DE102016207236A1 - projection system - Google Patents

Abstract

The invention relates to a projection system (100) for providing an image (106) in a viewing area, the projection system (100) comprising a projector (104) for projecting the image (106) onto a projection surface (102) and between the projector (104 ) and the viewing area arranged holographic optical device (500). The device (500) is arranged between the projector (104) and the projection surface (102) and / or between the projection surface (102) and the viewing region.

Description

State of the art

The invention is based on a device or a method according to the preamble of the independent claims.

In a head-up system, projection optics include optical lenses and / or mirrors to provide an image of a projector in a viewing area to an observer.

Disclosure of the invention

Against this background, with the approach presented here, a projection system for providing an image in a viewing area according to the main claims is presented. The measures listed in the dependent claims advantageous refinements and improvements of the independent claim device are possible.

Optical lenses and mirrors break and reflect light. The light is formed. An angle and a direction of refraction change over an area of the lens and the mirror, respectively. The refraction or reflection can be mapped in one function.

The function can be mapped in a hologram, ie a grid structure. Thus, lenses and mirrors of a projection system can be replaced by holograms.

A hologram can be written in a holographic layer. The layer can be very thin. For example, the hologram may have a film as a carrier material. As a result, holograms can have a low weight and a small footprint. By using at least one hologram, a projection system can be made compact and manufactured inexpensively.

A projection system for providing an image to a viewing area is presented, wherein the projection system has a projector for projecting the image onto a projection surface, and a holographic optical device arranged between the projector and the viewing area.

A projection system can be understood as meaning a field of view display device or head-up display. A viewing area can be called an eyebox. A projection screen may be, for example, a ground-glass screen. The projection surface can scatter an incident light beam into a cone of light. This makes the light cone visible from an angle range. The holographic optical device may comprise one or more holographic optical elements. According to one embodiment, the device is realized by a holographic optical element.

The holographic optical device may be arranged between the projector and the projection surface. The holographic optical device can direct the light from the projector at a predetermined angle to the projection surface. As a result, the light cones of the projection surface can be convergent and a narrow viewing range can be achieved. For example, an air gap may be arranged between the holographic optical device and the projection surface.

Additionally or alternatively, the holographic optical device may be arranged between the projection surface and the viewing region. The device can redirect the image to a viewer. By means of a holographic optical device between the projection surface and the viewer, the image can be shaped for the viewer. For example, a holographic optical element arranged between the projection surface and the viewing region of the device can be used to mirror the image into a field of view of the observer.

If the device is arranged at a distance from the projection surface between the projector and the projection surface, the device can be arranged at a distance from the projection surface. In this case, the device may be arranged, for example, separated from the projection surface by an air gap.

Alternatively, the device may be coupled to the projection surface. For example, the device may be bonded to the projection surface. The projection surface and the holographic element are explicitly two separate elements. If the holographic element is coupled without spacing directly to the projection surface or even bonded thereto, the holographic element and the projection surface are still two separate layers. While the deflection takes place in the holographic layer, the light is only scattered at the actual projection surface.

The device may be configured to redirect light used to project the image unscattered. The hologram realized by the device thus does not provide the projection surface or a functionality of the projection surface but represents a deflecting element in front of the projection surface, which itself has no scattering properties.

Thus, the projection surface is not designed as a holographic projection surface, which scatters the image played with the projector in different spatial directions, so that the image is visible only from limited, separate solid angles out. Such a holographic projection surface, as is not used according to the approach presented here, could be realized by three holographic layers, each of which directs the image in a spatial direction. In contrast, the hologram realized by the device used herein is not designed to split the image in different directions. Although the projector's light is redirected, it is not split into different channels.

The device can be realized as a single holographic layer in which three holograms for the three primary colors are imprinted. Thus, the holographic function used can be realized in a single holographic layer into which three holograms for the three primary colors are imprinted. Due to the wavelength selectivity of the hologram, the holograms for the three different wavelengths of the three primary colors can be imprinted in the same holographic layer.

The device may be a spherical wave deflector. A spherical wave deflector is a special form of hologram. The spherical waveguide deflects spherical waves propagating from one point and focuses them on another point. The spherical wave deflector can be reflective or translucent.

The device may include a plurality of individual pixel holograms. A pixel hologram can be a standalone hologram. Each pixel hologram can represent its own function. Thus, the holographic optical device can be well adapted to their application. The pixel holograms can be reflective or translucent.

The pixel holograms can be arranged in a row-shaped and / or column-shaped structure. Due to the matrix shape, the individual pixel holograms can be easily written while the other pixels are covered by a shutter.

The pixel holograms may be arranged in a hexagonal structure. The hexagonal structure may be honeycomb. Due to the hexagonal structure, a high pixel density can be achieved.

The projection system may comprise at least two holographic optical elements arranged between the projector and the viewing area. The holographic optical elements can map different functions. Each holographic optical element can replace a lens or a reflector. The elements may have different distances to the projector.

The projection surface may be a microlens array. A microlens array may comprise a plurality of regularly arranged lenses, each of which defines an incident light beam to break into a radiation cone. A microlens array can have a high light transmission.

The projector can be a laser projector. In a laser projector, the image is provided with laser light. The holographic optical device can convert the laser light into normal light.

Furthermore, a method for producing a holographic optical element is presented in which, in a step of writing, at least one hologram structure is written using a reference wave and an object wave.

This method can be implemented, for example, in software or hardware or in a mixed form of software and hardware, for example in a control unit.

Embodiments of the approach presented here are shown in the drawings and explained in more detail in the following description. It shows:

1 a representation of a projection system with a projection screen;

2 a representation of a projection system with a projection surface and a field lens;

3 a representation of a schematic structure of a head-up display;

4 a representation of an operation of a head-up display;

5 a representation of a system structure according to an embodiment;

6 a representation of an operation of a hologram according to an embodiment;

7 a schematic diagram of a recording of a hologram according to an embodiment;

8th Representation of a system structure of a HUD system according to an embodiment;

9 a representation of a hologram as a reflection hologram according to an embodiment;

10 a representation of various recording patters for a written HOE according to embodiments;

11 a representation of an operation of a pixel-wise written hologram according to an embodiment;

12 a representation of an operation of a windshield with holographic spherical wave deflector according to an embodiment;

13 a use of a windscreen hologram with extended light source according to an embodiment; and

14 a flowchart of a method for producing a holographic optical element according to an embodiment.

In the following description of favorable embodiments of the present invention, the same or similar reference numerals are used for the elements shown in the various figures and similar acting, wherein a repeated description of these elements is omitted.

1 shows a representation of a projection system 100 with a projection screen 102 , The projection screen 102 scatters the from a projector 104 projected pixels 106 in a Abstrahlkegel that corresponds to a certain solid angle α. A main direction of radiation of this cone is through the positioning of the projector 104 certainly.

In the projection system 100 is the projector 104 on the projection screen 102 directed the pixels 106 scatters in the cone covering the solid angle α. The main radiation direction of this cone depends on the positioning of the projector 104 and differs for the different pixels 106 , If a subsequent optical system uses only a limited solid angle α or if a viewer area is located only in a limited solid angle α, then it is advantageous if all the pixels 106 radiate α into this solid angle. This can be a very wide scattering or lambertartig scattering projection surface 102 be used.

In conventional projection systems 100 becomes the projection screen 102 from a projector 104 irradiated, without the need for an additional, direction-deflecting optics to the radiation of the projection surface 102 outgoing light in a certain direction. As a result, the radiation is essentially due to the location of the projector 104 relative to the projection surface 102 determined and the projection screen 102 emits divergent into the room. A deflection of the on the projection surface 102 The use of field lenses is only possible to a very limited extent because the field lenses only have a limited refractive power as refractive elements and, due to their thickness, are not arbitrarily close to the projection surface 102 can be placed. By the distance of a field lens to a projection surface 102 may also blur the image.

2 shows a representation of a projection system 100 with a projection screen 102 and a field lens 200 , The projection system 100 corresponds essentially to the projection system in 1 , The field lens 200 directs the light of the projector 104 order a certain direction of emission at the projection surface 102 to realize. The degree of deflection is limited by the refractive power of the lens 200 , Due to the lens thickness, aberrations can occur in the image.

To when using a scattering in narrower beam cone projection surface 102 To adjust the main emission direction of the cone, the field lens 200 be used. The field lens 200 is near the screen 102 and directs the light of the projector 104 such that the emission direction at the projection surface 102 is adjusted. Because the lens 200 due to their thickness not arbitrarily close to the projection surface 102 can be positioned, artifacts can occur. The Lens 200 may also cause the image to blur. Due to the limited refractive power of the lens 200 the rays can not be deflected at will. Especially for large projection surfaces 102 is the deflection by a field lens 200 no longer feasible.

3 shows a representation of a schematic structure of a head-up display 300 , In the head-up display 300 is an image plane of an image generator unit (PGU, Picture Generating Unit) 302 using optics (HUD optics) 304 on a virtual, in front of the vehicle 306 located picture 308 displayed. The driver 310 takes an enlarged picture 308 true, that of the PGU 302 was generated. This picture 308 is superimposed on the driving scene and is at a defined distance from the windscreen 312 on the virtual screen. LCD modules can act as an imaging element in the PGU 302 be used.

4 shows a representation of an operation of a head-up display 300 , The head-up display 300 essentially corresponds to the head-up display in 3 , The illustrated virtual image 308 Figure 13 is an enlarged diagram of the display generated by the imager unit. Therefore, the head-up display optics requires a certain magnification. The necessary magnification increases with the distance of the virtual screen, since it is necessary to increase the image generated by the image generator unit more strongly in order to occupy the desired field of view of the driver at a greater distance. For head-up displays 300 the virtual screen can be at a distance of about 15 m.

5 shows a representation of a system structure 100 according to an embodiment. The system structure 100 essentially corresponds to the projection system in the 1 and 2 , The system structure 100 For example, in an imager of a head-up display as in the 3 and 4 be used. A laser-based projector 104 projected onto a projection screen 102 , The projection screen 102 expands the projected pixels 106 in narrow cones. A holographic optical device 500 in the form of a holographic optical element (HOE), also referred to below as a hologram, is in front of the projection surface 102 placed to redirect the main radiation direction of the cone, so that a convergent emission of the projection surface 102 arises.

In 5 is the basic structure of the proposed system 100 shown. It projects a projector 104 a picture on a projection screen 102 , in front of the holographic optical device 500 in the form of the holographic optical element (HOE) 500 is placed. Because of the holographic optical element 500 as a thin layer close to the projection surface 102 placed or with the projection screen 102 can be coupled, a sharp picture of the image on the screen 102 receive. If the holographic optical element 500 directly to the projection screen 102 coupled, the holographic optical element 500 for example, via a bond to the projection surface 102 be bonded. The holographic optical element 500 directs this from the projector 104 from incident light in such a way that the projection surface 102 is irradiated by a convergent beam cone. The projection screen 102 itself widens the light of each pixel 106 in a radiating cone. The main emission direction of each cone is determined by the holographic function of the holographic optical element. The projection screen 102 can be realized here, for example, as a microlens array or a weakly scattering projection surface.

A subsequent viewing area of the projection screen 102 or a subsequent optical system for imaging the projection surface 102 For example, due to the design, only angles from a specific emission range of each pixel 106 take up. By the presented arrangement 100 A large part of the available light can be radiated into this area. The light does not become like broadly scattering projection surfaces 102 blasted into unused areas. Thus, the system efficiency can be increased.

In other words, it becomes a holographic optical device 500 in the form of a holographic beam-shaping element 500 for a laser projection system 100 presented. The approach presented here has a specific emission characteristic on a projection surface 102 a projection system 100 using the holographic optical element 500 reached.

The proposed concept works with the holographic optical element (HOE) 500 for beam shaping on the projection surface 102 , The holographic element 500 can be used as a simple spherical wave deflector 500 be realized and is thus easy and inexpensive to manufacture. It can thus realize very strong deflections of the light, since the holographic optical element 500 as a flat layer directly on or in front of or behind the projection surface 102 can be placed. Due to the placement directly on the projection surface 102 the image sharpness of the projection is retained.

It is thus also the use of a holographic optical device 500 in the form of a holographic attachment element in an imaging projection system 100 presented. By using the holographic element 500 Can the radiation on the screen 102 be redirected in certain directions. The system 100 is thus adapted to a particular viewing area or a subsequent optics.

By realizing the optical function of a field lens in a holographic optical device realized as a thin holographic layer 500 close to the projection screen 102 An improvement in image sharpness can be achieved.

Through the into the holographic layer 500 imprinted function can be a deflection of the projector 104 radiated light far beyond the possibilities of refractive working systems beyond realized.

In particular, this makes possible a convergent form of the radiation on the projection surface 102 to realize.

By adapting the radiation can high system efficiency of the projection system 100 be achieved. Due to the targeted radiation of the projection surface 102 in the working area, the luminance can be increased.

The concept lends itself to the use of holographic elements 500 and laser light for integrating further holographic elements. Due to the high adaptability of the holographic functions, the system offers 100 a high degree of design freedom.

The use of holographic elements 500 offers a cost-effective solution of complex optical functions and can lead to cost savings over refractive solutions.

By realizing complex optical functions in thin holographic layers 500 space can be saved compared to classic solutions. In particular, the proposed concept is also suitable for the realization of a holographic windshield.

In one embodiment, a holographic attachment element 500 for beam shaping a projection system 100 used.

6 shows a representation of an operation of a holographic optical device 500 in the form of a hologram according to an embodiment. The hologram 500 essentially corresponds to the hologram in 5 , The hologram 500 is a spherical wave deflector, the waves of a light source 600 so diverted that it becomes a point 602 converge in the room.

In 6 is the functioning of the in 5 presented hologram 500 shown. The hologram 500 acts as a spherical wave deflector that focuses a divergent spherical wave and on a point 602 focused in the room. Will after the holographic optical element 500 Placed a projection surface, so a convergent radiation can be realized on the projection surface.

7 shows a schematic diagram of a recording of a hologram 500 according to an embodiment. The hologram 500 essentially corresponds to the hologram in the 5 and 6 , The at an exposure of a holographic optical element 500 irradiated reference wave 700 is a divergent spherical wave. As an object wave 702 A convergent wave is used, which is at one point 704 in the room behind the holographic optical element 500 tapers. By means of the reference wave 700 can thus in operation the further course of the object wave 702 be reconstructed.

In 7 is the recording of a hologram 500 illustrated. This will be a reference wave 700 and an object wave 702 into the holographic layer 500 irradiated. The divergent reference wave 700 radiates from the place 706 where the projector is placed in the system. The object wave 702 runs convergent, radiates through the holographic layer 500 and converges to a point 704 in the room behind the hologram 500 , So that the light sources do not shade each other when shooting, the light sources from different directions on the hologram 500 irradiate or, for example, a beam splitter can be used in the recording. When playing the hologram 500 is determined by the reference wave 700 the further course of the object wave 702 after the hologram 500 reconstructed.

8th shows a representation of a system structure 100 a Head-Up Display (HUD) system 300 according to an embodiment. The Head-Up Display System 300 essentially corresponds to the head-up display in 3 , The imaging optics 304 of the head-up display 300 is here schematically as a multi-stage lens system with intermediate focus 800 shown. Through the intermediate focus 800 is a convergent emission on the display 102 required.

A convergent radiation of a projection surface 102 especially in systems 100 be required, where the projection screen 102 again through a subsequent optical system via an intermediate focus 800 is shown. This can, for example, when used in a head-up display 300 be the case. In 8th is an example of such a system 100 shown. Here is the imaging optics 304 of the head-up display 300 simplified by a two-stage lens system with intermediate focus 800 shown. In the intermediate focus 800 becomes the display 102 of the head-up display 300 shown reduced in size. the display 102 Here, for example, the projection surface 102 a projection-based imager unit 302 be.

9 shows a representation of a hologram 500 as a reflection hologram according to an embodiment. Will the beam-forming hologram 500 or intent element 500 used at a distance to the projection surface, an embodiment as a reflection hologram 500 respectively.

The holographic element 500 can also be placed at some distance from the screen. To continue the focus of the projection can be left on the screen to get a sharp picture, the partial focus through the hologram 500 compensated by the focusing of the lens or taken into account in the lens design. The holographic intent element 500 can be understood as part of the lens.

When using the holographic element 500 at some distance from the projection surface, instead of a transmissive hologram, a reflection hologram can also be used 500 be used. The functional principle of such a hologram 500 is in 9 shown. Similar to the hologram 6 becomes the light of a point light source 600 focused on one point in space. The reflective hologram 500 benefits from increased wavelength selectivity over transmission holograms, allowing the system to be adapted very well to the laser wavelengths of the imager unit.

10 shows a representation of various recording patters for a written holographic optical element 500 according to embodiments. The holographic optical elements 500 essentially correspond to the holographic optical elements in the preceding figures. On the left is the simple case of structuring the holographic surface 500 with separated areas 1000 , Such a hologram 500 can be produced by aperture during recording. In the middle, a recording structure is shown, in which individual imprinted spots 1002 are arranged in a square grid. On the right is a possible hexagonal structure.

As an alternative to the implementation of the proposed system by means of a point light source hologram, in another embodiment, a pixel-wise written hologram 500 be used. In a pixel-wise written holographic optical element 500 becomes the holographic layer when recording the holographic function 500 in single pixels 1000 illuminated step by step. The individual pixels 1000 thus contain an independent optical function. It is therefore possible to the element 500 to record any optical function that is very adaptable.

In 10 Different patterns are shown after which the pixels 1000 of the hologram 500 can be included. The holographic layer 500 For example, it can be divided into a square structure in which the individual pixels 1000 provided with apertures and exposed one after the other. Instead of a square structure here also, for example, hexagonal structures or round structures with unused intermediate areas 1004 be used. Due to the inclusion of diaphragms, effects can arise here due to the diffraction at the diaphragm structure itself, in particular in the case of very small structures.

In the concept proposed here, a pixel-wise written hologram 500 can be used where the individual pixels 1000 with overlapping areas 1004 were recorded. The round areas 1002 the pickup points 1000 can be arranged, for example, in a square or a hexagonal structure. Such recording patterns are exemplary in 10 in the middle and on the right. The overlapping area 1004 the inscribed pixels 1000 includes two overlapping holograms 1002 ,

11 shows a representation of an operation of a pixel-wise written hologram 500 according to an embodiment. The hologram 500 essentially corresponds to one of the holograms in 10 , In overlapping areas 1004 finds a transition in the diffraction efficiency of the individual imprinted pixel holograms 1002 instead of.

In 11 is the function of such a hologram 500 shown in operation. The central area of the single pixel 1000 is unaffected by the neighboring pixel 1000 , In the overlapping border area 1004 of the single pixel 1000 the diffraction efficiency of the holographic pixel decreases 1000 and there is a transition to the neighboring holographic function 1002 instead of. The diffraction efficiency of each pixel 1000 thus merges into each other while the optical functions 1002 the single pixel 1000 stay independent.

12 shows a representation of an operation of a windshield 312 with holographic spherical wave deflector 500 according to an embodiment. The spherical shaft deflector 500 corresponds essentially to a holographic optical element in one of the preceding figures. The windscreen hologram 500 acts as a spherical wave hologram and thus has a mapping function of the centers 600 . 602 of object and reference wave.

The system proposed here can be used in a projection-based head-up display in which a holographic element 500 with magnification function in the windscreen 312 is used. The holographic windshield 312 Such a head-up display can be realized as a spherical wave deflector, whereby the windscreen 312 acts as a magnifying lens and forms part of the magnifying head-up display optics. In 12 is the operation of such a windscreen hologram 500 shown. The hologram 500 is recorded in such a way that the light of a point light source 600 intercepted and to another point 602 is focused in the room.

13 shows a use of a windscreen hologram 500 with extended light source 800 according to an embodiment. The windscreen hologram 500 corresponds essentially to the holographic optical element in FIG 12 , With extended light source 800 Light rays from different angles hit the hologram 500 , Because the hologram 500 angle selective, decreases the efficiency of the hologram 500 for deviation from the acceptance angle of the hologram 500 from.

In the actual operation of the holographic head-up display, the windscreen acting as a magnifying lens forms 312 the image of the display virtually from. The display acts as an extended light source 800 , By the extension of the light source 800 becomes the hologram 500 irradiated from different pixels from different angles. Due to the angular selectivity of holograms 500 decreases the efficiency of the hologram 500 at a deviation from the recording angle and aberrations can occur especially in the edge region of the image. For large dimensions of the light source 800 This can be below the required efficiency at the edge area. In the approach presented here is an imaging head-up display optics with intermediate focus 800 used in which the intermediate focus 800 as a reduced image of the projection area of a smaller extended light source 800 equivalent.

As described above, in particular systems in which the projection surfaces subsequently require an intermediate focus 800 often a convergent radiation that can be realized with the proposed concept.

14 FIG. 12 shows a flowchart of a method for producing a holographic optical element according to an exemplary embodiment. The method has one step 1400 of writing in which at least one hologram structure is written by using a reference wave and an object wave.

In one embodiment, the method includes a step 1402 of providing a holographic layer in the step 1400 of writing the hologram structure is written.

In one embodiment, the method includes a step 1404 fixing, in which the written hologram structure is fixed in the holographic layer.

If an exemplary embodiment comprises a "and / or" link between a first feature and a second feature, then this is to be read so that the embodiment according to one embodiment, both the first feature and the second feature and according to another embodiment either only first feature or only the second feature.

Claims (12)

Projection system ( 100 ) for providing an image ( 106 ) into a viewing area, the projection system ( 100 ) a projector ( 104 ) for projecting the image ( 106 ) on a projection surface ( 102 ) and one between the projector ( 104 ) and the viewing area arranged holographic optical device ( 500 ), characterized in that the device ( 500 ) between the projector ( 104 ) and the projection surface ( 102 ) and / or between the projection surface ( 102 ) and the viewing area. Projection system ( 100 ) according to claim 1, wherein the device ( 500 ) spaced from the projection surface ( 102 ) between the projector ( 104 ) and the projection surface ( 102 ) is arranged. Projection system ( 100 ) according to one of the preceding claims, in which the device ( 500 ) to the projection surface ( 102 ), in particular bonded, is. Projection system ( 100 ) according to one of the preceding claims, in which the device ( 500 ) is configured to project the image ( 106 ) to divert the light used unscattered. Projection system ( 100 ) according to one of the preceding claims, in which the device ( 500 ) is realized as a single holographic layer in which three holograms for the three primary colors are imprinted. Projection system ( 100 ) according to one of the preceding claims, in which the device ( 500 ) is a spherical wave deflector. Projection system ( 100 ) according to one of the preceding claims, in which the device ( 500 ) a plurality of individual pixel holograms ( 1002 ) having. Projection system ( 100 ) according to claim 7, wherein the pixel holograms ( 1002 ) are arranged in a row-shaped and / or column-shaped structure. Projection system ( 100 ) according to claim 8, wherein the pixel holograms ( 1002 ) are arranged in a hexagonal structure. Projection system ( 100 ) according to one of the preceding claims, in which the device ( 500 ) at least two at different distances to the projector ( 104 ) between the projector ( 104 ) and the viewing area arranged holographic optical elements comprises. Projection system ( 100 ) according to one of the preceding claims, in which the projection surface ( 102 ) is a microlens array. Projection system ( 100 ) according to one of the preceding claims, in which the projector ( 104 ) is a laser projector.

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