DE102007008164B4 - Lighting adaptation to an image display on vehicle interior surfaces - Google Patents

Abstract

Method for adapting the lighting to an image display on vehicle interior surfaces (1), comprising:providing (S10) image information (10) relating to an image display area (110);determining (S30) an overlapping boundary area (130) between the image display area (110) and an illuminated area ( 120);analyzing (S31) image information (111) falling on the border area (130); andadapting (S40, S42) an illumination in the illumination area (120) to the image information of this sub-area (111) falling on the border area (130) in such a way that the sub-area (111) of the image display area (110) on the basis of which the adaptation takes place, essentially corresponds to a size of an illuminated area of an illumination source (259) and the boundary area (130), in which an overlap of image representation and illumination occurs, essentially corresponds to the illumination area (120) and that a transition between the image representation area (110) and the Illumination area (120) is essentially imperceptible.

Description

field of invention

The present invention relates to a method and apparatus for lighting adjustment to an image display on vehicle interior surfaces, and more particularly to a method and apparatus for lighting adjustment of peripheral lighting to an image display on vehicle interior surfaces of a passenger transport vehicle, such as an aircraft.

Background of the Invention

In commercial aircraft, and in particular in long-haul aircraft, it is desirable to design the cabin in such a way that the passengers' stay on board an aircraft is made more pleasant, in order in particular to obtain a generous spatial effect of the aircraft interior. The impression of a virtual daily routine should also be created through time-controlled changes in the light colour, the color temperature and the illuminance. This should compensate for the loss of the real sense of time and create perceptions that have a positive influence on the body's internal clock (reduction of the so-called "jet lag" effect). For this purpose, lighting scenarios are used that give the passenger a spacious interior.

Among other things, resorted to projection devices and methods. This is intended to suggest a virtual reality to the passenger, which, through the projection of images and films, suggests a more generous and spacious cabin environment to the passenger.

Out U.S. 7,070,150 B2 a method and system for displaying moving simulated images in a vehicle is proposed, in which a passenger in a so-called looking at a projection screen from a real window. A changed horizon based on the actual bank angle of the aircraft is shown to the passenger, so that the passenger is presented with a virtual horizon that corresponds to the body inclination he feels.

WO 2005/062608 A2 discloses a supplemental visual display system that, in the context of a display device, such as a television, generates illumination surrounding the display device. The lighting sources can be arranged on the side, above or below the display or behind the display in such a way that they illuminate a white wall behind the display, for example, and generate the light surrounding the display device through reflections on the wall. The color and intensity of the lighting can be adapted to the content of the display.

U.S. 6,611,297 B1 describes the lighting of a room, which is controlled in connection with an image displayed on a screen of a display device in order to design the viewer's perception space based on images or situations in the image in such a way that the virtual perception space generated by the image resembles the actual real perceptual space approximates.

WO 2007/036890 A2 discloses a method to operate a processor that adjusts illumination surrounding a display device through a coherence method.

WO 2006/059263 A1 FIG. 1 shows a method of how at least partially an illumination surrounding a display device can be adapted to an ambient light. For this purpose, the lighting surrounding the display device is registered by sensors and the lighting is adjusted in connection with the ambient light via a control device.

WO 2006/003600 A1 shows a method to adjust lighting surrounding a display device.

DE 20 2005 020 945 U1 shows a display device that uses the radiation of the image shown on a display device in order to filter and deflect the corresponding light rays, for example using prisms. This second radiation can escape through slits in the display device and create illumination all around the display.

EP 1 379 082 A1 Figure 1 shows a display device with controllable single color lighting surrounding the display device.

A realistic representation of a virtual reality usually ends for the viewer at the limit of the presented image of the virtual reality. However, known displays and projection devices only have a limited size or limited projection surface, so that the virtual reality for the passenger usually ends at the border of the projected or displayed image. The border of the image representation is usually sharply delimited and thus causes a clear structural limitation.

Summary of the Invention

It can therefore be seen as an object of the present invention to remove the limit of virtual reality at the edge of a projection representation or screen or display representation in order to present the viewer with virtual reality over a larger surface area and thereby present him with a more generous sense of space.

The object of the present invention is solved by the subject matter of the independent claims. Advantageous developments are embodied in the dependent claims.

According to an exemplary embodiment of the invention, a method is provided for adapting the lighting to an image representation on vehicle interior surfaces, comprising providing image information relating to an image representation area, determining a boundary area between the image representation area and an illumination area, analyzing image information that falls on the boundary area, and a Adaptation of lighting in the lighting area to the image information falling on the border area in such a way that a transition between the image display area and the lighting area is essentially imperceptible.

With such a method, in a border area of an image representation, adjacent illuminations can be adjusted in the border area to the adjacent image representation, so that a viewer or a passenger no longer perceives the boundaries of a representation area, for example a projection area, as a result of the adjustment and is responsible for the viewer continues the virtual reality beyond the limit of a single image display area, which significantly increases the spatial effect, especially in a narrow passenger cabin. The border area can be an area where, for example, the displayed image or the images adjoin the illuminated areas, in which case the border area is an area that is in the vicinity of the respective image area. However, the border area can also be an overlapping area, in particular when the lighting is directed onto the image display area, so that the overlapping area can consist of two superimposed areas of, for example, the image displays and the illuminated area.

The image display area is the area in which an image display of whatever kind takes place. This can be a non-luminous image representation, such as painting, printing, pasting or a non-luminous display, but also an illuminating image representation, such as a light projection or a self-illuminating display (e.g. OLED, organic LED).

According to an exemplary embodiment of the invention, the method further includes displaying an image on the image display area based on the image information and illuminating the illumination area based on an adjusted illumination.

In this way, the method is not only used for adjustment, but also for the subsequent display of the image and for the lighting application itself. An image display device represents the entirety of image display units, such as one or a plurality of projectors, one or a plurality of matrix displays, etc.

According to an exemplary embodiment of the invention, the illumination of the illumination area takes place with a planar reflected light illumination.

According to an exemplary embodiment of the invention, the illumination area is adjusted on the basis of a sub-area of the image display area which essentially corresponds to a size of an illumination source.

In this way, the transition area between a pictorial representation and general lighting in a cabin can also be adapted to one another in such a way that the transition between the pictorial representation and general lighting in the form of reflected light is harmoniously coordinated, which generally affects the spatial effect of a pictorial representation, particularly in the edge areas, increased or even continue to adjacent areas (e.g. side wall panel).

According to an exemplary embodiment of the invention, an image is displayed with an image display device in the form of a matrix display that extends over the image display area. Due to its self-illuminating design, the matrix display is also suitable as a partial replacement for the previous illumination of cabin interiors.

In this way, for example, interior paneling of an aircraft can be designed with matrix displays over a large area, so that a two-dimensional image can be displayed on the interior paneling. The display area can essentially cover the entire area Occupy the passenger-visible area of the interior trim unit. Alternatively, it is also possible for the display surfaces to extend to a partial edge area, which is adjoined by a further interior lining unit.

According to an exemplary embodiment of the invention, an image is displayed with an image display device in the form of a projection that extends over the image display area.

In this way, interior lining panels can be used in a largely conventional form, with the coating being able to be optimized for a projection, so that retrofitting of existing cabin configurations is also conceivable without great effort.

According to an exemplary embodiment of the invention, the illumination takes place with an illumination device in the form of a matrix display, which extends over an illumination area.

It should be noted here that the method can also be used in cases in which, for example, a first illumination area is illuminated with a matrix display, while a second illumination area is illuminated in the form of incident light illumination. In this case, too, a border area can be defined in which an adjustment of the transitions can be made, so that a viewer can no longer perceive such a transition or cannot easily perceive it.

According to an exemplary embodiment of the invention, the image information is in the form of an image sequence, and the lighting adjustment is carried out with image accuracy. This can be done frame-by-frame and synchronously with all other image output devices.

In this way, not only a virtual image, but also a virtual motion sequence can be displayed, with synchronization being able to be ensured even in the case of consecutive images as a result of the image-accurate adjustment. The image sequence is understood to be a chronological sequence of image representations on a predetermined representation area, which can be done discretely in the form of a film with a certain number of frames per second, but also continuously, such as with a projection of a per se moved over the predetermined illuminated area still image.

According to an exemplary embodiment of the invention, a pixel resolution of an image is adapted to a pixel resolution of a lighting device.

This enables an optimized display and utilization of the entire display area without leaving pixels that would actually be suitable for displaying an image lying idle.

According to an exemplary embodiment of the invention, a device is provided for adapting the lighting to an image representation on vehicle interior surfaces, having a storage device for storing image representation information, a boundary area determination device that is designed to determine a boundary area between the image representation area and an illumination area, an analysis device that is designed to analyze image information that falls on the border area, and an adjustment device that is designed to adapt lighting in the lighting area to the image information that falls on the border area in such a way that a transition between the image display area and the lighting area is essentially imperceptible is.

Such a device enables an illumination area to be adapted to one another in a border area to an image presentation area in such a way that a viewer or a passenger no longer perceives the illumination and the image presentation separately, but instead perceives the image presentation and the illumination as a whole. The color information, brightness and color temperature of the individual playback media are dynamically matched to each other.

According to an exemplary embodiment of the invention, the device further comprises an image display device, which is designed to display an image on the image display area based on the image information, and an illumination device, which is designed to illuminate the illumination area based on an adjusted illumination .

Thus, the device can not only make an adjustment based on available data, but also carry out the image display and the lighting itself.

According to an exemplary embodiment of the invention, the lighting device is designed to illuminate the area illuminated with incident light over a wide area.

According to an exemplary embodiment of the invention, the adaptation device designed to adapt an illumination of the illumination area on the basis of an illumination of a partial area of the image presentation area, which partial area essentially corresponds to a size of an illumination source of the illumination device.

In this way, the device also allows an adjustment to be made in border areas where an image display borders on or overlaps common illumination in the form of incident light, such that the common illumination can be harmoniously adjusted in the border areas of the image display. This also generally increases the spatial effect in a passenger cabin.

According to an exemplary embodiment of the invention, the image display device has at least one matrix display, which extends over an image display area.

Such matrix displays can be provided, for example, as flat displays in interior trims, so that, for example, two adjacent interior trims can be used as a large display area. It should be noted here that the invention is not limited to one image display area, but can have any number of image display areas, in particular in the case of more complex geometries, such as a passenger cabin. In this case, a large number of image display devices, such as matrix displays, can be provided in order to transform the entire cabin space into virtual reality.

According to an exemplary embodiment of the invention, the matrix display consists of a matrix with red, green, and blue light-emitting diodes. Alternatively, it can also be equipped with red, green, blue, and white light-emitting diodes in order to enable a homogeneous impression of white.

Any mixed colors can be provided in this way. It goes without saying that other combinations of light-emitting diodes can also be used, provided they cover the desired color spectral range.

According to an exemplary embodiment of the invention, the matrix display has organic light-emitting diodes.

Organic light-emitting diodes have relatively small dimensions, which allow small distances and thus a small pixel size, resulting in high resolution on the image display areas, which in turn allows high-quality images to be displayed. Furthermore, a curved and also flexible surface design is conceivable with organic light-emitting diodes.

According to an exemplary embodiment of the invention, the image display device has at least one projector that is designed to display an image on an image display area.

Projectors can also be used, for example, to illuminate or display images on surfaces that are inactive when illuminated, for example conventional interior paneling for cabins, so that illumination using projectors is also suitable for cabin configurations that were not originally intended for such illumination. Furthermore, projectors, particularly when they are moved, or when some part of their optics are moved, allow intrinsically still images to move across an illuminated area.

According to an exemplary embodiment of the invention, the image display device is designed to process image information in the form of an image sequence, and the adjustment device is designed to carry out an adjustment with image accuracy.

According to an exemplary embodiment of the invention, a synchronization device is provided, which is designed to synchronize an image refresh rate.

A device of this type also makes it possible to adapt lighting at the border areas to moving images in such a way that a viewer or passenger perceives moving images that are displayed separately as an overall moving image without perceiving the border areas as such.

In this way, corresponding adjustments to the motion sequences can be made in order to allow motion synchronization in addition to image synchronization.

According to an exemplary embodiment of the invention, the device is equipped with a pixel adaptation device that is designed to adapt a pixel resolution of an image to a pixel resolution of a lighting device.

According to an exemplary embodiment of the invention, an aircraft and in particular an airplane with a device according to the invention are provided.

According to another exemplary embodiment, a program element is provided which, when executed on a processor, executes the method according to the invention.

According to an exemplary embodiment of the invention, a computer-readable medium is provided on which the program element according to the invention is stored.

It should be noted that the previous and also the following statements relate equally to the method, the device, the aircraft or aircraft, the program element and the computer-readable medium.

It should be noted that the features described above and also below can also be combined with one another without deviating from the subject matter of the present invention. Further, the invention can also be applied to other vehicles such as trains or buses, as well as interiors of buildings where the effect of the invention is desired.

These and other aspects of the present invention will be appreciated and explained with reference to the embodiments described hereinafter.

character list

• 1 zeigt ein Ablaufdiagramm eines Verfahrens gemäß einer beispielhaften Ausführungsform der Erfindung.
• 2 zeigt eine Detaildarstellung eines Matrixdisplays gemäß einer beispielhaften Ausführungsform der Erfindung.
• 3 zeigt den Zusammenhang einer Lichtsteuerung gemäß einer beispielhaften Ausführungsform der Erfindung.
• 4 zeigt eine Darstellung eines Pixelmappings gemäß einer beispielhaften Ausführungsform der Erfindung.
• 5 zeigt eine Anordnung gemäß einer beispielhaften Ausführungsform der Erfindung mit einem Zusammenwirken von einer Bildprojektion und einer überlappenden Randbeleuchtung.
• 6 zeigt eine Anordnung gemäß einer beispielhaften Ausführungsform der Erfindung mit einem Zusammenwirken von einem Matrixdisplay und einer überlappenden Randbeleuchtung.
• 7 zeigt ein Passagierflugzeug mit einer erfindungsgemäßen Vorrichtung.
• 8 zeigt den schematischen Ablauf eines Pixelmappings.

Exemplary embodiments of the invention are described below with reference to the following drawings.

• 1 shows a flowchart of a method according to an exemplary embodiment of the invention.
• 2 shows a detailed representation of a matrix display according to an exemplary embodiment of the invention.
• 3 shows the context of a light control according to an exemplary embodiment of the invention.
• 4 12 shows a representation of a pixel mapping according to an exemplary embodiment of the invention.
• 5 12 shows an arrangement according to an exemplary embodiment of the invention with a cooperation of an image projection and an overlapping edge illumination.
• 6 shows an arrangement according to an exemplary embodiment of the invention with a cooperation of a matrix display and an overlapping edge lighting.
• 7 shows a passenger aircraft with a device according to the invention.
• 8th shows the schematic process of pixel mapping.

It should be noted that the same reference numbers refer to the same or similar elements.

Detailed description of exemplary embodiments

1 shows a flowchart of a method according to an exemplary embodiment of the invention. Image information 10 is provided S10. Further information relating to the general lighting can also be provided as lighting information 20 if, for example, a number of lighting sources illuminate an edge area, but only part of it can be adjusted S20. An image boundary area can be adjusted with general light reflected light illumination. A border area 130 is determined S30 from the provided image information and lighting information regarding the extent of the lighting areas, with the respective lighting being adapted to the image representation in this border area S40. In this case, for example, in the case of edge lighting that borders on an image display, a certain edge area can be provided for an adjustment, while an area of an image remote from the edge area remains more or less unaffected by incident light illumination. Thus, the adjustment is only made in the edge or border area in which an overlap or a border of image display and lighting occurs. The adjustment can also be made to the intensity of the image representation S41 if the edge lighting cannot provide the calculated intensity, for example. However, the image display is primarily left unchanged and the reflected light illumination is adjusted S42. A corresponding adaptation S41, S42 can then be carried out on the basis of the provided image information S10 and lighting information S20 as well as the analyzed border area S30.

A border area can also be detected by image recognition or any other correlation method that either accesses the lighting information directly from the system or indirectly, by detecting an already illuminated area.

After the corresponding adjustment of the lighting control, a corresponding lighting can be carried out S50 in the border area, with this separately for the image display area S51 in the exceptional case of an image intensity adjustment and the illumination area S52 for the normal case. In this case, for example, a synchronization S60 of an image refresh rate can also be carried out. Furthermore, a pixel adaptation S70 can also be carried out in order to adapt a pixel resolution of an image to a pixel resolution of a lighting device.

This process sequence can, for example, be repeated for each newly displayed image, so that this process sequence is repeated for each image display, for example when a film or moving images are displayed in general. However, it cannot be ruled out that the process sequence will be run through several times even for a single image, for example in order to make a new adjustment, for example in order to compensate for high-frequency vibrations and thus image shifts, such as those that can occur as a result of turbine movements and noise in aircraft.

2 1 shows an exemplary embodiment of an image display device with a first and a second matrix display 255, 256. These can display composite images, for example. Each matrix display 255, 256 can consist of a matrix with red R, green G and blue B light-emitting diodes. Such an arrangement permits color reproduction in a variety of desired colors. Other color combinations of light-emitting diodes can of course also be used, provided they cover the desired color spectral range. In this case, the light-emitting diodes can also be organic light-emitting diodes, in particular when a very large number of light-emitting diodes are desired on a small area or a high resolution is required.

3 shows a further exemplary embodiment of the invention, in which a light controller 245 interacts with a media server 246, via which, for example, a large number of projectors 253, 254, n can be controlled in order to produce composite images, for example with a softedging system known in the prior art. to present the procedure. The light control can also interact with other light components 257 . For a successful representation of the transitions in border areas 130, it makes sense for the various image generation or illumination devices to run synchronously with one another, for example image-synchronously, in order to generate a natural impression of a reproduced image. This can be done, for example, by intelligently controlling one or more content servers. A projector or beamer, for example, generates an image on the panel surfaces of an interior lining, with the projector being able to be arranged, for example, above or between luggage compartments above the seats. The overall picture is then generated by several projectors and combined to form a large-scale display using a so-called soft-edge cross-fade process, so that the viewer gets the impression of a large, coherent picture.

Of course, a matrix display can also be used instead of a projector, for example a matrix display incorporated in a panel with individually controllable red, green and blue light-emitting diodes for displaying image content. The image content can be converted in such a way that it is adapted to the actual resolution of the matrix display, for example by pixel summarization and averaging.

4 Figure 12 shows another application according to an exemplary embodiment of the invention.

in the in 4 In the embodiment shown, an image is displayed on an image display area 110 by means of a projector 253. However, an image can also be displayed on the image display area 110 using a matrix display. The image content at the edges 120, 130 is analyzed in terms of color according to the border area of the projection surface 110 and converted into corresponding control data for the general lighting 258 positioned on the side of the projection surface 110. With this pixel mapping, as many individual pixels are combined as correspond to the image display area of the smallest segmentable unit 259 of the general lighting 258 . In this case, the illumination of the first illumination region 110 is carried out on the basis of first illumination information 10 in the form of an image, while the second illumination information is provided in the form of control data 20 for the general illumination 258 . According to one embodiment, a pixel mapper 248 combines the corresponding pixels of the first piece of lighting information 10, obtained from the detection device 210, and the determined border area, obtained from the border area determination device 230, in order to obtain control of the light of the general lighting 258 on this basis. A single lighting unit 259 of the general lighting 258 can in turn consist of a combination of red R, green G, blue B and white light-emitting diodes (not shown here), which can be provided, for example, in the form of bars arranged one above the other or next to one another. Furthermore, point light source len are used so that lighting surfaces in the form of triangles result when red, green and blue LEDs are used, or squares when white LEDs are also used. A diffuser 290 can be used in order to create the impression of a planar illumination and to improve the homogeneity of the imaging.

In this way, an automatically generated transition that is homogeneous in color and brightness between an image or film representation and the illumination of general lighting can be made possible in order to create an optically homogeneous overall image with the illumination adjacent to a display or a projection. In this way, the display surface appears visually enlarged to the viewer through the pixel mapping process.

The system can be integrated into a standard aircraft lighting and audio system, so that the light from the standard lighting system is automatically adjusted to the image and film display and can be synchronized with audio scenarios.

5 FIG. 1 shows a representation in which a projection image is displayed with a projector 253, 254 in an image display area 110. This is partially overlapped here in a border area 130 by incident light illumination in area 120 by an illumination device 258 with a multiplicity of illumination sources 259 . The overlap can also take place in such a way that the border area 130 essentially corresponds to the incident light area 120 . The illumination can be provided by luminescence diodes (also light-emitting diodes or LEDs), but also by any other controllable light sources that can be controlled with regard to intensity and/or color.

6 12 shows a representation in which an image representation in area 110 by a matrix display 255, 256 overlaps with illumination in area 120 in border area 130. An adaptation of the lighting in the area 120 is then taken into account, taking into account the image information in the border area 130, in order to set the lighting area 120 adaptively. Of course, several matrix displays 255, 256 can also be lined up in a row. The edge areas can also be illuminated instead of reflected light illumination by means of illumination matrix displays, not shown here, for example with matrix displays whose pixels have a much larger grid spacing and do not have to correspond to the resolution of screens if they are only used for illumination. In this way, a uniform surface can be provided on the interior trim surfaces without providing trims behind which incident lighting is mounted.

7 shows an exemplary embodiment of an aircraft 1, in particular an airplane, with a system 200 according to the invention. Image display areas 110 and lighting areas 120 are provided in a cabin interior, which are each illuminated with an image display device, here in the form of projectors 253, or lighting devices. In a boundary area 130, which can consist, for example, in an overlapping area of the projection areas 110 and the illumination area 120, an adjustment is made such that the viewer no longer perceives the transition between the illumination areas 110 and 120 as such.

8th shows the schematic sequence of a pixel mapping based on an image display in the image display area 110. The partial edge areas 111a-e, which each contain a partial area of the edge of the image display and are shown enlarged to the right, have partial image areas. These sub-image areas are analyzed and, for example, subjected to an averaging in order to achieve a color and intensity value that is representative for each of the sub-areas 111a-e. This is represented by the areas 112a-e, which emerge accordingly from the analysis of the areas 111a-e. On the basis of the determined color and intensity value, the lighting sources 259a-e corresponding to the partial areas 111a-e are then controlled in such a way that they correspond to the associated areas 111a-e in terms of color and intensity. These light sources 259a-e can then illuminate the illumination area 120, which can include both the adjoining areas not covered by an image representation and/or the corresponding partial areas 111a-e, so that the boundary between image representation and edge illumination is eliminated for the eye.

With the method and the device according to the invention it is also possible to display different brandings, as well as a wide variety of source materials, such as real-time images, recordings, static images, animations, logos and videos etc. It is also possible to use this system as a flexible light source and it with the to synchronize existing light and audio sources.

It is noted that the term "comprising" does not exclude other elements or steps, just as the terms "a" and "an" do not exclude multiple elements and steps.

The reference numerals used are for convenience only and should not be taken as limiting in any way, the scope of protection being indicated by the claims.

Claims (20)

A method for adapting lighting to an image display on vehicle interior surfaces (1), comprising: Providing (S10) image information (10) relating to an image display area (110); determining (S30) an overlapping boundary area (130) between the image display area (110) and an illumination area (120); Analyzing (S31) an item of image information (111) falling on the border area (130); and Adjusting (S40, S42) an illumination in the illumination area (120) to the image information of this sub-area (111) falling on the border area (130) in such a way that the sub-area (111) of the image display area (110) on the basis of which the adjustment is made, essentially corresponds to a size of an illuminated area of an illumination source (259) and the boundary area (130), in which an overlap of image representation and illumination occurs, essentially corresponds to the illumination area (120) and that a transition between the image representation area (110) and the Illumination area (120) is essentially imperceptible. procedure after claim 1 , further comprising displaying an image (S50, S51) on the image display area (110) on the basis of the image information (10) and illuminating (S50, S52) the illumination area (120) on the basis of an adjusted illumination. Method according to one of the preceding claims, in which the illumination of the illumination area (120) takes place with planar incident light illumination (258). Method according to one of the preceding claims, in which an image (S50, S51) is displayed with an image display device in the form of a projection (253, 254) which extends over the image display area (110). Method according to one of the preceding claims, in which an image (S50, S51) is displayed using an image display device in the form of a matrix display which extends over the image display area (110). Method according to one of the preceding claims, in which the lighting (S50, S52) takes place with a lighting device in the form of a matrix display (255, 256) which extends over a lighting area (120). Method according to one of the preceding claims, in which the image information (10) is in the form of an image sequence and the lighting adjustment is carried out with image accuracy. Method according to one of the preceding claims, wherein a pixel resolution of an image is adapted to a pixel resolution of a lighting device (S70). Device for adapting lighting to an image display on vehicle interior surfaces (1), with: storage means (210) for storing image representation information (10); a boundary area determination device (230) which is designed to determine a boundary area (130) between the image display area (110) and an illumination area (120); an analysis device (231) which is designed to analyze image information (111) falling on the border area (130); and an adaptation device (240) which is designed to adapt an illumination in the illumination area (120) to the image information of this sub-area (111) falling on the border area (130) in such a way that the sub-area (111) of the image display area (110), on the basis of which the adjustment is made corresponds essentially to a size of an illuminated area of an illumination source (259) and the boundary area (130) essentially corresponds to the illumination area (120) and that a transition between the imaging area (110) and the illumination area (120) is essentially imperceptible. device after claim 9 , further comprising image display means (253, 254, 255, 256) arranged to display an image on the image display area (110) based on the image information (10), and lighting means (258, 259) arranged to illuminate the illumination area (120) based on adjusted illumination. Device according to one of the preceding claims 9 and 10 , wherein the lighting device (258, 259) is designed to carry out a planar incident light illumination of the illumination area (120). Device according to one of the preceding Claims 10 and 11 , wherein the image display device has at least one matrix display (255, 256) has, which extends over an image display area. device after claim 12 , wherein the matrix display (255, 256) consists of a matrix with red (R), green (G) and blue (B) light-emitting diodes. device after claim 12 or 13 , wherein the matrix display (255, 256) has organic light-emitting diodes. Device according to one of the preceding Claims 10 until 14 , wherein the image display device has at least one projector (253, 254) which is designed to display an image on an image display area (110). Device according to one of the preceding Claims 10 until 15 , wherein the image display device is designed to process image information (10) in the form of an image sequence and the adjustment device (240) is designed to carry out an adjustment with image accuracy. Device according to one of the preceding claims 9 until 16 , further having a pixel adaptation device (270) which is designed to adapt a pixel resolution of an image to a pixel resolution of a lighting device (253, 254, 255, 256). Airplane with a device (200) according to one of claims 9 until 17 . Program element which, when executed on a processor, implements the method according to any one of Claims 1 until 8th executes Computer-readable storage medium with a program element stored thereon claim 19 .

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