JPH09292587A - Display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a display device capable of allowing an operator view a clear image at a sufficiently front long distance and which is of compact and of a low cost and is suitable for a head-up display. SOLUTION: A second optical element 4 is confronted with a first optical element 3 at a position nearer to an observer than the translucent first optical element 3 to be arranged in the front side of the observer. An image display light L is emitted from an image display 2 being in a more front side of the observer than the second optical element 4 to the second optical element 4. An virtual image of the object to be observed is formed at the point P being in the front side of the first optical element 3. The optical path (a) from the second optical element 4 to the first optical element 3 of the image display light L emitted from one point of the image display 2 is positioned at an upper side than the optical path (b) from the light emitting point of the image display light L to the second optical element 4 and also a lower side than the optical path (c) from the first optical element 3 to the observer.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display device suitable for use as a head-up display mounted on vehicles such as vehicles and ships.

[0002]

2. Description of the Related Art For example, it has been proposed to use a head-up display as a display device for providing navigation information to a vehicle driver. That is, a driver for displaying an image corresponding to the navigation information and an optical system having a combiner arranged in front of the driver are provided, and the optical path of the image display light emitted from the display is changed by the optical system. By guiding it to the pupil, the virtual image formed in front of the combiner is visually recognized by the driver.

As shown in FIG. 2, a display device 101 constituting a conventional head-up display has an image display light emitted from an image display 103 by a reflecting surface 102a of a combiner 102 arranged in front of an observer. By directly reflecting L and guiding it to the observer's pupil E, a virtual image is formed in front of the combiner 102.

[0004]

When the image forming position of the virtual image of the observation object is close to the driver, it takes time to recognize the virtual image from the state of gazing at the actual scenery in front of the vehicle. It is not preferable for driving. Therefore, in order to quickly recognize the actual scenery and the virtual image in front of the vehicle, it is necessary to set the image formation position of the virtual image to the front of the driver.

However, when the image display light is directly reflected by the combiner 102 as described above, its reflecting surface 1
If a curved surface with a small aberration is used as 02a, the optical path length of the image display light L needs to be lengthened in order to sufficiently form a virtual image in the front distance. Therefore, it is necessary to increase the distance between the combiner 102 and the image display 103. However, since the driver's front space in the vehicle is limited, the combiner 102 and the image display 1
If the distance from the display device 03 is increased, the display device 101 becomes large and it becomes difficult to mount the display device 101 on a vehicle.

If a curved surface with large aberration is used as the reflecting surface 102a, a virtual image can be formed sufficiently in the front distant direction without increasing the optical path length of the image display light L. However, when the aberration of the reflecting surface 102a becomes large, a clear virtual image cannot be formed. Therefore, a complicated lens system for aberration correction is required between the combiner 102 and the image display 103, which increases the manufacturing cost.

An object of the present invention is to provide a display device that can solve the above-mentioned problem.

[0008]

According to the present invention, there is provided a semitransparent first optical element arranged in front of an observer and a position in front of the observer and closer to the observer than the first optical element. , The second optical element arranged so as to face the first optical element, and the image display light can be emitted toward the second optical element at a position further away from the observer than the second optical element. And an image display light emitting means arranged in the
A display device in which the optical path of the image display light is changed by the second optical element and then the optical path of the image display light is changed by the first optical element so as to form a virtual image of the observation object in front of the optical element. The optical path of the image display light emitted from one point from the second optical element to the first optical element is higher than the optical path from the emission point of the image display light to the second optical element,
Further, it is characterized in that it is positioned below the optical path of the image display light from the first optical element to the observer.

According to the structure of the present invention, the image display light is changed in optical path twice before reaching the observer, so that the optical path can be increased without increasing the size of the device as compared with the case where the optical path is changed only once in the combiner. It is possible to form a virtual image of an observation object in the front distant position without increasing the length and using an optical element having a large aberration as an optical element for changing each optical path. Further, the optical path of the image display light emitted from one point of the image display light emitting means from the second optical element to the first optical element is higher than the optical path from the emission point of the image display light to the second optical element, Moreover, since it is located below the optical path of the image display light from the first optical element to the observer, the image display light emitting means can be brought as close as possible to the first optical element. Therefore, the entire device can be downsized. Further, the first optical element and the second
Since the optical element faces the optical element, when the optical path changing surface of the first optical element and the optical path changing surface of the second optical element are curved surfaces, the aberration at the time of changing the optical path of the image display light in the second optical element is reduced. The shape and relative arrangement of both curved surfaces can be determined so as to be smaller due to the aberration at the time of changing the optical path in the first optical element. Thereby, a clearer display virtual image can be formed in front of the observer.

It is preferable that the surface of the image display light emitting means is inclined so as to be directed forward as it goes downward with respect to the vertical plane. Thereby, even if external light such as sunlight from the front of the first optical element is reflected on the surface,
The reflected light can be deflected in a direction that does not go to the second optical element and can be prevented from reaching the observer.

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows a display device 1 constituting a vehicle head-up display, which comprises an optical system and an image display 2. The optical system includes a first optical element 3 that is a semitransparent combiner, and a second optical element 4 that faces the first optical element 3.

The first optical element 3 is arranged in front of an observer (driver) by being mounted on a dashboard or attached to a windshield, for example. As the first optical element 3, for example, a half mirror, a hologram element, a prism or the like can be used. When a half mirror is used, the optical path of light is changed by reflection, when a hologram element is used, the optical path of light is changed by diffraction, and when a prism is used, it is refracted at the entrance surface of the prism and faces the entrance surface. The optical path of light is changed by reflection on the inner surface of the prism. In the present embodiment, the first optical element 3 is composed of a half mirror having a concave curved reflection surface 3a facing backward as an optical path changing surface of the image display light L.

The second optical element 4 is, for example, mounted on the dashboard or incorporated in the dashboard so that it is located closer to the observer than the first optical element 3 in front of the observer. It As the second optical element 4, for example, a total reflection concave mirror, a total reflection plane mirror, a hologram element, a prism or the like can be used. When a total reflection mirror is used, the optical path of light is changed by reflection, when a hologram element is used, the optical path of light is changed by diffraction, and when a prism is used, refraction at the entrance surface of the prism and facing the entrance surface The optical path of the light is changed by the reflection on the inner surface of the prism. In the present embodiment, the second optical element 4 is composed of a total reflection mirror having a concave curved reflection surface 4a facing forward as an optical path changing surface of the image display light L. When the second optical element 4 is built in the dashboard, the opening formed in the dashboard between the first optical element 3 and the second optical element 4 may be covered with a transparent member.

The image display 2 includes the first optical element 3
Below the second optical element 4, for example, by being mounted on the dashboard or incorporated in the dashboard, the first optical element 3 can be moved to a position farther from the observer than the second optical element 4 is. Are placed close to each other. The image display 2 emits image display light L corresponding to, for example, navigation information toward the second optical element 4 thereof. As the image display device 2, for example, a liquid crystal display device having a backlight as a light source can be used, and a display device for displaying an image by a fluorescent display tube, an LED, a cathode ray tube or the like which does not require a light source can also be used. it can. The surface 2a of the image display 2 is inclined so as to move forward as it goes downward with respect to the vertical plane.

The image display light L is changed in its optical path by the first optical element 3 after being changed in its optical path by the second optical element 4, so that the pupil E of the observer is observed together with the light from the front of the first optical element 3. Be led to. Thereby, the first optical element 3
A virtual image of the observation target is formed at a position P in front of, and the observer can visually recognize both the virtual image and an object actually existing in front.

The optical path of the image display light L emitted from one point of the image display 2 to the observer's pupil is uniquely determined, and the image display light L emitted from one point of the image display 2 is determined.
The optical path a from the second optical element 4 to the first optical element 3 of
Positioned above the optical path b from the emission point of the image display light L to the second optical element 4 and below the optical path c of the image display light L from the first optical element 3 to the observer's pupil E. To do.

In the present embodiment, at the reflection points of the image display light L emitted from one point of the image display 2 on the respective reflection surfaces 3a, 4a, the normal line of one reflection surface 3a and the other reflection surface 4a. The reflecting surfaces 3a, 4 are arranged so that they are not parallel to the normal.
The shape and relative arrangement of a are defined.

According to the above configuration, since the image display light L is changed its optical path twice until it reaches the observer's pupil E, the device 1 is different from the case where the optical path is changed only once in the combiner.
It is possible to form the virtual image of the observation object in the front distance without increasing the optical path length and without using optical elements 3 and 4 for changing the optical paths having large aberrations. The optical path a of the image display light L emitted from one point of the image display 2 to the first optical element 3 is from the emission point of the image display light L to the second optical element 4. Since it is located above the optical path b and below the optical path c of the image display light L from the first optical element 3 to the observer's pupil E,
The image display 2 can be brought as close as possible to the first optical element 3. Therefore, the entire device 1 can be downsized.
Furthermore, since the reflecting surface 3a of the first optical element 3 and the reflecting surface 4a of the second optical element 4 face each other, the aberration of the image display light L when the optical path is changed in the second optical element 4 is The shape and relative arrangement of the two reflecting surfaces 3a and 4a can be determined so as to be smaller due to the aberration when the optical path is changed in the first optical element 3. Thereby, a clearer display virtual image can be formed in front of the observer. Therefore, the components of the device 1 can be efficiently arranged, so that the device 1 can be made compact and suitable for installation in a narrow space such as the upper surface of the dashboard in front of the driver or the inside of the vehicle. Further, since a clear virtual image can be formed in front of the observer without using a complicated lens system, the cost can be reduced. Further, since the surface 2a of the image display 2 is inclined so as to be directed forward as it goes downward with respect to the vertical plane, as shown by a chain double-dashed line in FIG. Even if external light L ′ such as sun rays is reflected on the surface 2 a, the reflected light is reflected by the second optical element 4
It is possible to prevent the observer's eyes E from reaching the viewer's eyes E by clearly deflecting the display image.

The present invention is not limited to the above embodiment. For example, when it is not necessary to consider the influence of external light such as sun rays from the outside, the surface of the display unit may be arranged such that the surface of the display unit is a vertical plane or is directed downward as it goes downward with respect to the vertical plane. Further, the shape of the optical path changing surface of the image display light in each optical element is not limited to a concave surface, for example, a convex surface,
The plane may be concave in the vertical direction and convex in the horizontal direction, concave in the horizontal direction and convex in the vertical direction. Further, the present invention can be applied to a display device such as a ship other than an automobile, and the content of the display image is not limited to the navigation information.

[0021]

According to the present invention, it is possible to provide a compact and low-cost display device suitable for a head-up display which allows an operator to visually recognize a clear image sufficiently in the front distance.

[Brief description of drawings]

FIG. 1 is a diagram illustrating a configuration of a display device according to an embodiment of the present invention.

FIG. 2 is an explanatory diagram of a configuration of a conventional display device.

[Explanation of symbols]

 2 image display 3 first optical element 4 second optical element E observer's pupil L image display light

Claims (2)

[Claims] 1. A translucent first arranged in front of an observer.
An optical element, a second optical element arranged in front of the observer and closer to the observer than the first optical element, and a second optical element arranged to face the first optical element, and And an image display light emitting means arranged so as to be capable of emitting image display light toward the second optical element at a position away from the observer in front, and a virtual image of the observation target is provided in front of the first optical element. A display device that changes the optical path of the image display light by the second optical element and then changes the optical path by the first optical element so as to form the second image display light emitted from one point of the image display light emitting means. The optical path from the optical element to the first optical element is higher than the optical path from the emission point of the image display light to the second optical element, and is higher than the optical path of the image display light from the first optical element to the observer. Characterized by being located below Display device. 2. The display device according to claim 1, wherein the surface of the image display light emitting means is inclined so as to face forward with respect to a vertical plane.