EP1181615A2

EP1181615A2 - Display device

Info

Publication number: EP1181615A2
Application number: EP00990564A
Authority: EP
Inventors: Johannes Eschler; Reinhold Fiess
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 1999-12-21
Filing date: 2000-12-21
Publication date: 2002-02-27
Also published as: WO2001046739A3; DE19961572C2; US6791511B2; DE19961572A1; US20020167498A1; JP2003517971A; WO2001046739A2

Abstract

The invention relates to a display device for a motor vehicle which is provided for displaying a virtual image onto the windshield (1) of a motor vehicle. The image is displayed by an image generating unit (2) which is arranged in an upper area of the windshield (1) or in an area of the vehicle roof, whereby the generated image is directed onto the windshield by a first aspherical mirror and a second aspherical mirror.

Description

46739

display device

State of the art

The invention relates to a display device according to the preamble of the main claim. A display device in a motor vehicle is already known from US Pat. No. 5,414,439, in which an image recorded by an infrared camera can be projected onto the windshield from an display arranged in the instrument panel via an aspherical mirror likewise arranged in the instrument panel. A virtual image is created on the windshield that is visible to a driver who is in the vehicle. Both the display and the aspherical mirror must be arranged in the instrument panel. Furthermore, there must be an opening in the instrument panel for the light reflected from the aspherical mirror to the windshield and necessary for an image display.

Advantages of the invention

The display device according to the invention with the features of the main claim has the advantage over the fact that a display device for a virtual image can be realized in a space-saving manner in a vehicle. Because by one / 46739 - 2 -

is arranged in the area of the vehicle roof or in an upper area of the windshield, an arrangement of optical elements within the instrument panel can be largely dispensed with. In particular, it is not necessary to provide a light path within the instrument panel. A corresponding opening in the area of the instrument panel can thus be dispensed with. As a result of the reduced space requirement, the costs for the construction of the display device can be reduced. Furthermore, it is possible to retrofit a display device according to the invention on a vehicle which is not designed for such a display device in its manufacture and in which there is no space for a light path in the instrument panel. In addition, temperature problems can be avoided, which can occur when an image-forming unit is arranged in the instrument panel, since the instrument panel can generally become particularly hot due to direct sunlight.

The measures listed in the subclaims permit advantageous developments and improvements of the display device specified in the main claim. It is particularly advantageous to arrange the second aspherical mirror so that it can be covered on the instrument panel. In this way, contamination or damage to the mirror can be avoided.

Furthermore, it is advantageous to design the first or the second aspherical mirror to be motor-adjustable. Such an adjustment enables the alignment of the first and the second aspherical mirror to be adjusted to a driver's seating position, so that the position of the virtual image can be optimally adjusted. It is also advantageous to make this setting via a control panel, so that unnecessary touching of the mirror and any contamination that may be associated with it can be avoided.

Furthermore, it is advantageous to design the imaging unit as a liquid crystal cell with backlighting, since in this way the imaging unit can be implemented at particularly low cost.

It is also advantageous to make the windshield wedge-shaped. As a result, double images can be avoided in the projection, which arise from the fact that in the case of a windshield made of safety glass, multiple refraction at the individual glass layers of the

Safety glass can be done. The wedge-shaped design makes it possible for these double images to coincide and only one image to be visible to an observer.

It is also advantageous to integrate the imaging unit or the first aspherical mirror into an interior mirror module. As a result, the assembly effort can be reduced further, since only the inside mirror module has to be arranged on the windshield or on the vehicle roof. Furthermore, it is also possible for the image-forming unit to be covered by the inside mirror for a user and for the user to be prevented from being disturbed by a visible image-forming unit.

It is also advantageous to cover the mirror with a film that reduces the visibility of the mirror without significantly influencing the reflective properties of the mirror. This can in particular 46739 - 4 -

Glare e.g. be largely avoided by sunlight falling on the second aspherical mirror.

drawing

Exemplary embodiments of the invention are shown in the drawing and explained in more detail in the following description. FIG. 1 shows a first exemplary embodiment of the display device according to the invention in a motor vehicle, FIG. 2 shows an embodiment of an image-forming unit with a liquid crystal cell, FIG. 3 shows a further exemplary embodiment of a display device according to the invention, and FIG. 4 shows another exemplary embodiment of a display device according to the invention.

Description of the exemplary embodiment

1 shows the front region of a passenger compartment of a motor vehicle in a longitudinal section. An image-forming unit 2 is arranged on a windshield 1 of the vehicle. The imaging unit 2 is arranged on the windshield near a vehicle roof 3 and is connected to a camera 5 via a data connection 4, the entire connection not being shown in the figure, but rather being indicated by arrows. A cover 6 is arranged on the vehicle roof 3. The cover 6 has a bulge 7, in which a first aspherical mirror 8 is arranged. Below the windshield 1 is the

Instrument panel that connects to the windshield 1 with an upper side 10 of the instrument panel. A second aspheric mirror 11 is located on the top 10 of the instrument panel. The second aspherical mirror 11 is provided by a first motor 12 and a second Motor 13 changeable in its position. Both the first motor 12 and the second motor 13 are controlled by a control unit 14. The control unit 14 can be influenced by a user via an operating element 15. The control element 15 has, for example, rotary knobs and / or push buttons. The control unit 14 is also connected to an ignition lock 16. The figure does not show a data connection, in particular for controlling the brightness of the virtual image displayed on the windshield 1 from the control unit 14 to the image-generating one

Unit 2. A cover flap 17 is arranged next to the second aspherical mirror 11. The cover flap 17 can be folded over the second aspherical mirror 11 and for this purpose can be moved by a third motor 18, which is also controlled by the control unit 14. The second aspherical mirror 11 is located behind a steering wheel 19 on the side of the steering wheel 19 facing away from a driver of the vehicle. The ignition lock 16 and the operating element 15 are preferably arranged next to the steering wheel 19. Light rays run from the imaging unit 2 via the first aspherical mirror 8 to the second aspherical mirror 11, from there onto the windshield 1, from which they are in turn directed to the eye of an observer located in front of the steering wheel 19. A ray path 20 between the elements mentioned is shown, the eye of the beholder being indicated by an arrow 22 on the ray path 20. The reflections on the windshield 1 create a virtual image that an observer, preferably the driver, can perceive.

In the exemplary embodiment shown in FIG. 1, the imaging unit 2 is arranged on the windshield 1 near the vehicle roof. It is also possible to integrate the imaging unit 2 into the vehicle roof 3. Imaging in the imaging unit 2 is carried out, for example, by means of a backlit liquid crystal cell. On

Exemplary embodiment of this is shown in Figure 2. The imaging unit 2 has an opening 34, behind which a liquid crystal cell 33 is arranged. The liquid crystal cell 33 has segments which can be individually electrically controlled and whose optical transmission can be influenced by the electrical control. The individual segments are not shown in FIG. 2. The liquid crystal cell 33 has a preferred one

Exemplary embodiment on a screen size of 1.3 inches. A diffuser 32 is arranged on the side of the liquid crystal cell 33 facing away from the opening 34. On the side of the diffuser 32 facing away from the opening 34 there is an arrangement of light-emitting diodes 31, which are preferably arranged on a printed circuit board 30. A voltage supply for the light-emitting diodes 31 is not shown in FIG. 2. Instead of the light-emitting diodes 31, backlighting with incandescent lamps, glow lamps or cold cathode fluorescent lamps is possible, for example. That of the

Light diodes 31 generated light strikes the diffuser 32, which scatters the incident light and thus contributes to a homogeneous backlighting of the liquid crystal cell 33. By activating individual segments of the liquid crystal cell 33, an image generation is now possible. Depending on the color of the light emitting diodes 31, different image colors are possible, e.g. with red light-emitting diodes, the picture consists of different red levels, with white light-emitting diodes, the display is shown in gray levels.

The light of the image generated by the liquid crystal cell 33 emerges from the opening 34, runs along the beam path 20 and first strikes the first aspherical mirror 8, as shown in FIG. The first aspheric mirror 8 is on his the side facing the imaging unit 2 is concavely curved and has a focal length which is in a range from 50 mm to 120 mm. In a preferred exemplary embodiment, the first aspherical mirror 8 has a focal length of 90 mm. The first aspherical mirror 8 is, for example, concave in the form of a cutout from a spherical surface, an ellipsoid of revolution or a cylinder surface. The first aspherical mirror 8 is arranged via a holder 21 in the bulge 7 of the cover 6 of the vehicle roof 3. An adjustment of the first aspherical mirror 8 takes place when the display device is installed in the vehicle, the position of the first aspherical play gel 8 in the bulge 7 being adjusted such that an optimal image is displayed on the windshield 1. In an exemplary embodiment not shown in the drawing, however, it is also possible to provide a motor control or a manual adjusting device on the first aspherical mirror 8, which enables re-adjustment. The light shines along the

Beam path 20 directed to the second aspheric mirror 11. The second aspherical mirror 11 is also concave like the first aspherical mirror and has a focal length between 300 mm and 800 mm. In a preferred exemplary embodiment, the focal length is 430 mm. The second aspherical mirror 11 is adjustably mounted so that the mirror can be adjusted by two axes perpendicular to one another in a mirror plane by means of a first motor 12 and a second motor 13. One possible implementation, not shown in the figure, is, for example, to mount the second aspherical mirror 11 on these axes of rotation of the top 10 of the instrument panel and to connect the first motor 12 with one and the second motor 13 with the other axis. By adjusting the second aspherical mirror 11, the Changes the beam path 20, which extends from the second aspherical mirror to the windshield 1. As a result, the position of the virtual image that is visible to a viewer on the windshield 1 can be changed. In this way it is possible, for example, to adapt the position of the image to a driver's sitting position and to his height. For this purpose, the driver can activate the first motor 12 or the second motor 13 via the control element 15, which is connected to the control unit 14, which in turn is connected to the first motor 12 and the second motor 13, and in this way adjusts the second aspherical mirror 11. In addition to the second aspherical mirror 11, a cover flap 17 is arranged, which covers the second aspherical mirror 11 in a first state and releases it in a second state. For this purpose, the cover flap 17 can be folded by the third motor 18, which is also connected to the control unit 14, in a first exemplary embodiment over the second aspherical mirror 11, the cover flap being mounted on an axis. Furthermore, in another exemplary embodiment, it is possible to slide the cover flap 17 over the second aspherical mirror 11 with the aid of the third motor 18.

In particular, the display device is not required when the vehicle is stationary. The control unit 14 is therefore connected to the ignition lock 16. If the car is parked, the third motor 18 is activated and the second aspherical mirror 11 is covered by the cover flap 17. When the car is started again, the control unit 14 detects an actuation of the ignition lock 16 and the third motor is activated, so that the second aspherical mirror 11 is released again by the cover flap 17. The camera 5 is preferably designed as an infrared camera and is used to record an image of the course of the road in poor visibility conditions, for example in the case of fog, and from this an image

To create video information that is forwarded via the data connection 4 to the imaging unit 2 for display on the windshield 1. For this purpose, the camera 5 is preferably arranged in a front area of the vehicle, for example in the area of a radiator grille or a headlight.

FIG. 3 shows a further exemplary embodiment of the display device according to the invention. Here and in the following, the same reference symbols also denote the same elements. The imaging unit 2 is arranged on an inside mirror 40. The inner mirror 40 is in turn connected to a housing 43 via a holder 41. The inside mirror 40, the holder 41 and the housing 43 form an inside mirror module. An electrical connection to the imaging unit 2 runs via the holder 41. The housing 43 is integrated in the vehicle roof 3, preferably in a U-profile, which is present in a large number of vehicles for reasons of bodywork technology and thus offers space for the housing 43 without the housing 43 protruding into the passenger compartment. The first aspherical mirror 8 is arranged on the outside of the housing 43. The inside mirror 40 largely covers the imaging unit 2 from a viewer who is in front of the steering wheel 19. The

Data connection 4 to the imaging unit 2 runs, for example, along the spar 44, which is arranged between the windshield and a side window 46. The second aspherical mirror 11 is rectangular in the exemplary embodiment. In one preferred embodiment is the horizontal

Expansion, i.e. parallel to the windshield, at approximately 250 mm, in an expansion direction perpendicular to the windshield at 90 mm. The first aspherical mirror 8 has an area of 100 mm to 40 mm. The

Cover flap 17 can be folded over the second aspherical mirror 11.

Another exemplary embodiment is shown in FIG. In this exemplary embodiment, a second aspherical mirror 50 is shown. The second aspherical mirror 50 itself is designed to be foldable, with an axis of rotation running along a longitudinal side 52 of the second aspherical mirror 50. A trough 51 is arranged next to the second aspherical mirror 50, into which the second aspherical mirror 50 can be folded. The rear side of the second aspherical mirror, that is to say the side opposite the mirror side, is covered with a plastic, which preferably consists of the same material as the top 10 of FIG

Instrument panel so that the rear of the second aspherical mirror stands out as little as possible from the top 10 of the instrument panel. In this exemplary embodiment, the second aspherical mirror 50 can be adjusted with respect to the position of the virtual image on the windshield 1 about the axis running along the long side 52. Furthermore, this axis can itself be designed to be tiltable perpendicular to its axis direction.

A possible glare for a driver can be avoided by an additional cover, preferably by a cover film arranged on the second aspherical mirror 11 or 50. For this purpose it is possible, for example, to arrange a polarizer film on the second aspherical mirror 11 or 50. Especially when using a Liquid crystal cell or a coherent light source, for example a laser, in the imaging unit 2, the light striking the first aspherical mirror 8 and the second aspherical mirror 11 or 50 is polarized. If a polarizer, which is arranged in such a way that it has an absorption minimum for the light of the image-forming unit 2, is now arranged on the second aspherical mirror 11, 50, only a minimal loss of brightness occurs during the reflection, preferably with an additional anti-reflective layer the polarizer is applied. Ambient light, which generally has a uniform distribution over all polarization directions, is thus at least half absorbed and a possible glare is reduced without the brightness of the virtual image projected onto the windshield 1 being significantly impaired thereby. Furthermore, it is also possible to arrange Venetian blind foils on the second aspherical mirror 11, ie foils that only light incidence or exit in a preferred incidence or. Allow angles of relief, this effect being achieved, for example, by a mask structure integrated into the film. This also greatly reduces the incidence of light from the second aspherical mirror 11, 50 to an observer who is in front of the steering wheel 19.

The control element 15 also serves to adjust the image brightness. This takes place, for example, in that an operating voltage for the light-emitting diodes 31, which are located in the image-forming unit 2, is increased or decreased in order in this way to increase or decrease the brightness of the light-emitting diodes 31. In addition to the above-mentioned embodiment of the imaging unit 2 as a liquid crystal cell 33 with backlighting, it is also possible to use the imaging unit 2 as one Laser display, a micromirror display, a

Vacuum fluorescent display or a plasma display. While the vacuum fluorescent display and the plasma display itself are luminous displays, for which backlighting is unnecessary, the other two embodiments, the laser display and the micromirror display, are preferably a coherent light source, e.g. a laser unit to be arranged in the imaging unit 2. The image is now generated either by controlling the laser unit or by controlling the micromirrors.

The windshield 1 is preferably wedge-shaped in that it is made thicker in an upper area facing the vehicle roof 3 and is in

Tapered toward the top 10 of the instrument panel. The tapering is achieved in that two glass plates, which form the safety glass of the windshield, are not inserted completely in parallel, but are at a greater distance in an upper region of the windshield. When the light emerging from the second aspherical mirror 11, 50 is reflected onto the windshield 1, a reflection occurs on the two glass panes of the windshield 1. Due to the wedge-shaped design, the virtual images created by the reflection lie one above the other for an observer. Windshield vapor deposition, which prevents reflection from a windshield, for example, is no longer necessary.

Claims

Expectations

1. Display device in a motor vehicle with an image-forming unit (2), the image-forming unit (2) being arranged in an area of a vehicle roof (3) or in an upper area of a windshield (1) of the vehicle, with a first aspherical mirror ( 8) and with a second aspherical mirror (11, 50), and wherein light emitted by the imaging unit (2) can be emitted onto the first aspherical mirror (8), the first aspherical mirror (8) in a region of the vehicle roof ( 3, 7), the light from the first aspherical mirror (8) being projectable onto the second aspherical mirror (11, 50), the second aspherical mirror (11, 50) being arranged in a region of an instrument panel of the vehicle and wherein the light from the second aspherical mirror (11) can be projected onto the windshield (1) and a virtual image can be generated on the windshield (1).

2. Display device according to claim 1, characterized in that the second aspherical mirror (11, 50) is arranged such that it can be covered on the instrument panel, preferably on an upper side (10).

3. Display device according to one of the preceding claims, characterized in that the first and / or the second aspherical mirror (8, 11, 50) by at least one motor (12, 13) are motor-adjustable.

4. Display device according to one of the preceding claims, characterized in that an operating element (15) is arranged in the vehicle, that with the operating element (15) the first aspherical mirror (8) and / or the second aspherical mirror (11, 50) and / or an image brightness of the virtual image projected onto the windshield (1) is adjustable.

5. Display device according to one of the preceding claims, characterized in that the first aspherical mirror (8) has a focal length in a range from 50 mm to 120 mm and the second aspherical mirror (11) has a focal length in a range from 300 mm to 800 mm having.

6. Display device according to one of the preceding

Claims, characterized in that the imaging unit (2) is a backlit liquid crystal cell (33) or a laser display or a micromirror display or a vacuum fluorescent display or a plasma display.

7. Display device according to one of the preceding claims, characterized in that the windshield (1) is wedge-shaped.

8. Display device according to one of the preceding

Claims, characterized in that the imaging Unit (2) is arranged on an inside mirror module (40, 41, 43).

9. Display device according to one of the preceding claims, characterized in that the first aspherical mirror (8) is arranged on an inside mirror module (40, 41).

10. Display device according to one of the preceding claims, characterized in that the first aspherical mirror (8) is arranged on a housing (43) on the vehicle roof (3).

11. Display device according to one of the preceding claims, characterized in that a camera (5), preferably an infrared camera, is arranged on the vehicle and an image captured by the camera (5) can be projected as a virtual image onto the windshield (1) ,

12. Display device according to one of the preceding claims, characterized in that the second aspherical mirror (11) is covered with a film and that the film is designed to reduce the visibility of the second aspherical mirror (11).