JPH05201272A - Head-up display for vehicle - Google Patents

Abstract

PURPOSE:To obtain a head-up display for a vehicle capable of optionally changing the magnification of a display image imaged in the distance and having less distortion of a reproduced image. CONSTITUTION:A beam projected as a diffused light from a display information source 5 is first made an actual plane wave with a hologram 3 to be reflectively diffracted, and moreover becomes a divergence spherical surface beam with 9 hologram 2 to be reflectively diffracted in a driver's vision, direction of 6 to be recognized by the driver as a virtual image at a position of 7. Here, the holograms 3 and 2 are curved in a reverse direction.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vehicle head-up display (HUD).

[0002]

2. Description of the Related Art HUD has recently been used as a method of displaying information to a driver in a vehicle. This is a system in which optical information projected from a light emitting display means such as a liquid crystal display device is displayed on a combiner composed of a half mirror or the like so that the driver can read the information from the driving state without moving the line of sight. ..

Recently, as the above combiner, due to its simplicity as an optical element and the abundance of added functions,
The use of holograms has come to the fore. Since this holographic combiner can have not only the reflection function (diffraction function) but also the lens function and so on, it can diffract optical information in the driver's visual field direction, or use other optical systems such as lenses. It is possible to form an image at an arbitrary position without using it. Another feature is that a high-luminance display image can be obtained without impairing the foreground luminance.

FIG. 5 is a conceptual diagram showing the structure of such a vehicle HUD. Here, 31 is a driver's observation position, 32 is a holographic combiner, 33 is a light beam containing information, 34 is an image forming (virtual image) position for distant display, 35 is a transmissive liquid crystal display element as a display, and 36 is A light source including a halogen lamp, 37 is a windshield, 38 is a vehicle body,
39 is a lens.

The light emitted from the light source 36 passes through the transmissive liquid crystal display element 35, is applied to the holographic combiner 32 provided on the windshield 37 of the vehicle, and is reflected (diffracted) to the driver at the observation position 31. To be seen. At this time, the display information is recognized by the driver as a virtual image at the position 34.

[0006]

FIG. 2 shows a conventional hologram recording method for forming a reproduced image of a display device at a distance. A photosensitive material 8 for forming a hologram is irradiated with a reference light 9 which is a divergent spherical wave and an object light 10 which is a divergent spherical wave, respectively, by a single wavelength laser light,
The photosensitive material 8 is exposed. In particular, if the wavelengths of the reproducing light and the exposing light are the same, the center of the divergent spherical wave of the reference light 9 indicates that the photosensitive material 8 is placed parallel to the windshield surface. Should be placed, and the center of the diverging spherical wave of the object light 10 is the position where a distant display should be imaged.

In this case, the size of the display image is such that the distance between the center of the diverging spherical wave of the reference beam 9 and the photosensitive material 8 is f _R and the center of the diverging spherical wave of the object beam 10 at the time of hologram recording. When the distance between the photosensitive material 8 and the photosensitive material 8 is f _O , the magnification M of the display image with respect to the display is M = f _O / f _R.

By the way, as a holographic combiner, it is necessary to make the display as small as possible in order to place the display in an automobile instrument panel near the glass surface, while it is desirable to form a large display image. ..

In the conventional method, when the image forming position (f _O ) and size (M) of the display image are limited, the size of the display and the distance (f _R ) to be placed are uniquely determined. The degree of freedom in setting the position of the display unit in the instrument panel is limited.

Further, in the case where the windshield has a curved surface shape, there is a drawback that the display image is curved when the hologram recorded in a flat shape in FIG. 2 is attached to the windshield surface.

An object of the present invention is to solve the above-mentioned drawbacks of the prior art, and to provide a head-up display for a vehicle, which has not been heretofore known. Is.

[0012]

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and includes a display information source for generating a light beam containing information to be displayed and the light beam diffracted toward the viewer. In a vehicle head-up display including a first hologram for controlling a light beam and a second hologram between the first hologram and the information display source for diffracting the light beam toward the first hologram, the first hologram is a vehicle. Is supported by the windshield of the vehicle and diffracts the light rays so as to form a virtual image on the outside of the windshield of the vehicle, and the second hologram is substantially curved with the curved surface of the windshield of the vehicle. Is held so as to have a curved surface that coincides with the first hologram, and the light beam between the first hologram and the second hologram is substantially a plane wave. It is intended to provide a display.

The information to be displayed here is appropriately selected depending on the display application, and examples thereof include a vehicle speedometer, a tachometer, and a warning light.

The viewer is mainly the driver of the vehicle,
In addition, passengers and other passengers, and all of these can be included.

The hologram functions as a combiner for the HUD. Usually, it has an area of about several 10 mm square to several 100 mm square and a thickness of about several 10 μm, and has a light diffraction function. As this hologram, a Lippmann type is relatively easy to use, but other holograms can be widely used. As the hologram material, various photosensitive materials such as photopolymer and dichromated gelatin can be used.

The peak wavelength of the diffraction intensity of the hologram can be made to substantially match the peak wavelength of the intensity of the light source.
It is preferable for improving the diffraction efficiency. Further, the hologram may be formed by multiple exposure with light having different properties, or may be a stack of a plurality of holograms exposed with different light.

Two kinds of such holograms are used in the present invention, and the hologram (first hologram) for diffracting the information light to one of the viewers is within the natural visual field of the driver as a viewer. It is preferable to arrange it in the vicinity of the windshield of the vehicle, and in particular, from the viewpoint of hologram protection, it is used by being enclosed inside the laminated glass. The other hologram (second hologram) is
It is preferably installed in the vehicle instrument panel or dashboard.

When the first hologram is used by being enclosed in laminated glass, the laminated glass for windshield is obtained by laminating and adhering a synthetic resin film such as polyvinyl butyral film or polyurethane film on at least one glass. And
Examples of the form include glass plate / synthetic resin film, glass plate / synthetic resin film / glass plate, glass plate / synthetic resin film / glass plate / synthetic resin film, glass plate / synthetic resin film / synthetic resin film, etc. There is something. The hologram may be enclosed in the boundary between these glass plates or the synthetic resin film or inside the synthetic resin film. The glass plate on which the hologram is mounted may be colored, or the surface thereof may be provided with a heat ray reflective film or the like.

From the viewpoint of protecting the environment, the second hologram in the instrument panel is preferably laminated on the boundary between the glass plate and the synthetic resin film.

The display information source in the present invention has a function of emitting light to display, and as a typical example, a so-called light-receiving display element such as a liquid crystal display element is used for a hot cathode tube (H).
There is a combined use of a light source including a CT), a fluorescent display tube (VF), a tungsten lamp, a halogen lamp, and an LED.

As the liquid crystal display device, a transmission type twisted nematic type liquid crystal display device, a super twisted nematic type liquid crystal display device and the like can be preferably used.
Alternatively, instead of using the light-receiving display element, the light source itself may be patterned and arranged to generate specific information as light. When the light source is also used for the light receiving display element, an appropriate light guide means such as a light guide plate may be arranged between the light receiving display element and the light source. Further, if necessary, a light polarization means such as a mirror, a prism or a polarization element may be arranged in the light path until the light is projected on the holographic combiner.

In the present invention, the second hologram is held to have a curvature that substantially matches the curvature of the windshield of the vehicle. As a method thereof, a hologram is pasted on a glass plate formed to have the same curved surface as a windshield for a vehicle, and the surface of the hologram is further coated with a moisture resistant film (fluorine resin or the like), or the above. An example is one in which two sheets of molded glass are used and a windshield of a vehicle has a similar laminated structure with an interlayer film such as PVB.

Here, the reflecting surface of the second hologram is the first
The curved surface (convex surface) opposite to the curved surface (concave surface) of the hologram is used.

For this reason, the first hologram is exposed while being held in a planar shape, but the curvature of the reproduced image caused by being held in a curved shape by the curved surface of the windshield of the vehicle during reproduction is caused by the second hologram. The correction is made by bending the hologram in the opposite direction.

[0025]

EXAMPLES Examples will be described below according to the present invention.

FIG. 1 shows a sectional view of the basic structure of the present invention. The windshield fitted in the front opening of the automobile is a laminated glass 1 made of two pieces of glass, and a reflection hologram 2 (first hologram) is enclosed inside the laminated glass 1.

A predetermined information display source 5 and a reflective hologram 3 (second hologram) are installed in the vehicle instrument panel 4 near the glass surface. Here, the second hologram was held so as to have a curved surface substantially the same as that of the laminated glass 1, that is, the same curved surface as the hologram 2, and to be reflected by a convex surface.

The light beam projected as diffused light from the information display source 5 is first converted into a substantially parallel light beam (plane wave) by the hologram 3 and reflected and diffracted, and then from the predetermined opening of the instrument panel 4 to the hologram 2. Proceed towards. Further, the hologram 2 forms a divergent spherical light beam, which is reflected and diffracted in the driver's visual field direction 6 and is recognized by the driver as a virtual image of the display information at the position 7.

The second light diffracts the information to be displayed in this way so that the light beam enters the first hologram as a substantially plane wave.
By arranging the hologram of 1 between the first hologram that diffracts the light beam toward the viewer and the display information source,
The degree of freedom of alignment between the first hologram and the second hologram is increased, and further, regardless of the position of the information display source,
By selecting f _{R of} the second hologram, the magnification of the display image can be arbitrarily changed.

An exposure method for manufacturing such holograms is shown in FIGS. 3 and 4.

First, in order to form the second hologram, as shown in FIG. 3, a divergent spherical wave 12 as reference light is provided on one surface of the photosensitive material 11 held in a planar shape, and an opposite surface of the photosensitive material 11 is provided on the opposite surface. The plane wave 13 as the object light was exposed by the laser light. At this time, the center of the diverging spherical wave 12 and the photosensitive material 11
The distance between and is 200 mm, and the indicator is placed at this distance during playback.

Further, in order to form the first hologram, as shown in FIG. 4, a plane wave 15 as reference light is provided on one surface of the photosensitive material 14 held in a plane shape, and a divergent spherical surface as object light is provided on the opposite surface. Each wave 16 was exposed with laser light of the same wavelength as when the second hologram was made. At this time, the distance between the center of the divergent spherical wave 16 and the photosensitive material 14 is set to 1000 mm, and the viewer is set to 1000 mm from the windshield surface during reproduction.
The reproduced display image can be seen at a distant position.

According to the present embodiment, a vehicle head-up display with little distortion of the reproduced image was obtained.

[0034]

According to the present invention, not only the display image magnification of the holographic combiner which forms a distant image can be arbitrarily changed by the second hologram, but also the alignment of the two kinds of holograms is easy. Furthermore, the degree of freedom of the installation position of the display device is improved. Also, the second
Since the hologram is used while being held at a curvature corresponding to the curvature of the windshield of the automobile, there is an effect of eliminating the curvature aberration of the reproduced image by the first hologram attached to the windshield surface of the vehicle.

[Brief description of drawings]

FIG. 1 is a sectional view showing a basic configuration of the present invention.

FIG. 2 is a conceptual diagram showing a conventional exposure method during hologram production.

FIG. 3 is a conceptual diagram showing an exposure method during hologram production of the present invention.

FIG. 4 is a conceptual diagram showing an exposure method during hologram production of the present invention.

FIG. 5 is a conceptual diagram showing a configuration of a conventional HUD.

[Explanation of symbols]

 1 Laminated glass 2 Hologram (first hologram) 3 Hologram (second hologram) 4 Instrument panel 5 Information display source 6 Driver's field of view 8, 11, 14 Photosensitive material

Claims (1)

[Claims] 1. A display information source that generates a light beam containing information to be displayed, a first hologram that diffracts the light beam toward a viewer, and the light beam that is between the first hologram and the information display source. In a vehicle head-up display including a second hologram that diffracts light toward the first hologram, the first hologram is supported by the windshield of the vehicle and a virtual image is formed on the outside of the windshield of the vehicle. The second hologram is adapted to diffract the light rays so as to form an image, and the second hologram is held so as to have a curved surface that substantially matches the curved surface of the windshield of the vehicle. The vehicle head-up display, wherein the light beam between the second holograms is substantially a plane wave.