DE102016213474B3 - Display device for a motor vehicle and motor vehicle - Google Patents

Abstract

The invention relates to a display device (14) for a motor vehicle. In this case, the display device (14) comprises an optical output unit (24) with a display surface (30) for displaying image data and a projection body (22) with a plurality of mutually adjacent projection surfaces (28). The optical output unit (24) is configured to divide the image data into a plurality of picture elements (32) and display them on the display surface (30) by projecting one picture element (32) onto a projection surface of the projection surfaces (28) and thereby image data be represented by means of the projection body (22) as a hologram (34). Furthermore, the display device (14) has a holding device (26) which is set up to hold the projection body (22) over the display surface (30) of the optical output unit (24) and the optical output unit (24) and the projection body (22 ) relative to each other so that the display surface (30) facing the projection body (22) and the projection body (22) on the display surface (30) in a predetermined position on the display surface (30) is arranged.

Description

The invention relates to a display device for a motor vehicle. In this case, the display device comprises an optical output unit with a display surface for displaying image data and a projection body with a plurality of mutually adjacent projection surfaces. The optical output unit is set up to divide the image data into a plurality of picture elements and to display them on the display surface by projecting a respective picture element onto a projection surface of the projection surfaces and thereby displaying the image data as a hologram by means of the projection body. The invention also includes a method for operating a display device. Finally, the invention also includes a motor vehicle with the display device according to the invention.

In a motor vehicle, a driver or a passenger may use a mobile device, such as a mobile phone, as a mobile navigation device by attaching the mobile device in its field of view, such as on a dashboard, by means of a holding device.

For fixing a mobile device in a motor vehicle suggests the DE 10 2014 001 182 A1 a holder for releasably receiving the mobile device. The holding device is integrated into a center console of the motor vehicle. Furthermore, the mobile device is signal-coupled via an interface of the holder with an instrument cluster of the motor vehicle. As a result, a driver or a passenger of the motor vehicle information can be displayed on a display surface of the mobile device and / or the instrument cluster. The disadvantage of such information display is that the information can only be displayed two-dimensionally.

To be able to show the driver or the passenger realistically information, suggests the KR 2015 0051103 A a three-dimensional display of information by means of a smartphone holography navigation system and parking system for a motor vehicle. In such a system, image data is generated by means of the smartphone. These image data are represented by a transparent parallelepiped, which is coupled with the smartphone, three-dimensional hologram. In order to be able to implement the navigation system and parking system, such a system also requires, in addition to the smartphone and the parallelepiped, a high-resolution infrared camera and a navigation system, which must be signal-coupled with one another. Such a system has many technical components for implementing the three-dimensional display.

To represent a hologram is in the US 2015/0304642 A1 further described a mobile device having a first body and a second body, wherein the first and the second body are arranged together. The first body is configured to provide light to the second body. Furthermore, the mobile device comprises a film unit which is arranged on the second body, wherein the film unit is adapted to generate a hologram by the light provided by the first body. In this device, both bodies are matched to one another in order to produce a holographic display. If the bodies are not correctly matched or aligned with each other, no hologram can be displayed.

In the US 2015/0261004 A1 an indicator is described. The display device comprises an optical output unit having a display surface for displaying image data, a projection body having a plurality of mutually adjacent projection surfaces, wherein the optical display device is adapted to divide the image data into a plurality of image elements and to display on the display surface by each one pixel on a projection surface the projection surfaces is projected and thereby the image data by means of the projection body are displayed in three dimensions. Further, the display device has a holding device, which is adapted to hold the projection body on the display surface and to align the optical output unit and the projection body relative to each other, that the display surface faces the projection body and the projection body on the display surface in a predetermined position on the Display surface is arranged.

Due to a particularly high number of technical components and a coordination of the components on each other to allow a holographic representation, the structure of such systems or devices is particularly complex and expensive.

The object of the present invention is therefore to simplify the construction of a display device for displaying a hologram.

The object is solved by the subject matters of the independent claims. Advantageous developments of the invention are disclosed by the features of the dependent claims, the following description and the figure.

According to the invention, this object is achieved by a display device for a motor vehicle. In this case, the display device comprises an optical output unit with a display surface for Display of image data and a projection body with several adjoining projection surfaces. The optical output unit is set up to divide the image data into a plurality of picture elements and to display them on the display surface by projecting a respective picture element onto a projection surface of the projection surfaces and thereby displaying the image data three-dimensionally by means of the projection body. The optical output unit is preferably operated in a hologram mode, wherein in the hologram mode the image data is subdivided into picture elements and displayed on the display surface, so that a hologram can be displayed by means of the projection body. The invention is characterized in that the display device further comprises a holding device which is adapted to hold the projection body over the display surface of the optical output unit and to align the optical output unit and the projection body relative to each other such that the display surface faces the projection body and the projection body is arranged on the display surface in a predetermined position on the display surface.

To implement the holographic display of the display device so at least the optical output unit and the projection body are necessary. By the holding device can be ensured that the optical output unit, in particular the display surface, and the projection body are aligned exactly to each other. This results in a particularly simple construction of the display device. Furthermore, the holding device serves to align the optical output unit and the projection body correctly to each other. Thereby, the optical output unit and the projection body can no longer move to each other, whereby a particularly reliable display device is provided.

In the invention, the holding device is preferably used to position the projection body and the display surface in order to generate or generate a holographic display. On a display surface or a display of the optical output unit to image data are superimposed or displayed. In other words, the optical output unit is configured to process the image data and display it as picture elements. The optical output unit is preferably configured to divide the image data into picture elements and to display them in a predetermined arrangement on the display surface. As image data, for example, individual icons or elements or images or movies can be displayed. On the display surface, the picture elements are then preferably displayed multiple times. In particular, the picture elements are displayed repeatedly mirrored.

The superimposed image elements are projected by the arrangement of the projection body on the display surface in particular to a projection surface of the projection body. Preferably, a picture element of the picture elements is projected onto a projection surface of the projection surfaces. By means of the projection body, the picture elements can be joined together. By assembling the picture elements, a hologram is preferably formed. In other words, the picture elements are brought together by the projection body and preferably display the image data as a hologram. In other words, a holographic representation of the image data can be generated by the projection body. By means of the projection body, the image data displayed or displayed two-dimensionally on the display surface can be displayed in three dimensions. If, for example, a cuboid is to be displayed as a hologram, rectangles are preferably displayed as image data. The optical output unit then preferably displays rectangles several times in a predetermined arrangement. A hologram is preferably a three-dimensional image of an original object, ie the image data.

So that the picture elements can be projected onto the respective projection surfaces, the holding device aligns the optical output unit and the projection body to one another. In this case, the projection body can be arranged in a vertical direction of the display device on the display surface. Preferably, the projection body can rest on the display surface. If the projection body lies on the display surface, the display surface and a support surface of the projection body touch each other. Alternatively, the projection body may also be arranged at a predetermined distance from the display surface. In other words, the projection body can be arranged above the display surface in the predetermined position at a distance from the display surface.

To implement the holographic representation or display of the projection body is preferably designed as a prism. Particularly preferably, the prism is a trapezoidal prism. In particular, the prism has four adjoining projection surfaces. The projection surfaces preferably have a trapezoidal shape. The respective projection surfaces are also preferably inclined towards the display surface. In other words, the projection surfaces may be arranged at a predetermined angle inclined to the display surface. The image elements can then preferably be superimposed on the display surface in such a way that they are located in a vertical direction of the display device under a respective projection surface of the prism. In other words, each of the Picture elements associated projection surface of the projection body to cover the picture element. The holographic representation of the image data is then preferably generated in that the image elements are imaged on the projection surfaces and are brought together by the prism. With the aid of the prism, a holographic display can be provided in a particularly simple and reliable manner.

Advantageously, the projection body may be translucent or transparent or transparent. In other words, the projection body may be formed of a material which is transparent to light in the visible wavelength range. For example, the projection body may be formed from a translucent or transparent plastic or glass. As a result, the projection body can be provided in a particularly cost-effective manner. Furthermore, a plastic formed projection body contributes only slightly to an increase in weight of the display device. Thereby, a particularly easy display device can be provided.

The optical output unit can be provided in the manner described in a portable, mobile terminal, for example a smartphone or tablet computer. The display area may then form, for example, a screen or a display of the smartphone or of the tablet computer.

According to the invention, the holding device has a positioning unit, wherein the positioning unit is set up to predetermine the orientation of the optical output unit as a function of a position of the projection body relative to the display surface. This results in the advantage that the optical output unit and the projection body can be aligned with each other in a particularly simple and reliable manner by means of the positioning unit.

For this purpose, the positioning unit is advantageously set up to detect a deviation of the relative position from the predetermined position and to output a displacement command for aligning the optical output unit when detecting the deviation. The positioning unit can thus serve as a positioning aid. By positioning unit can be ensured in a particularly reliable manner that the optical output unit and the projection body are aligned correctly with each other. To output the shift command, the positioning unit may initially be set up to determine or detect the position of the projection body on the display surface. For position detection, the positioning unit may comprise a detection device. If the position of the projection body does not coincide with the predetermined position, then the positioning unit can signal a deviation. By "deviation" is preferably meant a distance of the projection body to the predetermined position, in particular in a plane of the display surface.

In order to determine the deviation, the positioning unit can have a control device which is set up to determine the deviation. For this purpose, the detection device can be coupled, for example, with the control device, wherein the detection device transmits the detected position of the projection body to the control device. In order to determine the deviation, the control device can then compare the detected position with the predetermined position. The control device can be designed, for example, as an electrical circuit. If the detected position does not coincide with the predetermined position, then the positioning unit, in particular the control unit of the positioning unit, can signal the deviation by outputting a shift command or a shift signal. For example, the positioning unit, in particular the control device, output the shift command to a further display device or to a microphone. On the further display device can be visually displayed to a user, for example with the aid of arrows, as the user has to move the optical output unit, so that the position of the projection body coincides with the predetermined position. If the display device is arranged, for example, in a motor vehicle, a user or a driver in an instrument cluster as an additional display device can be shown with an arrow in which direction the user has to move the optical output unit.

In addition, the positioning unit may have a holder in which the optical output unit is arranged. The output unit can be movably mounted in the holder. To move or move the optical output unit, the user can, for example, manually move or relocate the optical output unit in the holder. The position of the optical output unit can be detected in the holder by the detection device. The user can move the optical output unit until the positioning unit no longer issues a move command. The positioning of the optical output unit is partially automatic. As a result, a control effort of the display device can be reduced.

Alternatively, the positioning unit can be set up in an advantageous manner for the optical output unit depending on the position of the projection body relative to the Projection body for aligning the optical output unit to move to the predetermined position. In other words, the positioning unit itself can adjust the orientation of the optical output unit. The positioning of the optical output unit to the projection body is thus carried out by the positioning preferably automatically.

The positioning unit may be configured to detect a deviation of the relative position from the predetermined position and to move or move the optical output unit upon detection of the deviation. For position detection, the positioning unit may comprise a detection device. In order to determine the deviation, the positioning unit can have a control device which is set up to determine the deviation. For this purpose, the detection device can be coupled, for example, with the control device, wherein the detection device transmits the detected position of the projection body to the control device. In order to determine the deviation, the control device can then compare the detected position with the predetermined position.

Furthermore, the positioning unit may have a holder in which the optical output unit is arranged. The optical output unit can be held or stored by the holder. For example, the holder may be formed as a clamping device. The holder is also preferably movably or displaceably mounted. In order to move the optical output unit, the positioning unit may, for example, have an adjusting unit, which is set up to move the holder. The adjusting unit may be configured to move the optical output unit in a plane parallel to the display surface in a longitudinal direction and / or in a width direction. In other words, the adjustment unit can be set up to move or move or displace the optical output unit perpendicular to the vertical direction of the display device. For example, the positioning unit may have at least two turning wheels as adjusting unit. The adjusting unit can be actuated by the control device for moving the holder or the optical output unit. The control device can automatically control the holder or the optical output unit if the deviation of the projection body from the predetermined position is detected. If the detected position does not coincide with the predetermined position, the control device of the positioning unit can control the displacement unit, whereby the optical output unit is displaced.

A further embodiment of the invention provides that the holding device has a holding element, wherein the holding element is adapted to fix the projection body. In other words, the holding element can form a receptacle for the projection body. This results in the advantage that the projection body can be held or fixed in a particularly simple and reliable manner. Particularly preferably, the holding element is made of a plastic, in particular a transparent plastic.

An advantageous development of the invention provides that the holding device has a frame element, wherein the frame element is coupled to the holding element and having a bordered by the frame member opening exposing the display surface of the optical output unit. Preferably, the retaining element is non-positively and / or positively coupled or connected to the frame member. Particularly preferably, the holding element and the frame member are integrally or integrally formed. The frame member is preferably used to expose the display surface of the optical output unit and to support the projection body, so that it can be positioned in the predetermined position on the display surface. By the frame member there is the advantage that a stability of the holding device and thus the display device can be increased.

If the display surface is rectangular, for example, the opening framed by the frame element can also be rectangular. Preferably, a dimensioning of the opening is adapted to a dimensioning of the display surface. In other words, a length and / or a width of the opening may correspond to a length and a width of the display area.

For coupling the retaining element with the frame element, the retaining element may have a four-leg. The quadruple can be arranged in the rectangular opening of the frame element. For example, one leg of the four leg can extend within the opening to a corner of the frame element or extend to the same for coupling the retaining element to the frame element.

In particular, it is provided that the display device is realized in a motor vehicle. Accordingly, the invention also provides a motor vehicle with an embodiment of the display device according to the invention. The motor vehicle according to the invention is preferably designed as a motor vehicle, in particular as a passenger car.

In an advantageous embodiment of the invention, it is provided that the frame element forms part of a dashboard of the motor vehicle, wherein the projection body between a Windshield of the motor vehicle and the dashboard is arranged. This results in the advantage that the projection body, which holographically represents the image data, is located in a driver's field of vision. As a result, the driver does not have to avert his gaze from the road in order to be able to view the displayed image data, which increases traffic safety.

The advantages and preferred embodiments described for the display device according to the invention also apply to the motor vehicle according to the invention and vice versa.

In the following an embodiment of the invention is described. For this purpose, the sole figure (Fig.) In a schematic representation of a motor vehicle 10 with one in an interior 12 of the motor vehicle 10 arranged display device 14 ,

The exemplary embodiment explained below is a preferred embodiment of the invention. In the exemplary embodiment, the described components of the embodiment each represent individual features of the invention that are to be considered independently of one another, which also each independently further develop the invention and thus also individually or in a different combination than the one shown as part of the invention. Furthermore, the described embodiment can also be supplemented by further features of the invention already described.

In the figure, the display device 14 on a dashboard 16 of the motor vehicle 10 arranged. The display device is preferred 14 next to a steering wheel 18 and a combination instrument 20 of the motor vehicle 10 arranged. The display device 14 includes a projection body 22 , an optical output unit 24 and a holding device 26 ,

The projection body 22 is preferably formed as a prism. In the figure, the projection body 22 designed as a trapezoidal prism. The projection body 22 has projection surfaces 28 on. The projection body 22 has four mutually arranged projection surfaces 28 on. In other words, the lateral surface of the prism forms the projection surfaces 28 out. As the projection body 22 is preferably designed as a trapezoidal prism, have the projection surfaces 28 a trapezoidal shape.

The projection body 22 may be formed as a hollow body or solid body. Is the projection body 22 formed as a hollow body, so can the adjacent projection surfaces 28 form the hollow body.

The projection body is preferred 22 formed of a translucent or transparent or transparent material. For example, the projection body 22 be formed of glass or a plastic.

Furthermore, the display device comprises 14 the optical output unit 24 , The optical output unit 24 has a display area 30 on. The optical output unit 24 For example, it may be provided in a portable, mobile terminal, such as a smartphone or tablet computer. The display area 30 can then form, for example, a screen or a display of the smartphone or the tablet computer. The optical output unit 24 is set up to display image data on the display area 30 display or show. The optical output unit 24 is further adapted to convert the image data into picture elements 32 to divide and on the display area 30 display. In other words, the output unit 24 to set up the image data in picture elements 32 split and in different areas on the display area 30 display. So the image data on the display area 30 can be displayed or displayed, the optical output unit 24 For example, a storage medium having a program code that is configured, when executed by a processor device of the optical output unit, the picture elements 32 to display in the predetermined order.

In the figure, the projection body 22 above the display area 30 the optical output unit 24 arranged in a predetermined position. For example, the projection body 22 directly on the display surface 30 rest or at a predetermined distance to the display surface 30 be arranged.

The projection screens 28 of the projection body 22 are inclined to the display area 30 arranged. In other words, the projection surfaces 28 of the projection body 22 at a predetermined angle to the display area 30 arranged inclined. In the figure, the trapezoidal prism has a rectangular base or bearing surface, which is the display surface 30 is facing. On the display surface 30 become a total of four picture elements 32 appears. The four picture elements 32 be through the optical output unit 24 such on the display surface 30 faded in that each one pixel 32 next to an edge of the rectangular base of the projection body 22 is arranged.

Through the optical output unit 24 become the picture elements 32 on the projection screens 28 projected and through the projection body 22 together. In the figure, rectangles are displayed as image data. The optical output unit 24 shows the rectangles as four picture elements 32 at. On the display surface 30 So four cubes or rectangles are displayed, which are on the projection surfaces 28 of the projection body 22 be imaged and through the projection body 22 be joined together. On the display surface 30 the cuboids are displayed two-dimensionally. Through the projection body 22 the image data, in this case the cuboids, are displayed or displayed three-dimensionally. With the help of the projection body 22 can the image data - the cuboid - as a hologram 34 , as a cuboid.

So the image data as a hologram 34 can be represented are the optical output unit 24 or the display area 30 the optical output unit 24 and the projection body 22 arranged and aligned in a predetermined arrangement to each other. For this purpose, the display device 14 the holding device 26 on. The holding device 26 includes a holding element 36 and a positioning unit 38 ,

The holding element 36 is set to the projection body 22 to fix or support. The holding element 36 is preferably coupled to a frame element. In the figure, the frame member is part or component of the dashboard 16 , The holding element 36 So it's with the dashboard 16 coupled.

The frame member has an opening framed by the frame member 40 on which the display area 30 the optical output unit 24 exposes. The frame member serves as the preferred to the display surface 30 the optical output unit 24 expose and the projection body 22 support so that it in the predetermined position above the display surface 30 can be positioned. The opening 40 is a windshield of the motor vehicle 10 facing. This is the projection body 22 between the windshield of the motor vehicle 10 and the dashboard 16 arranged.

Is the display area 30 For example, rectangular, so may also be enclosed by the frame member opening 40 also be rectangular. In the figure, the holding element 36 for coupling the retaining element 36 with the frame element on a four-legged. Alternatively, the retaining element 36 also have a bipod. The four-legged of the retaining element 36 is in the opening 40 arranged. One leg of the four leg each runs to a corner of the dashboard 16 or the frame member provided opening 40 ,

Alternatively, the retaining element 36 also be designed as a transparent or transparent, in particular non-reflective, plate. The plate can be in the opening 40 , in particular positive or non-positive, be held. On a surface of the plate, which is the display surface 30 turned away, the projection body 22 rest or be arranged.

The positioning unit 38 indicates holding or storing the optical output unit 24 a bracket 42 exhibit. The optical output unit 24 is in the holder 42 arranged. As shown in the figure, the holder has a receiving area. The receiving area is formed as a cavity, in particular cuboid or square cavity. Via an insertion opening 44 can the optical output unit 24 in the receiving area of the holder 42 be inserted. The insertion opening 44 extends perpendicular to the opening 44 , The holder 42 forms part of the dashboard 16 , In the dashboard 16 is a recess as a receiving area for the optical output unit 24 brought in.

By means of the positioning unit 38 may be the orientation of the optical output unit in dependence on a position of the projection body 22 relative to the display area 30 be specified. For this purpose, the positioning unit 38 be adapted to detect a deviation of the relative position to the predetermined position and, upon detecting the deviation, a shift command for aligning the optical output unit 24 issue.

The positioning unit can be used to output the move command 38 initially set to the position of the projection body 22 on the display surface 30 to determine or record. For position detection, the positioning unit 38 a detection device (not shown in FIG.). The detection device may comprise a touch-sensitive operating surface, in particular a transparent touch foil. The touch-sensitive control surface may preferably be on the display surface 30 be arranged. Alternatively, the touch-sensitive user interface can also be integrated in the display area. In other words, the touch-sensitive operating surface can form part of the optical output unit. The touch-sensitive control surface preferably has an electrode layer. In particular, a matrix of electrodes is provided in the touch-sensitive operating surface, it being possible for each electrode to be assigned a coordinate. In addition, the retaining element 36 or the projection body 22 a magnetic element (not shown in FIG. Preferably, the magnetic element is on one side of the holding element 36 or the projection body 22 arranged which of the display area 30 is facing. The magnetic element may be formed as a permanent magnet or electromagnet. By the magnetic element, the detection device, for example, capacitively, a position of the projection body 22 above the display area 30 determine. In other words, there is a capacitive detection for determining the position of the projection body 22 above the display area 30 ,

The detection device can be coupled to a control device (not shown in FIG. 1), in particular by signal technology. The detection device can detect a detected position of the projection body 22 transmit to the controller. The predetermined position can be stored in a memory of the control device. The control device can then be set up for the detected or current position of the projection body 22 to compare with the predetermined position.

If the position of the projection body does not coincide with the predetermined position, then the control device can determine a deviation. Furthermore, the control device can be configured to signal the deviation by outputting a shift command V or a shift signal. For example, the control device, the move command to the instrument cluster 20 output. On the instrument cluster 20 can the user of the display device 14 optically, for example with the help of arrows 46 to be displayed as the user the optical output unit 24 has to shift, hence the position of the projection body 22 with the predetermined position on the display surface 30 matches.

The optical output unit 24 is movable in the holder 42 arranged. To move or move the optical output unit 24 For example, the user may manually place the optical output unit in the holder 42 move or relocate. The position of the optical output unit can be detected continuously in the holder by the detection device. The user can shift the optical output unit until the positioning unit no longer outputs a shift command V. As soon as the optical output unit 24 in the correct position, the user can use the optical output unit 24 fix so that she can not move anymore.

Overall, a 3D hologram is thus described in a vehicle cockpit via a smartphone. This integration of the smartphone in the cockpit of the motor vehicle to display three-dimensional holograms. The cockpit includes the prism for the implementation of the three-dimensional holographic representation. The prism is preferably arranged in a dashboard or a dashboard of the motor vehicle. The presentation is done by the smartphone. For this, the data processing takes place in the smartphone. Via an app or triggered via a contact, the display of the screen is changed to hologram mode. On the screen of the smartphone, a multi-mirrored display is displayed, which is merged via the prism. The dashboard is used to hold the prism to position the screen to the prism. The mount may vary to accommodate, for example, different display sizes or different models of smartphones. The holder is integrated in the dashboard. The smartphone is detachably received in the holder, so that a change of the smartphone is possible. Alternatively, the holder may have a unit size. In this case, a positioning unit is used, which aligns the smartphone two-dimensionally to the prism.

Claims (9)

Display device ( 14 ) for a motor vehicle ( 10 ) comprising: - an optical output unit ( 24 ) with a display area ( 30 ) for displaying image data, - a projection body ( 22 ) with several adjoining projection surfaces ( 28 ), wherein the optical output unit ( 24 ) is arranged to convert the image data into several image elements ( 32 ) and on the display surface ( 30 ) by displaying one pixel each ( 32 ) on a projection surface of the projection surfaces ( 28 ) is projected and thereby the image data by means of the projection body ( 22 ) are displayed in three dimensions, wherein - the display device ( 14 ) further a holding device ( 26 ), which is adapted to the projection body ( 22 ) above the display area ( 30 ) of the optical output unit ( 24 ) and the optical output unit ( 24 ) and the projection body ( 22 ) relative to each other so that the display surface ( 30 ) the projection body ( 22 ) and the projection body ( 22 ) on the display area ( 30 ) in a predetermined position on the display surface ( 30 ), - the holding device ( 26 ) a positioning unit ( 38 ), wherein the positioning unit ( 38 ) is adapted to the orientation of the optical output unit ( 24 ) in dependence on a position of the projection body ( 22 ) relative to the display area ( 30 ), characterized in that - the positioning unit ( 38 ) is adapted to detect a deviation of the position to the predetermined position and when detecting the Deviation a shift command for aligning the optical output unit ( 24 ). Display device ( 14 ) according to claim 1, characterized in that the positioning unit ( 38 ) is adapted to the optical output unit ( 24 ) as a function of the position of the projection body ( 22 ) relative to the projection body ( 22 ) for aligning the optical output unit ( 24 ) to move to the predetermined position. Display device ( 14 ) According to one of the preceding claims, characterized in that the holding device ( 26 ) a holding element ( 36 ), wherein the holding element is adapted to the projection body ( 22 ) to fix. Display device ( 14 ) according to claim 3, characterized in that the holding device comprises a frame element, wherein the frame element with the holding element ( 38 ) is coupled and a framed by the frame member opening ( 40 ), which the display surface ( 30 ) of the optical output unit ( 24 ). Display device ( 14 ) according to one of the preceding claims, characterized in that the projection body ( 22 ) is designed as a prism. Display device ( 14 ) according to one of the preceding claims, characterized in that the optical output unit ( 24 ) is provided in a portable mobile terminal. Display device ( 14 ) according to claim 6, characterized in that the portable mobile terminal is designed as a smartphone or tablet computer. Motor vehicle ( 10 ) with a display device ( 14 ) according to any one of the preceding claims. Motor vehicle ( 10 ) according to claim 8, with reference back to claim 4, characterized in that the frame element is part of a dashboard ( 16 ) of the motor vehicle ( 10 ), wherein the projection body ( 22 ) between a windshield of the motor vehicle ( 10 ) and the dashboard ( 16 ) is arranged.

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