JPH0756112A - Stereoscopic picture display device - Google Patents

Abstract

PURPOSE:To provide a stereoscopic picture display device by which many people can simultaneously view a stereoscopic picture, on which the clearer and deeper stereoscopic picture can be observed, and also which can be miniaturized. CONSTITUTION:This device 10 is provided with a light non-transmission panel 12 on which many fine light transmission parts 11 are arranged at specified intervals, and plural picture display panels 14-18 which are arranged on the back part of the panel 12 at the specified intervals, and on which small pictures obtained by viewing an object from slightly different viewpoints in accordance with the positions of the respective parts 11 are displayed. For example, as for the picture display panel 15 arranged on a front part, many light transmission areas 21 transmitting the light emitted from the small picture on the panel 15 arranged on a back part are formed, and also a small picture enlarged in accordance with a distance from the corresponding part 11 is displayed between mutually adjacent transmission areas 21.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a three-dimensional image display device capable of feeling a three-dimensional depth, and more particularly to a three-dimensional image display device capable of displaying an image more clearly.

[0002]

2. Description of the Related Art As a conventional stereoscopic image display device, an anaglyph type using special deflection and shutter glasses, a density difference type, a polarization type or a time division type, a parallax stereogram type, a lenticular type, Large concave mirror type or large convex lens type without glasses, parallax stereo flam type, integral type, multi-lens type such as lenticular type, varifocal mirror type, rotating cylinder type, display area layer type, half mirror Many methods have been proposed, such as a combination method, a depth sampling method such as a display surface vibration method, a hologram reconstructed hologram, a holofraffy method composed of a white light reproduced hologram, and a recently proposed spatial time division method. Attempts are being made.

[0003]

However, even in the above-mentioned conventional methods, there are various problems in reproduction of landscape images, simultaneous observation by a large number of people, viewpoint mobility, focus adjustment, etc., and all of these problems are encountered. It was difficult to solve the problem and display a natural stereoscopic image. Therefore, the applicant of the present application previously proposed a stereoscopic image reproducing device in Japanese Patent Application No. 4-263222. As shown in FIG. 5, the stereoscopic image reproducing apparatus 100 includes a pinhole panel 102 in which a large number of pinholes 101 are arranged at small intervals, and the pinhole panel 1
A large number of small images 103, which are arranged at a predetermined interval on the back of No. 02 and have slightly different viewpoint positions corresponding to the pinhole 101.
Is a device provided with an image display panel 104 on which is displayed. By viewing small images 103 with different viewpoint positions with respect to the object through each pinhole 101, it is possible to change the viewing position within a certain range. A plurality of people can view the stereoscopic image 105 at the same time without using a device such as transparent glasses.

However, in such an apparatus, since the small image 103 has a constant size as shown in FIG. 6, the interval Q ₁ between adjacent pinholes 101 is also constant corresponding to the size of the small image 103. In order to display a clear stereoscopic image, the number of pinholes 101 is increased, the area of the corresponding small image 103 becomes smaller, and the observation visual field of the stereoscopic image becomes narrower. When the position is changed, there is a problem in that the viewing field is limited, such as a so-called jumping area in which a stereoscopic image is not continuously visible is widened, which is not practical. Further, a method of enlarging the display device and observing from a distance can be considered, but in that case, there is a problem that the system is too large and not practical. Further, in the conventional method, the distance between the pinhole and the small image must be relatively small due to the restriction of the resolution of the stereoscopic image and the viewing area, and as a result, the depth of the stereoscopic image is restricted. The angular resolution in the depth direction of the stereoscopic image is determined by the distance between the pinhole and the small image. However, since the pixel size of the display device has a finite size, the smaller the distance between the two, the closer the depth direction of the stereoscopic image becomes. There is a problem that the resolution is lowered and the image is easily blurred. The present invention has been made in view of the above circumstances, and a large number of people can simultaneously view a stereoscopic image, can observe a clearer and deeper stereoscopic image, and can downsize the device. An object is to provide a stereoscopic image display device.

[0005]

A method according to the above-mentioned object.
The stereoscopic image display device described is a non-translucent panel in which a large number of minute light-transmitting parts are arranged at a predetermined interval, and is arranged at a predetermined interval on the back part of the light-not-transmitting panel, and at the positions of the respective minute light-transmitting parts. Correspondingly, a stereoscopic image display device comprising a plurality of image display panels on which small images of the object viewed from slightly different viewpoints are displayed, and the image display panel arranged in the front part. Is formed with a large number of light-transmitting regions that allow light from a small image of the image display panel arranged on the back to pass therethrough, and between the adjacent light-transmitting regions, the light-transmitting regions from the minute light-transmitting parts are formed. A small image enlarged according to the distance is displayed and configured. The stereoscopic image display device according to claim 2 is the stereoscopic image display device according to claim 1, except for a rearmost image display panel of the first image display panel group including the plurality of image display panels. A second image display panel group consisting of a plurality of image display panels arranged at a predetermined interval is arranged on the back portion including the plurality of image display panels, and each small image displayed on the rearmost image display panel of the first image display panel group. The image is divided into a central divided small image at the center position and a plurality of annular divided small images surrounding the central divided small image, and the central divided small image is the backmost part of the second image display panel group. Of the second image display panel group, the annular divided small image is displayed on the image display panel at the back of the second image display panel group in correspondence with the distance from the minute light-transmitting portion. Respectively displayed, and further Light from the annular divided small image and the central divided small image displayed on the back of the center portion of the second image display panel group excluding the backmost portion where the annular divided small image is not displayed Is formed by forming a light-transmitting region that allows light to pass therethrough. A three-dimensional image display device according to a third aspect is the stereoscopic image display device according to the first or second aspect, wherein the three-dimensional image display device is located in an intermediate region of each of the minute light-transmitting parts on the surface of the light-impermeable panel and in the middle of each of the minute light-transmitting parts. A small image corresponding to the virtual minute light-transmitting portion or a central minute area of the virtual small image is displayed, and a composite image composed of a set of the central minute areas is displayed on the surface of the opaque panel. There is. The stereoscopic image display device according to claim 4 is the one according to claim 1,
In the stereoscopic image display device described in 2 or 3, on the back surface of the small image and the divided small image of each image display panel,
A light scattering member is provided so as to be in contact with or close to it. The stereoscopic image display device according to claim 5 is the one according to claim 1,
In the stereoscopic image display device described in item 2, 3 or 4, a small lens is provided in place of each minute light transmitting portion. The stereoscopic image display device according to claim 6 is
In the stereoscopic image display device according to the second aspect of the invention, a translucent region is also formed on the backmost image display panel.
Here, the small image displayed on the image display panel may be an image created by a photographic method or an image created by an electrical method (for example, a liquid crystal display, a plasma display, etc.). Applied. Further, the image created by the electrical method includes an image created by an image pickup device as well as an image created by computer graphics or the like.

[0006]

In the three-dimensional image display device according to any one of claims 1 to 6, each of the image display panels provided with a plurality of image display panels, the image display panel provided in the front part and the image display panel provided in the back part. Since the translucent region that allows the light from the small image to pass therethrough is formed, each small image can be viewed through the minute translucent portion. On the image display panel, a small image or a divided small image of the object viewed from a slightly different viewpoint corresponding to the position of each minute light-transmitting part is displayed as the one on the back is enlarged. When viewed through each minute light-transmitting part, one image is viewed as a whole from one viewpoint (one eye), and when viewed with both eyes, it can be viewed as a stereoscopic image. Then, the small image or the divided small image arranged in the front part is arranged outside the visual field when the small image or the divided small image displayed on the image display panel on the back is viewed through the minute light-transmitting part, Since a small light-transmitting portion corresponding to each of the front and back small images or divided small images is formed, a narrow space can be used in three dimensions and the number of minute light-transmitting portions per unit area can be increased. It is possible to obtain a bright and clear stereoscopic image.

Particularly, in the three-dimensional image display device according to the second aspect, in the three-dimensional image display device according to the first aspect, the rearmost image display of the first image display panel group including the plurality of image display panels is displayed. A second image display panel group including a plurality of image display panels arranged at a predetermined interval is provided on the back portion including the panel except for the panel, and each small image at the backmost portion of the first image display panel group is The image is divided into a plurality of annular divided small images, leaving the central divided small image. The central divided small image is enlarged on the rearmost image display panel of the second image display panel group, and the annular divided small image is enlarged on the other image display panels closer to the center. Since a ring-shaped divided small image of the image display panel excluding the backmost portion is displayed, a transparent region for transmitting light from the divided small image displayed behind is formed in the central portion where it is displayed, It is possible to observe a clear three-dimensional image with higher resolution. In the three-dimensional image display device according to claim 3, a small image corresponding to a virtual minute light-transmitting portion located in the middle of each minute light-transmitting portion in the intermediate region of each minute light-transmitting portion on the surface of the light opaque panel. Since the central small area of the virtual small image is displayed and a composite image composed of a collection of the central small areas is displayed on the surface of the opaque panel, the front surface of the opaque panel is displayed through the small transparent section. Both the viewed stereoscopic image and the composite image displayed on the surface of the opaque panel are viewed at the same time, and a clearer stereoscopic image can be observed as a whole. In the stereoscopic image display device according to claim 4, a light scattering member is provided in contact with or in close proximity to the back surface of each of the small images displayed on each image display panel and the divided small image including the ring and center portions. Therefore, scattered light is generated from the small image and the divided small images by the light emitted from the back or side, and when viewed through the minute light-transmitting part,
You can observe bright and clear stereoscopic images. In the three-dimensional image display device according to the fifth aspect, since the small lenses are provided in place of the respective minute light-transmitting portions, the amount of light increases and a bright three-dimensional image can be obtained. In the stereoscopic image display device according to claim 6, since the rearmost image display panel of the second image display panel group in the stereoscopic image display device according to claim 2 is also formed with a light-transmitting region, A bright stereoscopic image is obtained by efficiently transmitting the light emitted from the back.

[0008]

Embodiments of the present invention will now be described with reference to the accompanying drawings to provide an understanding of the present invention. 1 and 2 are explanatory views of the main structure of a stereoscopic image display apparatus according to the first embodiment of the present invention, and FIGS. 3 and 4 are stereoscopic image display according to the second embodiment of the present invention. It is a principal part exploded perspective view of an apparatus.

As shown in FIG. 1, the stereoscopic image display device 10 according to the first embodiment of the present invention has pinholes 11, which are an example of a minute light transmitting portion, at predetermined small intervals of, for example, several hundreds to several tens of μm. Then, behind the opaque panel 12 arranged vertically and horizontally, five image display panels 14 to 18 made of transparent photographic film or the like in which a large number of small images of the object viewed from slightly different viewpoints are displayed. Are arranged in layers at predetermined intervals. Then, on the back surface of the small image display area of the image display panels 14 to 18, a light diffusing plate 19 which is an example of a light scattering member that scatters light from a light source arranged at the back of the stereoscopic image display device 10.
Is provided. In addition, each image display panel 1
It is free to interpose a transparent spacer between 4 to 18. The light diffusion plate 19 is used for the image display panels 14-1.
8 is used only in the case of a light-transmissive panel that does not emit light such as a photographic film or a liquid crystal panel, and the light source can be arranged not only on the back of the stereoscopic image display device 10 but also on the side thereof.

Further, on the image display panel 14 at the back,
As shown in FIG. 1, a small image 20 (FIG.
Is indicated by a chain line). The image display panel 1
The image display panel 15 arranged at the front of the image display panel 4 has a half distance between the non-translucent panel 12 and the image display panel 14 (that is, L / 2; The image display panel 15 is arranged at a distance from the panel 14).
Includes a small image 2 displayed on the image display panel 14 on the back.
Transparent region 2 for viewing 0 from the corresponding pinhole 11
1 is formed. Another pinhole 22 formed in the middle of the pinhole 11 is formed in the middle of the light transmitting region 21.
Corresponding to the above, a small image 23 (shown by a solid diagonal line in FIG. 2) having a vertical and horizontal size of ½ that is different from the small image 20 in terms of viewing the object is displayed. The small image 23 is a pinhole 1
When viewing the small image 20 from 1, there is no obstacle, and thus the small image 23 and the pinhole 2 for viewing the small image 23 are displayed.
By additionally providing 2, a clearer stereoscopic image can be observed.

Further, image display panels 16 to 18 are sequentially provided between the light opaque panel 12 and the image display panel 15 at intervals of L / 4, L / 8, L / 16, respectively. Corresponding small images are displayed on 16 to 18 based on the same method as the image display panel 15, and pinholes corresponding to the small images are formed on the opaque panel 12, and the image is displayed. Display panel 1
Since 6 to 18 are provided with a light-transmitting region that allows light from a small image displayed on the image display panel on the back to pass therethrough,
By using the opaque panel 12 having a limited size, the number of small images corresponding to pinholes can be dramatically increased, and a clearer stereoscopic image can be observed.

By the way, the image display panel 14 of the embodiment.
In creating the small images displayed in Nos. 18 to 18, the back of the opaque panel in which the pinhole is formed is photographed without applying the photosensitizer to the portion corresponding to the translucent area or shielding the portion from light. Film for the stereoscopic image display device 1
0, a stereoscopic image recording device having substantially the same structure as the stereoscopic image display device 10 arranged in layers corresponding to the distance at which the image display panels 14 to 18 are arranged is used, and a large number of small images corresponding to each pinhole are used. Is photographed on the photographic film.
Since the captured small images are inverted upside down, the small images are inverted and transferred point-symmetrically, and the image display panels 14-18
Create a small image to be displayed on.

The image display panel 1 by an electrical method.
When creating the small images displayed on 4 to 18, the image pickup devices are arranged in layers at positions corresponding to the image display panels 14 to 18. In this case, the image display panel 15-
A portion corresponding to the translucent area of 18 is transparent without an image pickup device for giving light to the image pickup device arranged on the back portion. Then, a video signal whose light quantity is converted into an electric signal and recorded by each image pickup device is output to the stereoscopic image display device 10 to create a small image. In this case, the image display panels 14 to 18 are plasma displays or liquid crystal displays. Create using etc. In addition, the point-symmetrical inverted small images displayed on the image display panels 14 to 18 are
It is also possible to read the small images photographed and recorded on the film of each layer by an image scanner or a TV camera, invert them geometrically in point symmetry by a computer image processing technique or the like, and print out to create.

Next, the stereoscopic image display device 30 according to the second embodiment of the present invention shown in FIGS. 3 and 4 will be described.
The same components as those in the above embodiment are designated by the same reference numerals, and detailed description thereof will be omitted. The stereoscopic image display device 30
In the above, the small image 20 displayed on the rearmost image display panel 14 of the first image display panel group 10a including the image display panels 14 to 18 used in the above-described embodiment.
Are divided and displayed on the second image display panel group 30a including the image display panels 31 to 33. Therefore, the frontmost image display panel 31 of the second image display panel group 30a is arranged in place of the rearmost image display panel 14 of the first image display panel group 10a. When the distance between the image display panel 31 and the opaque panel 12 is L, the image display panel 32 is arranged at a position 2L from the opaque panel 12, and the image display panel 33 is set as the opaque panel 12.
To the 4L position. Then, as shown in FIG. 4, the small image 20 is divided into a ring shape while leaving the small image 20 in the center part, and a central part divided small image 34 and ring-shaped divided small images 35 and 36 are formed. Corresponding to
The images are displayed on the image display panels 33, 32 and 31, respectively.
In the center of the image display panel 31, a translucent area 37 that allows light from the annular split small image 35 and the central split small image 34 to pass therethrough is formed.
A light-transmitting region 38 that allows light from the central divided small image 34 to pass therethrough is formed in the central portion of. As a result, the number of images in the central portion of the small image 20 can be increased, and a sharper stereoscopic image can be observed using a flat image display panel that is easy to manufacture. The method of creating the image display panels 31 to 33 is as follows.
Similar to 8.

In the stereoscopic image display device according to the first and second embodiments, a small image or a virtual small image corresponding to a virtual pinhole located in the middle of each pinhole on the observation side surface of the opaque panel. It is also possible to display the central micro area of the above and display a composite image composed of a set of the central micro areas. As a result, when viewed from the front of the stereoscopic image display device, both the image displayed on the opaque panel and the stereoscopic image viewed through the pinhole are viewed at the same time, resulting in a clear and bright stereoscopic image as a whole. Can be observed.

The present invention is not limited to this embodiment, and changes and modifications within the scope of the invention are included in the present invention. For example, although the number of stacked image display panels is set to 5 or 7 in the embodiment, the number is not limited to this and may be any number. Further, in the embodiment, as described above, the distance of each image display panel from the non-translucent panel was specified, and the size of the translucent area was also specified, but any distance, any size may be used. Good.

In the embodiment, a pinhole panel in which a large number of pinholes are punched in an opaque thin plate is shown as an opaque panel, but a liquid crystal panel or the like may be used. This facilitates the formation of minute light-transmitting parts of the opaque panel,
It is not necessary to perform a highly accurate process of accurately punching a minute light-transmitting portion having a predetermined size at a predetermined position of the light-impermeable panel. Furthermore,
In the embodiment, each small image and divided small image are formed into a quadrangle, but not limited to this, and may have any shape such as a circle or a triangle. Further, in the embodiment, the small image and the divided small image created by the photographic method are illustrated, but the invention is not limited to this. The small image and the divided small image created by the computer graphic method or the like, electromagnetic waves, radiation, magnetism, sound waves, etc. It may be a small image or a divided small image obtained by image-processing the data recorded by. Further, as the image display panel, a panel such as a plasma display or a liquid crystal display which electrically reproduces the light quantity according to the light quantity at the time of recording may be used. By doing so, for example, when changing a stereoscopic image to another stereoscopic image, it is easy to simply input another image signal without changing the small image and the divided small images one by one unlike the photographic method. Can be changed.

[0018]

According to the three-dimensional image display device of the present invention, a plurality of image display panels are provided, and the image display panel arranged at the front part is different from the image display panel arranged at the back part. Since a light-transmitting region that allows light from each of the displayed small images or the central divided small image and the ring-shaped divided small image to pass therethrough is formed, the small images arranged in layers through the minute light-transmitting portion and You can see the split small image,
An extremely clear stereoscopic image can be obtained. Particularly, in the stereoscopic image display device according to claim 2, since the small image of the backmost part in the stereoscopic image display device according to claim 1 is further divided, and the one displayed on the back part is enlarged and displayed. When a single image display panel is used, the disadvantage that the resolution becomes lower in the central portion of the small image is improved, and the number of pixels in the central portion of the small image can be dramatically increased, resulting in a sharper image. You can observe stereoscopic images. In the three-dimensional image display device according to claim 3, a small image corresponding to a virtual minute light-transmitting portion located in the middle of each minute light-transmitting portion or a central minute region of the virtual small image on the observation-side surface of the opaque panel. Is displayed on the surface of the opaque panel, and a composite image composed of a set of the central minute areas is displayed on the surface of the opaque panel. Since both the composite image displayed on the panel surface are viewed at the same time, a clearer stereoscopic image can be observed as a whole. In the stereoscopic image display device according to claim 4, since the light scattering member is provided in contact with or close to the back surface of the small image and the divided small image displayed on each image display panel, the back portion or the side portion. Scattered light is generated from the small image and the divided small images by the light emitted from, and a bright and clear stereoscopic image can be observed by viewing through the minute light-transmitting portion. In the stereoscopic image display device according to claim 5, since the small lenses are provided in place of the respective minute light-transmitting portions, the amount of light increases, and a bright stereoscopic image is obtained. You can see a clear stereoscopic image without getting tired. Further, in the stereoscopic image display device according to the sixth aspect, since the light-transmitting area is also formed in the image display panel at the backmost part, the light emitted from the back part is transmitted and a brighter stereoscopic image is obtained.

[Brief description of drawings]

FIG. 1 is an explanatory view of a main part structure of a stereoscopic image display device according to a first embodiment of the present invention.

FIG. 2 is an explanatory diagram of a main part structure of a stereoscopic image display device according to a first embodiment of the present invention.

FIG. 3 is an explanatory view of a main part structure of a stereoscopic image display device according to a second embodiment of the present invention.

FIG. 4 is an explanatory view of a main part structure of a stereoscopic image display apparatus according to a second embodiment of the present invention.

FIG. 5 is an enlarged cross-sectional view of a main part of the stereoscopic image display device previously proposed by the applicant.

FIG. 6 is an enlarged cross-sectional view of a main part of the stereoscopic image display device previously proposed by the applicant.

[Explanation of symbols]

 10 stereoscopic image display device 11 pinhole (small light-transmitting part) 12 opaque panel 14 image display panel 15 image display panel 16 image display panel 17 image display panel 18 image display panel 19 light diffusion plate (light scattering member) 20 small Image 21 Light transmissive area 22 Pinhole (micro light transmissive part) 23 Micro light transmissive part 30 Stereoscopic image display device 31 Image display panel 32 Image display panel 33 Image display panel 34 Divided small image 35 Divided small image 36 Divided small image 37 Translucent Light window 38 translucent window

Claims (6)

[Claims] 1. A non-translucent panel in which a large number of minute light-transmitting portions are arranged at a predetermined interval, and a back portion of the non-light-transmitting panel is arranged at a predetermined interval, corresponding to the positions of the respective minute light-transmitting portions. A stereoscopic image display device comprising: a plurality of image display panels displaying small images of an object viewed from slightly different viewpoints, wherein the image display panel arranged in the front part is a back part. A large number of light-transmitting regions that allow the light from the small image of the image display panel disposed in the image transmission panel to pass therethrough are formed, and the adjacent light-transmitting regions correspond to the distance from the minute light-transmitting portion. The stereoscopic image display device is characterized in that a small image that has been enlarged is displayed. 2. The stereoscopic image display device according to claim 1, wherein the first image display panel group including the plurality of image display panels except for the rearmost image display panel is provided with a predetermined portion on a back portion including the portion. A second image display panel group including a plurality of image display panels arranged at intervals is arranged, and each small image displayed on the rearmost image display panel of the first image display panel group is at the center position. The image is divided into a certain central divided small image and a plurality of annular divided small images surrounding the central divided small image, and the central divided small image is displayed on the rearmost image display panel of the second image display panel group. The ring-shaped divided small image is displayed closer to the center on the back image display panel of the second image display panel group in an enlarged manner corresponding to the distance from the minute light transmitting portion.
Further, in the center portion of the second image display panel group excluding the backmost portion of the image display panel where the annular split small image is not displayed, the annular split small image and the central split small image displayed on the back are displayed. A three-dimensional image display device, wherein a light-transmitting region for transmitting the light is formed. 3. The stereoscopic image display device according to claim 1, wherein a virtual minute light-transmitting portion positioned in the middle of each minute light-transmitting portion is provided in an intermediate region of each minute light-transmitting portion on the surface of the light-impermeable panel. 3D image display characterized by displaying a small central area of a small image or a virtual small image corresponding to, and displaying a composite image composed of a collection of the central small areas on the surface of the opaque panel. apparatus. 4. The stereoscopic image display device according to claim 1, 2 or 3, wherein a light scattering member is provided in contact with or close to the back surface of the small image and the divided small image of each image display panel. A stereoscopic image display device characterized by being. 5. The three-dimensional image display device according to claim 1, wherein a small lens is provided in place of each of the minute light-transmitting portions. 6. The stereoscopic image display device according to claim 2, wherein a translucent region is also formed on the image display panel at the backmost part.