two-dimensional image representation. This can in particular ensure that the first image representation is displayed as a two-dimensional image representation for a viewer. By using a corresponding hologram, installation space can advantageously be saved.

According to the invention, the second optical function of the hologram is designed as a holographic micro-lens array, or MLA, for deflecting the second image representation to display the three-dimensional image representation. It can be ensured that the second image representation in particular can be reliably displayed as a three-dimensional image representation. By using a corresponding hologram, installation space can advantageously be saved. Furthermore, several optical functions can be made possible by, for example, printed MLAs.

In an advantageous embodiment, the hologram is designed as a transmission hologram and/or as a reflection hologram. By using a corresponding hologram, installation space can advantageously be saved.

Furthermore, the hologram can be designed as a multiplex hologram, for example. By using a multiplex hologram, several optical functions can be made possible by means of a hologram, whereby at least two images are redirected independently of one another and thus displayed for a viewer. Furthermore, installation space can be saved in particular. In a further development, the optical functions can each be incorporated in a layer, whereby the layers can be brought together to form a hologram.

Furthermore, the projection device can have at least one imaging optics for aligning one or more of the at least two image representations. As a result, the at least two image representations can be aligned and/or deflected and/or redirected and/or reflected accordingly by at least one imaging optics of the projection device. This can save installation space in particular.

In an advantageous embodiment, the hologram is angle-selective, whereby the at least two image representations impinge on a first side of the hologram from different directions in order to deflect the at least two image representations independently of one another. This ensures that at least two image representations can be deflected or redirected independently of one another by using the hologram. This allows, for example, two image representations to be shown to a viewer independently of one another. By using a corresponding hologram, installation space can preferably be saved.

In an exemplary embodiment, the image generation device has at least two image generation units, wherein the at least two image representations are each generated by means of the two image generation units. This can ensure that the two image representations, in particular a first image representation for representing a two-dimensional image and a second image representation for representing a three-dimensional image, can each be reliably represented one after the other or simultaneously, wherein the at least two image representations can be represented and/or generated independently of one another.

In a further development, the image generation device can have an image generation unit for generating the first image representation and/or the second image representation, wherein the image generation device and/or the image generation unit and/or an imaging optics of the projection device can be moved in a defined manner such that the light rays of the at least two image representations impinge on a first side of the hologram from different directions. By using an image generation unit for generating at least two image representations, installation space can be saved in particular. Furthermore, a reliable representation of the two image representations can be ensured.

Furthermore, the hologram can be wavelength-selective, whereby in order to deflect the at least two image representations independently of one another, the at least two image representations are generated using light beams with different wavelengths and impinge on a first side of the hologram. In particular, light beams can be deflected independently of one another depending on their wavelength, whereby, for example, at least two image representations can be displayed independently of one another. By using a corresponding hologram, installation space can advantageously be saved.

In a further embodiment, the image generation device has a laser projector, wherein the laser projector has at least two laser units for generating the at least two image representations and wherein the at least two laser units emit light beams with different wavelengths. The use of a laser ensures in particular that light beams with defined different wavelengths can be generated. Furthermore, installation space can preferably be saved and image representations can be displayed safely for a viewer. Preferably, a laser unit has in particular three laser sources, wherein the three laser sources emit light beams in three primary colors, in particular red, green and blue, with different wavelengths.

In a further development, the hologram can be polarization-selective, whereby in order to deflect the at least two image representations independently of one another, the at least two image representations are generated using light beams with different polarizations and impinge on a first side of the hologram. This can ensure that at least two image representations can be deflected independently of one another using the hologram. This can, for example, show a viewer at least two image representations independently of one another. By using a corresponding hologram, installation space can preferably be saved.

• Erzeugen einer ersten Bilddarstellung und/oder einer zweiten Bilddarstellung mittels einer Bilderzeugungsvorrichtung einer Projektionsvorrichtung, wobei mittels der Bilderzeugungsvorrichtung eine erste Bilddarstellung zur Darstellung einer zweidimensionalen Bilddarstellung und/oder eine zweite Bilddarstellung zur Darstellung einer dreidimensionalen Bilddarstellung erzeugt wird,

Furthermore, a method for displaying image representations for a viewer is proposed, comprising the following steps:

• Generating a first image representation and/or a second image representation by means of an image generation device of a projection device, wherein a first image representation for representing a two-dimensional image representation and/or a second image representation for representing a three-dimensional image representation is generated by means of the image generation device,

Deflecting the light rays of the image representation by means of a hologram of the projection device, wherein the hologram of the projection device has at least two optical functions for deflecting the first image representation and the second image representation independently of one another,
wherein the second optical function of the hologram (40) is designed as a holographic micro-lens array for deflecting the second image representation to display the three-dimensional image representation,
Displaying the first image representation as a first virtual image and/or displaying the second image representation as a second virtual image.

This advantageously ensures that the two independently redirected image representations are directed to a viewer. This allows a viewer to be shown at least two independent image representations, in particular a first two-dimensional image representation and/or a second three-dimensional image representation, on a virtual screen in front of the vehicle or in the direction of travel behind the windshield of a vehicle. The use of a hologram can in particular save installation space. A viewer can advantageously perceive the information displayed safely.

In a further development, the hologram can be used to deflect the first image representation using a first optical function of the hologram and the second image representation using a second optical function of the hologram, independently of the deflection of the first image representation. In this way, in particular the at least two image representations can be deflected independently of one another, whereby, for example, two image representations can be displayed independently of one another, in particular a two-dimensional image representation and/or a three-dimensional image representation. By using a corresponding hologram, installation space can advantageously be saved.

Short description of the drawings

• 1 eine schematische Darstellung eines Fahrzeugs mit einer Projektionsvorrichtung gemäß eines Ausführungsbeispiels der vorliegenden Erfindung;
• 2 eine schematische Darstellung eines Fahrzeugs mit einer Projektionsvorrichtung gemäß eines Ausführungsbeispiels der vorliegenden Erfindung;
• 3 eine schematische Darstellung einer Projektionsvorrichtung gemäß eines Ausführungsbeispiels der vorliegenden Erfindung;
• 4 eine schematische Darstellung einer Projektionsvorrichtung gemäß eines Ausführungsbeispiels der vorliegenden Erfindung;
• 5 eine schematische Darstellung einer Projektionsvorrichtung gemäß eines Ausführungsbeispiels der vorliegenden Erfindung;
• 6 eine schematische Darstellung von Eyeboxen gemäß eines Ausführungsbeispiels der vorliegenden Erfindung;
• 7 ein Verfahren gemäß eines Ausführungsbeispiels der vorliegenden Erfindung;
• 8 eine schematische Darstellung eines Hologramms gemäß eines Ausführungsbeispiels der vorliegenden Erfindung;
• 9 eine schematische Darstellung eines Hologramms gemäß eines Ausführungsbeispiels der vorliegenden Erfindung;
• 10 eine schematische Darstellung eines Hologramms gemäß eines Ausführungsbeispiels der vorliegenden Erfindung;
• 11 eine schematische Darstellung einer Projektionsvorrichtung gemäß eines Ausführungsbeispiels der vorliegenden Erfindung;
• 12 eine schematische Darstellung einer Bilderzeugungsvorrichtung gemäß eines Ausführungsbeispiels der vorliegenden Erfindung;
• 13 eine schematische Darstellung einer Bilderzeugungsvorrichtung gemäß eines Ausführungsbeispiels der vorliegenden Erfindung;
• 14 eine schematische Darstellung eines Diagramms gemäß eines Ausführungsbeispiels der vorliegenden Erfindung;
• 15 eine schematische Darstellung eines Diagramms gemäß eines Ausführungsbeispiels der vorliegenden Erfindung.

Embodiments of the invention are shown in the drawings and explained in more detail in the following descriptions. The same reference numerals are used for the elements shown in the various figures and which have a similar effect, and a repeated description of the elements is omitted. They show:

• 1 a schematic representation of a vehicle with a projection device according to an embodiment of the present invention;
• 2 a schematic representation of a vehicle with a projection device according to an embodiment of the present invention;
• 3 a schematic representation of a projection device according to an embodiment of the present invention;
• 4 a schematic representation of a projection device according to an embodiment of the present invention;
• 5 a schematic representation of a projection device according to an embodiment of the present invention;
• 6 a schematic representation of eyeboxes according to an embodiment of the present invention;
• 7 a method according to an embodiment of the present invention;
• 8 a schematic representation of a hologram according to an embodiment of the present invention;
• 9 a schematic representation of a hologram according to an embodiment of the present invention;
• 10 a schematic representation of a hologram according to an embodiment of the present invention;
• 11 a schematic representation of a projection device according to an embodiment of the present invention;
• 12 a schematic representation of an image forming apparatus according to an embodiment of the present invention;
• 13 a schematic representation of an image forming apparatus according to an embodiment of the present invention;
• 14 a schematic representation of a diagram according to an embodiment of the present invention;
• 15 a schematic representation of a diagram according to an embodiment of the present invention.

Embodiments of the invention:

1 shows a schematic representation of a top view of a vehicle 20, for example a motor vehicle, for example a car, with a projection device 22, wherein the projection device 22 can be designed as a head-up display or HUD. The projection device 22 can alternatively also be referred to as a display device. The projection device 22 is arranged in the vehicle 20 such that a viewer 24 can view the image representations projected by means of the projection device 22, wherein the projection device 22 can output information to the viewer 24. A viewer 24 can in particular be a driver 24 of the vehicle 20. The information output can be, for example, information about the vehicle condition, such as the speed, the rpm display and/or the fuel level, and/or information about navigation instructions and/or information from driving safety systems and/or information or representations from an entertainment system.

2 shows a part of a vehicle 20 with a projection device 22. The vehicle 20 is operated by a driver 24. In this embodiment, the projection device 22 is designed like a head-up display. The projection device 22 is designed to display an image visible to the driver 24 on a virtual screen 26 in a field of vision of the driver 24, wherein the virtual screen appears to float in the environment. The projection device 22 comprises an image generating device 30, for example a picture generating unit (PGU), and at least one optical device 32, for example a HUD optics with, for example, at least one mirror. The image generation device 30 comprises in particular at least one image generation unit 33, for example a laser projector, and a projection surface 38, wherein the at least one image generation unit 33 emits light rays 28 in the direction of the projection surface 38, wherein image representations are created or displayed on the projection surface 38 by means of the light rays 28. The light rays 28 of the image representations are emitted from the projection surface 38 and can subsequently be mirrored, reflected, deflected and/or diffracted by the optics 32. The light rays 28 mirrored, reflected, deflected and/or diffracted by means of the optics 32 are projected onto a windshield 34 of the vehicle 20 or a combiner. The light rays 28 are reflected in the direction of the viewer 24 on the windshield 34 of the vehicle 20 or the combiner. An image thus appears to a viewer 24 on a virtual, floating screen 26 in front of the vehicle 20, with the virtual screen 26 being located in front of the vehicle 20 or, in the direction of travel, behind the windshield 34 of the vehicle 20. A combiner can be arranged, for example, in front of the windshield 34 in the interior of the vehicle 20. The image can be superimposed with the environment of the vehicle 20 and can display information corresponding to the information from 1 , to the driver 24 or the viewer. Using a head-up display, the information can be superimposed on the environment, so that the viewer 24 can continue to see the environment or quickly focus on the traffic again.

3 shows a projection device 22 according to the projection device 22 in a vehicle 20 according to 2 . The projection device 22 comprises, among other things, an image generation device 30 for generating light beams 28 for generating at least two image representations, in particular a first image representation for representing a two-dimensional image representation and a second image representation for representing a three-dimensional image representation. In a further development, the image generation device 30 can have an image generation unit 33 for emitting light beams 28, for example a laser projector with three laser sources for emitting light beams or laser beams in three primary colors, in particular red, green and blue. In another embodiment, the image generation device 30 can also have several, for example two, image generation units 33. Furthermore, the image generation device 30 comprises a projection surface for displaying an image representation by means of the light beams 28. The at least one image generation unit 33 emits light beams 28 in the direction of the projection surface, with the Projection surface by means of the light rays 28 images are created or displayed. The light rays 28 of the images are emitted or radiated from the projection surface.

The projection device 22 also has an imaging optics 32 for aligning the image display. The imaging optics 32 can in particular comprise one or more free-form surfaces and/or mirrors. Furthermore, in a further development, the image generation device 30 and/or the image generation unit 33 and/or the imaging optics 32 can be moved and/or pivoted in a defined manner. Advantageously, one or more free-form surfaces and/or mirrors of the imaging optics 32 can be moved and/or pivoted in a defined manner. The movement and/or pivoting of the image generation unit 30 and/or the imaging optics 32 can advantageously be generated by means of a motor and/or, for example, by means of the defined movement of micromirrors. In this embodiment, the image generation device 30 and the imaging optics 32 are arranged in a housing 31, in particular arranged in such a way that the light beams 28 generated by means of the image generation device 30 or the image representations shown on the projection surface are directed via the imaging optics 32 in the direction of the windshield or in the direction of a combiner and/or in the direction of a hologram.

The projection device 22 according to 3 further comprises a hologram 40 for deflecting and/or redirecting and/or diffracting and/or reflecting the light rays 28. The hologram 40 can advantageously be designed as a volume hologram.

In this embodiment, the hologram 40 is part of the image generation device 30. Furthermore, the hologram 40 can be part of a projection surface 38 or the hologram 40 can be integrated into the projection surface 38. In other words, the projection surface can be designed as a holographic projection surface 40, with the image representations being created on the holographic projection surface 40. The holographic projection surface 40 or the hologram 40 is advantageously arranged in the beam path of the light beams 28, in particular in the vicinity of the image generation unit in the image generation device 30.

In one embodiment, the hologram 40 or the holographic projection surface 40 of the projection device 22 has a first side 41, wherein the light rays 28 impinge on the first side 41 of the hologram 40 of the projection device 22. The hologram 40 of the projection device 22 can have at least two optical functions for the independent deflection and/or redirection and/or diffraction and/or reflection of the light rays 28 of the at least two image representations. The image generation device 30 and the imaging optics 32 are arranged in this embodiment such that the light rays 28 generated by means of the image generation device 30 are directed via the imaging optics 32 onto the hologram or onto the first side 41 of the hologram 40.

The hologram 40 can preferably have a first optical function for deflecting the first image representation, in particular for displaying a two-dimensional image representation, and a second optical function for deflecting the second image representation, in particular for displaying a three-dimensional image representation, independently of the deflection of the first image representation. In other words, the two image representations generated by the image generation device 30, in this embodiment in particular by means of an image generation unit 33, can be deflected by means of the hologram, wherein the first image representation is preferably deflected to display a two-dimensional image representation by means of a first optical function of the hologram 40, and wherein the second image representation is preferably deflected to display a three-dimensional image representation by means of a second optical function of the hologram 40.

In a further development, the first optical function of the hologram 40 can be designed as a scattering function for deflecting and/or scattering the first image representation to display the two-dimensional image representation. Furthermore, the second optical function of the hologram 40 is designed as a holographic micro-lens array for deflecting the second image representation to display the three-dimensional image representation.

To display a three-dimensional image, two image representations are generated, each for one eye of the viewer 24. For this purpose, the two image representations are projected into two eye boxes, in particular a first eye box and a second eye box, each above one eye of the viewer 24. In other words, to display a three-dimensional image, a first image representation is projected into the first eye box and a second image representation is projected into the second eye box. The two image representations for generating the three-dimensional image representation are deflected or bent by means of the hologram 40 or by means of the second optical function of the hologram 40 in such a way that the two image representations are each projected into an eye box. This allows a viewer to see three-dimensional images. dimensional images are displayed on a virtual screen.

In other words, a switchable 2D and/or 3D imager for head-up displays is preferably arranged in the projection device 22. In particular, two or more optical functions can be stored in a holographic volume in the hologram 40. One optical function can be used for the 2D representation, for example a holographic diffuser, and one for the 3D representation, for example a holographic MLA. The change between the two functions can take place via the reconstruction wave, for example via a laser scanner. The separation of the optical functions can be ensured via the angle and wavelength selectivity of the hologram or the HOE.

In this embodiment, the hologram is designed as a transmission hologram, for example. In a further development, the hologram 40 can also be designed as a reflection hologram, for example. The hologram 40 can also be designed as a multiplex hologram and/or as a stack or combination of several hologram layers. An image representation can be displayed in particular as a virtual image on a virtual screen 26 for a viewer 24 in the direction of travel behind a windshield of a vehicle, in particular outside the vehicle 20. The distance 42 between the viewer 24 and the virtual screen 26 is referred to as the virtual screen distance 42.

Two holographic optical functions are implemented in the hologram 40, in particular a 2D representation HOE1 and a 3D representation HOE2. By means of holographic multiplexing, for example, both optical functions can be stored in a hologram layer. Furthermore, a layer stack or film composite can be produced from two holograms or HOEs.

4 shows a projection device 22 according to the projection device 22 according to 3 . In contrast to the projection device 22 according to 3 the hologram 40 is in accordance with 4 in the projection device 22 in or on the projection device 22 in the beam path of the light rays 28, for example at the exit of the light rays 28 from the projection device 22 on the cover of the projection device 22. In other words, the hologram 40 can be arranged on a housing 31 of the projection device 22 in a beam path of the light rays 28, for example at an exit of the light rays 28 from the housing 31. In a further development, the hologram 40 can also be arranged within the housing 31 in the beam path of the light rays 28. In this embodiment, the hologram is designed, for example, as a transmission hologram.

Furthermore, in a further development, the hologram 40 can be designed as a reflection hologram, for example. As an alternative embodiment, the hologram 40 can be integrated into a windshield of a vehicle. In a further development, the hologram 40 can be arranged on a windshield of a vehicle and/or arranged in a combiner in front of the windshield of a vehicle.

5 shows a projection device 22 according to 3 . In contrast to the projection device 22 according to 3 the projection device 22 according to 5 two image generation units 44, 46, in particular a first image generation unit 44 and a second image generation unit 46. As a result, the projection device 22 can display at least two image representations.

The projection device 22 can in particular be designed as an autostereoscopic head-up display 22. This allows three-dimensional image representations to be shown to a viewer on the virtual screen 26.

In a further embodiment, the hologram 40 can be 5 also according to the hologram 40 according to 4 as a transmission hologram in the projection device 22 and/or in the instrument panel in the projection direction 22 in the beam path of the light rays 28 or as a reflection hologram in and/or on and/or as a windshield of a vehicle.

6 shows a face of a viewer 24 with eyeboxes 48, 50. A first, rectangular eyebox 48 is shown above a first eye 52 of the viewer 24 and a second, rectangular eyebox 50 is shown above a second eye 54 of the viewer 24. To display a three-dimensional image, a first image representation is projected into the first eyebox 48 and a second image representation into the second eyebox 50. This allows a viewer to be shown three-dimensional image representations on a virtual screen.

• In einem ersten Schritt 62 des Verfahrens 60 werden eine erste Bilddarstellung und/oder eine zweite Bilddarstellung mittels einer Bilderzeugungsvorrichtung einer Projektionsvorrichtung erzeugt, wobei mittels der Bilderzeugungsvorrichtung eine erste Bilddarstellung zur Darstellung einer zweidimensionalen Bilddarstellung und/oder eine zweite Bilddarstellung zur Darstellung einer dreidimensionalen Bilddarstellung erzeugt werden.

7 shows a method 60 for displaying image representations to a viewer with the following steps:

• In a first step 62 of the method 60, a first image representation and/or a second image representation are generated by means of an image generating device of a projection device device, wherein a first image representation for representing a two-dimensional image representation and/or a second image representation for representing a three-dimensional image representation are generated by means of the image generation device.

In a second step 64 of the method 60, light rays of the image representation are deflected by means of a hologram of the projection device, wherein the hologram of the projection device has at least two optical functions for deflecting the first image representation and the second image representation independently of one another. In a further development, the hologram can deflect the first image representation by means of a first optical function and the second image representation by means of a second optical function independently of the deflection of the first image representation.

In a third step 66 of the method 60, the first image representation is displayed as a first virtual image and/or the second image representation is displayed as a second virtual image.

In a further development, before the third step 66, in a further step, the first image representation and/or the second image representation can be reflected on a reflective surface, for example on a windshield or on a combiner of a vehicle.

8 shows a hologram 40 or a holographic projection surface 40, wherein the hologram 40 or the holographic projection surface 40 according to 8 according to the hologram 40 according to 3 , 4 and/or 5 and can be arranged in a projection device 22. In this embodiment, the hologram 40 is angle-selective, wherein in order to deflect the at least two image representations independently of one another, the at least two image representations impinge on a first side 41 of the hologram 40 from different directions. Preferably, light rays 28, 70 impinge on a first side 41 of the hologram 40 at different angles or angles of incidence, wherein first light rays 28 impinge on the first side 41 of the hologram 40 from a first direction at a first angle to display the first image representation and/or wherein second light rays 70 impinge on the first side 41 of the hologram 40 from a second direction at a second angle to display the second image representation. The hologram 40 of the projection device 22 can have at least two optical functions for the independent deflection and/or redirection and/or reflection and/or diffraction of the light rays 28, 70 depending on the angle of incidence of the light rays 28, 70 on the hologram 40. In particular, the hologram 40 advantageously has a first optical function for deflecting the first image representation and a second optical function for deflecting the second image representation independently of the deflection of the first image representation. In other words, the hologram 40 has a first optical function for deflecting a first light beam 28 or first beam 28 impinging on the hologram 40 at a first angle of incidence to display a first image representation and a second optical function for deflecting a second light beam 70 or first beam 70 impinging on the hologram 40 at a second angle of incidence to display a second image representation independently of the deflection of the first light beam. To achieve different angles of incidence of the light rays 28, 70 on the hologram 40, the image generation unit and/or the imaging optics can be moved and/or pivoted in a defined manner. In other words, the direction of the light rays 28, 70 can be changed depending on the movement of the image generation device 30 and/or the movement of the imaging optics so that the light rays 28, 70 impinge on the hologram 40 at defined angles of incidence. In an alternative embodiment, the image generation device can have two image generation units, the two image generation units making it possible for the light rays 28, 70 to impinge on the hologram 40 at different angles of incidence.

In this embodiment, the optical function is separated by the angle of the reconstruction wave. This is advantageously defined when the holograms are recorded. The volume diffraction on the hologram creates a defined angle selectivity. Light rays are only directed from a defined direction into a defined area. The structure or hologram 40 is transparent for all other angles. The optical functions can be recorded either analogously, for example by means of mastering and/or contact copying, or pixel by pixel using a holographic printer.

In 8a the first light rays 28 impinge on the hologram 40 at a first angle of incidence to display a first, two-dimensional image representation and in 8b the second light rays 70 strike the hologram 40 at a second angle of incidence to display a second, three-dimensional image.

In 8a the first light rays 28 of the first image representation strike the first side 41 of the hologram 40 of the projection device 22 from a first direction and/or with a first angle of incidence. The hologram 40 has in this Execution has a first optical function, wherein the first optical function causes the first light rays 28, which impinge on the hologram 40 at a first angle of incidence, to be deflected and/or redirected and/or reflected and/or diffracted in a defined manner depending on the first angle of incidence of the first light rays 28 on the hologram 40. The first optical function of the hologram is designed in particular as a scattering function for deflecting and/or scattering the first image representation for displaying the two-dimensional image representation. In this embodiment, the first light rays 28 impinge on the first side 41 of the hologram 40 from a first direction at a first angle θ ₁ .

In other words, a first reconstruction wave hits the hologram 40 from a first direction and thereby reconstructs a scattering function for the 2D representation. A virtual 2D image is generated for the observer via a subsequent HUD optic.

In 8b the second light rays 70 of the second image representation strike the first side 41 of the hologram 40 of the projection device 22 from a second direction and/or at a second angle of incidence. In this embodiment, the hologram 40 has a second optical function, the second optical function causing the second light rays 70, which strike the hologram 40 at a second angle of incidence, to be deflected and/or redirected and/or reflected and/or diffracted in a defined manner depending on the second angle of incidence of the second light rays 70 on the hologram 40. The second optical function of the hologram is designed as a holographic micro-lens array for deflecting the second image representation to display the three-dimensional image representation. In this embodiment, the second light rays 70 strike the first side 41 of the hologram 40 from a second direction at a second angle θ ₂ .

For the 3D representation, a second reconstruction wave hits the hologram from a second direction and the optical function of an MLA creates the 3D representation.

To display a three-dimensional image, two image representations are generated in particular, each for one eye of the viewer. For this purpose, the two image representations are projected into two eyeboxes, in particular a first eyebox for a first eye 52 and a second eyebox for a second eye 54 of the viewer. In other words, to display a three-dimensional image, a first image representation is projected into the first eyebox and a second image representation into the second eyebox. This allows a viewer to be shown three-dimensional image representations on a virtual screen.

9 shows a hologram 40 or a holographic projection surface 40, wherein the hologram 40 or a holographic projection surface 40 according to 9 according to the hologram 40 according to 3 , 4 and/or 5 and can be arranged in a projection device 22. In this embodiment, the hologram 40 is wavelength-selective, wherein in order to deflect the at least two image representations independently of one another, the at least two image representations are generated by means of light beams 28, 70, each with different wavelengths, and impinge on a first side 41 of the hologram 40. Preferably, light beams 28, 70 with different wavelengths impinge on a first side 41 of the hologram 40, wherein first light beams 28 impinge on the first side 41 of the hologram 40 for displaying the first image representation with a first wavelength and wherein second light beams 70 impinge on the first side 41 of the hologram 40 for displaying the second image representation with a second wavelength. The hologram 40 of the projection device 22 can have at least two optical functions for the independent deflection and/or redirection and/or reflection and/or diffraction of the light rays 28, 70 depending on the wavelength of the light rays 28, 70. In particular, the hologram 40 advantageously has a first optical function for deflecting the first image representation and a second optical function for deflecting the second image representation independently of the deflection of the first image representation. In other words, the hologram 40 has a first optical function for deflecting an incident first light beam 28 or beam bundle 28 with a first wavelength to display a first, in particular two-dimensional, image representation and a second optical function for deflecting an incident second light beam 70 or beam bundle 70 with a second wavelength to display a second, in particular three-dimensional, image representation independently of the deflection of the first light beam. To realize different wavelengths of the light beams 28, 70, different laser projectors with different wavelengths can be used according to 12 be used.

The hologram 40 can, for example, have at least two holographic layers, with one holographic layer fulfilling an optical function. Furthermore, a holographic layer has at least two different levels for deflecting light rays of different colors. In this exemplary embodiment, the hologram 40 has in particular a first layer with a first optical function for Deflecting a first light beam 28 having a first wavelength and a second layer having a second optical function for deflecting a second light beam 28 having a second wavelength independently of the deflection of the first light beam 28 having the first wavelength.

In this embodiment, the optical function is separated by the angle of the reconstruction wave. This is advantageously defined when the holograms are recorded. The volume diffraction on the hologram creates a defined wavelength selectivity. Light rays are only directed into a defined area with a specific wavelength. The structure or hologram 40 is transparent for all other wavelengths. The optical functions can be recorded either analogously, for example by means of mastering and/or contact copying, or pixel by pixel using a holographic printer.

In 9a the first light rays 28 with a first wavelength strike the hologram 40 to display a first, two-dimensional image representation and in 9b the second light rays 70 with a second wavelength strike the hologram 40 to display a second, three-dimensional image.

In 9a the first light rays 28 of the first image representation with a first wavelength strike the first side 41 of the hologram 40 of the projection device 22. In this embodiment, the hologram 40 has a first optical function, the first optical function causing the first light rays 28 with a first wavelength to be deflected and/or redirected and/or reflected and/or diffracted in a defined manner on the hologram 40 depending on the first wavelength of the first light rays 28. The first optical function of the hologram is designed in particular as a scattering function for deflecting and/or scattering the first image representation to display the two-dimensional image representation. In this embodiment, the first light rays 28 with a first wavelength λ ₁ strike the first side 41 of the hologram 40.

In other words, this design enables the separation of the two optical functions via the wavelength of the light beams. The hologram 40 is played back using two different laser wavelengths in the same spectral range, for example twice red, twice green, twice blue, while the reconstruction angle remains the same. Depending on the thickness of the holographic material and the refractive index modulation, a wavelength difference of approximately 5-30 nm, in particular 15-20 nm, can result in a separation of the optical function. In this approach, all lasers are installed in the same imaging unit and can be controlled separately.

In 9b the second light rays 70 of the second image representation with a second wavelength hit the first side 41 of the hologram 40 of the projection device 22. In this embodiment, the hologram 40 has a second optical function, the second optical function causing the second light rays 70 with a second wavelength to be deflected and/or redirected and/or reflected and/or diffracted in a defined manner on the hologram 40 depending on the second wavelength of the second light rays 70. The second optical function of the hologram is designed as a holographic micro-lens array for deflecting the second image representation to display the three-dimensional image representation. In this embodiment, the second light rays 70 with a second wavelength λ ₂ hit the first side 41 of the hologram 40.

To display a three-dimensional image, two image representations are generated in particular, each for one eye of the viewer. For this purpose, the two image representations are projected into two eye boxes, in particular a first eye box for a first eye 52 and a second eye box for a second eye 54 of the viewer. In other words, to display a three-dimensional image, a first image representation is projected into the first eye box and a second image representation into the second eye box. This allows a viewer to be shown three-dimensional image representations on a virtual screen.

10 shows a hologram 40 or a holographic projection surface 40, wherein the hologram 40 or a holographic projection surface 40 according to 10 according to the hologram 40 according to 3 , 4 and/or 5 and can be arranged in a projection device 22. In this embodiment, the hologram 40 is polarization-selective, wherein in order to deflect the at least two image representations independently of one another, the at least two image representations are generated by means of light beams each with a different polarization and impinge on a first side of the hologram. Preferably, light beams 28, 70 with different polarization impinge on a first side 41 of the hologram 40, wherein first light beams 28 impinge on the first side 41 of the hologram 40 for displaying the first image representation with a first polarization and wherein second light beams 70 impinge on the first side 41 of the hologram 40 for displaying the second image representation with a second polarization. The hologram 40 of the projection device 22 can have at least two optical functions. for the independent deflection and/or redirection and/or reflection and/or diffraction of the light rays 28, 70 depending on the polarization of the light rays 28, 70 onto the hologram 40. In particular, the hologram 40 advantageously has a first optical function for deflecting the first image representation and a second optical function for deflecting the second image representation independently of the deflection of the first image representation. In other words, the hologram 40 has a first optical function for deflecting an incident first light beam 28 or beam bundle 28 with a first polarization to display a first, in particular two-dimensional, image representation and a second optical function for deflecting an incident second light beam 70 or beam bundle 70 with a second polarization to display a second, in particular three-dimensional, image representation independently of the deflection of the first light beam. To realize different polarizations of the light beams 28, 70, different polarization rotators can be used according to 12 be used.

Anisotropic holographic materials in particular enable polarization-dependent diffraction in the hologram 40. The polarization of the reconstruction wave is adjusted via a switchable polarization rotator so that light rays are deflected and/or diffracted depending on the polarization by means of the first optical function of the hologram 40 or by means of the second optical function of the hologram 40. This requires in particular a modification of the imaging unit with an additional switchable polarization rotator.

In 10a the first light rays 28 with a first polarization impinge on the hologram 40 to display a first, two-dimensional image representation and in 10b the second light rays 70 impinge on the hologram 40 with a second polarization to display a second, three-dimensional image.

In 10a the first light rays 28 of the first image representation with a first polarization strike the first side 41 of the hologram 40 of the projection device 22. In this embodiment, the hologram 40 has a first optical function, the first optical function causing the first light rays 28 with a first polarization to be deflected and/or redirected and/or reflected and/or diffracted in a defined manner on the hologram 40 depending on the first polarization of the first light rays 28. The first optical function of the hologram is designed in particular as a scattering function for deflecting and/or scattering the first image representation to display the two-dimensional image representation.

In 10b the second light rays 70 of the second image representation with a second polarization strike the first side 41 of the hologram 40 of the projection device 22. In this embodiment, the hologram 40 has a second optical function, the second optical function causing the second light rays 70 with a second polarization to be deflected and/or redirected and/or reflected and/or diffracted in a defined manner on the hologram 40 depending on the second polarization of the second light rays 70. The second optical function of the hologram is designed as a holographic micro-lens array for deflecting the second image representation to display the three-dimensional image representation.

To display a three-dimensional image, two image representations are generated in particular, each for one eye of the viewer. For this purpose, the two image representations are projected into two eyeboxes, in particular a first eyebox for a first eye 52 and a second eyebox for a second eye 54 of the viewer. In other words, to display a three-dimensional image, a first image representation is projected into the first eyebox and a second image representation into the second eyebox. This allows a viewer to be shown three-dimensional image representations on a virtual screen.

11 shows a projection device 22 with a hologram 40. The projection device 22 and the hologram 40 according to 11 can be according to the projection device 22 according to 3 , 4 and/or 5 be carried out.

In this version, the hologram 40 is angle selective according to 8 designed, wherein for the independent deflection of at least two image representations, the at least two image representations impinge on a first side 41 of the hologram 40 from different directions. Furthermore, the projection device 22 has a first imaging element 72, wherein the first imaging element 72 is mounted so as to be movable and/or pivotable. The imaging optics 72 of the projection device 22 can be moved in a defined manner such that the light beams 28, 70 of the at least two image representations impinge on a first side 41 of the hologram 40 from different directions or with different angles of incidence. In other words, in this embodiment, an element 72 of the imaging optics is moved and/or pivoted in a correspondingly defined manner. The movement and/or pivoting of the imaging element 72 can advantageously be carried out by means of a motor and/or for example, by means of the defined movement of micromirrors.

By moving and/or pivoting the first imaging element 72 into a first position 72', first light rays 28 are directed or reflected such that the first light rays 28, in particular via a second imaging optics 32, are reflected at a first angle of incidence according to 8a impinge on a first side 41 of the hologram 40 to display a first, two-dimensional image. By moving and/or pivoting the first imaging element 72 into a second position 72", the second light beams 70 are directed or reflected in such a way that the second light beams 70, in particular via a third imaging optics 73, are reflected at a second angle of incidence according to 8b impinge on a first side 41 of the hologram 40 to display a second, three-dimensional image representation. In this embodiment, the image generation device 30 has an image generation unit for generating the first image representation and/or the second image representation.

In a further embodiment, the image generation device 30 and/or the image generation unit of the projection device can also be mounted so as to be movable and/or pivotable, so that the light rays 28, 70 of the at least two image representations impinge on a first side 41 of the hologram 40 from different directions or at different angles of incidence.

In another embodiment, the image forming device 30 may comprise at least two image forming units according to 5 wherein the at least two image representations are each generated by means of the two image generation units and thus impinge on a first side 41 of the hologram 40 from different directions or with different angles of incidence.

This image generating device 30 can preferably be used in a projection device 22 according to 3 , 4 and/or 5 and light rays 28 onto a hologram 40 according to 8 conduct or radiate.

In other words, to separate the optical functions via the angle, a switchable imager can advantageously be used, in which the reconstruction angle can be achieved mechanically, for example via a folding mirror. Furthermore, in a further embodiment, the reconstruction angle can be achieved electronically via a phase shifting element, wherein the phase shifting element can be adapted to the respective optical function in the beam path. The two optical functions are controlled via a mechanically pivotable or electrically controllable folding mirror or a deflection element. In a further embodiment, the separation of the optical functions via the angle can preferably be achieved by two imager units with different angles of incidence. The minimum distance between the reconstruction angles is also specified here by the selectivity, in particular the angular selectivity. The maximum distance between the two imager units can be specified in particular by installation space restrictions.

12 shows an image generation device 30, wherein the image generation device 30 is designed as a laser or laser projector. The image generation device 30 has at least two image generation units or laser units for generating the at least two image representations, wherein the at least two laser units emit light beams with different wavelengths. In this advantageous embodiment, the image generation device 30 has three laser units. A laser unit has three laser sources, wherein the three laser sources each emit light beams in one of the three primary colors, in particular red, green and blue, with different wavelengths. In this advantageous embodiment, the first laser unit has a first blue laser source 74, a first green laser source 75 and a first red laser source 76. The second laser unit advantageously has a second blue laser source 77, a second green laser source 78 and a second red laser source 79. A third laser unit has in particular a third blue laser source 80, a third green laser source 81 and a third red laser source 82. The laser beams 28 emitted by the laser sources are combined or collimated by means of optics 84 and guided out of the image generating device 30.

All lasers 74, 75, 76, 77, 78, 79, 80, 81, 82 output laser beams with different wavelengths. In other words, the first blue laser source 74 outputs a laser beam with different wavelengths like the second blue laser source 77 and the third blue laser source 80. Furthermore, the second blue laser source 77 outputs a laser beam with different wavelengths like the third blue laser source 80. The first green laser source 75 outputs a laser beam with different wavelengths like the second green laser source 78 and the third green laser source 81. Furthermore, the second green laser source 78 outputs a laser beam with different wavelengths like the third green laser source 81. The first red laser source 76 outputs a laser beam with different wavelengths like the second red laser source 79 and the third red laser source 82. Furthermore, the second red laser source 79 outputs a laser beam with different wavelength as the third red laser source 82.

This image generating device 30 can preferably be used in a projection device 22 according to 3 , 4 and/or 5 and light rays 28 onto a hologram 40 according to 9 conduct or radiate.

The separation via wavelength can be achieved by a modified PGU. In this case, several laser diodes with different wavelengths can be installed in the PGU for each color. The number of laser diodes per wavelength corresponds to the number of optical functions. This is in 12 for three optical functions or holograms with three laser diodes per color. For a full-color display, three times n laser diodes are required. For the case with two optical functions, in particular for two-dimensional image display and three-dimensional image display, three times two laser diodes must be installed in the PGU.

In order to separate the optical functions of a color, for example red, green or blue, the wavelengths of the laser diodes must be at a certain spectral distance. This distance is determined by the spectral selectivity of the holographic function and can be controlled via the material parameters thickness of the holographic layer and refractive index modulation. As the thickness of the holographic layer increases and the refractive index modulation decreases, the spectral selectivity of the volume hologram increases and the minimum distance between the laser wavelengths of a color can be reduced, for example. The maximum distance between the laser wavelengths is represented by the color space.

13 shows an image generating device 30, wherein the image generating device 30 is designed as a laser or laser projector. The image generating device 30 has an image generating unit or laser units for generating the at least two image representations. The laser unit has three laser sources, wherein the three laser sources emit light beams in three primary colors, in particular red, green and blue, each with different wavelengths. In this advantageous embodiment, the laser unit has a blue laser source 74, a green laser source 75 and a red laser source 76. To adjust the polarization, a polarization rotator 86, 88, 90 is arranged in front of each laser source at the output of the laser beam, wherein the polarization rotator 86, 88, 90 changes or adjusts the polarization of the laser beams or light beams. A first polarization rotator 86 is arranged in front of the blue laser source 74, a second polarization rotator 88 in front of the green laser source 75 and a third polarization rotator 90 in front of the red laser source 76. The laser beams 28 emitted by the laser sources and adjusted by means of the polarization rotators are combined or collimated by means of optics 84 and guided out of the image generation device 30.

This image generating device 30 can preferably be used in a projection device 22 according to 3 , 4 and/or 5 and light rays 28 onto a hologram 40 according to 10 conduct or radiate.

In other words, the polarization of the imager can be adjusted, for example, by means of liquid crystal cells, for example LC cells, whereby the adjustment can be carried out separately for each wavelength.

14 shows a first diagram 100 with a first function 101 for the diffraction efficiency with respect to an angle selectivity of a holographic optical element or a hologram, wherein the hologram is in accordance with the hologram according to 8 can be designed. Rays or light rays that impinge on the hologram at a defined angle of incidence are diffracted at the hologram, whereby the hologram acts as a type of filter. The angular selectivity of a hologram depends on the geometry, the material properties, the thickness of the holographic layer and the refractive index modulation in the holographic material. The diffraction efficiency is shown in percent on the first Y-axis 102 of the first diagram 100. The angles of incidence are shown in degrees on the first X-axis 104 of the first diagram 100. In this exemplary embodiment, the maximum diffraction efficiency is achieved in a range around the angle of incidence 30 °.

15 shows a second diagram 200 with a second function 201 for the diffraction efficiency with respect to a wavelength selectivity of a holographic optical element or a hologram, wherein the hologram is in accordance with the hologram according to 9 can be designed. Beams or light rays with a defined wavelength are reflected or diffracted on the hologram, whereby the hologram acts as a type of filter. The wavelength selectivity of a hologram depends on the geometry, the material properties, the thickness of the holographic layer and the refractive index modulation in the holographic material. The diffraction efficiency is shown in percent on the second Y-axis 202 of the second diagram 200. The wavelength of a light beam is shown in nanometers on the second X-axis 204 of the second diagram 200. In this exemplary embodiment, the maximum diffraction transmission efficiency is achieved in a range around the wavelength of 450 nm.

Claims (12)

Projection device (22), in particular for a vehicle, wherein the projection device (22) has an image generation device (30) for generating at least two image representations, namely a first image representation for representing a two-dimensional image representation and a second image representation for representing a three-dimensional image representation, wherein the projection device (22) has a hologram (40) for deflecting the light rays (28, 70) of the at least two image representations and wherein the hologram (40) of the projection device (22) has a first optical function for deflecting the first image representation and wherein the hologram (40) has a second optical function for deflecting the second image representation independently of the deflection of the first image representation, and wherein the second optical function of the hologram (40) is designed as a holographic micro-lens array for deflecting the second image representation to represent the three-dimensional image representation. Projection device (22) according to Claim 1 , characterized in that the first optical function of the hologram (40) is designed as a scattering function for deflecting and/or scattering the first image representation for displaying the two-dimensional image representation. Projection device (22) according to one of the preceding claims, characterized in that the hologram (40) is designed as a transmission hologram and/or as a reflection hologram. Projection device (22) according to one of the preceding claims, characterized in that the hologram (40) is designed as a multiplex hologram. Projection device (22) according to one of the preceding claims, characterized in that the projection device (22) has at least one imaging optics for aligning one or more of the at least two image representations. Projection device (22) according to one of the preceding claims, characterized in that the hologram (40) is angle-selective and that in order to deflect the at least two image representations independently of one another, the at least two image representations impinge on a first side (41) of the hologram (40) from different directions. Projection device (22) according to Claim 6 , characterized in that the image generation device (30) has at least two image generation units (33), wherein a first of the at least two image generation units is provided for generating the first image representation and a second of the at least two image generation units is provided for generating the second image representation. Projection device (22) according to Claim 6 , characterized in that the image generation device (30) has an image generation unit (33) for generating the first image representation and/or the second image representation and that the image generation device (30) and/or the image generation unit (33) and/or an imaging optics of the projection device (22) can be moved in a defined manner such that the light rays (28, 70) of the at least two image representations impinge on a first side (41) of the hologram (40) from different directions. Projection device (22) according to one of the preceding Claims 1 - 5 , characterized in that the hologram (40) is wavelength-selective and that, in order to deflect the at least two image representations independently of one another, the at least two image representations are generated by means of light beams (28, 70) each having different wavelengths and impinge on a first side (41) of the hologram (40). Projection device (22) according to Claim 9 , characterized in that the image generating device (30) has a laser projector, wherein the laser projector has at least two laser units for generating the at least two image representations and wherein the at least two laser units emit light beams (28, 70) each having different wavelengths. Projection device (22) according to one of the preceding Claims 1 - 5 , characterized in that the hologram (40) is polarization-selective and that, in order to deflect the at least two image representations independently of one another, the at least two image representations are generated by means of light beams (28, 70) each having a different polarization and impinge on a first side (41) of the hologram (40). Method for displaying image representations for a viewer, comprising the following steps: generating a first image representation and/or a second image representation by means of an image generator device (30) of a projection device (22), wherein by means of the image generation device (30) a first image representation for representing a two-dimensional image representation and/or a second image representation for representing a three-dimensional image representation is generated, deflecting the light rays (28, 70) of the image representation by means of a hologram (40) of the projection device (22), wherein by means of the hologram (40) the first image representation is deflected by means of a first optical function of the hologram (40) and wherein by means of the hologram (40) the second image representation is deflected by means of a second optical function of the hologram (40) independently of the deflection of the first image representation, wherein the second optical function of the hologram (40) is designed as a holographic micro-lens array for deflecting the second image representation to represent the three-dimensional image representation, representing the first image representation as a first virtual image and/or representing the second image representation as a second virtual image.

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